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| ? 2000?2011 xilinx, inc. all rights reserved. xilinx, the xilinx logo, the brand window, and other designated brands included h erein are trademarks of xilinx, inc. powerpc is a trademark of ibm corp. and is used under license. all ot her trademarks are the property of their respective owners. ds083 (v5.0) june 21, 2011 www.xilinx.com 1 product specification product not recommended for new designs module 1: introduction and overview 10 pages ? summary of features ? general description ? architecture ? ip core and reference support ? device/package combinations and maximum i/o ? ordering information module 2: functional description 60 pages ? functional description: rocketio? x multi-gigabit transceiver ? functional description: rocketio multi-gigabit transceiver ? functional description: processor block ? functional description: powerpc? 405 core ? functional description: fpga - input/output blocks (iobs) - digitally controlled impedance (dci) - on-chip differential termination - configurable logic blocks (clbs) - 3-state buffers - clb/slice configurations - 18-kb block selectram? resources - 18-bit x 18-bit multipliers - global clock multiplexer buffers - digital clock manager (dcm) ?routing ? configuration module 3: dc and switching characteristics 59 pages ? electrical characteristics ? performance characteristics ? switching characteristics ? pin-to-pin output parameter guidelines ? pin-to-pin input parameter guidelines ? dcm timing parameters ? source-synchronous switching characteristics module 4: pinout information 302 pages ? pin definitions ?pinout tables - fg256/fgg256 wire-bond fine-pitch bga package - fg456/fgg456 wire-bond fine-pitch bga package - fg676/fgg676 wire-bond fine-pitch bga package - ff672 flip-chip fine-pitch bga package - ff896 flip-chip fine-pitch bga package - ff1148 flip-chip fine-pitch bga package - ff1152 flip-chip fine-pitch bga package - ff1517 flip-chip fine-pitch bga package - ff1696 flip-chip fine-pitch bga package - ff1704 flip-chip fine-pitch bga package important note: page, figure, and table numbers begin at 1 for each module, and each module has its own revision history at the end. use the pdf "bookmarks" pane for easy navigation in this volume. 1 virtex-ii pro and virtex-ii pro x platform fpgas: complete data sheet ds083 (v5.0) june 21, 2011 0 product specification r
? 2000?2011 xilinx, inc. all rights reserved. xilinx, the xilinx logo, the brand window, and other designated brands included h erein are trademarks of xilinx, inc. powerpc is a trademark of ibm corp. and is used under license. all ot her trademarks are the property of their respective owners. ds083 (v5.0) june 21, 2011 www.xilinx.com module 1 of 4 product specification 1 product not recommended for new designs summary of virtex-ii pro? / virtex-ii pro x features ? high-performance platform fpga solution, including - up to twenty rocketio? or rocketio x embedded multi-gigabit transceivers (mgts) - up to two ibm powerpc? risc processor blocks ? based on virtex-ii? platform fpga technology - flexible logic resources - sram-based in-system configuration - active interconnect technology - selectram?+ memory hierarchy - dedicated 18-bit x 18 -bit multiplier blocks - high-performance clock management circuitry - selecti/o?-ultra technology - xcite digitally contro lled impedance (dci) i/o virtex-ii pro / virtex-ii pro x family members and resources are shown in ta bl e 1 . rocketio x transceiver features (xc2vpx20 and xc2vpx70 only) ? variable-speed full-duplex transceiver (xc2vpx20) allowing 2.488 gb/s to 6.25 gb/s baud transfer rates. - includes specific baud rates used by various standards, as listed in table 4, module 2 . ? fixed-speed full-duplex tranceiver (xc2vpx70) operating at 4.25 gb/s baud transfer rate. ? eight or twenty transceiver modules on an fpga, depending upon device ? monolithic clock synthesis and clock recovery - eliminates the need for external components ? automatic lock-to-reference function ? programmable serial output differential swing - 200 mv to 1600 mv, peak-peak - allows compatibility with other serial system voltage levels ? programmable pre-emphasis levels 0 to 500% ? telecom/datacom support modes - "x8" and "x10" clocking/data paths - 64b/66b clocking support 1 0 virtex-ii pro and virtex-ii pro x platform fpgas: introduction and overview ds083 (v5.0) june 21, 2011 product specification r ta bl e 1 : virtex-ii pro / virtex-ii pro x fpga family members device (1) rocketio transceiver blocks powerpc processor blocks logic cells (2) clb (1 = 4 slices = max 128 bits) 18 x 18 bit multiplier blocks block selectram+ dcms maximum user i/o pads slices max distr ram (kb) 18 kb blocks max block ram (kb) xc2vp2 4 0 3,168 1,408 44 12 12 216 4 204 xc2vp4 4 1 6,768 3,008 94 28 28 504 4 348 xc2vp7 8 1 11,088 4,928 154 44 44 792 4 396 xc2vp20 8 2 20,880 9,280 290 88 88 1,584 8 564 xc2vpx20 8 (4) 1 22,032 9,792 306 88 88 1,584 8 552 xc2vp30 8 2 30,816 13,696 428 136 136 2,448 8 644 xc2vp40 0 (3) , 8, or 12 2 43,632 19,392 606 192 192 3,456 8 804 xc2vp50 0 (3) or 16 2 53,136 23,616 738 232 232 4,176 8 852 xc2vp70 16 or 20 2 74,448 33,088 1,034 328 328 5,904 8 996 xc2vpx70 20 (4) 2 74,448 33,088 1,034 308 308 5,544 8 992 xc2vp100 0 (3) or 20 2 99,216 44,096 1,378 444 444 7,992 12 1,164 notes: 1. -7 speed grade devices are not available in industrial grade. 2. logic cell ? (1) 4-input lut + (1)ff + carry logic 3. these devices can be ordered in a confi guration without rocketio transceivers. see ta b l e 3 for package configurations. 4. virtex-ii pro x devices equipped with rocketio x transceiver cores. virtex-ii pro and virtex-ii pro x platform fpgas: introduction and overview r ds083 (v5.0) june 21, 2011 www.xilinx.com module 1 of 4 product specification 2 product not recommended for new designs ? programmable receiver equalization ? internal ac coupling ? on-chip 50 ?? termination - eliminates the need for external termination resistors ? pre- and post-driver serial and parallel tx-to-rx internal loopback modes for testing operability ? programmable comma detection - allows for any protocol - allows for detection of any 10-bit character ? 8b/10b and 64b/66b encoding blocks rocketio transceiver features (a ll except xc2v px20 and xc2vpx70) ? full-duplex serial transce iver (serdes) capable of baud rates from 600 mb/s to 3.125 gb/s ? 100 gb/s duplex data rate (20 channels) ? monolithic clock synthesis and clock recovery (cdr) ? fibre channel, 10g fibre channel, gigabit ethernet, 10 gb attachment unit interface (xaui), and infiniband-compliant transceivers ? 8-, 16-, or 32-bit selectable internal fpga interface ? 8b /10b encoder and decoder (optional) ?50 ? /75 ? on-chip selectable transmit and receive terminations ? programmable comma detection ? channel bonding support (from 2 to 20 channels) ? rate matching via insertion/deletion characters ? four levels of selectable pre-emphasis ? five levels of output differential voltage ? per-channel internal loopback modes ? 2.5v transceiver supply voltage powerpc risc processor block features (all except xc2vp2) ? embedded 300+ mhz harvard architecture block ? low power consumption: 0.9 mw/mhz ? five-stage data path pipeline ? hardware multiply/divide unit ? thirty-two 32-bit general purpose registers ? 16 kb two-way set-associative instruction cache ? 16 kb two-way set-associative data cache ? memory management unit (mmu) - 64-entry unified translation look-aside buffers (tlb) - variable page sizes (1 kb to 16 mb) ? dedicated on-chip memory (ocm) interface ? supports ibm coreconnect? bus architecture ? debug and trace support ? timer facilities virtex-ii pro platform fpga technology (all devices) ? selectram+ memory hierarchy - up to 8 mb of true dual-port ram in 18 kb block selectram+ resources - up to 1,378 kb of distributed selectram+ resources - high-performance interfaces to external memory ? arithmetic functions - dedicated 18-bit x 18 -bit multiplier blocks - fast look-ahead carry logic chains ? flexible logic resources - up to 88,192 internal registers/latches with clock enable - up to 88,192 look-up tables (luts) or cascadable variable (1 to 16 bits) shift registers - wide multiplexers and wide-input function support - horizontal cascade chain and sum-of-products support - internal 3-state busing ? high-performance clock management circuitry - up to twelve digital clock manager (dcm) modules precise clock de-skew flexible frequency synthesis high-resolution phase shifting - 16 global clock multiplexer buffers in all parts ? active interconnect technology - fourth-generation segmented routing structure - fast, predictable routing delay, independent of fanout - deep sub-micron noise immunity benefits ? selectio?-ultra technology - up to 1,164 user i/os - twenty-two single-ended standards and ten differential standards - programmable lvcmos sink/source current (2 ma to 24 ma) per i/o - xcite digitally contro lled impedance (dci) i/o - pci/ pci-x support (1) - differential signaling 840 mb/s low-voltage differential signaling i/o (lvds) with current mode drivers on-chip differential termination bus lvds i/o 1. refer to xapp653 for more information. virtex-ii pro and virtex-ii pro x platform fpgas: introduction and overview r ds083 (v5.0) june 21, 2011 www.xilinx.com module 1 of 4 product specification 3 product not recommended for new designs hypertransport (ldt) i/o with current driver buffers built-in ddr input and output registers - proprietary high-performance selectlink technology for communic ations between xilinx devices high-bandwidth data path double data rate (ddr) link web-based hdl generation methodology ? sram-based in-system configuration - fast selectmap? configuration - triple data encryption standard (des) security option (bitstream encryption) - ieee 1532 support - partial reconfiguration - unlimited reprogrammability - readback capability ? supported by xilinx foundation? and alliance series? development systems - integrated vhdl and verilog design flows - chipscope? integrated logic analyzer ? 0.13 m nine-layer copper process with 90 nm high-speed transistors ?1.5v (v ccint ) core power supply, dedicated 2.5v v ccaux auxiliary and v cco i/o power supplies ? ieee 1149.1 compatible boundary-scan logic support ? flip-chip and wire-bond ball grid array (bga) packages in standard 1.00 mm pitch. ? wire-bond bga devices available in pb-free packaging ( www.xilinx.com/pbfree) ? each device 100% factory tested general description the virtex-ii pro and virtex-ii pro x families contain plat- form fpgas for designs that are based on ip cores and customized modules. the family incorporates multi-gigabit transceivers and powerpc cpu blocks in virtex-ii pro series fpga architecture. it empowers complete solutions for telecommunication, wireless, networking, video, and dsp applications. the leading-edge 0.13 m cmos nine-layer copper pro- cess and virtex-ii pro architecture are optimized for high performance designs in a wide range of densities. combin- ing a wide variety of flexible features and ip cores, the virtex-ii pro family enhances programmable logic design capabilities and is a powerful alternative to mask-pro- grammed gate arrays. architecture array overview virtex-ii pro and virtex-ii pro x devices are user-program- mable gate arrays with various configurable elements and embedded blocks optimized for high-density and high-per- formance system designs. virtex-ii pro devices implement the following functionality: ? embedded high-speed serial transceivers enable data bit rate up to 3.125 gb/s per channel (rocketio) or 6.25 gb/s (rocketio x). ? embedded ibm powerpc 405 risc processor blocks provide performance up to 400 mhz. ? selectio-ultra blocks provide the interface between package pins and the internal configurable logic. most popular and leading-edge i/o standards are supported by the programmable iobs. ? configurable logic blocks (clbs) provide functional elements for combinatorial and synchronous logic, including basic storage elements. bufts (3-state buffers) associated with each clb element drive dedicated segmentable horizontal routing resources. ? block selectram+ memory modules provide large 18 kb storage elements of true dual-port ram. ? embedded multiplier blocks are 18-bit x 18-bit dedicated multipliers. ? digital clock manager (dcm) blocks provide self-calibrating, fully digital solutions for clock distribution delay compensation, clock multiplication and division, and coarse- and fine-grained clock phase shifting. a new generation of programmable routing resources called active interconnect technology interconnects all these ele- ments. the general routing matrix (grm) is an array of rout- ing switches. each programmable element is tied to a switch matrix, allowing multip le connections to the general routing matrix. the overall programmable interconnection is hierarchical and supports high-speed designs. all programmable elements, including the routing resources, are controlled by values stored in static memory cells. these values are loaded in the memory cells during configuration and can be reloaded to change the functions of the programmable elements. features this section briefly describes virtex-ii pro / virtex-ii pro x features. for more details, refer to virtex-ii pro and virtex-ii pro x platform fpgas: functional description . rocketio / rocketio x mgt cores the rocketio and rocketio x multi-gigabit transceivers are flexible parallel-to-serial and serial-to-parallel embed- ded transceiver cores used for high-bandwidth interconnec- tion between buses, backpl anes, or other subsystems. multiple user instantiations in an fpga are possible, providing up to 100 gb/s (rocketio) or 170 gb/s (rocketio x) of full-duplex raw data transfer. each channel can be operated at a maximum data transfer rate of 3.125 gb/s (rocketio) or 6.25 gb/s (rocketio x). virtex-ii pro and virtex-ii pro x platform fpgas: introduction and overview r ds083 (v5.0) june 21, 2011 www.xilinx.com module 1 of 4 product specification 4 product not recommended for new designs each rocketio or rocketio x core implements the following technology: ? serializer and deserializer (serdes) ? monolithic clock synthesis and clock recovery (cdr) ? 10 gigabit attachment unit interface (xaui) fibre channel (3.1875 gb/s xaui), infiniband, pci express, aurora, sxi-5 (sfi-5,/spi-5), and oc-48 compatibility (1) ? 8/16/32-bit (rocketio) or 8/16/32/64-bit (rocketio x) selectable fpga interface ? 8b/10b (rocketio) or 8b/10b and 64b/66b (rocketio x) encoder and decoder with bypassing option on each channel ? channel bonding support (two to twenty channels) - elastic buffers for inter-chip deskewing and channel-to-channel alignment ? receiver clock recovery tolerance of up to 75 non-transitioning bits ?50 ? (rocketio x) or 50 ? /75 ? selectable (rocketio) on-chip transmit and receive terminations ? programmable comma detection and word alignment ? rate matching via insertion/deletion characters ? automatic lock-to-reference function ? programmable pre-emphasis support ? per-channel serial and parallel transmitter-to-receiver internal loopback modes ? optional transmit and receive data inversion ? cyclic redundancy check support (rocketio only) powerpc 405 processor block the ppc405 risc cpu can execute instructions at a sus- tained rate of one instruction per cycle. on-chip instruction and data cache reduce design complexity and improve sys- tem throughput. the ppc405 features include: ? powerpc risc cpu - implements the powerpc user instruction set architecture (uisa) and extensions for embedded applications - thirty-two 32-bit general purpose registers (gprs) - static branch prediction - five-stage pipeline with single-cycle execution of most instructions, in cluding loads/stores - unaligned and aligned load/store support to cache, main memory, and on-chip memory - hardware multiply/divid e for faster integer arithmetic (4-cycle mu ltiply, 35-cycle divide) - enhanced string and multiple-word handling - big/little endian operation support ?storage control - separate instruction and data cache units, both two-way set-associative and non-blocking - eight words (32 bytes) per cache line - 16 kb array instruction cache unit (icu), 16 kb array data cache unit (dcu) - operand forwarding during instruction cache line fill - copy-back or write-through dcu strategy - doubleword instruction fetch from cache improves branch latency ? virtual mode memory management unit (mmu) - translation of the 4 gb logical address space into physical addresses - software control of page replacement strategy - supports multiple simultaneous page sizes ranging from 1 kb to 16 mb ? ocm controllers provide dedicated interfaces between block selectram+ memory and processor block instruction and data paths for high-speed access ? powerpc timer facilities - 64-bit time base - programmable interval timer (pit) - fixed interval timer (fit) - watchdog timer (wdt) ? debug support - internal debug mode - external debug mode - debug wait mode - real time trace debug mode - enhanced debug support with logical operators - instruction trace and trace-back support - forward or backward trace ? two hardware interrupt levels support ? advanced power management support input/output blocks (iobs) iobs are programmable and can be categorized as follows: ? input block with an optional single data rate (sdr) or double data rate (ddr) register ? output block with an optional sdr or ddr register and an optional 3-state buffer to be driven directly or through an sdr or ddr register ? bidirectional block (any combination of input and output configurations) these registers are either edge-triggered d-type flip-flops or level-sensitive latches. iobs support the following single-ended i/o standards: ? lvttl, lvcmos (3.3v, (2) 2.5v, 1.8v, and 1.5v) ? pci-x compatible (133 mhz and 66 mhz) at 3.3v (3) ? pci compliant (66 mhz and 33 mhz) at 3.3v (3) ? gtl and gtlp 1. refer to table 4, module 2 for detailed information about rocketio and rocketio x transceiver compatible protocols. 2. refer to xapp659 for more information. 3. refer to xapp653 for more information. virtex-ii pro and virtex-ii pro x platform fpgas: introduction and overview r ds083 (v5.0) june 21, 2011 www.xilinx.com module 1 of 4 product specification 5 product not recommended for new designs ? hstl (1.5v and 1.8v, class i, ii, iii, and iv) ? sstl (1.8v and 2.5v, class i and ii) the dci i/o feature automatically provides on-chip termina- tion for each single-ended i/o standard. the iob elements also support the following differential sig- naling i/o standards: ? lvds and extended lvds (2.5v) ? b lv d s ( b u s lv d s ) ?ulvds ?ldt ? lvpecl (2.5v) two adjacent pads are used for each differential pair. two or four iobs connect to one switch matrix to access the routing resources. on-chip differential termination is available for lv d s, lv d s extended, ulvds, and ldt standards. configurable logic blocks (clbs) clb resources include four slices and two 3-state buffers. each slice is equivalent and contains: ? two function generators (f & g) ? two storage elements ? arithmetic logic gates ? large multiplexers ? wide function capability ? fast carry look-ahead chain ? horizontal cascade chain (or gate) the function generators f & g are configurable as 4-input look-up tables (luts), as 16-bit shift registers, or as 16-bit distributed selectram+ memory. in addition, the two storage elements are either edge-triggered d-type flip-flops or level-sensitive latches. each clb has internal fast interconnect and connects to a switch matrix to access general routing resources. block selectram+ memory the block selectram+ memory resources are 18 kb of true dual-port ram, programmable from 16k x 1 bit to 512 x 36 bit, in various depth and width configurations. each port is totally synchronous and independent, offering three "read-during-write" modes. block selectram+ mem- ory is cascadable to implement large embedded storage blocks. supported memory configurations for dual-port and single-port modes are shown in ta bl e 2 . 18 x 18 bit multipliers a multiplier block is associ ated with each selectram+ memory block. the multip lier block is a dedicated 18 x 18-bit 2s complement signed multiplier, and is opti- mized for operations based on the block selectram+ con- tent on one port. the 18 x 18 multiplier can be used independently of the block selectram+ resource. read/multiply/accumulate operations and dsp filter struc- tures are extremely efficient. both the selectram+ memory and the multiplier resource are connected to four switch matrices to access the general routing resources. global clocking the dcm and global clock multiplexer buffers provide a complete solution for designing high-speed clock schemes. up to twelve dcm blocks are available. to generate deskewed internal or external clocks, each dcm can be used to eliminate clock distribution delay. the dcm also provides 90-, 180-, and 270-degree phase-shifted versions of its output clocks. fine-grained phase shifting offers high-resolution phase adjustments in increments of 1 / 256 of the clock period. very flexible frequency synthesis provides a clock output frequency equal to a fractional or integer mul- tiple of the input clock frequency. for exact timing parame- ters, see virtex-ii pro and virtex-ii pro x platform fpgas: dc and switching characteristics . virtex-ii pro devices have 16 global clock mux buffers, with up to eight clock nets per quadrant. each clock mux buffer can select one of the two clock inputs and switch glitch-free from one clock to the other. each dcm can send up to four of its clock outputs to global clock buffers on the same edge. any global clock pin can drive any dcm on the same edge. routing resources the iob, clb, block selectra m+, multiplier, and dcm ele- ments all use the same interconnect scheme and the same access to the global routing matrix. timing models are shared, greatly improving the predictability of the perfor- mance of high-speed designs. there are a total of 16 global clock lines, with eight available per quadrant. in addition, 24 vertical and horizontal long lines per row or column, as well as massive secondary and local routing resources, pr ovide fast interconnect. virtex-ii pro buffered interconnects are relatively unaffected by net fanout, and the interconnect layout is designed to minimize crosstalk. horizontal and vertical routing resources for each row or column include: ? 24 long lines ? 120 hex lines ? 40 double lines ? 16 direct connect lines (total in all four directions) boundary scan boundary-scan instructions and associated data registers support a standard methodology for accessing and config- uring virtex-ii pro devices, complying with ieee standards 1149.1 and 1532. a system mode and a test mode are ta bl e 2 : dual-port and single-port configurations 16k x 1 bit 4k x 4 bits 1k x 18 bits 8k x 2 bits 2k x 9 bits 512 x 36 bits virtex-ii pro and virtex-ii pro x platform fpgas: introduction and overview r ds083 (v5.0) june 21, 2011 www.xilinx.com module 1 of 4 product specification 6 product not recommended for new designs implemented. in s ystem mode, a virtex-ii pro device will continue to function while executing non-test bound- ary-scan instructions. in test mode, boundary-scan test instructions control the i/o pins for testing purposes. the virtex-ii pro test access port (tap) supports bypass, preload, sample, idcode , and usercode non-test instructions. the extest, intest, and highz test instruc- tions are also supported. configuration virtex-ii pro / virtex-ii pro devices are configured by load- ing the bitstream into internal configuration memory using one of the following modes: ? slave-serial mode ? master-serial mode ? slave selectmap mode ? master selectmap mode ? boundary-scan mode (ieee 1532) a data encryption standard (des) decryptor is available on-chip to secure the bitstreams. one or two triple-des key sets can be used to optionally encrypt the configuration data. the xilinx system advanced configuration enviornment (system ace) family offers high-capacity and flexible solu- tion for fpga configuration as well as program/data storage for the processor. see ds080 , system ace compactflash solution for more information. readback and integrated logic analyzer configuration data stored in virtex-ii pro / virtex-ii pro con- figuration memory can be read back for verification. along with the configuration data, the contents of all flip-flops and latches, distributed selectram+, and block selectram+ memory resources can be read back. this capability is use- ful for real-time debugging. the xilinx chipscope integrated logic analyzer (ila) cores and integrated bus analyzer (iba) cores, along with the chipscope pro analyzer software, provide a complete solu- tion for accessing and verifying user designs within virtex-ii pro devices. ip core and reference support intellectual property is part of the platform fpga solution. in addition to the existing fpga fabric cores, the list below shows some of the currently available hardware and soft- ware intellectual propertie s specially developed for virtex-ii pro / virtex-ii pro x by xilinx. each ip core is mod- ular, portable, real-time operating system (rtos) inde- pendent, and coreconnect compatible for ease of design migration. refer to www.xilinx.com/ipcenter for the latest and most complete list of cores. hardware cores ? bus infrastructure cores (arbiters, bridges, and more) ? memory cores (ddr, flash, and more) ? peripheral cores (uart, iic, and more) ? networking cores (atm, ethernet, and more) software cores ? boot code ?test code ? device drivers ? protocol stacks ? rtos integration ? customized board support package virtex-ii pro and virtex-ii pro x platform fpgas: introduction and overview r ds083 (v5.0) june 21, 2011 www.xilinx.com module 1 of 4 product specification 7 product not recommended for new designs virtex-ii pro / virtex-ii pro x device/p ackage combinations and maximum i/os offerings include ball grid array (bga) packages with 1.0 mm pitch. in addition to traditional wire-bond intercon- nect (fg/fgg packages), flip-chip interconnect (ff pack- ages) is used in some of the bga offerings. flip-chip interconnect construction supports more i/os than are pos- sible in wire-bond versions of similar packages, providing a high pin count and excellent power dissipation. the device/package combination table ( ta b l e 3 ) details the maximum number of user i/os and rocketio / rocketio x mgts for each device and package using wire-bond or flip-chip technology. the ff1148 and ff1696 packages have no rocketio transceivers bonded out. extra selectio-ultra resources occupy available pins in these packages, resulting in a higher user i/o count. these packages are available for the xc2vp40, xc2vp50, and xc2vp100 devices only. the i/os per package count includes all user i/os except the 15 control pins (cclk, done, m0, m1, m2, prog_b, pwrdwn_b, tck, tdi, tdo, tms, hswap_en, dxn, dxp, and rsvd), vbatt, and the rocketio / rocketio x transceiver pins. maximum performance maximum performance of the rocketio / rocketio x transceiver and the powerpc processor block varies, depending on package style and speed grade. see ta bl e 4 for details. virtex-ii pro and virtex-ii pro x platform fpgas: dc and switching characteristics contains the rest of the fpga fabric performance parameters. ta bl e 3 : virtex-ii pro device/package combinations and maximum number of available i/os package (1) fg256/ fgg256 fg456/ fgg456 fg676 ff672 ff896 ff115 2 ff1148 ff1517 ff1704 ff1696 pitch (mm) 1.00 1.00 1.00 1.00 1.00 1.00 1.00 1.00 1.00 1.00 size (mm) 17 x 17 23 x 23 26 x 26 27 x 27 31 x 31 35 x 35 35 x 35 40 x 40 42.5 x 42.5 42.5 x 42.5 xc2vp2 140 / 4 156 / 4 204 / 4 xc2vp4 140 / 4 248 / 4 348 / 4 xc2vp7 248 / 8 396 / 8 396 / 8 xc2vp20 404 / 8 556 / 8 564 / 8 xc2vpx20 552 / 8 (2) xc2vp30 416 / 8 556 / 8 644 / 8 xc2vp40 416 / 8 692 / 12 804 / 0 (3) xc2vp50 692 / 16 812 / 0 (3) 852 / 16 xc2vp70 964/16 996/20 xc2vpx70 992 / 20 (2) xc2vp100 1,040 / 20 1,164 / 0 (3) notes: 1. wirebond packages fg256, fg456, and fg676 are also availabl e in pb-free versions fgg2 56, fgg456, and fgg676. see virtex-ii pro ordering examples for details on how to order. 2. virtex-ii pro x device is equipped with rocketio x transceiver cores. 3. the rocketio transceivers in devices in the ff1148 and ff1696 packages are not bonded out to the package pins. ta bl e 4 : maximum rocketio / rocketio x transceiver and processor block performance device speed grade units -7 (1) -6 -5 rocketio x transceiver flipchip (ff) n/a 6.25 (3) 4.25 (3) gb/s rocketio transceiver flipchip (ff) 3.125 3.125 2.0 gb/s rocketio transceiver wirebond (fg) 2.5 2.5 2.0 gb/s powerpc processor block 400 (2) 350 (2) 300 mhz notes: 1. -7 speed grade devices are not available in industrial grade. 2. important! when cpmc405clock runs at speeds greater than 350 mhz in -7 commercial grade dual-processor devices, or greater than 300 mhz in -6 industrial grade dual-processor devices, users must implement the technology presented in xapp755 , ?powerpc 405 clock macro for -7(c) and -6(i) speed grade dual-processor devices.? refer to ta b l e 1 to identify dual-processor devices. 3. xc2vpx70 is only available at fixed 4.25 gb/s baud rate. virtex-ii pro and virtex-ii pro x platform fpgas: introduction and overview r ds083 (v5.0) june 21, 2011 www.xilinx.com module 1 of 4 product specification 8 product not recommended for new designs virtex-ii pro ordering examples virtex-ii pro ordering examples are shown in figure 1 (flip-chip package) and figure 2 (pb-free wire-bond package). virtex-ii pro x ordering example a virtex-ii pro x ordering example is shown in figure 3 . figure 1: virtex-ii pro ordering example, flip-chip package figure 2: virtex-ii pro ordering example, pb-free wire-bond package figure 3: virtex-ii pro x ordering example, flip-chip package example: xc2vp40 -7 ff 1152 c device type temperature range: c = commercial (tj = 0?c to +85?c) i = industrial* (tj = ?40?c to +100?c) number of pins package type speed grade (-5, -6, -7*) ds083_02_062104 *note: -7 devices not available in industrial grade. example: xc2vp40 -6 fg g 676 i device type temperature range: c = commercial (tj = 0?c to +85?c) i = industrial* (tj = ?40?c to +100?c) number of pins package type pb-free speed grade (-5, -6, -7*) ds083-1_02b_062104 *note: -7 devices not available in industrial grade. example: xc2vpx20 -6 ff 8 96 c device type temper a t u re r a nge: c = commerci a l (tj = 0c to + 8 5c) i = ind us tri a l * (tj = ?40c to +100c) n u m b er of pin s p a ck a ge type s peed gr a de (-5, -6) d s 0 83 _02 a _092705 virtex-ii pro and virtex-ii pro x platform fpgas: introduction and overview r ds083 (v5.0) june 21, 2011 www.xilinx.com module 1 of 4 product specification 9 product not recommended for new designs revision history this section records the change history for this module of the data sheet. date version revision 01/31/02 1.0 initial xilinx release. 06/13/02 2.0 new virtex-ii pro family members. new timing parameters per speedsfile v1.62 . 09/03/02 2.1 updates to ta b l e 1 and ta b l e 3 . processor block information added to ta b l e 4 . 09/27/02 2.2 in ta bl e 1 , correct max number of xc2vp30 i/os to 644. 11/20/02 2.3 add bullet items for 3.3v i/o features. 01/20/03 2.4 ?in ta b l e 3 , add fg676 package option for xc2vp20, xc2vp30, and xc2vp40. ? remove ff1517 package option for xc2vp40. 03/24/03 2.4.1 ? correct number of single-ended i/o standards from 19 to 22. ? correct minimum rocketio serial speed from 622 mbps to 600 mbps. 08/25/03 2.4.2 ? add footnote referring to xapp659 to callo ut for 3.3v i/o standards on page 4. 12/10/03 3.0 ? xc2vp2 through xc2vp70 speed grades -5, -6, and -7, and xc2vp100 speed grades -5 and -6, are released to production status . 02/19/04 3.1 ? ta b l e 1 : corrected number of rocketio transceiver blocks for xc2vp40. ? section virtex-ii pro platform fpga technology (all devices) : updated number of differential standards supported from six to ten. ? section input/output blocks (iobs) : added text stating that differential termination is available for lvds, lv d s extended, ulvds, and ldt standards. ? figure 1 : added note stating that -7 devices are not available in industrial grade. 03/09/04 3.1.1 ? recompiled for back ward compatibility with acrobat 4 and above. no content changes. 06/30/04 4.0 merged in ds110-1 (module 1 of virtex-ii pro x data sheet). added information on available pb-free packages. 11/17/04 4.1 no changes in module 1 for this revision. 03/01/05 4.2 ta b l e 3 : corrected number of rocketio transceivers for xc2vp7-fg456. 06/20/05 4.3 no changes in module 1 for this revision. 09/15/05 4.4 ? changed all instances of 10.3125 gb/s (rocketio transceiver maximum bit rate) to 6.25 gb/s. ? changed all instances of 412.5 gb/s (rocketio x transceiver maximum multi-channel raw data transfer rate) to 250 gb/s. 10/10/05 4.5 ? changed xc2vpx70 variable baud rate specification to fixed-rate operation at 4.25 gb/s. ? changed maximum performance for -7 virtex-ii pro x mgt ( ta b l e 4 ) to n/a. 03/05/07 4.6 no changes in module 1 for this revision. 11/05/07 4.7 updated copyright notice and legal disclaimer. 06/21/11 5.0 added product not recommended for new designs banner. virtex-ii pro and virtex-ii pro x platform fpgas: introduction and overview r ds083 (v5.0) june 21, 2011 www.xilinx.com module 1 of 4 product specification 10 product not recommended for new designs notice of disclaimer the xilinx hardware fpga and cpld devices referred to herein (?products?) are subject to the terms and conditions of the xilinx limite d warranty which can be viewed at http://www.xilinx.com/warranty.htm . this limited warranty does not extend to any use of products in an application or environment that is not within the specifications stated in the xilinx data sheet. all specifications are subject to change without notice. products are not designed or intended to be fail-safe or for use in any application requiring fail-safe performance, such as life-support or safety devic es or systems, or any other application that invokes the potential risks of death, personal injury, or property or environmental damage (?critical applications?). use of products in critical applications is at the sole risk of customer, subject to applicable laws and regulations. virtex-ii pro data sheet the virtex-ii pro data sheet contains the following modules: ? virtex-ii pro and virtex-ii pro x platform fpgas: introduction and overview (module 1) ? virtex-ii pro and virtex-ii pro x platform fpgas: functional description (module 2) ? virtex-ii pro and virtex-ii pro x platform fpgas: dc and switching characteristics (module 3) ? virtex-ii pro and virtex-ii pro x platform fpgas: pinout information (module 4) ? 2000?2011 xilinx, inc. all rights reserved. xilinx, the xilinx logo, the brand window, and other designated brands included h erein are trademarks of xilinx, inc. powerpc is a trademark of ibm corp. and is used under license. all ot her trademarks are the property of their respective owners. ds083 (v5.0) june 21, 2011 www.xilinx.com module 2 of 4 product specification 1 product not recommended for new designs virtex-ii pro (1) array functional description this module describes the following virtex?-ii pro func- tional components, as shown in figure 1 : ? embedded rocketio? (up to 3.125 gb/s) or rocketio x (up to 6.25 gb/s) multi-gigabit transceivers (mgts) ? processor blocks with embedded ibm powerpc? 405 risc cpu core (ppc405) and integration circuitry. ? fpga fabric based on virtex-ii architecture. virtex-ii pro user guides virtex-ii pro user guides cover theory of operation in more detail, and include implementa tion details, primitives and attributes, command/instruction sets, and many hdl code examples where appropriate. all parameter specifications are given only in module 3 of this data sheet. these user guides are available: ? for detailed descriptions of ppc405 embedded core programming models and internal core operations, see powerpc processor reference guide and powerpc 405 processor block reference guide . ? for detailed rocketio transceiver digital/analog design considerations, see rocketio transceiver user guide . ? for detailed rocketio x transceiver digital/analog design considerations, see rocketio x transceiver user guide , ? for detailed descriptions of the fpga fabric (clb, iob, dcm, etc.), see virtex-ii pro platform fpga user guide . all of the documents above, as well as a complete listing and description of xilinx-deve loped intellectual property cores for virtex-ii pro, are available on the xilinx website. contents of this module ? functional description: rocketio x multi-gigabit transceiver (mgt) ? functional description: rocketio multi-gigabit transceiver (mgt) ? functional description: processor block ? functional description: embedded powerpc 405 core ? functional description: fpga ? revision history virtex-ii pro compared to virtex-ii devices virtex-ii pro devices are built on the virtex-ii fpga archi- tecture. most fpga features are identical to virtex-ii devices. major differences are described below: ? the virtex-ii pro fpga family is the first to incorporate embedded ppc405 and rocketio/rocketio x cores. ?v ccaux , the auxiliary supply volt age, is 2.5v instead of 3.3v as for virtex-ii devices. advanced processing at 0.13 ? m has resulted in a smaller die, faster speed, and lower power consumption. ? virtex-ii pro devices are neither bitstream-compatible nor pin-compatible with virtex-ii devices. however, virtex-ii designs can be compiled into virtex-ii pro devices. ? on-chip input lvds different ial termination is available. ? sstl3, agp-2x/agp, lvpecl_33, lvds_33, and lvdsext_33 standards are not supported. ? the open-drain output pin tdo does not have an internal pull-up resistor. 6 0 virtex-ii pro and virtex-ii pro x platform fpgas: functional description ds083 (v5.0) june 21, 2011 product specification 1. unless otherwise noted, "virtex-ii pro" refers to members of the virtex-ii pro and/or virtex-ii pro x families. r figure 1: virtex-ii pro generic architecture overview clb multipliers and block selectram processor block configurable logic selectio-ultra ds083-1_01_050304 dcm rocketio or rocketio x multi-gigabit transceiver clb clb clb virtex-ii pro and virtex-ii pro x platform fpgas: functional description r ds083 (v5.0) june 21, 2011 www.xilinx.com module 2 of 4 product specification 2 product not recommended for new designs functional description: rocketio x multi-gigabit transceiver (mgt) this section summarizes the features of the rocketio x multi-gigabit transceiver. for an in-depth discussion of the rocketio x mgt, including digital and analog design con- siderations, refer to the rocketio x transceiver user guide. rocketio x overview either eight or twenty rocketio x mgts are available on the xc2vpx20 and xc2vpx70 devices, respectively. the xc2vpx20 mgt is designed to op erate at any baud rate in the range of 2.488 gb/s to 6.25 gb/s per channel. this includes specific baud rates used by various standards as listed in ta b l e 1 . the xc2vpx70 mgt operates at a fixed 4.25 gb/s per channel. the rocketio x mgt consists of the physical media attachment (pma) and physical coding sublayer (pcs). the pma contains the 6.25 gb/s serializer/deserializer (serdes), tx/rx buffers, clock generator, and clock recovery circuitry. the rocketio x pcs has been signifi- cantly updated relative to the rocketio pcs. in addition to the existing rocketio pcs features, the rocketio x pcs features 64b/66b encoder/decoder/scrambler/descrambler and sonet compatibility. see table 7, page 17 , for a summary of the differences between the rocketio x pma/pcs and the rocketio pma/pcs. figure 4, page 3 shows a high-level block diagram of the rocketio x transceiver and its fpga interface signals. pma transmitter output the rocketio x transceiver is implemented in current mode logic (cml). a cml transmitter output consists of transistors configured as shown in figure 2 . cml uses a positive supply and offers easy interface requirements. in this configuration, both legs of the driver, vp and vn, sink current, with one leg always sinking more current than its complement. the cml output consists of a differential pair with 50 ? source resistors. the signal swing is created by switching the current in a common-source differential pair. transmitter termination on-chip termination is provided at the transmitter, eliminat- ing the need for external termination. the output driver and termination are powered by v ttx at 1.5v. this configuration uses a cml approach with 50 ? termination to txp and txn as shown in figure 3 . ta b l e 1 : communications standards supported by rocketio x transceiver (2) mode channels (lanes) (1) i/o bit rate (gb/s) sonet oc-48 1 2.488 pci express 1, 2, 4, 8, 16 2.5 infiniband 1, 4, 12 2.5 xaui (10-gb ethernet) 4 3.125 xaui (10-gb fibre channel) 4 3.1875 aurora (xilinx protocol) 1, 2, 3, 4,... 2.488 to 6.25 custom mode 1, 2, 3, 4,... 2.488 to 6.25 notes: 1. one channel is consider ed to be one transceiver. 2. xc2vpx70 operates at a fi xed 4.25 gb/s baud rate. figure 2: cml output configuration cml output driver ds083-2_66_052104 v p v n v p v n -= v data figure 3: rocketio x transmit termination 50 50 ug083_34_050704 vttx (1.5v) txp txn virtex-ii pro and virtex-ii pro x platform fpgas: functional description r ds083 (v5.0) june 21, 2011 www.xilinx.com module 2 of 4 product specification 3 product not recommended for new designs figure 4: rocketio x transceiver block diagram fpga fabric multi-gigabit transceiver core serializer rxp txp clock manager power down package pins deserializer comma detect realign 8b/10b decoder tx fifo channel bonding and clock correction chbondi[4:0] chbondo[4:0] 8b/10b encoder rx elastic buffer output polarity rxn gnda txn ds083-2_37_050704 powerdown rxrecclk rxpolarity rxrealign rxcommadet rxreset rxclkcorcnt[2:0] rxlossofsync[1:0] rxdata[63:0] rxnotintable[7:0] rxdisperr[7:0] rxcharisk[7:0] rxchariscomma[7:0] rxrundisp[7:0] rxbufstatus[1:0] enchansync rxusrclk rxusrclk2 chbonddone txbuferr txdata[63:0] txbypass8b10b[7:0] txcharisk[7:0] txchardispmode[7:0] txchardispval[7:0] txkerr[7:0] txrundisp[7:0] txpolarity txinhibit loopback[1:0] txreset refclk refclk2 refclksel enpcommaalign enmcommaalign txusrclk txusrclk2 vtrx avccauxtx vttx avccauxrx 2.5v tx/rx gnd termination supply rx 1.5v termination supply tx post driver serial loopback path parallel loopback path brefclkp brefclkn 64b/66b block sync 64b/66b decoder gear box scrambler 64b/66b encoder pma attribute load pmaregdatain[7:0] rxcommadetuse rxdatawidth[1:0] rxdecc64b66buse pmainit pmaregaddr[5:0] pmaregrw pmaregstrobe pmarxlocksel[1:0] pmarxlock rxdec8b10buse rxdescram64b66buse refclkbsel rxblcoksync64b66buse rxslide txintdatawidth[1:0] txscram64b66buse txoutclk rxignorebtf rxintdatawidth[1:0] txdatawidth[1:0] txenc64b66buse txenc8b10buse txforcecrcerr txgearbox64b66buse pre-driver loopback path 64b/66b descrambler clock / reset virtex-ii pro and virtex-ii pro x platform fpgas: functional description r ds083 (v5.0) june 21, 2011 www.xilinx.com module 2 of 4 product specification 4 product not recommended for new designs output swing and emphasis the output swing and emphasis levels are fully programma- ble. each is controlled via attributes at configuration, and can be modified via the pma attribute programming bus. the programmable output swing control can adjust the dif- ferential peak-to-peak output level between 200 mv and 1600 mv. with emphasis, the differential voltage swing is boosted to create a stronger rising or falling waveform. this method compensates for high frequency loss in the transmission media that would otherwise limit the magnitude of this wave- form. lossy transmission lines cause the dissipation of elec- trical energy. this emphasis technique extends the distance that signals can be driven down lossy line media and increases the signal-to-noise ratio at the receiver. emphasis can be described from two perspectives, additive to the smaller voltage (v sm ) (pre-emphasis) or subtractive from the larger voltage (v lg ) (de-emphasis). the resulting benefits in compensating for channel loss are identical. it is simply a relative way of specifying the effect at the transmit- ter. the equations for calculating pre-emphasis as a percent- age and db are as follows: pre-emphasis % = ((v lg -v sm ) / v sm ) x 100 pre-emphasis db = 20 log(v lg /v sm ) the equations for calculating de-emphasis as a percentage and db are as follows: de-emphasis % = (v lg - v sm ) / v lg ) x 100 de-emphasis db = 20 log(v sm /v lg ) the pre-emphasis amount can be programmed in discrete steps between 0% and 500%. the de-emphasis amount can be programmed in discrete steps between 0% and 83%. serializer the serializer multiplies the reference frequency provided on refclk by 10, 16, 20, 32, or 40, depending on the oper- ation mode. the multiplication of the clock is achieved by using an embedded pll. data is converted from parallel to serial format and transmit- ted on the txp and txn differential outputs. the electrical connection of txp and txn can be interchanged through configuration. this option can be controlled by an input (txpolarity) at the fpga transmitter interface. deserializer synchronous serial dat a reception is facilitated by a clock and data recovery (cdr) circuit. this circuit uses a fully monolithic phase lock loop (pll), which does not require any external components. the cdr circuit extracts both phase and frequency from the incoming data stream. the derived clock, rxrecclk, is generated and locked to as long as it remains within the specified component range. this clock is presented to the fpga fabric at 1 / 10 , 1 / 16 , 1 / 20 , 1 / 32 , or 1 / 40 the incoming data rate depending on the oper- ating mode. a sufficient number of transitions must be present in the data stream for cdr to work properly. the cdr circuit is guaranteed to work with 8b/10b and 64b/66b encoding. further, cdr requires approximately 5,000 transitions upon power-up to guarantee locking to the incoming data rate. once lock is achieved, up to 75 missing transitions can be tolerated before lock to the incoming data stream is lost. another feature of cdr is its ability to accept an external precision reference clock, re fclk, which either acts to clock incoming data or to assi st in synchronizing the derived rxrecclk. for further clarity, the txusrclk is used to clock data from the fpga fabric to the tx fifo. the fifo depth accounts for the slight phase difference between these two clocks. if the clocks are locked in frequency, then the fifo acts much like a pass-through buffer. the receiver can be configured to reverse the rxp and rxn inputs. this can be useful in the event that printed cir- cuit board traces have been reversed. receiver lock control the cdr circuits will lock to the reference clock automati- cally if the data is not present. for proper operation, the fre- quency of the reference clock must be within 100 ppm of the nominal frequency. during normal operation, the receiver pll automatically locks to incoming data (when present) or to the local refer- ence clock (when data is not present). this is the default configuration for all primitives. this function can be overrid- den via the pmarxlocksel port when receive pll lock is fo rced to the local reference, phase information from the incoming data stream is ignored. data continues to be sampled, but synchronous to the local reference rather than relative to edges in the data stream. receive equalization in addition to transmit emphasis, the rocketio x mgt pro- vides a programmable active receive equalization feature to further compensate the effects of channel attenuation at high frequencies. by adjusting rxfer, the right amount of equalization can be added to reverse the signal degradation caused by a printed circuit board, a backplane, or a line/switch card. rxfer can be set through software configuration or the pma attribute bus. receiver termination on-chip termination is provided at the receiver, eliminating the need for external termination. the receiver termination supply (v trx ) is the center tap of differential termination to virtex-ii pro and virtex-ii pro x platform fpgas: functional description r ds083 (v5.0) june 21, 2011 www.xilinx.com module 2 of 4 product specification 5 product not recommended for new designs rxp and rxn as shown in figure 5 . this supports multiple termination styles, including high-side, low-side, and differ- ential (floating or active). this configuration supports receiver termination compatib le to virtex-ii pro devices, using a cml (high-side) termination to an active supply of 1.8v ? 2.5v. for dc coupling of two virtex-ii pro x devices, a 1.5v cml termination for vtrx is recommended. pcs fabric data interface internally, the pcs operates in either 2-byte mode (16/20 bits) or 4-byte mode (32/40 bits). when in 2-byte mode, the fpga fabric interface can either be 1, 2, or 4 bytes wide. when in 4-byte mode, the fpga fabric interface can either be 4 or 8 bytes wide. when accompanied by the predefined modes of the pma, the user thus has a large combination of protocols and data rates from which to choose. usrclk2 clocks data on the fabric side, while usrclk clocks data on the pcs side. this creates distinct usrclk/usrclk2 frequency ratios for different combina- tions of fabric and internal data widths. ta bl e 2 summarizes the usrclk2-to-usrclk ratios for the different possible combinations of data widths. as a general guide, use 2-byte internal data width mode when the serial speed is below 5 gb/s, and 4-byte internal data width mode when the serial speed is greater than 5 gb/s. in 2-byte mode, the pcs processes 4-byte data every other byte. no fixed phase relationship is assumed between refclk, rxrecclk, and/or any other clock that is not tied to either of these clocks. when rxusrclk and rxusrclk2 have different frequencies, each edge of the slower clock is aligned to a falling edge of the faster clock. the same rela- tionships apply to txusrclk and txusrclk2. fpga transmit interface the fpga can send either one, two, or four characters of data to the transmitter. each character can be either 8 bits or 10 bits wide. if 8-bit data is applied, the additional inputs become control signals for the 8b/10b encoder. when the 8b/10b encoder is bypassed, the 10-bit character order is generated as follows: txchardispmode[0] (first bit transmitted) txchardispval[0] txdata[7:0] (last bit transmitted is txdata[0]) 64b/66b encoder/decoder the rocketio x pcs features a 64b/66b encoder/decoder, scrambler/descrambler, and gearbox functions that can be bypassed as needed. the encoder is compliant with ieee 802.3ae specifications. scrambler/gearbox the bypassable scrambler operates on the read side of the transmit fifo. the scrambler uses the following generator polynomial to scramble 64b/66b payload data: g ( x ) = 1 + x 39 + x 58 the scrambler works in conjunction with the gearbox, which frames 64b/66b data for the pma. the gearbox should always be enabled when using the 64b/66b protocal. figure 5: rocketio x receive termination 50 50 vtrx rxp rxn ds083-2_35_050704 ta bl e 2 : clock ratios for various data widths fabric data width frequency ratio of usrclk:usrclk2 2-byte internal data width 4-byte internal data width 1 byte 1:2 (1) n/a 2 byte 1:1 n/a 4 byte 2:1 (1) 1:1 8 byte n/a 2:1 (1) notes: 1. each edge of slower clock must align with falling edge of faster clock. virtex-ii pro and virtex-ii pro x platform fpgas: functional description r ds083 (v5.0) june 21, 2011 www.xilinx.com module 2 of 4 product specification 6 product not recommended for new designs disparity control the 8b/10b encoder is initialized with a negative running disparity. unique control allows forcing the current running disparity state. txrundisp signals its current running disparity. this may be useful in those cases where there is a need to manipu- late the initial running disparity value. bits txchardispmode and txchardispval control the generation of running disparity before each byte. for example, the transceiver can generate the sequence k28.5+ k28.5+ k28.5? k28.5? or k28.5? k28.5? k28.5+ k28.5+ by specifying inverted running disparity for the second and fourth bytes. transmit fifo proper operation of the circuit is only possible if the fpga clock (txusrclk) is frequency-locked to the reference clock (refclk). phase variations up to one clock cycle are allowable. the fifo has a depth of four. overflow or under- flow conditions are detected and signaled at the interface. bypassing of this fifo is programmable. 8b/10b encoder note: in the rocketio transceiver, the most-significant byte is sent first; in the rocketio x transceiver, the least-signifi- cant byte is sent first. a bypassable 8b/10b encoder is included. the encoder uses the same 256 data characters and 12 control characters used by gigabit ethernet, fibre channel, and infiniband. the encoder accepts 8 bits of data along with a k-character signal for a total of 9 bits per character applied, and generates a 10 bit character for transmission. if the k-character signal is high, the data is encoded into one of the twelve possible k-characters available in the 8b/10b code. if the k-character input is low, the 8 bits are encoded as standard data. if the k-character input is high, and a user applies other than one of the twelve possible combinations, txkerr indicates the error. 8b/10b decoder note: in the rocketio transceiver, the most-significant byte is sent first; in the rocketio x transceiver, the least-significant byte is sent first. an optional 8b/10b decoder is included. a programmable option allows the decoder to be bypassed. when the 8b/10b decoder is bypassed, the 10-bit character order is, for example, rxcharisk[0] (first bit received) rxrundisp[0] rxdata[7:0] (last bit received is rxdata[0]) the decoder uses the same table that is used for gigabit ethernet, fibre channel, and infiniband. in addition to decoding all data and k-characters, the decoder has sev- eral extra features. the decoder separately detects both ?disparity errors? and ?out-of-band? errors. a disparity error is the reception of 10-bit character that exists within the 8b/10b table but has an incorrect disparity. an out-of-band error is the reception of a 10-bit character that does not exist within the 8b/10b table. it is possible to obtain an out-of-band error without having a disparity error. the proper disparity is always comp uted for both legal and ille- gal characters. the current running disparity is available at the rxrundisp signal. the 8b/10b decoder performs a unique operation if out-of-band data is detected. if out-of-band data is detected, the decoder signals the error and passes the ille- gal 10-bits through and places them on the outputs. this can be used for debugging purposes if desired. the decoder also signals the reception of one of the 12 valid k-characters. in addition, a programmable comma detect is included. the comma detect signal registers a comma on the receipt of any comma+, comma?, or both. since the comma is defined as a 7-bit character, this includes several out-of-band characters. another option allows the decoder to detect only the three defined commas (k28.1, k28.5, and k28.7) as comma+, comma?, or both. in total, there are six possible options, three for valid commas and three for "any comma." note that all bytes (1, 2, 4, or 8) at the rx fpga interface each have their own individual 8b/10b indicators (k-charac- ter, disparity error, out-of-band error, current running dispar- ity, and comma detect). power sequencing receiver buffer the receiver includes buffers (fifos) in the datapath. this section gives the reasons for including the buffers and out- lines their operation. the receiver buffer is required for two reasons: ? clock correction to accommodate the slight difference in frequency between the recovered clock rxrecclk and the internal fpga user clock rxusrclk ? channel bonding to allow realignment of the input stream to ensure proper alignment of data being read through multiple transceivers the receiver uses an elastic buffer , where "elastic" refers to the ability to modify the read pointer for clock correction and channel bonding. comma detection word alignment is dependent on the state of comma detect bits. if comma detect is enabled, the transceiver recognizes up to two 10-bit preprogrammed characters. upon detection of the character or characters, the comma detect output is driven high and the data is synchronously aligned. if a comma is detected and the data is aligned, no further align- ment alteration takes place. if a comma is received and realignment is necessary, the data is realigned and an indi- virtex-ii pro and virtex-ii pro x platform fpgas: functional description r ds083 (v5.0) june 21, 2011 www.xilinx.com module 2 of 4 product specification 7 product not recommended for new designs cation is given at the receiver interface. the realignment indicator is a distinct output. the transceiver continuously monitors the data for the pres- ence of the 10-bit character(s). upon each occurrence of a 10-bit character, the data is checked for word alignment. if comma detect is disabled, the data is not aligned to any par- ticular pattern. the programmable option allows a user to align data on comma+, comma?, both, or a unique user-defined and programmed sequence. comma detection has been expanded beyond 10-bit sym- bol detection and alignment to include 8-bit symbol detec- tion and alignment for 16-, 20-, 32-, and 40-bit paths. the ability to detect symbols, and th en either align to 1-word, 2-word, or 4-word boundaries is included. the rxslide input allows the user to ?slide? or ?slip? the alignment by one bit in each 16-, 20-, 32- and 40-bit mode at any time for sonet applications. comma detection can be bypassed when needed. clock correction rxrecclk (the recovered clock) reflects the data rate of the incoming data. rxusrclk defines the rate at which the fpga fabric consumes the data. ideally, these rates are identical. however, since the clocks typically have different sources, one of the clocks will be faster than the other. the receiver buffer accommodates this difference between the clock rates. see figure 6 . nominally, the buffer is always ha lf full. this is shown in the top buffer, figure 6 , where the shaded area represents buff- ered data not yet read. received data is inserted via the write pointer under control of rxrecclk. the fpga fabric reads data via the read pointer under control of rxus- rclk. the half full/half empty condition of the buffer gives a cushion for the differing clock rates. this operation contin- ues indefinitely, regardless of whether or not "meaningful" data is being received. when there is no meaningful data to be received, the incoming data will consist of idle charac- ters or other padding. if rxusrclk is faster than rxrecclk, the buffer becomes more empty over time. the clock correction logic corrects for this by decrementing the read pointer to reread a repeatable byte sequence. this is shown in the middle buffer, figure 6 , where the solid read pointer decrements to the value represented by the dashed pointer. by decrement- ing the read pointer instead of incrementing it in the usual fashion, the buffer is partially refilled. the transceiver design will repeat a single repeatable byte sequence when neces- sary to refill a buffer. if the byte sequence le ngth is greater than one, and if attribute clk_cor_repeat_wait is 0, then the transceiver may repeat the same sequence multi- ple times until the buffer is refilled to the desired extent. similarly, if rxusrclk is slower than rxrecclk, the buf- fer will fill up over time. the cl ock correction logic corrects for this by incrementing the read pointer to skip over a removable byte sequence that need not appear in the final fpga fabric byte stream. this is shown in the bottom buffer, figure 6 , where the solid read pointer increments to the value represented by the dashed pointer. this accelerates the emptying of the buffer, preventing its overflow. the transceiver design will skip a single byte sequence when necessary to partially empty a buffer. if attribute clk_cor_repeat_wait is 0, the transceiver may also skip two consecutive removable byte sequences in one step to further empty the buffer when necessary. these operations require the clock correction logic to recog- nize a byte sequence that can be freely repeated or omitted in the incoming data stream. this sequence is generally an idle sequence, or other sequence comprised of special values that occur in the gaps separating packets of mean- ingful data. these gaps are required to occur sufficiently often to facilitate the timely execution of clock correction. channel bonding some gigabit i/o standards such as infiniband specify the use of multiple transceivers in parallel for even higher data rates. words of data are split into bytes, with each byte sent over a separate channel (transceiver). see figure 7 . the top half of the figure shows the transmission of words split across four transceivers (channels or lanes). pppp, qqqq, rrrr, ssss, and tttt re present words sent over the four channels. the bottom-left portion of figure 7 shows the initial situation in the fpga?s receivers at the other end of the four chan- nels. due to variations in transmission delay?especially if the channels are routed through repeaters?the fpga fab- ric might not correctly assemb le the bytes into complete words. the bottom-left illustra tion shows the incorrect assembly of data words pqpp, qrqq, rsrr, and so forth. to support correction of this misalignment, the data stream includes special byte sequences that define corresponding points in the several channels. in the bottom half of figure 7 , the shaded "p" bytes represent these special characters. each receiver recognizes the "p" channel bond- figure 6: clock correction in receiver read rxusrclk read read write rxrecclk write write "nominal" condition: buffer half-full buffer less than half -full (emptying) buffer more than half-full (filling up) repeatable sequence removable sequence ds083-2_15_100901 virtex-ii pro and virtex-ii pro x platform fpgas: functional description r ds083 (v5.0) june 21, 2011 www.xilinx.com module 2 of 4 product specification 8 product not recommended for new designs ing character, and remembers its location in the buffer. at some point, one transceiver designated as the master instructs all the transceivers to align to the channel bonding character "p" (or to some location relative to the channel bonding character). after this operation, words transmitted to the fpga fabric are properly aligned: rrrr, ssss, tttt, and so forth, as shown in the bottom-right portion of figure 7 . to ensure that the channels remain properly aligned following the channel bonding operation, the master transceiver must also control the clock correction operations described in the previous section for all channel-bonded transceivers. transmitter buffer the transmitter's buffer writ e pointer (txusrclk) is fre- quency-locked to its read pointer (refclk). therefore, clock correction and channel bonding are not required. the purpose of the transmitter's buffer is to accommodate a phase difference between txusrclk and refclk. a simple fifo suffices for this purpose. a fifo depth of four will permit reliable operation wit h simple detection of over- flow or underflow, which could occur if the clocks are not fre- quency-locked. rocketio x configuration this section outlines functions that can be selected or con- trolled by configuration. x ilinx implementation software sup- ports the transceiver primitives shown in ta bl e 3 . figure 7: channel bonding (alignment) ta b l e 3 : supported rocketio x transceiver primitives primitive description gt10_custom fully customizable by user gt10_oc48_1 sonet oc-48, 1-byte data path gt10_oc48_2 sonet oc-48, 2-byte data path gt10_oc48_4 sonet oc-48, 4-byte data path gt10_pci_express_1 pci ex press, 1-byte data path gt10_pci_express_2 pci ex press, 2-byte data path gt10_pci_express_4 pci ex press, 4-byte data path gt10_infiniband_1 infiniband, 1-byte data path gt10_infiniband_2 infiniband, 2-byte data path gt10_infiniband_4 infiniband, 4-byte data path pqrs t pqrs t pqrs t pqrs t pqrs t pqrs t pqrs t pqrs t pqrs t pqrs t pqrs t pqrs t before channel bonding after channel bonding read rxusrclk read rxusrclk full word ssss sent over four channels, one byte per channel channel (lane) 0 channel (lane) 1 channel (lane) 2 channel (lane) 3 ds083-2_16_010202 in transmitters: in receivers: virtex-ii pro and virtex-ii pro x platform fpgas: functional description r ds083 (v5.0) june 21, 2011 www.xilinx.com module 2 of 4 product specification 9 product not recommended for new designs other rocketio x features and notes loopback in order to facilitat e testing without having the need to either apply patterns or measure data at ghz rates, four program- mable loop-back features are available. the first option, serial loopback, is available in two modes: pre-driver and post-driver . ? the pre-driver mode loops back to the receiver without going through the output driver. in this mode, txp and txn are not driven and therefore need not be terminated. ? the post-driver mode is the same as the rocketio loopback. in this mode, txp and txn are driven and must be properly terminated. the third option, parallel loopback, checks the digital cir- cuitry. when parallel loopback is enabled, the serial loop- back path is disabled. however, the transmitter outputs remain active, and data can be transmitted. if txinhibit is asserted, txp is forced to 0 until txinhibit is de-asserted. the fourth option, repeater loopback, allows received data to be transmitted without going through the fpga fabric. reset the receiver and transmitter have their own synchronous reset inputs. the transmitter reset, txreset, recenters the transmission fifo and resets all transmitter registers and the encoder. the receiver re set, rxreset, recenters the receiver elastic buffer and resets all receiver registers and the decoder. when the signals txreset or rxreset are asserted high, the pcs is in reset. after txreset or rxreset are deasserted, the pcs takes five clocks to come out of reset for each clock domain. the pma configuration vector is not affected during this reset, so the pma speed, filter settings, and so on, all remain the same. also, the pm a internal pipeline is not affected and continues to operate in normal fashion. power the transceiver voltage regulator circuits must not be shared with any other supplies (including fpga supplies v ccint , v cco , v ccaux , and v ref ). voltage regulators can be shared among transceiver power supplies of the same voltage, but each supply pin must still have its own separate passive filtering network. all rocketio transceivers in the fpga, whether instantiated in the design or not, must be connected to power and ground. unused transceivers can be powered by any 1.5v or 2.5v source, and passive filtering is not required. the power down feature is controlled by the transceiver?s powerdown input pin. any given transceiver that is not instantiated in the design is automatically set to the pow- erdown state by the xilinx ise development software. the power down pin on the fpga package has no effect on the mgt. virtex-ii pro and virtex-ii pro x platform fpgas: functional description r ds083 (v5.0) june 21, 2011 www.xilinx.com module 2 of 4 product specification 10 product not recommended for new designs functional description: rocketio multi-gigabit transceiver (mgt) this section summarizes the features of the rocketio multi-gigabit transceiver. for an in-depth discussion of the rocketio mgt, including digital and analog design consid- erations, refer to the rocketio transceiver user guide . rocketio overview up to twenty rocketio mgts are available. the mgt is designed to operate at any baud rate in the range of 622 mb/s to 3.125 gb/s per channel. this includes specific baud rates used by various standards as listed in ta bl e 4 . the rocketio mgt consists of the physical media attach- ment (pma) and physical coding sublayer (pcs). the pma contains the 3.125 gb/s serializer/deserializer (serdes), tx/rx buffers, clock generator, and clock recovery circuitry. the pcs contains the bypassable 8b/10b encoder/ decoder, elastic buffers, and cyclic redundancy check (crc) units. the encoder and decoder handle the 8b/10b coding scheme. the elastic buffers support the clock correction (rate matching) and channel bonding fea- tures. the crc units perform crc generation and check- ing. see table7, page17 , for a summary of the differences between the rocketio x pma/pcs and the rocketio pma/pcs. figure 10, page 11 shows a high-level block diagram of the rocketio transceiver and its fpga interface signals. pma transmitter output the rocketio transceiver is implemented in current mode logic (cml). a cml transmitter output consists of transis- tors configured as shown in figure 8 . cml uses a positive supply and offers easy interface requirements. in this con- figuration, both legs of the driver, vp and vn, sink current, with one leg always sinking more current than its comple- ment. the cml output consists of a differential pair with 50 ? (or, optionally, 75 ? ) source resistors. the signal swing is created by switching the current in a common-source dif- ferential pair. transmitter termination on-chip termination is provided at the transmitter, eliminat- ing the need for external termination. the output driver and termination are powered by v ttx . this configuration uses a cml approach wit h selectable 50 ? or 75 ? termination to txp and txn as shown in figure 9 . ta bl e 4 : protocols supported by rocketio transceiver mode channels (lanes) (1) i/o bit rate (gb/s) fibre channel 1 1.06 2.12 3.1875 (2) gigabit ethernet 1 1.25 10gbit ethernet 4 3.125 infiniband 1, 4, 12 2.5 aurora 1, 2, 3, 4, ... 0.622 ? 3.125 custom protocol 1, 2, 3, 4, ... up to 3.125 notes: 1. one channel is consider ed to be one transceiver. 2. virtex-ii pro mgt can support t he 10g fibre channel data rates of 3.1875 gb/s across 6" of standard fr-4 pcb and one connector (molex 74441 or equivalent) with a bit error rate of 10 -12 or better. figure 8: cml output configuration cml output driver ds083-2_66_052104 v p v n v p v n -= v data figure 9: rocketio transmit termination 50 /7 5 50 /7 5 ug083_33_061504 vttx txp txn virtex-ii pro and virtex-ii pro x platform fpgas: functional description r ds083 (v5.0) june 21, 2011 www.xilinx.com module 2 of 4 product specification 11 product not recommended for new designs output swing and pre-emphasis the output swing and pre-emphasis levels of the rocketio mgts are fully programmable. each is controlled via attri- butes at configuration, but can be modified via partial recon- figuration. the programmable output swing control can adjust the dif- ferential output level between 400 mv and 800 mv in four increments of 100 mv. with pre-emphasis, the differential voltage swing is boosted to create a stronger rising waveform. this method compen- sates for high-frequency loss in the transmission media that would otherwise limit the magnitude of this waveform. lossy transmission lines cause the di ssipation of electrical energy. this pre-emphasis technique extends the distance that sig- nals can be driven down lossy line media and increases the signal-to-noise ratio at the receiver. figure 10: rocketio transceiver block diagram fpga fabric multi-gigabit transceiver core serializer rxp txp clock manager power down package pins deserializer comma detect realign 8b/10b decoder tx fifo crc check crc channel bonding and clock correction chbondi[3:0] chbondo[3:0] 8b/10b encoder rx elastic buffer output polarity rxn gnda txn ds083-2_04_090402 powerdown rxrecclk rxpolarity rxrealign rxcommadet rxreset rxclkcorcnt rxlossofsync rxdata[15:0] rxdata[31:16] rxcheckingcrc rxcrcerr rxnotintable[3:0] rxdisperr[3:0] rxcharisk[3:0] rxchariscomma[3:0] rxrundisp[3:0] rxbufstatus[1:0] enchansync rxusrclk rxusrclk2 chbonddone txbuferr txdata[15:0] txdata[31:16] txbypass8b10b[3:0] txcharisk[3:0] txchardispmode[3:0] txchardispval[3:0] txkerr[3:0] txrundisp[3:0] txpolarity txforcecrcerr txinhibit loopback[1:0] txreset refclk refclk2 refclksel enpcommaalign enmcommaalign txusrclk txusrclk2 vtrx avccauxrx vttx avccauxtx 2.5v rx tx/rx gnd termination supply rx 2.5v tx termination supply tx serial loopback path parallel loopback path brefclk brefclk2 virtex-ii pro and virtex-ii pro x platform fpgas: functional description r ds083 (v5.0) june 21, 2011 www.xilinx.com module 2 of 4 product specification 12 product not recommended for new designs serializer the serializer multiplies the reference frequency provided on refclk by 20. the multiplication of the clock is achieved by using an embedded pll. data is converted from parallel to serial format and transmit- ted on the txp and txn differential outputs. the electrical connection of txp and txn can be interchanged through configuration. this option can be controlled by an input (txpolarity) at the fpga transmitter interface. deserializer the serial transceiver input is locked to the input data stream through clock and data recovery (cdr), a built-in feature of the rocketio transceiver. cdr keys off the rising and falling edges of incoming data and derives a clock that is representative of the incoming data rate. the derived clock, rxrecclk, is generated and locked to as long as it remains within the specified component range. this clock is presented to the fpga fabric at 1 / 20 the incom- ing data rate. a sufficient number of transitions must be present in the data stream for cdr to work properly. cdr requires approximately 5,000 transitions upon power-up to guaran- tee locking to the incoming data rate. once lock is achieved, up to 75 missing transitions can be tolerated before lock to the incoming data stream is lost. the cdr circuit is guaran- teed to work with 8b/10b encoding. another feature of cdr is its ability to accept an external precision reference clock, re fclk, which either acts to clock incoming data or to assi st in synchronizing the derived rxrecclk. for further clarity, the txusrclk is used to clock data from the fpga fabric to the tx fifo. the fifo depth accounts for the slight phase difference between these two clocks. if the clocks are locked in frequency, then the fifo acts much like a pass-through buffer. the receiver can be configured to reverse the rxp and rxn inputs. this can be useful in the event that printed cir- cuit board traces have been reversed. receiver termination on-chip termination is provided at the receiver, eliminating the need for external termination. the receiver includes pro- grammable on-chip termination circuitry for 50 ? (default) or 75 ? impedance, as shown in figure 11 . pcs fabric data interface internally, the pcs operates in 2-byte mode (16/20 bits). the fpga fabric interface can either be 1, 2, or 4 bytes wide. when accompanied by the predefined modes of the pma, the user thus has a large combination of protocols and data rates from which to choose. usrclk2 clocks data on the fabric side, while usrclk clocks data on the pcs side. this creates distinct usrclk/usrclk2 frequency ratios for different combina- tions of fabric and internal data widths. ta b l e 5 summarizes the usrclk2 to usrclk ratios for the three fabric data widths. no fixed phase relationship is assumed between refclk, rxrecclk, and/or any other clock that is not tied to either of these clocks. when rxusrclk and rxusrclk2 have different frequencies, each edge of the slower clock is aligned to a falling edge of the faster clock. the same rela- tionships apply to txusrclk and txusrclk2. figure 11: rocketio receive termination 50/75 50/75 vtrx rxp rxn ds083-2_36_111704 virtex-ii pro and virtex-ii pro x platform fpgas: functional description r ds083 (v5.0) june 21, 2011 www.xilinx.com module 2 of 4 product specification 13 product not recommended for new designs fpga transmit interface the fpga can send either one, two, or four characters of data to the transmitter. each character can be either 8 bits or 10 bits wide. if 8-bit data is applied, the additional inputs become control signals for the 8b/10b encoder. when the 8b/10b encoder is bypassed, the 10-bit character order is generated as follows: txchardispmode[0] (first bit transmitted) txchardispval[0] txdata[7:0] (last bit transmitted is txdata[0]) disparity control the 8b/10b encoder is initialized with a negative running disparity. unique control allows forcing the current running disparity state. txrundisp signals its current running disparity. this may be useful in those cases where there is a need to manipu- late the initial running disparity value. bits txchardispmode and txchardispval control the generation of running disparity before each byte. for example, the transceiver can generate the sequence k28.5+ k28.5+ k28.5? k28.5? or k28.5? k28.5? k28.5+ k28.5+ by specifying inverted running disparity for the second and fourth bytes. transmit fifo proper operation of the circuit is only possible if the fpga clock (txusrclk) is frequency-locked to the reference clock (refclk). phase variations up to one clock cycle are allowable. the fifo has a depth of four. overflow or under- flow conditions are detected and signaled at the interface. bypassing of this fifo is programmable. 8b/10b encoder note: in the rocketio transceiver, the most-significant byte is sent first; in the rocketio x transceiver, the least-signifi- cant byte is sent first. a bypassable 8b/10b encoder is included. the encoder uses the same 256 data characters and 12 control characters used by gigabit ethernet, fibre channel, and infiniband. the encoder accepts 8 bits of data along with a k-character signal for a total of 9 bits per character applied, and generates a 10 bit character for transmission. if the k-character signal is high, the data is encoded into one of the twelve possible k-characters available in the 8b/10b code. if the k-character input is low, the 8 bits are encoded as standard data. if the k-character input is high, and a user applies other than one of the twelve possible combinations, txkerr indicates the error. 8b/10b decoder note: in the rocketio transceiver, the most-significant byte is sent first; in the rocketio x transceiver, the least-significant byte is sent first. an optional 8b/10b decoder is included. a programmable option allows the decoder to be bypassed. when the 8b/10b decoder is bypassed, the 10-bit character order is, for example, rxcharisk[0] (first bit received) rxrundisp[0] rxdata[7:0] (last bit received is rxdata[0]) the decoder uses the same table that is used for gigabit ethernet, fibre channel, and infiniband. in addition to decoding all data and k-characters, the decoder has sev- eral extra features. the decoder separately detects both ?disparity errors? and ?out-of-band? errors. a disparity error is the reception of 10-bit character that exists within the 8b/10b table but has an incorrect disparity. an out-of-band error is the reception of a 10-bit character that does not exist within the 8b/10b table. it is possible to obtain an out-of-band error without having a disparity error. the proper disparity is always comp uted for both legal and ille- gal characters. the current running disparity is available at the rxrundisp signal. the 8b/10b decoder performs a unique operation if out-of-band data is detected. if out-of-band data is detected, the decoder signals the error and passes the ille- gal 10-bits through and places them on the outputs. this can be used for debugging purposes if desired. the decoder also signals the reception of one of the 12 valid k-characters. in addition, a programmable comma detect is included. the comma detect signal registers a comma on the receipt of any comma+, comma?, or both. since the comma is defined as a 7-bit character, this includes several out-of-band characters. another option allows the decoder to detect only the three defined commas (k28.1, k28.5, and k28.7) as comma+, comma?, or both. in total, there are six possible options, three for valid commas and three for "any comma." note that all bytes (1, 2, or 4) at the rx fpga interface each have their own individual 8b/10b indicators (k-charac- ter, disparity error, out-of-band error, current running dispar- ity, and comma detect). power sequencing ta bl e 5 : clock ratios for various data widths fabric data width frequency ratio of usrclk:usrclk2 1-byte 1:2 (1) 2-byte 1:1 4-byte 2:1 (1) notes: 1. each edge of slower clock must align with falling edge of faster clock. virtex-ii pro and virtex-ii pro x platform fpgas: functional description r ds083 (v5.0) june 21, 2011 www.xilinx.com module 2 of 4 product specification 14 product not recommended for new designs receiver buffer the receiver includes buffers (fifos) in the datapath. this section gives the reasons for including the buffers and out- lines their operation. the receiver buffer is required for two reasons: ? clock correction to accommodate the slight difference in frequency between the recovered clock rxrecclk and the internal fpga user clock rxusrclk ? channel bonding to allow realignment of the input stream to ensure proper alignment of data being read through multiple transceivers the receiver uses an elastic buffer, where "elastic" refers to the ability to modify the read pointer for clock correction and channel bonding. comma detection word alignment is dependent on the state of comma detect bits. if comma detect is enabled, the transceiver recognizes up to two 10-bit preprogrammed characters. upon detection of the character or characters, the comma detect output is driven high and the data is synchronously aligned. if a comma is detected and the data is aligned, no further align- ment alteration takes place. if a comma is received and realignment is necessary, the data is realigned and an indi- cation is given at the receiver interface. the realignment indicator is a distinct output. the transceiver continuously monitors the data for the pres- ence of the 10-bit character(s). upon each occurrence of a 10-bit character, the data is checked for word alignment. if comma detect is disabled, the data is not aligned to any par- ticular pattern. the programmable option allows a user to align data on comma+, comma?, both, or a unique user-defined and programmed sequence. clock correction rxrecclk (the recovered clock) reflects the data rate of the incoming data. rxusrclk defines the rate at which the fpga fabric consumes the data. ideally, these rates are identical. however, since the clocks typically have different sources, one of the clocks will be faster than the other. the receiver buffer accommodates this difference between the clock rates. see figure 12 . nominally, the buffer is always ha lf full. this is shown in the top buffer, figure 12 , where the shaded area represents buffered data not yet read. received data is inserted via the write pointer under control of rxrecclk. the fpga fabric reads data via the read pointer under control of rxus- rclk. the half full/half empty condition of the buffer gives a cushion for the differing clock rates. this operation contin- ues indefinitely, regardless of whether or not "meaningful" data is being received. when there is no meaningful data to be received, the incoming data will consist of idle charac- ters or other padding. if rxusrclk is faster than rxrecclk, the buffer becomes more empty over time . the clock correction logic corrects for this by decrementing the read pointer to reread a repeatable byte sequence. this is shown in the middle buffer, figure 12 , where the solid read pointer decrements to the value represented by the dashed pointer. by decrementing the read pointer instead of incrementing it in the usual fashion, the buffer is partially refilled. the transceiver design will repeat a single repeatable byte sequence when necessary to refill a buffer. if the byte sequence length is greater than one, and if attribute clk_cor_repeat_wait is 0, then the transceiver may repeat the same sequence mul- tiple times until the buffer is refilled to the desired extent. similarly, if rxusrclk is slower than rxrecclk, the buf- fer will fill up over time. the cl ock correction logic corrects for this by incrementing the read pointer to skip over a removable byte sequence that need not appear in the final fpga fabric byte stream. this is shown in the bottom buffer, figure 12 , where the solid read pointer increments to the value represented by the dashed pointer. this accelerates the emptying of the buffer, preventing its overflow. the transceiver design will skip a single byte sequence when necessary to partially empty a buffer. if attribute clk_cor_repeat_wait is 0, the transceiver may also skip two consecutive removable byte sequences in one step to further empty the buffer when necessary. these operations require the clock correction logic to recog- nize a byte sequence that can be freely repeated or omitted in the incoming data stream. this sequence is generally an idle sequence, or other sequence comprised of special values that occur in the gaps separating packets of mean- ingful data. these gaps are required to occur sufficiently often to facilitate the timely execution of clock correction. channel bonding some gigabit i/o standards such as infiniband specify the use of multiple transceivers in parallel for even higher data rates. words of data are split into bytes, with each byte sent over a separate channel (transceiver). see figure 13 . figure 12: clock correction in receiver read rxusrclk read read write rxrecclk write write "nominal" condition: buffer half-full buffer less than half -full (emptying) buffer more than half-full (filling up) repeatable sequence removable sequence ds083-2_15_100901 virtex-ii pro and virtex-ii pro x platform fpgas: functional description r ds083 (v5.0) june 21, 2011 www.xilinx.com module 2 of 4 product specification 15 product not recommended for new designs the top half of the figure shows the transmission of words split across four transceivers (channels or lanes). pppp, qqqq, rrrr, ssss, and tttt re present words sent over the four channels. the bottom-left portion of figure 13 shows the initial situa- tion in the fpga?s receivers at the other end of the four channels. due to variations in transmission delay?espe- cially if the channels are routed through repeaters?the fpga fabric might not correctly assemble the bytes into complete words. the bottom- left illustration shows the incorrect assembly of data words pqpp, qrqq, rsrr, and so forth. to support correction of this misalignment, the data stream includes special byte sequences that define corresponding points in the several channels. in the bottom half of figure 13 , the shaded "p" bytes represent these special characters. each receiver recognizes the "p" channel bond- ing character, and remembers its location in the buffer. at some point, one transceiver designated as the master instructs all the transceivers to align to the channel bonding character "p" (or to some location relative to the channel bonding character). after this operation, words transmitted to the fpga fabric are properly aligned: rrrr, ssss, tttt, and so forth, as shown in the bottom-right portion of figure 13 . to ensure that the channels remain properly aligned following the channel bonding operation, the master transceiver must also control the clock correction operations described in the previous section for all channel-bonded transceivers. transmitter buffer the transmitter's buffer write pointer (txusrclk) is fre- quency-locked to its read pointer (refclk). therefore, clock correction and channel bonding are not required. the purpose of the transmitter's buffer is to accommodate a phase difference between txusrclk and refclk. a simple fifo suffices for this purpose. a fifo depth of four will permit reliable operation wit h simple detection of over- flow or underflow, which could occur if the clocks are not fre- quency-locked. rocketio configuration this section outlines functions that can be selected or con- trolled by configuration. x ilinx implementation software sup- ports 16 transceiver primitives, as shown in ta b l e 6 . each of the primitives in ta bl e 6 defines default values for the configuration attributes, allowing some number of them to be modified by the user. refer to the rocketio trans- ceiver user guide for more details. other rocketio features and notes crc the rocketio transceiver crc logic supports the 32-bit invariant crc calculation used by infiniband, fibrechannel, and gigabit ethernet. on the transmitter side, the crc logic recognizes where the crc bytes should be inserted and replaces four place- holder bytes at the tail of a data packet with the computed crc. for gigabit ethernet and fibrechannel, transmitter figure 13: channel bonding (alignment) pqrs t pqrs t pqrs t pqrs t pqrs t pqrs t pqrs t pqrs t pqrs t pqrs t pqrs t pqrs t before channel bonding after channel bonding read rxusrclk read rxusrclk full word ssss sent over four channels, one byte per channel channel (lane) 0 channel (lane) 1 channel (lane) 2 channel (lane) 3 ds083-2_16_010202 in transmitters: in receivers: ta b l e 6 : supported rocketio mgt protocol primitives gt_custom fully customizable by user gt_fibre_chan_1 fibre channel, 1-byte data path gt_fibre_chan_2 fibre channel, 2-byte data path gt_fibre_chan_4 fibre channel, 4-byte data path gt_ethernet_1 gigabit ethernet, 1-byte data path gt_ethernet_2 gigabit ethernet, 2-byte data path gt_ethernet_4 gigabit ethernet, 4-byte data path gt_xaui_1 10-gigabit ethernet, 1-byte data path gt_xaui_2 10-gigabit ethernet, 2-byte data path gt_xaui_4 10-gigabit ethernet, 4-byte data path gt_infiniband_1 infiniband, 1-byte data path gt_infiniband_2 infiniband, 2-byte data path gt_infiniband_4 infiniband, 4-byte data path gt_aurora_1 (1) 1-byte data path gt_aurora_2 (1) 2-byte data path gt_aurora_4 (1) 4-byte data path notes: 1. for more information on the aurora protocol, visit http://www.xilinx.com . virtex-ii pro and virtex-ii pro x platform fpgas: functional description r ds083 (v5.0) june 21, 2011 www.xilinx.com module 2 of 4 product specification 16 product not recommended for new designs crc may adjust certain trailing bytes to generate the required running disparity at the end of the packet. on the receiver side, the crc logic verifies the received crc value, supporting the same standards as above. the crc logic also supports a user mode, with a simple data packet stucture beginning and ending with user-defined sop and eop characters. loopback in order to facilitat e testing without having the need to either apply patterns or measure data at ghz rates, two program- mable loop-back features are available. one option, serial loopback, places the gigabit transceiver into a state where transmit data is directly fed back to the receiver. an important point to note is that the feedback path is at the output pads of the transmitter. this tests the entirety of the transmitter and receiver. the second option, parallel loopback, checks the digital cir- cuitry. when parallel loopback is enabled, the serial loop- back path is disabled. however, the transmitter outputs remain active, and data can be transmitted. if txinhibit is asserted, txp is forced to 0 until txinhibit is de-asserted. reset the receiver and transmitter have their own synchronous reset inputs. the transmitter reset recenters the transmis- sion fifo, and resets all transmitter registers and the 8b/10b decoder. the receiver reset recenters the receiver elastic buffer, and resets all receiver registers and the 8b/10b encoder. neither reset has any effect on the plls. power all rocketio transceivers in the fpga, whether instantiated in the design or not, must be connected to power and ground. unused transceivers can be powered by any 2.5v source, and passive filtering is not required. power down the power down module is controlled by the transceiver?s powerdown input pin. the power down pin on the fpga package has no effect on the transceiver. virtex-ii pro and virtex-ii pro x platform fpgas: functional description r ds083 (v5.0) june 21, 2011 www.xilinx.com module 2 of 4 product specification 17 product not recommended for new designs rocketio and rocketio x feature comparison ta bl e 7 summarizes the major differences between the rocketio and rocketio x mgts. the rocketio x transceiver user guide has more details, including a design migration guide in the appendix. ta bl e 7 : rocketio pma versus rocketio x pma rocketio x transceiver rocketio transceiver pcs features: fpga interface 1, 2, 4, and 8 byte width 1, 2, and 4 byte width coding support 8b/10b and 64b/66b bypassable 8b/10b bypassable gearbox/scrambler support yes n/a crc support no yes half rate no yes pma features: baud rate 2.488 gb/s - 6.25 gb/s (2) 622 mb/s - 3.125 gb/s reference clock frequency tolerance 350 ppm 100 ppm reference clock multiplier x16, x20, x32, x40 x20 max run length 75 75 receive equalization built-in an alog linear, programmable none output swing (differential p-p) 200 mv to 1600 mv, programmable 800 mv to 1600 mv, programmable pre-emphasis 0% to 500%, programmable 4 selectable levels from 10% to 33% slew rate control 2 selectable levels none termination on-chip internal, 50 ? on-chip internal, 50 ? /75 ? selectable ac coupling capacitor on-chip internal. can be ac- or dc-coupled externally none transmit supply voltage ( avccauxtx ) 2.5v 2.5v receive supply voltage ( avccauxrx ) 1.5v, 1.8v (1) 2.5v pma configuration support direct, dynamic, and partial configuration partial configuration others: jtag support input only none process technology 0.13 m 0.25 m available packages flip-chip only flip-chip and wire-bond notes: 1. avccauxrx for rocketio x mgt is 1.5v (nominal) for 8b/10b-e ncoded data. for all other encod ing protocols, avccauxrx is 1.8v (nominal). 2. the xc2vpx70 operates at a fixed 4.25 gb/s baud rate. virtex-ii pro and virtex-ii pro x platform fpgas: functional description r ds083 (v5.0) june 21, 2011 www.xilinx.com module 2 of 4 product specification 18 product not recommended for new designs functional description: processor block this section briefly describes the interfaces and compo- nents of the processor block. the subsequent section, functional description: embedded powerpc 405 core beginning on page 20 , offers a summary of major ppc405 core features. for an in-depth discussion on both the pro- cessor block and ppc405, see tthe powerpc processor reference guide and the powerpc 405 processor block reference guide available on the xilinx website at http://www.xilinx.com . processor block overview figure 14 shows the internal architecture of the processor block. within the virtex-ii pro processor block, there are four com- ponents: ? embedded ibm powerpc 405-d5 risc cpu core ? on-chip memory (ocm) c ontrollers and interfaces ? clock/control interface logic ? cpu-fpga interfaces embedded powerpc 405 risc core the powerpc 405d5 core is a 0.13 m implementation of the ibm powerpc 405d4 core. the advanced process tech- nology enables the embedded powerpc 405 (ppc405) core to operate at 300+ mhz while maintaining low power consumption. specially designed interface logic integrates the core with the surrounding clbs, block rams, and gen- eral routing resources. up to four processor blocks can be available in a single virtex-ii pro device. the embedded ppc405 core implements the powerpc user instruction set architecture (uisa), user-level regis- ters, programming model, data types, and addressing modes for 32-bit fixed-point operations. 64-bit operations, auxiliary processor operations , and floating -point opera- tions are trapped and can be emulated in software. most of the ppc405 core features are compatible with the specifications for the powerpc virtual environment architecture (vea) and operating environment architecture (oea). they also provide a number of optimizations and extensions to the lower layers of the powerpc architecture. the full architecture of the ppc405 is defined by the powerpc embedded environment and powerpc uisa documentation, available from ibm. on-chip memory (ocm) controllers introduction the ocm controllers serve as dedicated interfaces between the block rams in the fpga fabric (see 18 kb block selectram+ resources, page 44 ) and ocm signals available on the embedded ppc405 core. the ocm signals on the ppc405 core are designed to provide very quick access to a fixed amount of instruction and data memory space. the ocm controller provides an interface to both the 64-bit instruction-side block ram (isbram) and the 32-bit data-side block ram (dsbram). the designer can choose to implement: ? isbram only ? dsbram only ? both isbram and dsbram ? no isbram and no dsbram one of ocm?s primary advantages is that it guarantees a fixed latency of execution for a higher level of determinism. additionally, it reduces cache pollution and thrashing, since the cache remains available for caching code from other memory resources. typical applications for dsocm include scratch-pad mem- ory, as well as use of the dual-port feature of block ram to enable bidirectional data transfer between processor and fpga. typical applications for isocm include storage of interrupt service routines. functional features common features ? separate instruction and data memory interface between processor core and brams in fpga ? dedicated interface to device control register (dcr) bus for isocm and dsocm figure 14: processor block architecture processor block = cpu core + interface logic + cpu-fpga interface ds083-2_03a_060701 ppc 405 core ocm controller ocm controller control bram bram bram bram fpga clb array interface logic cpu-fpga interfaces virtex-ii pro and virtex-ii pro x platform fpgas: functional description r ds083 (v5.0) june 21, 2011 www.xilinx.com module 2 of 4 product specification 19 product not recommended for new designs ? single-cycle and multi-cycle mode option for i-side and d-side interfaces ? single cycle = one cpu clock cycle; multi-cycle = minimum of two and maximum of eight cpu clock cycles ? fpga configurable dcr addresses within dsocm and isocm. ? independent 16 mb logical memory space available within ppc405 memory map for each of the dsocm and isocm. the number of block rams in the device might limit the maximum amount of ocm supported. ? maximum of 64k and 128k bytes addressable from dsocm and isocm interfaces, respectively, using address outputs from ocm directly without additional decoding logic. data-side ocm (dsocm) ? 32-bit data read bus and 32-bit data write bus ? byte write access to dsbram support ? second port of dual port dsbram is available to read/write from an fpga interface ? 22-bit address to dsbram port ? 8-bit dcr registers: dscntl, dsarc ? three alternatives to write into dsbram: bram initialization, cpu, fpga h/w using second port instruction-side ocm (isocm) the isocm interface contains a 64-bit read only port, for instruction fetches, and a 32-bit write only port, to initialize or test the isbram. when implementing the read only port, the user must deassert the write port inputs. the preferred method of initializing the isbr am is through the configura- tion bitstream. ? 64-bit data read only bus (two instructions per cycle) ? 32-bit data write only bus (through dcr) ? separate 21-bit address to isbram ? 8-bit dcr registers: iscntl, isarc ? 32-bit dcr registers: isinit, isfill ? two alternatives to write into isbram: bram initialization, dcr and write instruction clock/control interface logic the clock/control interface logi c provides proper initializa- tion and connections for ppc405 clock/power manage- ment, resets, plb cycle control, and ocm interfaces. it also couples user signals between the fpga fabric and the embedded ppc405 cpu core. the processor clock connectivity is similar to clb clock pins. it can connect either to global clock nets or general routing resources. therefore the processor clock source can come from dcm, clb, or user package pin. cpu-fpga interfaces all processor block user pins link up with the general fpga routing resources through the cpu-fpga interface. there- fore processor signals have the same routability as other non-processor block user signals. longlines and hex lines travel across the processor block both vertically and hori- zontally, allowing signals to route through the processor block. processor local bus (plb) interfaces the ppc405 core accesses hi gh-speed system resources through plb interfaces on the instruction and data cache controllers. the plb interfaces provide separate 32-bit address/64-bit data buses for the instruction and data sides. the cache controllers are both plb masters. plb arbiters are implemented in the fpga fabric and are available as soft ip cores. device control register (dcr) bus interface the device control register (dcr) bus has 10 bits of address space for components external to the ppc405 core. using the dcr bus to manage status and configura- tion registers reduces plb traffic and improves system integrity. system resources on the dcr bus are protected or isolated from wayward code since the dcr bus is not part of the system memory map. external interrupt controller (eic) interface two level-sensitive user interrupt pins (critical and non-criti- cal) are available. they can be either driven by user defined logic or xilinx soft interrupt controller ip core outside the processor block. clock/power management (cpm) interface the cpm interface supports several methods of clock distri- bution and power management. three modes of operation that reduce power consumption below the normal opera- tional level are available. reset interface there are three user reset input pins (core, chip, and sys- tem) and three user reset output pins for different levels of reset, if required. debug interface debugging interfaces on the embedded ppc405 core, con- sisting of the jtag and trace ports, offer access to resources internal to the core and assist in software devel- opment. the jtag port provides basic jtag chip testing functionality as well as the ability for external debug tools to gain control of the processor for debug purposes. the trace port furnishes programmers with a mechanism for acquiring instruction execution traces. the jtag port is compatible with ieee std 1149.1, which defines a test access port (tap) and boundary-scan architecture. extensions to the jtag interface provide debuggers with processor control that includes stopping, starting, and stepping the ppc405 core. these extensions are compliant with the ieee 1149.1 specifications for vendor-specific extensions. virtex-ii pro and virtex-ii pro x platform fpgas: functional description r ds083 (v5.0) june 21, 2011 www.xilinx.com module 2 of 4 product specification 20 product not recommended for new designs the trace port provides instruction execution trace informa- tion to an external trace tool. the ppc405 core is capable of back trace and forward trace. back trace is the tracing of instructions prior to a debug event while forward trace is the tracing of instructions after a debug event. the processor jtag port and the fpga jtag port can be accessed independently, or the two can be programmati- cally linked together and accessed via the dedicated fpga jtag pins. for detailed information on the ppc405 jtag interface, please refer to the "jtag interface" section of the powerpc 405 processor block reference guide coreconnect? bus architecture the processor block is compatible with the coreconnect? bus architecture. any coreconn ect compliant cores includ- ing xilinx soft ip can integrate with the processor block through this high-performance bus architecture imple- mented on fpga fabric. the coreconnect architecture provides three buses for interconnecting processor blocks, xilinx soft ip, third party ip, and custom logic, as shown in figure 15 : ? processor local bus (plb) ? on-chip peripheral bus (opb) ? device control register (dcr) bus high-performance peripherals connect to the high-band- width, low-latency plb. slower peripheral cores connect to the opb, which reduces traffi c on the plb, resulting in greater overall system performance. for more information, refer to: http://www-3.ibm.com/chips/te chlib/techlib.nfs/productfa milies/coreconnect_bus_architecture/ functional description: embedded powerpc 405 core this section offers a brief overview of the various functional blocks shown in figure 16 . embedded ppc405 core the embedded ppc405 core is a 32-bit harvard architec- ture processor. figure 16 illustrates its functional blocks: ? cache units ? memory management unit ? fetch decode unit figure 15: coreconnect block diagram ds083-2_02a_010202 system core system core system core processor block peripheral core peripheral core processor local bus on-chip peripheral bus bus bridge coreconnect bus architecture arbiter arbiter dcr bus instruction data dcr bus dcr bus figure 16: embedded ppc405 core block diagram mac alu ds083-2_01_062001 plb master interface data ocm jtag instruction trace d-cache controller d-cache array i-cache controller i-cache array data cache unit instruction cache unit 32 x 32 gpr execution unit (exu) plb master interface instruction ocm instruction shadow tlb (4 entry) unified tlb (64 entry) data shadow tlb (8 entry) fetch and decode logic 3-element fetch queue (pfb1, pfb0, dcd) timers (fit, pit, watchdog) debug logic timers & debug fetch & decode mmu cache units execution unit virtex-ii pro and virtex-ii pro x platform fpgas: functional description r ds083 (v5.0) june 21, 2011 www.xilinx.com module 2 of 4 product specification 21 product not recommended for new designs ?execution unit ?timers ? debug logic unit it operates on instructions in a five stage pipeline consisting of a fetch, decode, execute, write-back, and load write-back stage. most instructions execute in a single cycle, including loads and stores. instruction and data cache the embedded ppc405 core provides an instruction cache unit (icu) and a data cache unit (dcu) that allow concur- rent accesses and minimize pipeline stalls. the instruction and data cache array are 16 kb each. both cache units are two-way set associative. each way is organized into 256 lines of 32 bytes (eight words). the instruction set provides a rich assortment of cache control instructions, including instructions to read tag information and data arrays. the ppc405 core accesses external memory through the instruction (icu) and data cache units (dcu). the cache units each include a 64-bit plb master interface, cache arrays, and a cache controller. the icu and dcu handle cache misses as requests over the plb to another plb device such as an external bus interface unit. cache hits are handled as single cycle memory accesses to the instruction and data caches. instruction cache unit (icu) the icu provides one or two instructions per cycle to the instruction queue over a 64-bit bus. a line buffer (built into the output of the array for manufacturing test) enables the icu to be accessed only once for every four instructions, to reduce power consumption by the array. the icu can forward any or all of the four or eight words of a line fill to the exu to minimi ze pipeline stalls caused by cache misses. the icu aborts speculative fetches aban- doned by the exu, eliminatin g unnecessary line fills and enabling the icu to handle the next exu fetch. aborting abandoned requests also eliminates unnecessary external bus activity, thereby increasing external bus utilization. data cache unit (dcu) the dcu transfers one, two, three, four, or eight bytes per cycle, depending on the number of byte enables presented by the cpu. the dcu contains a single-element command and store data queue to reduce pipeline stalls; this queue enables the dcu to independently process load/store and cache control instructions. dy namic plb request prioritiza- tion reduces pipeline stalls even further. when the dcu is busy with a low-priority request while a subsequent storage operation requested by the cpu is stalled; the dcu auto- matically increases the priority of the current request to the plb. the dcu provides additional f eatures that allow the pro- grammer to tailor its performance for a given application. the dcu can function in write-back or write-through mode, as controlled by the data cache write-through register (dcwr) or the translation look-aside buffer (tlb); the cache controller can be tuned for a balance of performance and memory coherency. write-on-allocate, controlled by the store word on allocate (swoa) field of the core configura- tion register 0 (ccr0), can inhibit line fills caused by store misses, to further reduce potential pipeline stalls and unwanted external bus traffic. fetch and decode logic the fetch/decode logic maintains a steady flow of instruc- tions to the execution unit by placing up to two instructions in the fetch queue. the fetch queue consists of three buf- fers: pre-fetch buffer 1 (pfb1), pre-fetch buffer 0 (pfb0), and decode (dcd). the fetch logic ensures that instructions proceed directly to decode when the queue is empty. static branch prediction as implemented on the ppc405 core takes advantage of some standard statistical proper- ties of code. branches with negative address displacement are by default assumed taken. branches that do not test the condition or count registers are also predicted as taken. the ppc405 core bases branch prediction upon these default conditions when a branch is not resolved and speculatively fetches along the predicted path. the default prediction can be overridden by software at assembly or compile time. branches are examined in the decode and pre-fetch buffer 0 fetch queue stages. two branch instructions can be handled simultaneously. if the branch in decode is not taken, the fetch logic fetches along the predicted path of the branch instruction in pre-fetch buffer 0. if the branch in decode is taken, the fetch logic ignores the branch instruction in pre-fetch buffer 0. execution unit the embedded ppc405 core has a single issue execution unit (exu) containing the register file, arithmetic logic unit (alu), and the multiply-accumulate (mac) unit. the execu- tion unit performs all 32-bit powerpc integer instructions in hardware. the register file is comprised of thirty-two 32-bit general purpose registers (gpr), which are accessed with three read ports and two write ports. during the decode stage, data is read out of the gprs and fed to the execution unit. likewise, during the write-back stage, results are written to the gpr. the use of the five ports on the register file enables either a load or a store operation to execute in par- allel with an alu operation. memory management unit (mmu) the embedded ppc405 core has a 4 gb address space, which is presented as a flat address space. the mmu provides address translation, protection func- tions, and storage attribute control for embedded applica- tions. the mmu supports demand-paged virtual memory and other management schemes that require precise con- trol of logical-to-physical address mapping and flexible virtex-ii pro and virtex-ii pro x platform fpgas: functional description r ds083 (v5.0) june 21, 2011 www.xilinx.com module 2 of 4 product specification 22 product not recommended for new designs memory protection. working with appropriate system-level software, the mmu provides the following functions: ? translation of the 4 gb effective address space into physical addresses ? independent enabling of instruction and data translation/protection ? page-level access contro l using the translation mechanism ? software control of page replacement strategy ? additional control over protection using zones ? storage attributes for cache policy and speculative memory access control the mmu can be disabled under software control. if the mmu is not used, the ppc405 core provides other storage control mechanisms. translation look-aside buffer (tlb) the translation look-aside buffer (tlb) is the hardware resource that controls translation and protection. it consists of 64 entries, each specifying a page to be translated. the tlb is fully associative; a given page entry can be placed anywhere in the tlb. the translation function of the mmu occurs pre-cache. cache tags and indexing use physical addresses. software manages the establishment and replacement of tlb entries. this gives system software significant flexibility in implementing a custom page replacement strategy. for example, to reduce tlb thrashing or translation delays, software can reserve several tlb entries in the tlb for globally accessible static mappings. the instruction set pro- vides several instructions used to manage tlb entries. these instructions are privileged and require the software to be executing in supervisor state. additional tlb instruc- tions are provided to move tlb entry fields to and from gprs. the mmu divides logical storage into pages. eight page sizes (1kb, 4kb, 16kb, 64kb, 256kb, 1mb, 4mb, and 16 mb) are simultaneously supported, such that, at any given time, the tlb can contain entries for any combination of page sizes. in order for a logical to physical translation to exist, a valid entry for the page containing the logical address must be in the tlb. addresses for which no tlb entry exists cause tlb-miss exceptions. to improve performance, four instruction-side and eight data-side tlb entries are kept in shadow arrays. the shadow arrays allow single-cycle address translation and also help to avoid tlb contention between load/store and instruction fetch operations. hardware manages the replacement and invalidation of shadow-tlb entries; no system software action is required. memory protection when address translation is enabled, the translation mech- anism provides a basic level of protection. the zone protection register (zpr) enables the system software to override the tlb access controls. for example, the zpr provides a way to deny read access to application programs. the zpr can be used to classify storage by type; access by type can be changed without manipulating indi- vidual tlb entries. the powerpc architecture provides wiu0ge (write-back / write-through, cacheability, user-defined 0, guarded, endian) storage attributes that control memory accesses, using bits in the tlb or, wh en address translation is dis- abled, storage attribute control registers. when address translation is enabled, storage attribute con- trol bits in the tlb control the storage attributes associated with the current page. when address translation is disabled, bits in each storage attribute control register control the storage attributes associated with storage regions. each storage attribute control register contains 32 fields. each field sets the associated storage attribute for a 128 mb memory region. timers the embedded ppc405 core contains a 64-bit time base and three timers, as shown in figure 17 : ? programmable interval timer (pit) ? fixed interval timer (fit) ? watchdog timer (wdt) the time base counter increments either by an internal sig- nal equal to the cpu clock rate or by a separate external timer clock signal. no interrupts are generated when the time base rolls over. the three timers are synchronous with the time base. the pit is a 32-bit register that decrements at the same rate as the time base is incremented. the user loads the pit register with a value to create the desired delay. when the register reaches zero, the timer stops decrementing and generates a pit interrupt. optionally, the pit can be pro- grammed to auto-reload the last value written to the pit register, after which the pit continues to decrement. the fit generates periodic interrupts based on one of four selectable bits in the time base. when the selected bit changes from 0 to 1, the ppc405 core generates a fit interrupt. the wdt provides a periodic critical-class interrupt based on a selected bit in the time base. this interrupt can be used for system error recovery in the event of software or system lockups. users may select one of four time periods for the interval and the type of reset generated if the wdt expires twice without an intervening clear from software. if enabled, the watchdog timer generates a reset unless an exception handler updates the wdt status bit before the timer has completed two of the selected timer intervals. virtex-ii pro and virtex-ii pro x platform fpgas: functional description r ds083 (v5.0) june 21, 2011 www.xilinx.com module 2 of 4 product specification 23 product not recommended for new designs interrupts the ppc405 provides an interface to an interrupt controller that is logically outside the ppc405 core. this controller combines the asynchronous interrupt inputs and presents them to the embedded core as a single interrupt signal. the sources of asynchronous interrupts are external signals, the jtag/debug unit, and any implemented peripherals. debug logic all architected resources on the embedded ppc405 core can be accessed through the debug logic. upon a debug event, the ppc405 core provides debug information to an external debug tool. three different types of tools are sup- ported depending on the debug mode: rom monitors, jtag debuggers, and instruction trace tools. in internal debug mode, a debug event enables excep- tion-handling software at a dedicated interrupt vector to take over the cpu core and communicate with a debug tool. the debug tool has read-write access to all registers and can set hardware or software breakpoints. rom monitors typically use the internal debug mode. in external debug mode, the cpu core enters stop state (stops instruction execution) when a debug event occurs. this mode offers a debug tool read-write access to all regis- ters in the ppc405 core. once t he cpu core is in stop state, the debug tool can start the cpu core, step an instruction, freeze the timers, or set hardware or software break points. in addition to cpu core control, the debug logic is capable of writing instructions into th e instruction cache, eliminating the need for external memory during initial board bring-up. communication to a debug tool using external debug mode is through the jtag port. debug wait mode offers the same functionality as external debug mode with one exception. in debug wait mode, the cpu core goes into wait state instead of stop state after a debug event. wait state is identical to stop state until an interrupt occurs. in wait state, the ppc405 core can vector to an exception handler, service an interrupt and return to wait state. this mode is particularly useful when debugging real time control systems. real-time trace debug mode is always enabled. the debug logic continuously broadcasts instruction trace information to the trace port. when a debug event occurs, the debug logic signals an external debug tool to save instruction trace information before and after the event. the number of instructions traced depends on the trace tool. debug events signal the debug logic to stop the cpu core, put the cpu core in debug wait state, cause a debug excep- tion or save instruction trace information. big endian and little endian support the embedded ppc405 core supports big endian or little endian byte ordering for instructions stored in external memory. since the powerpc architecture is big endian internally, the icu rearranges the instructions stored as little endian into the big endian format. therefore, the instruction cache always contains instructions in big endian format so that the byte ordering is correct for the execution unit. this feature allows the 405 core to be used in systems designed to function in a little endian environment. figure 17: relationship of timer facilities to base clock tbu (32 bits) bit 3 (2 29 clocks) bit 7 (2 25 clocks) bit 11 (2 21 clocks) bit 15 (2 17 clocks) bit 11 (2 21 clocks) bit 15 (2 17 clocks) bit 19 (2 13 9 clocks) bit 23 (2 clocks) wdt events fit events time base (incrementer) 31 tbl (32 bits) 31 00 pit (decrementer) (32 bits) 31 0 zero detect pit events external clock source ds083-2_06_062001 virtex-ii pro and virtex-ii pro x platform fpgas: functional description r ds083 (v5.0) june 21, 2011 www.xilinx.com module 2 of 4 product specification 24 product not recommended for new designs functional description: fpga input/output blocks (iobs) virtex-ii pro i/o blocks (iobs) are provided in groups of two or four on the perimeter of each device. each iob can be used as input and/or output for single-ended i/os. two iobs can be used as a differential pair. a differential pair is always connected to the same switch matrix, as shown in figure 18 . iob blocks are designed for high-performance i/o, support- ing 22 single-ended standards, as well as differential sig- naling with lvds, ldt, bus lvds, and lvpecl. note: differential i/os must use the same clock. supported i/o standards virtex-ii pro iob blocks feature selectio-ultra inputs and outputs that support a wide variety of i/o signaling stan- dards. in addition to the internal supply voltage (v ccint = 1.5v), output driver supply voltage (v cco ) is dependent on the i/o standard (see ta b l e 8 and ta b l e 9 ). an auxiliary supply voltage (v ccaux = 2.5v) is required, regardless of the i/o standard used. for exact supply volt- age absolute maximum ratings, see virtex-ii pro and virtex-ii pro x platform fpgas: dc and switching charac- teristics . all of the user iobs have fixed-clamp diodes to v cco and to ground. the iobs are not compatible or compliant with 5v i/o standards (not 5v-tolerant). ta b l e 1 0 lists supported i/o stan dards with digitally con- trolled impedance. see digitally controlled impedance (dci), page 31 . figure 18: virtex-ii pro input/output tile iob pad4 iob pad3 differential pair iob pad2 iob pad1 differential pair switch matrix ds083-2_30_010202 ta b l e 8 : supported single-ended i/o standards iostandard attribute output v cco input v cco input v ref board termination voltag e (v tt ) lv t t l (1) 3.3 3.3 n/r n/r lv c m o s 3 3 (1) 3.3 3.3 n/r n/r lvcmos25 2.5 2.5 n/r n/r lvcmos18 1.8 1.8 n/r n/r lvcmos15 1.5 1.5 n/r n/r pci33_3 note (2) note (2) n/r n/r pci66_3 note (2) note (2) n/r n/r pcix note (2) note (2) n/r n/r gtl note (3) note (3) 0.8 1.2 gtlp note (3) note (3) 1.0 1.5 hstl_i 1.5 n/r 0.75 0.75 hstl_ii 1.5 n/r 0.75 0.75 hstl_iii 1.5 n/r 0.9 1.5 hstl_iv 1.5 n/r 0.9 1.5 hstl_i_18 1.8 n/r 0.9 0.9 hstl_ii_18 1.8 n/r 0.9 0.9 hstl_iii _18 1.8 n/r 1.1 1.8 hstl_iv_18 1.8 n/r 1.1 1.8 sstl2_i 2.5 n/r 1.25 1.25 sstl2_ii 2.5 n/r 1.25 1.25 sstl18_i (4) 1.8 n/r 0.9 0.9 sstl18_ii 1.8 n/r 0.9 0.9 notes: 1. refer to xapp659 for more details on interfacing to these 3.3v standards. 2. for pci and pci-x standards, refer to xapp653 . 3. v cco of gtl or gtlp should not be lower than the termination voltage or the voltage seen at the i/o pad. example: if the pin high level is 1.5v, connect v cco to 1.5v. 4. sstl18_i is not a jedec-supported standard. 5. n/r = no requirement. virtex-ii pro and virtex-ii pro x platform fpgas: functional description r ds083 (v5.0) june 21, 2011 www.xilinx.com module 2 of 4 product specification 25 product not recommended for new designs logic resources iob blocks include six storage elements, as shown in figure 19 . each storage element can be configured either as an edge-triggered d-type flip-flop or as a level-sensitive latch. on the input, output, and 3-state path, one or two ddr reg- isters can be used. double data rate is directly accomplished by the two regis- ters on each path, clocked by the rising edges (or falling edges) from two different clock nets. the two clock signals are generated by the dcm and must be 180 degrees out of phase, as shown in figure 20 . there are two input, output, and 3-state data signals, each being alternately clocked out. ta bl e 9 : supported differential signal i/o standards i/o standard output v cco input v cco input v ref output v od ldt_25 2.5 n/r n/r 0.500 ? 0.740 lvds_25 2.5 n/r n/r 0.247 ? 0.454 lvdsext_25 2.5 n/r n/r 0.440 ? 0.820 blvds_25 2.5 n/r n/r 0.250 ? 0.450 ulvds_25 2.5 n/r n/r 0.500 ? 0.740 lvpecl_25 2.5 n/r n/r 0.345 ? 1.185 ldt_25_dt (1) 2.5 2.5 n/r 0.500 ? 0.740 lvds_25_dt (1) 2.5 2.5 n/r 0.247 ? 0.454 lvdsext_25_dt (1) 2.5 2.5 n/r 0.330 ? 0.700 ulvds_25_dt (1) 2.5 2.5 n/r 0.500 ? 0.740 notes: 1. these standards support on-chip 100 ? termination. 2. n/r = no requirement. ta bl e 1 0 : supported dci i/o standards i/o standard output v cco input v cco input v ref termination type lvdci_33 (1) 3.3 3.3 n/r series lvdci_25 2.5 2.5 n/r series lvdci_dv2_25 2.5 2.5 n/r series lvdci_18 1.8 1.8 n/r series lvdci_dv2_18 1.8 1.8 n/r series lvdci_15 1.5 1.5 n/r series lvdci_dv2_15 1.5 1.5 n/r series gtl_dci 1.2 1.2 0.8 single gtlp_dci 1.5 1.5 1.0 single hstl_i_dci 1.5 1.5 0.75 split hstl_ii_dci 1.5 1.5 0.75 split hstl_iii_dci 1.5 1.5 0.9 single hstl_iv_dci 1.5 1.5 0.9 single hstl_i_dci_18 1.8 1.8 0.9 split hstl_ii_dci_18 1.8 1.8 0.9 split hstl_iii_dci_18 1.8 1.8 1.1 single hstl_iv_dci_18 1.8 1.8 1.1 single sstl2_i_dci (2) 2.5 2.5 1.25 split sstl2_ii_dci (2) 2.5 2.5 1.25 split sstl18_i_dci (3) 1.8 1.8 0.9 split sstl18_ii_dci 1.8 1.8 0.9 split lvds_25_dci 2.5 2.5 n/r split lvdsext_25_dci 2.5 2.5 n/r split notes: 1. lvdci_xx is lvcmos output controlled impedance buffers, matching all or half of the reference resistors. 2. these are sstl compatible. 3. sstl18_i is not a jedec-supported standard. 4. n/r = no requirement. figure 19: virtex-ii pro iob block table 10: supported dci i/o standards (continued) i/o standard output v cco input v cco input v ref termination type reg ock1 reg ock2 reg ick1 reg ick2 ddr mux input pa d 3-state reg ock1 reg ock2 ddr mux output iob ds031_29_100900 virtex-ii pro and virtex-ii pro x platform fpgas: functional description r ds083 (v5.0) june 21, 2011 www.xilinx.com module 2 of 4 product specification 26 product not recommended for new designs this ddr mechanism can be used to mirror a copy of the clock on the output. this is useful for propagating a clock along the data that has an identical delay. it is also useful for multiple clock generation, where there is a unique clock driver for every clock load. virtex-ii pro devices can pro- duce many copies of a clock with very little skew. each group of two registers has a clock enable signal (ice for the input registers, oce for the output registers, and tce for the 3-state registers). the clock enable signals are active high by default. if left unconnected, the clock enable for that storage element defaults to the active state. each iob block has common synchronous or asynchronous set and reset (sr and rev signals). two neighboring iobs have a shared routing resource connecting the iclk and otclk pins on pairs of iobs. if two adjacent iobs using ddr registers do not share the same clock signals on their clock pins (iclk1, iclk2, otclk1, and otclk2), one of the clock signals will be unroutable. the iob pairing is identical to the lvds iob pairs. hence, the package pin-out table can also be used for pin assign- ment to avoid conflict. sr forces the storage element into the state specified by the srhigh or srlow attribute. srhigh forces a logic 1. srlow forces a logic ?0?. when sr is used, a second input (rev) forces the storage element into the opposite state. the reset condition predominates over the set condition. the ini- tial state after configuration or global initialization state is defined by a separate init0 and init1 attribute. by default, the srlow attribute forces init0, and the srhigh attribute forces init1. for each storage element, the srhigh, srlow, init0, and init1 attributes are independent. synchronous or asynchronous set / reset is consistent in an iob block. all the control signals have independent polarity. any inverter placed on a control input is automatically absorbed. each register or latch, independent of all other registers or latches, can be configured as follows: ? no set or reset ? synchronous set ? synchronous reset ? synchronous set and reset ? asynchronous set (preset) ? asynchronous reset (clear) ? asynchronous set and reset (preset and clear) the synchronous reset overrides a set, and an asynchro- nous clear overrides a preset. refer to figure 21 . figure 20: double data rate registers d1 clk1 ddr mux q1 fddr d2 clk2 qq q2 d1 clk1 ddr mux dcm q1 fddr d2 clk2 q2 180 0 dcm 0 ds083-2_26_122001 virtex-ii pro and virtex-ii pro x platform fpgas: functional description r ds083 (v5.0) june 21, 2011 www.xilinx.com module 2 of 4 product specification 27 product not recommended for new designs input/output individual options each device pad has optional pull-up/pull-down resistors and weak-keeper circuit in the lvttl, lvcmos, and pci selectio-ultra configurat ions, as illustrated in figure 22 . values of the optional pull-up and pull-down resistors fall within a range of 40 k ? to 120 k ? when v cco = 2.5v (from 2.38v to 2.63v only). the clamp diodes are always present, even when power is not. the optional weak-keeper circuit is connected to each user i/o pad. when selected, the circuit monitors the voltage on the pad and weakly drives the pin high or low. if the pin is connected to a multiple-source signal, the weak-keeper holds the signal in its last st ate if all drivers are disabled. maintaining a valid logic level in this way eliminates bus chatter. an enabled pull-up or pull-down overrides the weak-keeper circuit. lvcmos25 sinks and sources current up to 24 ma. the current is programmable (see ta b l e 1 1 ). drive strength and slew rate controls for each output driver minimize bus tran- sients. for lvdci and lvdci_dv2 standards, drive strength and slew rate controls are not available. figure 21: register / latch configuration in an iob block ff latch sr rev d1 q1 ce ck1 ff latch sr rev d2 ff1 ff2 ddr mux q2 ce ck2 rev sr (o/t) clk1 (oq or tq) (o/t) ce (o/t) 1 (o/t) clk2 (o/t) 2 attribute init1 init0 srhigh srlow attribute init1 init0 srhigh srlow reset type sync async ds031_25_110300 shared by all registers figure 22: lvttl, lvcmos, or pci selectio-ultra standard v cco v cco v cco weak keeper program delay obuf ibuf program current clamp diode pa d v ccaux = 2.5v ds083-2_07_101801 v ccint = 1.5v 40k ? 120k 40k ? 120k virtex-ii pro and virtex-ii pro x platform fpgas: functional description r ds083 (v5.0) june 21, 2011 www.xilinx.com module 2 of 4 product specification 28 product not recommended for new designs figure 23 shows the sstl2, sstl18, and hstl configura- tions. hstl can sink current up to 48 ma. (hstl iv) all pads are protected against damage from electrostatic discharge (esd) and from over-voltage transients. virtex-ii pro uses two memory cells to control the configura- tion of an i/o as an input. th is is to reduce the probability of an i/o configured as an input from flipping to an output when subjected to a single event upset (seu) in space applications. prior to configuration, all out puts not involved in configura- tion are forced into their high-impedance state. the pull-down resistors and the weak-keeper circuits are inac- tive. the dedicated pin hswap_en controls the pull-up resistors prior to configuration. by default, hswap_en is set high, which disables the pull-up resistors on user i/o pins. when hswap_en is set low, the pull-up resistors are activated on user i/o pins. all virtex-ii pro iobs (except rocketio transceiver pins) support ieee 1149.1 and ieee 1532 compatible bound- ary-scan testing. input path the virtex-ii pro iob input path routes input signals directly to internal logic and / or through an optional input flip-flop or latch, or through t he ddr input registers. an optional delay element at the d-input of the storage element eliminates pad-to-pad hold time. the delay is matched to the internal clock-distribution delay of the virtex-ii pro device, and when used, assures that the pad-to-pad hold time is zero. each input buffer can be configured to conform to any of the low-voltage signaling standards supported. in some of these standards the input buff er utilizes a user-supplied threshold voltage, v ref . the need to supply v ref imposes constraints on which standards can be used in the same bank. see i/o banking description. output path the output path includes a 3-state output buffer that drives the output signal onto the pad. the output and / or the 3-state signal can be routed to the buffer directly from the internal logic or through an output / 3-state flip-flop or latch, or through the ddr output / 3-state registers. each output driver can be individually programmed for a wide range of low-voltage signaling standards. in most sig- naling standards, the output high voltage depends on an externally supplied v cco voltage. the need to supply v cco imposes constraints on which standards can be used in the same bank. see i/o banking description. i/o banking some of the i/o standards described above require v cco and v ref voltages. these voltages are externally supplied and connected to device pins that serve groups of iob blocks, called banks. consequently, restrictions exist about which i/o standards can be combined within a given bank. eight i/o banks result from dividing each edge of the fpga into two banks, as shown in figure 24 and figure 25 . each bank has multiple v cco pins, all of which must be con- nected to the same voltage. this voltage is determined by the output standards in use. ta bl e 1 1 : lvcmos programmable currents (sink and source) selectio-ultra programmable current (worst-case guaranteed minimum) lvttl 2ma 4ma 6ma 8ma 12ma 16ma 24ma lvcmos33 2 ma 4 ma 6 ma 8 ma 12 ma 16 ma 24 ma lvcmos25 2 ma 4 ma 6 ma 8 ma 12 ma 16 ma 24 ma lvcmos18 2 ma 4 ma 6 ma 8 ma 12 ma 16 ma n/a lvcmos15 2 ma 4 ma 6 ma 8 ma 12 ma 16 ma n/a figure 23: sstl or hstl selectio-ultra standards v cco obuf v ref clamp diode pa d v ccaux = 2.5v v ccint = 1.5v ds031_24_100900 virtex-ii pro and virtex-ii pro x platform fpgas: functional description r ds083 (v5.0) june 21, 2011 www.xilinx.com module 2 of 4 product specification 29 product not recommended for new designs some input standards require a user-supplied threshold voltage (v ref ), and certain user-i/o pins are automatically configured as v ref inputs. approximately one in six of the i/o pins in the bank assume this role. v ref pins within a bank are interconnected internally, thus only one v ref voltage can be used within each bank. how- ever, for correct operation, all v ref pins in the bank must be connected to the external reference voltage source. the v cco and the v ref pins for each bank appear in the device pinout tables. within a given package, the number of v ref and v cco pins can vary depending on the size of device. in larger devices, more i/o pins convert to v ref pins. since these are always a superset of the v ref pins used for smaller devices, it is possible to design a pcb that permits migration to a larger device if necessary. all v ref pins for the largest device anticipated must be con- nected to the v ref voltage and not used for i/o. in smaller devices, some v cco pins used in larger devices do not con- nect within the package. these unconnected pins can be left unconnected externally, or, if necessary, they can be connected to v cco to permit migration to a larger device. rules for combining i/o standards in the same bank the following rules must be obeyed to combine different input, output, and bi-directional standards in the same bank: 1. combining output standards only. output standards with the same output v cco requirement can be combined in the same bank. compatible example: sstl2_i and lvds_25 outputs incompatible example: sstl2_i (output v cco = 2.5v) and lvcmos33 (output v cco = 3.3v) outputs 2. combining input standards only. input standards with the same input v cco and input v ref requirements can be combined in the same bank. compatible example: lvcmos15 and hstl_iv inputs incompatible example: lvcmos15 (input v cco = 1.5v) and lvcmos18 (input v cco = 1.8v) inputs incompatible example: hstl_i_dci_18 (v ref = 0.9v) and hstl_iv_dci_18 (v ref = 1.1v) inputs 3. combining input standards and output standards. input standards and output standards with the same input v cco and output v cco requirement can be combined in the same bank. compatible example: lvds_25 output and hstl_i input incompatible example: lvds_25 output (output v cco = 2.5v) and hstl_i_dci_18 input (input v cco = 1.8v) 4. combining bi-directional standards with input or output standards. when combining bi-directional i/o with other standards, make sure the bi-directional standard can meet rules 1 through 3 above. 5. additional rules for combining dci i/o standards. a. no more than one single termination type (input or output) is allowed in the same bank. incompatible example: hstl_iv_dci input and hstl_iii_dci input b. no more than one split termination type (input or output) is allowed in the same bank. incompatible example: hstl_i_dci input and hstl_ii_dci input the implementation tools will enforce the above design rules. table 12, page 30 , summarizes all standards and voltage supplies. figure 24: i/o banks: wire-bond packages (fg) top view figure 25: i/o banks: flip-chip packages (ff) top view ug002_c2_014_041403 bank 0 bank 1 bank 5 bank 4 bank 7 bank 6 bank 2 bank 3 ds031_66_041403 bank 1 bank 0 bank 4 bank 5 bank 2 bank 3 bank 7 bank 6 virtex-ii pro and virtex-ii pro x platform fpgas: functional description r ds083 (v5.0) june 21, 2011 www.xilinx.com module 2 of 4 product specification 30 product not recommended for new designs ta bl e 1 2 : summary of voltage supply requirements for all input and output standards i/o standard v cco v ref termination type output input input output input lvt t l (1) 3.3 3.3 n/r n/r n/r lvc m o s 3 3 (1) n/r n/r n/r lvdci_33 (1) n/r series n/r pcix (2) n/r n/r n/r pci33_3 (2) n/r n/r n/r pci66_3 (2) n/r n/r n/r lvds_25 2.5 note (3) n/r n/r n/r lvdsext_25 n/r n/r n/r ldt_25 n/r n/r n/r ulvds_25 n/r n/r n/r blvds_25 n/r n/r n/r lvpecl_25 n/r n/r n/r sstl2_i 1.25 n/r n/r sstl2_ii 1.25 n/r n/r lvc m o s 2 5 2.5 n/r n/r n/r lvdci_25 n/r series n/r lvdci_dv2_25 n/r series n/r lvds_25_dci n/r n/r split lvdsext_25_dci n/r n/r split sstl2_i_dci 1.25 n/r split sstl2_ii_dci 1.25 split split lvds_25_dt n/r n/r n/r lvdsext_25_dt n/r n/r n/r ldt_25_dt n/r n/r n/r ulvds_25_dt n/r n/r n/r hstl_iii_18 1.8 note (3) 1.1 n/r n/r hstl_iv_18 1.1 n/r n/r hstl_i_18 0.9 n/r n/r hstl_ii_18 0.9 n/r n/r sstl18_i 0.9 n/r n/r sstl18_ii 0.9 n/r n/r lv c m o s1 8 1.8 n/r n/r n/r lvdci_18 n/r series n/r lvdci_dv2_18 n/r series n/r hstl_iii_dci_18 1.1 n/r single hstl_iv_dci_18 1.1 single single hstl_i_dci_18 0.9 n/r split hstl_ii_dci_18 0.9 split split sstl18_i_dci 0.9 n/r split sstl18_ii_dci 0.9 split split hstl_iii 1.5 note (3) 0.9 n/r n/r hstl_iv 0.9 n/r n/r hstl_i 0.75 n/r n/r hstl_ii 0.75 n/r n/r lv c m o s1 5 1.5 n/r n/r n/r lvdci_15 n/r series n/r lvdci_dv2_15 n/r series n/r gtlp_dci 1 single single hstl_iii_dci 0.9 n/r single hstl_iv_dci 0.9 single single hstl_i_dci 0.75 n/r split hstl_ii_dci 0.75 split split gtl_dci 1.2 1.2 0.8 single single gtlp n/r note (3) 1n/rn/r gtl 0.8 n/r n/r notes: 1. see application note xapp659 for more detailed information. 2. see application note xapp653 for more detailed information. 3. pin voltage must not exceed v cco . 4. n/r = no requirement. table 12: summary of voltage supply requirements for all input and output standards (continued) i/o standard v cco v ref termination type output input input output input virtex-ii pro and virtex-ii pro x platform fpgas: functional description r ds083 (v5.0) june 21, 2011 www.xilinx.com module 2 of 4 product specification 31 product not recommended for new designs digitally controlled impedance (dci) today?s chip output signals with fast edge rates require ter- mination to prevent reflections and maintain signal integrity. high pin count packages (especially ball grid arrays) can not accommodate external termination resistors. virtex-ii pro xcite dci provides controlled impedance drivers and on-chip termination for single-ended and differ- ential i/os. this eliminates the need for external resistors and improves signal integrity. the dci feature can be used on any iob by selecting one of the dci i/o standards. when applied to inputs, dci pr ovides input parallel termina- tion. when applied to outputs, dci provides controlled impedance drivers (series termination) or output parallel termination. dci operates independently on each i/o bank. when a dci i/o standard is used in a particular i/o bank, external refer- ence resistors must be connected to two dual-function pins on the bank. these resistors, voltage reference of n transis- tor (vrn) and the voltage reference of p transistor (vrp) are shown in figure 26 . when used with a terminated i/o standard, the value of the resistors are specified by the standard (typically 50 ? ). when used with a controlled impedance driver, the resistors set the output impedance of the driver within the specified range (20 ? to 100 ?? . for all series and parallel termina- tions listed in ta b l e 1 3 and ta bl e 1 4 , the reference resistors must have the same value for any given bank. one percent resistors are recommended. the dci system adjusts the i/o impedance to match the two external reference resistors, or half of the reference resis- tors, and compensates for impedance changes due to volt- age and/or temperature fluctuations. the adjustment is done by turning parallel transistors in the iob on or off. controlled impedance drivers (series termination) dci can be used to provide a buffer with a controlled output impedance. it is desirable for this output impedance to match the transmission line impedance (z 0 ). virtex-ii pro input buffers also support lvdci and lvdci_dv2. controlled impedance terminations (parallel) dci also provides on-chip termination for sstl2, sstl18, hstl (class i, ii, iii, or iv), lvds_25, lvdsext_25, and gtl/gtlp receivers or transmitters on bidirectional lines. ta b l e 1 4 and ta bl e 1 5 list the on-chip parallel terminations available in virtex-ii pro devices. v cco must be set accord- ing to ta b l e 1 0 . there is a v cco requirement for gtl_dci and gtlp_dci, due to the on-chip termination resistor. figure 26: dci in a virtex-ii pro bank ds031_50_101200 v cco gnd dci dci dci dci vrn vrp 1 bank r ref (1%) r ref (1%) figure 27: internal series termination table 13: selectio-ultra controlled impedance buffers v cco dci dci half impedance 3.3v lvdci_33 n/a 2.5v lvdci_25 lvdci_dv2_25 1.8v lvdci_18 lvdci_dv2_18 1.5v lvdci_15 lvdci_dv2_15 table 14: selectio-ultra buffers with on-chip parallel termination i/o standard description iostandard attribute external termination on-chip termination sstl class i, 2.5v sstl2_i sstl2_i_dci (1) sstl class ii, 2.5v sst l2_ii sstl2_ii_dci (1) sstl class i, 1.8v sstl18_i sstl18_i_dci sstl class ii, 1.8v sstl18_ii sstl18_ii_dci hstl class i hstl_i hstl_i_dci hstl class i, 1.8v hstl_i_18 hstl_i_dci_18 hstl class ii hstl_ii hstl_ii_dci hstl class ii, 1.8v hstl_ii_18 hstl_ii_dci_18 hstl class iii hstl_iii hstl_iii_dci hstl class iii, 1.8v hstl_iii_18 hstl_iii_dci_18 hstl class iv hstl_iv hstl_iv_dci hstl class iv, 1.8v hs tl_iv_18 hstl_iv_dci_18 gtl gtl gtl_dci gtl plus gtlp gtlp_dci notes: 1. sstl compatible. z 0 iob z virtex-ii pro dci ds083-2_09_082902 v cco = 3.3v, 2.5 v, 1.8 v, or 1.5 v virtex-ii pro and virtex-ii pro x platform fpgas: functional description r ds083 (v5.0) june 21, 2011 www.xilinx.com module 2 of 4 product specification 32 product not recommended for new designs figure 28 provides examples illustrating the use of the hstl_i _dci, hstl_ii_dci, hstl_iii _dci, and hstl_iv_dci i/o standards. for a complete list, see the virtex-ii pro platform fpga user guide . ta bl e 1 5 : selectio-ultra differential buffers with on-chip termination i/o standard description iostandard attribute external termination on-chip termination lvds 2.5v lvds_25 lvds_25_dci lvds extended 2.5v lvdsext_25 lvdsext_25_dci figure 28: hstl dci usage examples rr rr r r r r rr 2r 2r r 2r r 2r 2r 2r 2r 2r ds083-2_65a_082102 conventional dci transmit conventional receive conventional transmit dci receive dci transmit dci receive bidirectional reference resistor recommended z 0 vrn = vrp = r = z 0 50 vrn = vrp = r = z 0 50 vrn = vrp = r = z 0 50 vrn = vrp = r = z 0 50 hstl_i hstl_ii hstl_iii hstl_iv n/a n/a r r r r z 0 r r 2r 2r 2r 2r z 0 z 0 z 0 z 0 z 0 z 0 z 0 z 0 z 0 z 0 z 0 z 0 z 0 z 0 z 0 virtex-ii pro dci virtex-ii pro dci virtex-ii pro dci z 0 virtex-ii pro dci virtex-ii pro dci virtex-ii pro dci virtex-ii pro dci virtex-ii pro dci virtex-ii pro dci virtex-ii pro dci virtex-ii pro dci virtex-ii pro dci virtex-ii pro dci virtex-ii pro dci virtex-ii pro dci virtex-ii pro dci virtex-ii pro dci virtex-ii pro dci 2r 2r 2r 2r z 0 r r v cco /2 v cco /2 v cco /2 v cco /2 v cco /2 v cco /2 v cco v cco v cco v cco v cco v cco v cco v cco v cco v cco v cco v cco v cco v cco v cco v cco v cco v cco v cco v cco v cco v cco virtex-ii pro and virtex-ii pro x platform fpgas: functional description r ds083 (v5.0) june 21, 2011 www.xilinx.com module 2 of 4 product specification 33 product not recommended for new designs figure 29 provides examples illustrating th e use of the sstl2_i_dci, sstl2_ii_d ci, sstl18_i_dci, and sstl18_ii_dci i/o standards. for a complete list, see the virtex-ii pro platform fpga user guide . figure 29: sstl dci usage examples ds083-2_65b_011603 conventional dci transmit conventional receive conventional transmit dci receive dci transmit dci receive bidirectional reference resistor recommended z 0 (2) vrn = vrp = r = z 0 50 vrn = vrp = r = z 0 50 sstl2_i or sstl18_i sstl2_ii or sstl18_ii n/a z 0 r v cco /2 z 0 r/2 rr v cco /2 v cco /2 z 0 r/2 r v cco /2 z 0 r/2 2r 2r v cco z 0 r/2 2r 2r v cco 2r r v cco v cco /2 2r z 0 r v cco /2 z 0 2r 2r v cco 2r 2r v cco z 0 2r 2r v cco z 0 2r 2r v cco 2r 2r v cco 25 (1) 25 (1) 25 (1) 25 (1) 25 (1) 25 virtex-ii pro dci virtex-ii pro dci virtex-ii pro dci virtex-ii pro dci virtex-ii pro dci virtex-ii pro dci virtex-ii pro dci virtex-ii pro dci virtex-ii pro dci virtex-ii pro dci notes: 1. the sstl-compatible 25 series resistor is accounted for in the dci buffer, and it is not dci controlled. 2. z 0 is the recommended pcb trace impedance. virtex-ii pro and virtex-ii pro x platform fpgas: functional description r ds083 (v5.0) june 21, 2011 www.xilinx.com module 2 of 4 product specification 34 product not recommended for new designs figure 30 provides examples illust rating the use of the lvds_25_dci and lvdsext_25_ dci i/o standards. for a complete list, see the virtex-ii pro platform fpga user guide . on-chip differential termination virtex-ii pro provides a true 100 ? differential termination (dt) across the input differential receiver terminals. the lvds_25_dt, lvdsext_25_dt, ldt_25_dt, and ulvds_25_dt standards support on-chip differential termi- nation. the on-chip input differential termination in virtex-ii pro provides major advantages over the external resistor or the dci termination solution: ? eliminates the stub at th e receiver completely and therefore greatly improve signal integrity ? consumes less power than dci termination ? supports ldt (not supported by dci termination) ? frees up vrp/vrn pins figure 31 provides examples illustrating the use of the lvds_25_dt, lvdsext_2 5_dt, ldt_25_dt, and ulvds_25_dt i/o standards. for further details, refer to solution record 17244 . also see the virtex-ii pro platform fpga user guide for more design information. figure 30: lvds dci usage examples ds083-2_65c_022103 conventional conventional transmit dci receive reference resistor recommended z 0 vrn = vrp = r = z 0 50 lvds_25_dci and lvdsext_25_dci receiver virtex-ii pro lvds dci z 0 2r 2r v cco z 0 2r 2r v cco virtex-ii pro lvds z 0 2r z 0 note: only lvds25_dci is supported (v cco = 2.5v only) figure 31: lvds differential termination usage examples ds083-2_65e_052703 conventional conventional transmit, on-chip differential termination receive recommended z 0 50 lvds_25_dt, lvdsext_25_dt, ldt_25_dt, and ulvds_25_dt receiver virtex-ii pro lvds on-chip differential termination z 0 100 z 0 virtex-ii pro lvds z 0 2r z 0 note: only 2.5v lvds standards are supported (v cco = 2.5v only) virtex-ii pro and virtex-ii pro x platform fpgas: functional description r ds083 (v5.0) june 21, 2011 www.xilinx.com module 2 of 4 product specification 35 product not recommended for new designs configurable log ic blocks (clbs) the virtex-ii pro configurable logic blocks (clb) are orga- nized in an array and are used to build combinatorial and synchronous logic designs. each clb element is tied to a switch matrix to access the general routing matrix, as shown in figure 32 . a clb element comprises 4 similar slices, with fast local feedback within the clb. the four slices are split in two columns of two slices with two inde- pendent carry logic chains and one common shift chain. slice description each slice includes two 4-input function generators, carry logic, arithmetic logic gates, wide function multiplexers and two storage elements. as shown in figure 33 , each 4-input function generator is programmable as a 4-input lut, 16 bits of distributed selectram+ memory, or a 16-bit vari- able-tap shift register element. the output from the function generator in each slice drives both the slice output and the d input of the storage element. figure 34 shows a more detailed view of a single slice. configurations look-up table virtex-ii pro function generators are implemented as 4-input look-up tables (luts). four independent inputs are provided to each of the two function generators in a slice (f and g). these function generators are each capable of implementing any arbitrarily defined boolean function of four inputs. the propagation delay is therefore independent of the function implemented. signals from the function gener- ators can exit the slice (x or y output), can input the xor dedicated gate (see arithmetic logic), or input the carry-logic multiplexer (see fast look-ahead carry logic), or feed the d input of the storage element, or go to the muxf5 (not shown in figure 34 ). in addition to the basic luts, the virtex-ii pro slice contains logic (muxf5 and muxfx multiplexers) that combines function generators to provide any function of five, six, seven, or eight inputs. the muxfx is either muxf6, muxf7, or muxf8 according to the slice considered in the clb. selected functions up to nine inputs (muxf5 multi- plexer) can be implemented in one slice. the muxfx can also be a muxf6, muxf7, or muxf8 multiplexer to map any function of six, seven, or eight inputs and selected wide logic functions. register/latch the storage elements in a virtex-ii pro slice can be config- ured either as edge-triggered d-type flip-flops or as level-sensitive latches. the d input can be directly driven by the x or y output via the dx or dy input, or by the slice inputs bypassing the function generators via the bx or by input. the clock enable signal (ce) is active high by default. if left unconnected, the clock enable for that storage ele- ment defaults to the active state. in addition to clock (ck) and clock enable (ce) signals, each slice has set and reset signals (sr and by slice inputs). sr forces the storage element into the state speci- fied by the attribute srhigh or srlow. srhigh forces a logic 1 when sr is asserted. srlow forces a logic 0. when sr is used, an optional second input (by) forces the stor- age element into the opposite state via the rev pin. the reset condition is predominant over the set condition. (see figure 35 .) the initial state after configurat ion or global initial state is defined by a separate init0 and init1 attribute. by default, setting the srlow attribute sets init0, and setting the srhigh attribute sets init1. for each slice, set and reset can be set to be synchronous or asynchronous. virtex-ii pro devices also have the ability to set init0 and init1 independent of srhigh and srlow. the control signals clock (clk), clock enable (ce) and set/reset (sr) are common to both storage elements in one slice. all of the control signals have independent polarity. any inverter placed on a control input is automatically absorbed. figure 32: virtex-ii pro clb element figure 33: virtex-ii pro slice configuration slice x1y1 slice x1y0 slice x0y1 slice x0y0 fast connects to neighbors switch matrix ds083-2_32_122001 shift cin cout tbuf cout cin tbuf register/ latch muxf5 muxfx cy srl16 ram16 lut g register/ latch arithmetic logic cy lut f ds083-2_31_122001 srl16 ram16 orcy virtex-ii pro and virtex-ii pro x platform fpgas: functional description r ds083 (v5.0) june 21, 2011 www.xilinx.com module 2 of 4 product specification 36 product not recommended for new designs figure 34: virtex-ii pro slice (top half) g4 sopin a4 g3 a3 g2 a2 g1 a1 wg4 wg4 wg3 wg3 wg2 wg2 wg1 by wg1 dual-port lut ff latch ram rom shift-reg d 0 mc15 ws sr sr rev di g y g2 g1 by 1 0 prod dq ce ce ck clk muxcy yb dig dy y 0 1 muxcy 0 1 1 sopout dymux gymux ybmux orcy wsg we[2:0] shiftout cyog xorg we clk wsf altdig ce sr clk slicewe[2:0] multand shared between x & y registers shiftin cout cin ds031_01_112502 q virtex-ii pro and virtex-ii pro x platform fpgas: functional description r ds083 (v5.0) june 21, 2011 www.xilinx.com module 2 of 4 product specification 37 product not recommended for new designs the set and reset functionality of a register or a latch can be configured as follows: ? no set or reset ? synchronous set ? synchronous reset ? synchronous set and reset ? asynchronous set (preset) ? asynchronous reset (clear) ? asynchronous set and re set (preset and clear) the synchronous reset has precedence over a set, and an asynchronous clear has precedence over a preset. distributed selectram+ memory each function generator (lut) can implement a 16 x 1-bit synchronous ram resource called a distributed selectram+ element. selectram+ elements are configu- rable within a clb to implement the following: ? single-port 16 x 8-bit ram ? single-port 32 x 4-bit ram ? single-port 64 x 2-bit ram ? single-port 128 x 1-bit ram ? dual-port 16 x 4-bit ram ? dual-port 32 x 2-bit ram ? dual-port 64 x 1-bit ram distributed selectram+ memory modules are synchronous (write) resources. the combinatorial read access time is extremely fast, while the syn chronous write simplifies high-speed designs. a synchronous read can be imple- mented with a storage element in the same slice. the dis- tributed selectram+ memory and the storage element share the same clock input. a write enable (we) input is active high, and is driven by the sr input. ta b l e 1 6 shows the number of luts (2 per slice) occupied by each distributed selectram+ configuration. for single-port configurations, distributed selectram+ memory has one address port for synchronous writes and asynchronous reads. for dual-port configurations, distributed selectram+ mem- ory has one port for synchronous writes and asynchronous reads and another port for asynchronous reads. the func- tion generator (lut) has separated read address inputs (a1, a2, a3, a4) and write address inputs (wg1/wf1, wg2/wf2, wg3/wf 3, wg4/wf4). in single-port mode, read and write addresses share the same address bus. in dual-port mode, one function genera- tor (r/w port) is connected with shared read and write addresses. the second function generator has the a inputs (read) connected to the second read-only port address and the w inputs (write) shared with the first read/write port figure 35: register / latch configuration in a slice ff ffy latch sr rev dq ce ck yq ff ffx latch sr rev d q ce ck xq ce dx dy by clk bx sr attribute init1 init0 srhigh srlow attribute init1 init0 srhigh srlow reset type sync async ds083-2_22_122001 ta bl e 1 6 : distributed selectra m+ configurations ram number of luts 16 x 1s 1 16 x 1d 2 32 x 1s 2 32 x 1d 4 64 x 1s 4 64 x 1d 8 128 x 1s 8 notes: 1. s = single-port configuration; d = dual-port configuration virtex-ii pro and virtex-ii pro x platform fpgas: functional description r ds083 (v5.0) june 21, 2011 www.xilinx.com module 2 of 4 product specification 38 product not recommended for new designs figure 36 , figure 37 , and figure 38 illustrate various exam- ple configurations. similar to the ram configuration, each function generator (lut) can implement a 16 x 1-bit rom. five configurations are available: rom16x1, rom32x1, rom64x1, rom128x1, and rom256x1. the rom elements are cas- cadable to implement wider or/and deeper rom. rom con- tents are loaded at configuration. ta b l e 1 7 shows the number of luts occupied by each configuration. figure 36: distributed selectram+ (ram16x1s) figure 37: single-port distributed selectram+ (ram32x1s) a[3:0] d d di ws wsg we wclk ram 16x1s d q ram we ck a[4:1] wg[4:1] output registered output (optional) (sr) 4 4 (by) ds031_02_100900 a[3:0] d wsg f5mux we wclk ram 32x1s d q we we0 ck wsf d di ws ram g[4:1] a[4] wg[4:1] d di ws ram f[4:1] wf[4:1] output registered output (optional) (sr) 4 (by) (bx) 4 ds083-2_10_050901 figure 38: dual-port distributed selectram+ (ram16x1d) table 17: rom configuration rom number of luts 16 x 1 1 32 x 1 2 64 x 1 4 128 x 1 8 (1 clb) 256 x 1 16 (2 clbs) a[3:0] d wsg we wclk ram 16x1d we ck d di ws ram g[4:1] wg[4:1] dual_port ram dual_port 4 (by) dpra[3:0] spo a[3:0] wsg we ck d di ws g[4:1] wg[4:1] dpo 4 4 ds031_04_110100 (sr) virtex-ii pro and virtex-ii pro x platform fpgas: functional description r ds083 (v5.0) june 21, 2011 www.xilinx.com module 2 of 4 product specification 39 product not recommended for new designs shift registers each function generator can also be configured as a 16-bit shift register. the write operation is synchronous with a clock input (clk) and an optional clock enable, as shown in figure 39 . a dynamic read access is performed through the 4-bit address bus, a[3:0]. the configurable 16-bit shift regis- ter cannot be set or reset. the read is asynchronous; how- ever, the storage element or flip-flop is available to implement a synchronous read. any of the 16 bits can be read out asynchronously by varying the address. the stor- age element should always be used with a constant address. for example, when building an 8-bit shift register and configuring the addresses to point to the 7th bit, the 8th bit can be the flip-flop. the overall system performance is improved by using the superior clock-to-out of the flip-flops. an additional dedicated connection between shift registers allows connecting the last bit of one shift register to the first bit of the next, without using the ordinary lut output. (see figure 40 .) longer shift registers can be built with dynamic access to any bit in the chain. the shift register chaining and the muxf5, muxf6, and muxf7 multiplexers allow up to a 128-bit shift register with addressable access to be implemented in one clb. figure 39: shift register configurations a[3:0] shiftin shiftout d(by) d mc15 di wsg ce (sr) clk srlc16 d q shift-reg we ck a[4:1] output registered output (optional) 4 ds031_05_110600 ws figure 40: cascadable shift register srlc16 mc15 mc15 d srlc16 di shiftin cascadable out slice s0 slice s1 slice s2 slice s3 1 shift chain in clb clb ds031_06_110200 ff ff d srlc16 mc15 mc15 d srlc16 di shiftin shiftout ff ff d srlc16 mc15 mc15 d srlc16 di di shiftin in shiftout ff ff d srlc16 mc15 mc15 d srlc16 di shiftout ff ff d di di di out virtex-ii pro and virtex-ii pro x platform fpgas: functional description r ds083 (v5.0) june 21, 2011 www.xilinx.com module 2 of 4 product specification 40 product not recommended for new designs multiplexers virtex-ii pro function generators and associated multiplex- ers can implement the following: ? 4:1 multiplexer in one slice ? 8:1 multiplexer in two slices ? 16:1 multiplexer in one clb element (4 slices) ? 32:1 multiplexer in two clb elements (8 slices) each virtex-ii pro slice has one muxf5 multiplexer and one muxfx multiplexer. th e muxfx multiplexer imple- ments the muxf6, muxf7, or muxf8, as shown in figure 41 . each clb element has two muxf6 multiplexers, one muxf7 multiplexer and one muxf8 multiplexer. exam- ples of multiplexers are shown in the virtex-ii pro platform fpga user guide . any lut can implement a 2:1 multi- plexer. fast lookahead carry logic dedicated carry logic provides fast arithmetic addition and subtraction. the virtex-ii pro clb has two separate carry chains, as shown in the figure 42 . the height of the carry chains is two bits per slice. the carry chain in the virtex-ii pro device is running upward. the ded- icated carry path and carry multiplexer (muxcy) can also be used to cascade function generators for implementing wide logic functions. arithmetic logic the arithmetic logic includes an xor gate that allows a 2-bit full adder to be implemented within a slice. in addition, a dedicated and (mult_and) gate (shown in figure 34 ) improves the efficiency of multiplier implementation. figure 41: muxf5 and muxfx multiplexers slice s1 slice s0 slice s3 slice s2 clb ds031_08_110200 f5 f6 f5 f7 f5 f6 f5 f8 muxf8 combines the two muxf7 outputs (two clbs) muxf6 combines the two muxf5 outputs from slices s2 and s3 muxf7 combines the two muxf6 outputs from slices s0 and s2 muxf6 combines the two muxf6 outputs from slices s0 and s1 g f g f g f g f virtex-ii pro and virtex-ii pro x platform fpgas: functional description r ds083 (v5.0) june 21, 2011 www.xilinx.com module 2 of 4 product specification 41 product not recommended for new designs figure 42: fast carry logic path ff lut oi muxcy ff lut oi muxcy ff lut oi muxcy ff lut oi muxcy cin cin cin cout ff lut oi muxcy ff lut oi muxcy ff lut oi muxcy ff lut oi muxcy cin cout cout to cin of s2 of the next clb cout to s0 of the next clb (first carry chain) (second carry chain) slice s1 slice s0 slice s3 slice s2 clb ds031_07_110200 virtex-ii pro and virtex-ii pro x platform fpgas: functional description r ds083 (v5.0) june 21, 2011 www.xilinx.com module 2 of 4 product specification 42 product not recommended for new designs sum of products each virtex-ii pro slice has a dedicated or gate named orcy, oring together outputs from the slices carryout and the orcy from an adjacent slice. the orcy gate with the dedicated sum of products (sop) chain are designed for implementing large, flexible sop chains. one input of each orcy is connected through the fast sop chain to the output of the previous orcy in the same slice row. the second input is connected to the output of the top muxcy in the same slice, as shown in figure 43 . luts and muxcys can implement large and gates or other combinatorial logic functions. figure 44 illustrates lut and muxcy resources configured as a 16-input and gate. figure 43: horizontal cascade chain muxcy 4 muxcy 4 slice 1 ds031_64_110300 orcy lut lut muxcy 4 muxcy 4 slice 0 v cc lut lut muxcy 4 muxcy 4 slice 3 orcy lut lut muxcy 4 muxcy 4 slice 2 v cc lut lut sop clb muxcy 4 muxcy 4 slice 1 orcy lut lut muxcy 4 muxcy 4 slice 0 v cc lut lut muxcy 4 muxcy 4 slice 3 orcy lut lut muxcy 4 muxcy 4 slice 2 v cc lut lut clb figure 44: wide-input and gate (16 inputs) muxcy and 4 16 muxcy 4 ?0? 01 01 ?0? 01 ?0? muxcy 4 slice out out slice lut ds031_41_110600 lut lut v cc muxcy 4 01 lut virtex-ii pro and virtex-ii pro x platform fpgas: functional description r ds083 (v5.0) june 21, 2011 www.xilinx.com module 2 of 4 product specification 43 product not recommended for new designs 3-state buffers introduction each virtex-ii pro clb contains two 3-state drivers (tbufs) that can drive on-chip buses. each 3-state buffer has its own 3-state control pin and its own input pin. each of the four slices have access to the two 3-state buf- fers through the switch matrix, as shown in figure 45 . tbufs in neighboring clbs can access slice outputs by direct connects. the outputs of the 3-state buffers drive hor- izontal routing resources used to implement 3-state buses. the 3-state buffer logic is implemented using and-or logic rather than 3-state drivers, so that timing is more predict- able and less load dependant especially with larger devices. locations / organization four horizontal routing resources per clb are provided for on-chip 3-state buses. each 3-state buffer has access alter- nately to two horizontal lines, which can be partitioned as shown in figure 46 . the switch matrices corresponding to selectram+ memory and mult iplier or i/o blocks are skipped. number of 3-state buffers ta b l e 1 8 shows the number of 3-state buffers available in each virtex-ii pro device. the number of 3-state buffers is twice the number of clb elements. figure 45: virtex-ii pro 3-state buffers slice s3 slice s2 slice s1 slice s0 switch matrix ds031_37_060700 tbuf tbuf table 18: virtex-ii pro 3-state buffers device 3-state buffers per row total number of 3-state buffers xc2vp2 44 704 xc2vp4 44 1,504 xc2vp7 68 2,464 xc2vp20 92 4,640 xc2vpx20 92 4,896 xc2vp30 92 6,848 xc2vp40 116 9,696 xc2vp50 140 11,808 xc2vp70 164 16,544 xc2vpx70 164 16,544 xc2vp100 188 22,048 figure 46: 3-state buffer connection to horizontal lines switch matrix clb-ii switch matrix clb-ii ds031_09_032700 programmable connection 3 - state lines virtex-ii pro and virtex-ii pro x platform fpgas: functional description r ds083 (v5.0) june 21, 2011 www.xilinx.com module 2 of 4 product specification 44 product not recommended for new designs clb/slice configurations ta bl e 1 9 summarizes the logic resources in one clb. all of the clbs are identical and each clb or slice can be implemented in one of the configurations listed. ta b l e 2 0 shows the available re sources in all clbs. 18 kb block selectram+ resources introduction virtex-ii pro devices incorporate large amounts of 18 kb block selectram+ resources. these complement the dis- tributed selectram+ resource s that provide shallow ram structures implemented in clbs. each virtex-ii pro block selectram+ resource is an 18 kb true dual-port ram with two independently clocked and independently controlled synchronous ports that access a common storage area. both ports are functionally identical. clk, en, we, and ssr polarities are defined through configuration. each port has the following ty pes of inputs: clock and clock enable, write enable, set/reset, and address, as well as separate data/parity data inputs (for write) and data/parity data outputs (for read). operation is synchronous; the block selectram+ behaves like a register. control, address and data inputs must (and need only) be valid during the set-up time window prior to a rising (or falling, a configuration option) clock edge. data outputs change as a result of the same clock edge. configuration virtex-ii pro block selectram+ supports various configura- tions, including single- and dual-port ram and various data/address aspect ratios. supported memory configura- tions for single- and dual-port modes are shown in ta b l e 2 1 . single-port configuration as a single-port ram, the block selectram+ has access to the 18 kb memory locations in any of the 2k x 9-bit, 1k x 18-bit, or 512 x 36-bit configurations and to 16 kb memory locations in any of the 16k x 1-bit, 8k x 2-bit, or 4k x 4-bit configurations. the advantage of the 9-bit, 18-bit and 36-bit widths is the ability to store a parity bit for each eight bits. parity bits must be generated or checked exter- ta bl e 1 9 : logic resources in one clb slices luts flip-flops mult_ands arithmetic & carry-chains sop chains distributed selectram+ shift registers tbuf 4 8 8 8 2 2 128 bits 128 bits 2 ta bl e 2 0 : virtex-ii pro logic resources available in all clbs device clb array: row x column number of slices number of luts max distributed selectram or shift register (bits) number of flip-flops number of carry-chains (1) number of sop chains (1) xc2vp2 16 x 22 1,408 2,816 45,056 2,816 44 32 xc2vp4 40 x 22 3,008 6,016 96,256 6,016 44 80 xc2vp7 40 x 34 4,928 9,856 157,696 9,856 68 80 xc2vp20 56 x 46 9,280 18,560 296,960 18,560 92 112 xc2vpx20 56 x 46 9,792 19,58 4 313,334 18,560 92 112 xc2vp30 80 x 46 13,696 27,392 438,272 27,392 92 160 xc2vp40 88 x 58 19,392 38,784 620,544 38,784 116 176 xc2vp50 88 x 70 23,616 47,232 755,712 47,232 140 176 xc2vp70 104 x 82 33,088 66,176 1,058,816 66,176 164 208 xc2vpx70 104 x 82 33,088 66,17 6 1,058,816 66,176 164 208 xc2vp100 120 x 94 44,096 88,192 1,411,072 88,192 188 240 notes: 1. the carry-chains and sop chains can be split or cascaded. table 21: dual- and single-port configurations 16k x 1 bit 2k x 9 bits 8k x 2 bits 1k x 18 bits 4k x 4 bits 512 x 36 bits virtex-ii pro and virtex-ii pro x platform fpgas: functional description r ds083 (v5.0) june 21, 2011 www.xilinx.com module 2 of 4 product specification 45 product not recommended for new designs nally in user logic. in such cases, the width is viewed as 8 + 1, 16 + 2, or 32 + 4. these extra parity bits are stored and behave exactly as the other bits, including the timing parameters. video applications can use the 9-bit ratio of virtex-ii pro block selectram+ memory to advantage. each block selectram+ cell is a fully synchronous memory as illustrated in figure 47 . input data bus and output data bus widths are identical. dual-port configuration as a dual-port ram, each port of block selectram+ has access to a common 18 kb me mory resource. these are fully synchronous ports with independent control signals for each port. the data widths of the two ports can be config- ured independently, providing built-in bus-width conversion. ta b l e 2 2 illustrates the different co nfigurations available on ports a and b. if both ports are configured in either 2k x 9-bit, 1k x 18-bit, or 512 x 36-bit configurations, the 18 kb block is accessible from port a or b. if both ports are configured in either 16k x 1-bit, 8k x 2-bit. or 4k x 4-bit configurations, the 16 k-bit block is accessible from port a or port b. all other configu- rations result in one port having access to an 18 kb memory block and the other port having access to a 16 k-bit subset of the memory block equal to 16 kbs. figure 47: 18 kb block selectram+ memory in single-port mode dop dip addr we en ssr clk 18-kbit block selectram ds031_10_102000 di do ta bl e 2 2 : dual-port mode configurations port a 16k x 1 16k x 1 16k x 1 16k x 1 16k x 1 16k x 1 port b 16k x 1 8k x 2 4k x 4 2k x 9 1k x 18 512 x 36 port a 8k x 2 8k x 2 8k x 2 8k x 2 8k x 2 port b 8k x 2 4k x 4 2k x 9 1k x 18 512 x 36 port a 4k x 4 4k x 4 4k x 4 4k x 4 port b 4k x 4 2k x 9 1k x 18 512 x 36 port a 2k x 9 2k x 9 2k x 9 port b 2k x 9 1k x 18 512 x 36 port a 1k x 18 1k x 18 port b 1k x 18 512 x 36 port a 512 x 36 port b 512 x 36 virtex-ii pro and virtex-ii pro x platform fpgas: functional description r ds083 (v5.0) june 21, 2011 www.xilinx.com module 2 of 4 product specification 46 product not recommended for new designs each block selectram+ cell is a fully synchronous memory, as illustrated in figure 48 . the two ports have independent inputs and outputs and are independently clocked. port aspect ratios ta bl e 2 3 shows the depth and the width aspect ratios for the 18 kb block selectram+ resource. virtex-ii pro block selectram+ also includes dedicated routing resources to provide an efficient interface with clbs, block selectram+, and multipliers. read/write operations the virtex-ii pro block selectram+ read operation is fully synchronous. an address is presented, and the read opera- tion is enabled by control signal ena or enb. then, depending on clock polarity, a rising or falling clock edge causes the stored data to be loaded into output registers. the write operation is also fully synchronous. data and address are presented, and the write operation is enabled by control signals wea and web in addition to ena or enb. then, again depending on the clock input mode, a ris- ing or falling clock edge causes the data to be loaded into the memory cell addressed. a write operation performs a simultaneous read operation. three different options are available, selected by configura- tion: 1. write_first the write_first option is a transparent mode. the same clock edge that writes the data input (di) into the memory also transfers di into the output registers do, as shown in figure 49 . 2. read_first the read_first option is a read-before-write mode. the same clock edge that writes data input (di) into the memory also transfers the prior content of the memory cell addressed into the data output registers do, as shown in figure 50 . figure 48: 18 kb block selectram + in dual-port mode ta bl e 2 3 : 18 kb block selectram+ port aspect ratio width depth address bus data bus parity bus 1 16,384 addr[13:0] data[0] n/a 2 8,192 addr[12:0] data[1:0] n/a 4 4,096 addr[11:0] data[3:0] n/a 9 2,048 addr[10:0] data[7:0] parity[0] 18 1,024 addr[9:0] data[15:0] parity[1:0] 36 512 addr[8:0] data[31:0] parity[3:0] dopa dopb dipa addra wea ena ssra clka dipb addrb web enb ssrb clkb 18-kbit block selectram ds031_11_102000 dob doa dia dib figure 49: write_first mode figure 50: read_first mode clk we data_in data_in new aa address internal memory do data_out = data_in data_out di ds083-2_14_050901 new ram contents new old clk we data_in data_in new aa old address internal memory do prior stored data data_out di ds083-2_13_050901 ram contents new old virtex-ii pro and virtex-ii pro x platform fpgas: functional description r ds083 (v5.0) june 21, 2011 www.xilinx.com module 2 of 4 product specification 47 product not recommended for new designs 3. no_change the no_change option maintains the content of the out- put registers, regardless of the write operation. the clock edge during the write mode has no effect on the content of the data output register do. when the port is configured as no_change, only a read operation loads a new value in the output register do, as shown in figure 51 . control pins and attributes virtex-ii pro selectram+ memory has two independent ports with the control signals described in ta bl e 2 4 . all con- trol inputs including the clock have an optional inversion. initial memory content is determined by the init_xx attri- butes. separate attributes determine the output register value after device configuration (init) and ssr is asserted (srval). both attributes (init_b and srval) are available for each port when a block selectram+ resource is config- ured as dual-port ram. total amount of selectram+ memory virtex-ii pro selectram+ memory blocks are organized in multiple columns. the number of blocks per column depends on the row size, the number of processor blocks, and the number of rocketio transceivers. ta b l e 2 5 shows the number of columns as well as the total amount of block selectram+ memory available for each virtex-ii pro device. the 18 kb selectram+ blocks are cascadable to implement deeper or wider single- or dual-port memory resources. figure 52 shows the layout of the block ram columns in the xc2vp4 device. figure 51: no_change mode ta bl e 2 4 : control functions control signal function clk read and write clock en enable affects read, write, set, reset we write enable ssr set do register to srval (attribute) clk we data_in data_in new aa last read cycle content (no change) address internal memory do no change during write data_out di ds083-2_12_050901 ram contents new old table 25: virtex-ii pro selectram+ memory available device columns total selectram+ memory blocks in kb in bits xc2vp2 4 12 216 221,184 xc2vp4 4 28 504 516,096 xc2vp7 6 44 792 811,008 xc2vp20 8 88 1,584 1,622,016 xc2vp30 8 136 2,448 2,506,752 xc2vpx20 8 88 1,584 1,622,016 xc2vp40 10 192 3,456 3,538,944 xc2vp50 12 232 4,176 4,276,224 xc2vp70 14 328 5,904 6,045,696 xc2vpx70 14 308 5,544 5,677,056 xc2vp100 16 444 7,992 8,183,808 figure 52: xc2vp4 block ram column layout bram multiplier blocks ppc405 cpu clbs clbs clbs clbs clbs ds083-2_11_010802 tm rocketio serial transceivers tm rocketio serial transceivers dcm dcm dcm dcm virtex-ii pro and virtex-ii pro x platform fpgas: functional description r ds083 (v5.0) june 21, 2011 www.xilinx.com module 2 of 4 product specification 48 product not recommended for new designs 18-bit x 18-bit multipliers introduction a virtex-ii pro multiplier block is an 18-bit by 18-bit 2?s com- plement signed multiplier. virtex-ii pro devices incorporate many embedded multiplier bloc ks. these multipliers can be associated with an 18 kb block selectram+ resource or can be used independently. they are optimized for high-speed operations and have a lower power consump- tion compared to an 18-bit x 18-bit multiplier in slices. each selectram+ memory and multiplier block is tied to four switch matrices, as shown in figure 53 . association with block selectram+ memory the interconnect is designed to allow selectram+ memory and multiplier blocks to be used at the same time, but some interconnect is shared between the selectram+ and the multiplier. thus, selectram+ memory can be used only up to 18 bits wide when the multiplier is used, because the mul- tiplier shares inputs with the upper data bits of the selectram+ memory. this sharing of the interconnect is optimized for an 18-bit-wide block se lectram+ resource feeding the multi- plier. the use of selectram+ memory and the multiplier with an accumulator in luts a llows for implementation of a digital signal processor (dsp) multiplier-accumulator (mac) function, which is commonly used in finite and infinite impulse response (fir and iir) digital filters. configuration the multiplier block is an 18-bi t by 18-bit signed multiplier (2's complement). both a and b are 18-bit-wide inputs, and the output is 36 bits. figure 54 shows a multiplier block. locations / organization multiplier organization is iden tical to the 18 kb selectram+ organization, because each multiplier is associated with an 18 kb block selectram+ resource. in addition to the built-in mult iplier blocks, the clb elements have dedicated logic to implement efficient multipliers in logic. (refer to configurable logic blocks (clbs), page 35 ). global clock multiplexer buffers virtex-ii pro devices have 16 clock input pins that can also be used as regular user i/os. eight clock pads center on both the top edge and the bottom edge of the device, as illustrated in figure 55 . the global clock multiplexer buffer represents the input to dedicated low-skew clock tree distribution in virtex-ii pro devices. like the clock pads, eight global clock multiplexer buffers are on the top edge of the device and eight are on the bottom edge. figure 53: selectram+ and multiplier blocks switch matrix switch matrix 18-kbit block selectram 18 x 18 multiplier switch matrix switch matrix ds031_33_101000 figure 54: multiplier block table 26: multiplier resources device columns total multipliers xc2vp2 4 12 xc2vp4 4 28 xc2vp7 6 44 xc2vp20 8 88 xc2vp30 8 136 xc2vpx20 8 88 xc2vp40 10 192 xc2vp50 12 232 xc2vp70 14 328 xc2vpx70 14 308 xc2vp100 16 444 mult 18 x 18 a[17:0] p[35:0] b[17:0] multiplier block ds031_40_100400 virtex-ii pro and virtex-ii pro x platform fpgas: functional description r ds083 (v5.0) june 21, 2011 www.xilinx.com module 2 of 4 product specification 49 product not recommended for new designs each global clock multiplexer buffer can be driven either by the clock pad to distribute a clock directly to the device, or by the digital clock manager (dcm), discussed in digital clock manager (dcm), page 51 . each global clock multi- plexer buffer can also be driven by local interconnects. the dcm has clock output(s) that can be connected to global clock multiplexer buffer inputs, as shown in figure 56 . global clock buffers are used to distribute the clock to some or all synchronous logic elements (such as registers in clbs and iobs, and selectram+ blocks. eight global clocks can be used in each quadrant of the virtex-ii pro device. designers should consider the clock distribution detail of the device prior to pin-locking and floor- planning. (see the virtex-ii pro platform fpga user guide .) figure 55: virtex-ii pro clock pads 8 clock pads 8 clock pads virtex-ii pro device ds083-2_42_052902 figure 56: virtex-ii pro clock multiplexer buffer configuration clock pad local interconnect clock pad clock buffer clock multiplexer i o clock distribution clkin clkout dcm ds083-2_43_122001 virtex-ii pro and virtex-ii pro x platform fpgas: functional description r ds083 (v5.0) june 21, 2011 www.xilinx.com module 2 of 4 product specification 50 product not recommended for new designs figure 57 shows clock distribution in virtex-ii pro devices. in each quadrant, up to eight clocks are organized in clock rows. a clock row supports up to 16 clb rows (eight up and eight down). to reduce power consumption, an y unused clock branches remain static. global clocks are driven by dedicated clock buffers (bufg), which can also be used to gate the clock (bufgce) or to mul- tiplex between two independent clock inputs (bufgmux). the most common configuration option of this element is as a buffer. a bufg function in this (global buffer) mode, is shown in figure 58 . the virtex-ii pro global clock buffer bufg can also be con- figured as a clock enable/disable circuit ( figure 59 ), as well as a two-input clock multiplexer ( figure 60 ). a functional description of these two options is provided below. each of them can be used in either of two modes, selected by con- figuration: rising clock edge or falling clock edge. this section describes the rising clock edge option. for the opposite option, falling clock edg e, just change all "rising" references to "falling" and all "high" references to "low", except for the description of the ce and s levels. the rising clock edge option uses the bufgce and bufgmux prim- itives. the falling clock edge option uses the bufgce_1 and bufgmux_1 primitives. bufgce if the ce input is active (high) prior to the incoming rising clock edge, this low-to-high-to-low clock pulse passes through the clock buffer. any level change of ce during the incoming clock high time has no effect. if the ce input is inactive (low) prior to the incoming rising clock edge, the following clock pulse does not pass through the clock buffer, and the output stays low. any level change of ce during the incoming clock high time has no effect. ce must not change during a short setup window just prior to the rising clock edge on the bufgce input i. violating this setup time requirement can result in an undefined runt pulse output. bufgmux bufgmux can switch between two unrelated, even asyn- chronous clocks. basically, a low on s selects the i 0 input, a high on s selects the i 1 input. switching from one clock to the other is done in such a way that the output high and low time is never shorter than the shortest high or low time of either input clock. as long as the presently selected clock is high, any level change of s has no effect. figure 57: virtex-ii pro clock distribution 8 8 8 8 nw ne sw se ds083-2_45_122001 8 bufgmux 8 max 8 bufgmux 16 clocks nw ne sw se 8 bufgmux 8 bufgmux 16 clocks figure 58: virtex-ii pro bufg function o i bufg ds031_61_101200 figure 59: virtex-ii pro bufgce function o i ce bufgce ds031_62_101200 virtex-ii pro and virtex-ii pro x platform fpgas: functional description r ds083 (v5.0) june 21, 2011 www.xilinx.com module 2 of 4 product specification 51 product not recommended for new designs if the presently selected clock is low while s changes, or if it goes low after s has changed, the output is kept low until the other ("to-be-selected") clock has made a transition from high to low. at that instant, the new clock starts driv- ing the output. the two clock inputs can be asynchronous with regard to each other, and the s input can change at any time, except for a short setup time prior to the rising edge of the presently selected clock (i0 or i1). violating this setup time require- ment can result in an undefined runt pulse output. all virtex-ii pro devices have 16 global clock multiplexer buffers. figure 61 shows a switchover from i0 to i1. ? the current clock is clk0. ? s is activated high. ? if clk0 is currently high, th e multiplexer waits for clk0 to go low. ? once clk0 is low, the mu ltiplexer output stays low until clk1 transitions high to low. ? when clk1 transitions from high to low, the output switches to clk1. ? no glitches or short pulses can appear on the output. local clocking in addition to global clocks, there are local clock resources in the virtex-ii pro devices. there are more than 72 local clocks in the virtex-ii pro family. these resources can be used for many different applications, including but not lim- ited to memory interfaces. for example, even using only the left and right i/o banks, virtex-ii pro fpgas can support up to 50 local clocks for ddr sdram. these interfaces can operate beyond 200 mhz on virtex-ii pro devices. digital clock manager (dcm) the virtex-ii pro dcm offers a wide range of powerful clock management features. ? clock de-skew : the dcm generates new system clocks (either internally or externally to the fpga), which are phase-aligned to the input clock, thus eliminating clock distribution delays. ? frequency synthesis : the dcm generates a wide range of output clock frequencies, performing very flexible clock multiplication and division. ? phase shifting : the dcm provides both coarse phase shifting and fine-grained phase shifting with dynamic phase shift control. the dcm utilizes fully digital delay lines allowing robust high-precision control of clock phase and frequency. it also utilizes fully digital feedback systems, operating dynamically to compensate for temperature and voltage variations dur- ing operation. up to four of the nine dcm clock outputs can drive inputs to global clock buffers or global clock multiplexer buffers simul- taneously (see figure 62 ). all dcm clock outputs can simul- taneously drive general routing resources, including routes to output buffers. the dcm can be configured to delay the completion of the virtex-ii pro configuration process until after the dcm has achieved lock. this guarantees that the chip does not begin operating until after the system clocks generated by the dcm have stabilized. figure 60: virtex-ii pro bufgmux function figure 61: clock multiplexer waveform diagram o i 0 i 1 s bufgmux ds083-2_63_121701 s i0 i1 out wait for low switch ds083-2_46_020604 figure 62: digital clock manager clkin clkfb clk180 clk270 clk0 clk90 clk2x clk2x180 clkdv dcm ds031_67_112900 clkfx clkfx180 locked status[7:0] psdone rst dssen psincdec psen psclk clock signal control signal virtex-ii pro and virtex-ii pro x platform fpgas: functional description r ds083 (v5.0) june 21, 2011 www.xilinx.com module 2 of 4 product specification 52 product not recommended for new designs the dcm has the following general control signals: ? rst input pin : resets the entire dcm ? locked output pin: asserted high when all enabled dcm circuits have locked. ? status output pins (active high): shown in ta b l e 2 7 . clock de-skew the dcm de-skews the output clocks relative to the input clock by automatically adjustin g a digital delay line. addi- tional delay is introduced so that clock edges arrive at inter- nal registers and block rams simultaneously with the clock edges arriving at the input clock pad. alternatively, external clocks, which are also de-skewed relative to the input clock, can be generated for board-level routing. all dcm output clocks are phase-aligned to clk0 and, therefore, are also phase-aligned to the input clock. to achieve clock de-skew, connect the clkfb input to clk0. note that clkfb must always be connected, unless only the clkfx or clkfx180 outputs are used and de-skew is not required. frequency synthesis the dcm provides flexible methods for generating new clock frequencies. each method has a different operating frequency range and different ac characteristics. the clk2x and clk2x180 outputs double the clock frequency. the clkdv output creates divided output clocks with divi- sion options of 1.5, 2, 2.5, 3, 3.5, 4, 4.5, 5, 5.5, 6, 6.5, 7, 7.5, 8, 9, 10, 11, 12, 13, 14, 15, and 16. the clkfx and clkfx180 outputs can be used to pro- duce clocks at the following frequency: where m and d are two integers. specifications for m and d are provided under dcm timing parameters in virtex-ii pro and virtex-ii pro x platform fpgas: dc and switching characteristics . by default, m = 4 and d =1, which results in a clock output frequency four times faster than the clock input frequency (clkin). clk2x180 is phase shifted 180 degrees relative to clk2x. clkfx180 is phase shifted 180 degrees relative to clkfx. all frequency synthesis outputs automatically have 50/50 duty cycles, with the exception of the clkdv output when performing a non-integer divide in high-frequency mode. see ta b l e 2 8 for more details. note that clk2x and clk2x180 are not available in high-frequency mode. phase shifting the dcm provides additional control over clock skew through either coarse or fine-grained phase shifting. the clk0, clk90, clk180, and clk270 outputs are each phase shifted by ? of the input clock period relative to each other, providing coarse phase control. note that clk90 and clk270 are not available in high-frequency mode. fine-phase adjustment affects all nine dcm output clocks. when activated, the phase shift between the rising edges of clkin and clkfb is a specified fraction of the input clock period. in variable mode, the phase_shift value can also be dynamically incremented or decremented as determined by psincdec synchronously to psclk, when the psen input is active. figure 63 illustrates the effects of fine-phase shifting. for more information on dcm features, see the virtex-ii pro platform fpga user guide . ta b l e 2 9 lists fine-phase shifting control pins, when used in variable mode. ta bl e 2 7 : dcm status pins status pin function 0 phase shift overflow 1 clkin stopped 2 clkfx stopped 3n/a 4n/a 5n/a 6n/a 7n/a freq clkfx md ? ?? freq clkin ? = table 28: clkdv duty cycle for non-integer divides clkdv_divide duty cycle 1.5 1/ 3 2.5 2 / 5 3.5 3 / 7 4.5 4 / 9 5.5 5 / 11 6.5 6 / 13 7.5 7 / 15 table 29: fine phase shifting control pins control pin direction function psincdec in increment or decrement psen in enable phase shift psclk in clock for phase shift psdone out active when completed virtex-ii pro and virtex-ii pro x platform fpgas: functional description r ds083 (v5.0) june 21, 2011 www.xilinx.com module 2 of 4 product specification 53 product not recommended for new designs two separate components of the phase shift range must be understood: ? phase_shift attribute range ? fine_shift_range dcm timing parameter range the phase_shift attribute is the numerator in the following equation: phase shift (ns) = ( phase_shift /256) * period clkin the full range of this attribute is always -255 to +255, but its practical range varies with clkin frequency, as constrained by the fine_shift_range component, which represents the total delay achievable by the phase shift delay line. total delay is a function of the number of delay taps used in the circuit. across process, voltag e, and temperature, this abso- lute range is guaranteed to be as specified under dcm tim- ing parameters in virtex-ii pro and virtex-ii pro x platform fpgas: dc and switching characteristics . absolute range (fixed mode) = fine_shift_range absolute range (variable mode) = fine_shift_range /2 the reason for the difference between fixed and variable modes is as follows. for variable mode to allow symmetric, dynamic sweeps from -255/256 to +255/256, the dcm sets the "zero phase skew" point as the middle of the delay line, thus dividing the total delay line range in half. in fixed mode, since the phase_shift value never changes after configu- ration, the entire delay line is available for insertion into either the clkin or clkfb path (to create either positive or negative skew). taking both of these components into consideration, the fol- lowing are some usage examples: ? if period clkin = 2 * fine_shift_range , then phase_shift in fixed mode is limited to 128, and in variable mode it is limited to 64. ? if period clkin = fine_shift_range , then phase_shift in fixed mode is limited to 255, and in variable mode it is limited to 128. ? if period clkin ? 0.5 * fine_shift_range , then phase_shift is limited to 255 in either mode. operating modes the frequency ranges of dcm input and output clocks depend on the operating mode specified, either low-frequency mode or high-frequency mode, according to ta b l e 3 0 . for actual values, see virtex-ii pro and virtex-ii pro x platform fpgas: dc and switching charac- teristics . the clk2x, clk2x180, clk90, and clk270 out- puts are not available in high-frequency mode. high or low-frequency mode is selected by an attribute. figure 63: fine-phase shifting effects clkout_phase_shift = fixed clkout_phase_shift = variable clkout_phase_shift = none clkin clkfb clkin clkin clkfb (ps/256) x period clkin (ps negative) (ps/256) x period clkin (ps positive) clkfb (ps/256) x period clkin (ps negative) (ps/256) x period clkin (ps positive) ds031_48_110300 ta bl e 3 0 : dcm frequency ranges output clock low-frequency mode high-frequency mode clkin input clk output clkin input clk output clk0, clk180 clkin_freq_dll_lf clkout_freq_ 1x_lf clkin_freq_dll_hf clkout_freq_1x_hf clk90, clk270 clkin_freq_d ll_lf clkout_freq_1x_lf na na clk2x, clk2x180 clkin_freq_dll_lf clkout_freq_2x_lf na na clkdv clkin_freq_dll_lf clkout_freq_dv_l f clkin_freq_dll_hf clkout_freq_dv_hf clkfx, clkfx180 clkin_ freq_fx_lf clkout_fre q_fx_lf clkin_freq_fx _hf clkout_freq_fx_hf virtex-ii pro and virtex-ii pro x platform fpgas: functional description r ds083 (v5.0) june 21, 2011 www.xilinx.com module 2 of 4 product specification 54 product not recommended for new designs routing dcm and mgt locati ons/organization virtex-ii pro dcms and serial transceivers (mgts) are placed on the top and bottom of each block ram and multi- plier column in some co mbination, as shown in ta bl e 3 1 . the number of dcms and rocketio transceivers total twice the number of block ram columns in the device. refer to figure 52, page 47 for an illustration of this in the xc2vp4 device. place-and-route software takes advantage of this regular array to deliver optimum system performance and fast com- pile times. the segmented routing resources are essential to guarantee ip cores portabilit y and to efficiently handle an incremental design flow that is based on modular imple- mentations. total design time is reduced due to fewer and shorter design iterations. hierarchical routing resources most virtex-ii pro signals are routed using the global rout- ing resources, which are located in horizontal and vertical routing channels between each switch matrix. as shown in figure 64, page 54 , virtex-ii pro has fully buff- ered programmable interconnections, with a number of resources counted between any two adjacent switch matrix rows or columns. fanout has minimal impact on the perfor- mance of each net. ? the long lines are bidirectional wires that distribute signals across the device. vertical and horizontal long lines span the full height and width of the device. ? the hex lines route signals to every third or sixth block away in all four directions. organized in a staggered pattern, hex lines can only be driven from one end. hex-line signals can be accessed either at the endpoints or at the midpoint (three blocks from the source). ta bl e 3 1 : dcm and mgt organization device block ram columns dcms mgts xc2vp2 4 4 4 xc2vp4 4 4 4 xc2vp7 6 4 8 xc2vp20 8 8 8 xc2vpx20 8 8 8 xc2vp30 8 8 8 xc2vp40 10 8 12 xc2vp50 12 8 16 xc2vp70 14 8 20 xc2vpx70 14 8 20 xc2vp100 16 12 20 figure 64: hierarchical routing resources 24 horizontal long lines 24 vertical long lines 120 horizontal hex lines 120 vertical hex lines 40 horizontal double lines 40 vertical double lines 16 direct connections (total in all four directions) 8 fast connects ds031_60_110200 virtex-ii pro and virtex-ii pro x platform fpgas: functional description r ds083 (v5.0) june 21, 2011 www.xilinx.com module 2 of 4 product specification 55 product not recommended for new designs ? the double lines route signals to every first or second block away in all four directions. organized in a staggered pattern, double lines can be driven only at their endpoints. double-line signals can be accessed either at the endpoints or at the midpoint (one block from the source). ? the direct connect lines route signals to neighboring blocks: vertically, horizontally, and diagonally. ? the fast connect lines are the internal clb local interconnections from lut outputs to lut inputs. dedicated routing in addition to the global and local routing resources, dedi- cated signals are available. ? there are eight global clock nets per quadrant. (see global clock multiplexer buffers, page 48 .) ? horizontal routing resources are provided for on-chip 3-state buses. four partitionable bus lines are provided per clb row, permitting multiple buses within a row. (see 3-state buffers, page 43 .) ? two dedicated carry-chain resources per slice column (two per clb column) propagate carry-chain muxcy output signals vertically to the adjacent slice. (see clb/slice configurations, page 44 .) ? one dedicated sop chain per slice row (two per clb row) propagate orcy output logic signals horizontally to the adjacent slice. (see sum of products, page 42 .) ? one dedicated shift-chain per clb connects the output of luts in shift-register mode to the input of the next lut in shift-register mode (vertically) inside the clb. (see shift registers, page 39 .) virtex-ii pro and virtex-ii pro x platform fpgas: functional description r ds083 (v5.0) june 21, 2011 www.xilinx.com module 2 of 4 product specification 56 product not recommended for new designs configuration virtex-ii pro devices are configured by loading application specific configuration data in to the internal configuration memory. configuration is carri ed out using a subset of the device pins, some of which are dedicated, while others can be re-used as general purpose inputs and outputs once configuration is complete. depending on the system design, several configuration modes are supported, selectable via mode pins. the mode pins m2, m1, and m0 are dedicated pins. the m2, m1, and m0 mode pins should be set at a constant dc voltage level, either through pull-up or pull-down resistors, or tied directly to ground or v ccaux . the mode pins should not be toggled during and after configuration. an additional pin, hswap_en is used in conjunction with the mode pins to select whether user i/o pins have pull-ups during configuration. by default, hswap_en is tied high (internal pull-up) which shuts off the pull-ups on the user i/o pins during configuration. when hswap_en is tied low, user i/os have pull-ups during configuration. other dedi- cated pins are cclk (the configuration clock pin), done, prog_b, and the boundary-scan pins: tdi, tdo, tms, and tck. (the tdo pin is open-drain and does not have an internal pull-up resistor.) depending on the configuration mode chosen, cclk can be an output generated by the fpga, or an input accepting an externally generated clock. the configuration pins and boundary-scan pins are inde- pendent of the v cco . the auxiliary power supply (v ccaux ) of 2.5v is used for these pins. all configuration pins are lvcmos25 12ma. see virtex-ii pro and virtex-ii pro x platform fpgas: dc and switching characteristics . a "persist" option is available which can be used to force the configuration pins to retain their configuration function even after device configuration is complete. if the persist option is not selected then the configuration pins with the exception of cclk, prog_b, and done can be used as user i/o in normal operation. the persist option does not apply to the boundary-scan related pins. the persist feature is valuable in applications which employ partial reconfiguration or reconfiguration on the fly. configuration modes virtex-ii pro supports the following five configuration modes: ? slave-serial mode ? master-serial mode ? slave selectmap mode ? master selectmap mode ? boundary-scan (jtag, ieee 1532) mode refer to table 32, page 57 . a detailed description of configuration modes is provided in the virtex-ii pro platform fpga user guide. slave-serial mode in slave-serial mode, the fpga receives configuration data in bit-serial form from a serial prom or other serial source of configuration data. the cclk pin on the fpga is an input in this mode. the serial bitstream must be setup at the din input pin a short time before each rising edge of the externally generated cclk. multiple fpgas can be daisy-chained for configuration from a single source. after a particular fpga has been config- ured, the data for the next device is routed internally to the dout pin. the data on the dout pin changes on the falling edge of cclk. slave-serial mode is selected by applying [ 111 ] to the mode pins (m2, m1, m0). a weak pull-up on the mode pins makes slave serial the default mode if the pins are left uncon- nected. master-serial mode in master-serial mode, the cclk pin is an output pin. it is the virtex-ii pro fpga device that drives the configuration clock on the cclk pin to a xilinx serial prom which in turn feeds bit-serial data to the din input. the fpga accepts this data on each rising cclk edge. after the fpga has been loaded, the data for the next device in a daisy-chain is presented on the dout pin after the falling cclk edge. the interface is identical to slave serial except that an inter- nal oscillator is used to gene rate the configuration clock (cclk). a wide range of frequencies can be selected for cclk which always starts at a slow default frequency. con- figuration bits then switch cclk to a higher frequency for the remainder of the configuration. slave selectmap mode the selectmap mode is the fa stest configuration option. byte-wide data is written into the virtex-ii pro fpga device with a busy flag controlling the flow of data. an external data source provides a byte stream, cclk, an active low chip select (cs_b) signal and a write signal (rdwr_b). if busy is asserted (high) by the fpga, the data must be held until busy goes low. data can also be read using the selectmap mode. if rdwr_b is asserted, configuration data is read out of the fpga as part of a readback operation. after configuration, the pins of the selectmap port can be used as additional user i/o. alternatively, the port can be retained to permit high-speed 8-bit readback using the per- sist option. multiple virtex-ii pro fpgas can be configured using the selectmap mode, and be made to start-up simultaneously. to configure multiple devices in this way, wire the individual cclk, data, rdwr_b, and busy pins of all the devices in parallel. the individual devices are loaded separately by deasserting the cs_b pin of each device in turn and writing the appropriate data. virtex-ii pro and virtex-ii pro x platform fpgas: functional description r ds083 (v5.0) june 21, 2011 www.xilinx.com module 2 of 4 product specification 57 product not recommended for new designs master selectmap mode this mode is a master version of the selectmap mode. the device is configured byte-wide on a cclk supplied by the virtex-ii pro fpga device. timing is similar to the slave serialmap mode except that cclk is supplied by the virtex-ii pro fpga. boundary-scan (jtag, ieee 1532) mode in boundary-scan mode, dedicated pins are used for con- figuring the virtex-ii pro device. the configuration is done entirely through the ieee 1149 .1 test access port (tap). virtex-ii pro device configuration using boundary-scan is compatible with with ieee 11 49.1-1993 stan dard and the new ieee 1532 standard for in -system configurable (isc) devices. the ieee 1532 stan dard is backward compliant with the ieee 1149.1-1993 t ap and state machine. the ieee standard 1532 for in-system configurable (isc) devices is intended to be programmed, reprogrammed, or tested on the board via a physic al and logical protocol. con- figuration through the boundary-scan port is always avail- able, independent of the mode selection. selecting the boundary-scan mode simply turns off the other modes. ta bl e 3 3 lists the default total number of bits required to configure each device. configuration sequence the configuration of virtex-ii pro devices is a three-phase process. first, the configuration memory is cleared. next, configuration data is loaded into the memory, and finally, the logic is activated by a start-up process. configuration is automatically initiated on power-up unless it is delayed by the user. the init_b pin can be held low using an open-drain driver. an open-drain is required since init_b is a bidirectional open-drain pin that is held low by a virtex-ii pro fpga device while the configuration memory is being cleared. extending the time that the pin is low causes the configuration sequencer to wait. thus, configu- ration is delayed by preventing entry into the phase where data is loaded. the configuration process can also be initiated by asserting the prog_b pin. the end of the memory-clearing phase is signaled by the init_b pin going high, and the completion of the entire process is sign aled by the done pin going high. the global set/reset (gsr) signal is pulsed after the last frame of configuration data is written but before the start-up sequence. the gsr signal resets all flip-flops on the device. the default start-up sequence is that one cclk cycle after done goes high, the global 3-state signal (gts) is released. this permits device outputs to turn on as neces- sary. one cclk cycle later, the global write enable (gwe) signal is released. this permits the internal storage ele- ments to begin changing state in response to the logic and the user clock. the relative timing of these events can be changed via con- figuration options in software. in addition, the gts and gwe events can be made dependent on the done pins of multiple devices all going high, forcing the devices to start ta bl e 3 2 : virtex-ii pro configuration mode pin settings configuration mode (1) m2 m1 m0 cclk direction data width serial d out (2) master serial 0 0 0 out 1 yes slave serial 1 1 1 in 1 yes master selectmap 0 1 1 out 8 no slave selectmap 1 1 0 in 8 no boundary-scan 1 0 1 n/a 1 no notes: 1. the hswap_en pin controls the pull-ups. setting m2, m1, and m0 selects the configuration mode, while the hswap_en pin controls whether or not the pull-ups are used. 2. daisy chaining is possible only in modes where serial d out is used. for example, in selectmap modes, the first device does not support daisy chaining of downstream devices. ta bl e 3 3 : virtex-ii pro default bitstream lengths device number of configuration bits xc2vp2 1,305,376 xc2vp4 3,006,496 xc2vp7 4,485,408 xc2vp20 8,214,560 xc2vpx20 8,214,560 xc2vp30 11,589,920 xc2vp40 15,868,192 xc2vp50 19,021,344 xc2vp70 26,098,976 xc2vpx70 26,098,976 xc2vp100 34,292,768 virtex-ii pro and virtex-ii pro x platform fpgas: functional description r ds083 (v5.0) june 21, 2011 www.xilinx.com module 2 of 4 product specification 58 product not recommended for new designs synchronously. the sequence can also be paused at any stage, until lock has been achieved on any or all dcms, as well as dci. readback in this mode, configuration data from the virtex-ii pro fpga device can be read back. readback is supported only in the selectmap (master and slave) and boundary-scan mode. along with the configuration data, it is possible to read back the contents of all registers, distributed selectram+, and block ram resources. this capability is used for real-time debugging. for more detailed configuration information, see the virtex-ii pro platform fpga user guide. bitstream encryption virtex-ii pro devices have an on-chip decryptor using one or two sets of three keys for triple-key data encryption stan- dard (des) operation. xilinx so ftware tools offer an optional encryption of the configuration data (bitstream) with a tri- ple-key des determined by the designer. the keys are stored in the fpga by jtag instruction and retained by a battery connected to the v batt pin, when the device is not powered. virtex-ii pro devices can be config- ured with the corresponding encrypted bitstream, using any of the configuration modes described previously. a detailed description of how to use bitstream encryption is provided in the virtex-ii pro platform fpga user guide . your local fae can also provide specific information on this feature. partial reconfiguration partial reconfiguration of virtex-ii pro devices can be accomplished in either slave selectmap mode or bound- ary-scan mode. instead of resetting the chip and doing a full configuration, new data is loaded into a specified area of the chip, while the rest of th e chip remains in operation. data is loaded on a column ba sis, with the smallest load unit being a configuration ?frame? of the bitstream (device size dependent). partial reconfiguration is useful for applications that require different designs to be loaded into the same area of a chip, or that require the ability to change portions of a design without having to reset or reconfigure the entire chip. for more information on partial reconfiguration in virtex-ii pro devices, please refer to xilinx application note xapp290 , two flows for partial reconfiguration . revision history this section records the change history for this module of the data sheet. date version revision 01/31/02 1.0 initial xilinx release. 06/13/02 2.0 new virtex-ii pro family members. new timing parameters per speedsfile v1.62 . 09/03/02 2.1 ? revised reset and power sections. ? updated ta b l e 8 , which lists compatible input standards. [table deleted in v2.6.] ? added figure 28 , figure 29 , and figure 30 , which provide examples illustrating the use of i/o standards. 09/27/02 2.2 ? in section rocketio overview , corrected max number of mgts from 16 to 24. ? in section input/output blocks (iobs) , added references to xapp653 regarding implementation of 3.3v i/o standards. 11/20/02 2.3 ? ta b l e 8 : added rows for lvttl, lvcmos33, and pci-x. ? ta b l e 8 : added lvttl and lvcmos33 to compatible 3.3v cells. [table deleted in v2.6.] ? ta b l e 3 3 : correct bitstream lengths. 12/03/02 2.4 ? added mention of lvttl and pci with respect to selectio-ultra configurations. see section input/output individual options and figure 22 . 01/20/03 2.5 ? added qualification to features vs. virtex-ii (open-drain output pin tdo does not have internal pull-up resistor) ? table 7: added hstl18 (i, ii, iii, & iv) and hstl18_dci (i,ii, iii & iv) to 1.8v vcco row. [table deleted in v2.6.] ? table 8: numerous revisions. [table deleted in v2.6.] virtex-ii pro and virtex-ii pro x platform fpgas: functional description r ds083 (v5.0) june 21, 2011 www.xilinx.com module 2 of 4 product specification 59 product not recommended for new designs 03/24/03 2.5.1 ? ta b l e 1 0 : corrected i/o standard names sstl18_i and sstl18_ii to sstl18_i_dci and sstl18_ii_dci respectively. ? figure 61 , text below: corrected wording of criteria for clock switching. 05/27/03 2.6 ? removed compatible output standards and compatible input standards tables. ? added new ta bl e 1 2 , summary of voltage supply requirements for all input and output standards . this table replaces deleted i/o standards tables. ? corrected sentence in section input/output individual options, page 27 , to read ?the optional weak-keeper circuit is connected to each user i/o pad .? ? added section rules for combining i/o standards in the same bank, page 29 . 06/02/03 2.7 ? added four differential termination i/o standards to ta b l e 9 and ta b l e 1 2 . ? added section on-chip differential termination and figure 31, page 34 . 08/25/03 2.7.1 ? added footno te referring to xapp659 to 3.3v i/o callouts in ta b l e 8 and ta bl e 1 2 . 09/10/03 2.8 ? section configuration, page 56 : added text indicating that the mode pins m0-m2 must be held to a constant dc level during and after configuration. 10/14/03 2.9 ? deleted section functional description: rocketio multi-gigabit transceiver (mgt), page 10 . added section local clocking, page 51 . ? sections slave-serial mode and master-serial mode, page 56 : changed "rising" to "falling" edge with respect to dout. ? table 8, page 24 and table 10, page 25 : corrected input v ref for hstl_iii-iv_18 from 1.08v to 1.1v. 12/10/03 3.0 ? xc2vp2 through xc2vp70 speed grades -5, -6, and -7, and xc2vp100 speed grades -5 and -6, are released to production status . 02/19/04 3.1 ? section bufgmux, page 50 : corrected the definition of the "presently selected clock" to be i0 or i1. corrected signal names in figure 61 and associated text from clk0 and clk1 to i0 and i1. 03/09/04 3.1.1 ? recompiled for back ward compatibility with acrobat 4 and above. no content changes. 04/22/04 3.2 ? section clock de-skew, page 52 : removed reference to clk2x as an option for dcm clock feedback. 06/30/04 4.0 merged in ds110-2 (module 2 of virtex-ii pro x data sheet). separate rocketio and rocketio x sections created. 11/17/04 4.1 ? figure 11, page 12 : corrected figure by removing coupling capacitors from input. ? section rules for combining i/o standards in the same bank, page 29 : corrected i/o standard in the first example from lvds_25_dci to lvds_25. 03/01/05 4.2 ? reassigned heading hierarchies for better agreement with content. ? ta b l e 7 : corrected vccauxtx and vccauxrx to avccauxtx and avccauxrx respectively. ? ta b l e 9 : corrected v od (output voltage) ra nge for lvdsext_25. ? ta b l e 2 5 : corrected selectram+ memory available for xc2vpx70 device. ? ta b l e 3 3 : updated configuration default bitstream lengths. 06/20/05 4.3 no changes in module 2 for this revision. 09/15/05 4.4 ? ta b l e 1 : deleted sonet oc-192 protocol. ? ta b l e 3 : deleted rocketio x primitives for sonet oc-192, 10 gbit ethernet, and xilinx 10g (aurora) protocols. ? changed all instances of 10.3125 gb/s to 6.25 gb/s. ? ta b l e 7 : changed rocketio x vccauxrx from 1.5v globally to 1.5v for 8b/10b encoding, 1.8v for all other encoding protocols. date version revision virtex-ii pro and virtex-ii pro x platform fpgas: functional description r ds083 (v5.0) june 21, 2011 www.xilinx.com module 2 of 4 product specification 60 product not recommended for new designs notice of disclaimer the xilinx hardware fpga and cpld devices referred to herein (?products?) are subject to the terms and conditions of the xilinx limite d warranty which can be viewed at http://www.xilinx.com/warranty.htm . this limited warranty does not extend to any use of products in an application or environment that is not within the specifications stated in the xilinx data sheet. all specifications are subject to change without notice. products are not designed or intended to be fail-safe or for use in any application requiring fail-safe performance, such as life-support or safety devic es or systems, or any other application that invokes the potential risks of death, personal injury, or property or environmental damage (?critical applications?). use of products in critical applications is at the sole risk of customer, subject to applicable laws and regulations. virtex-ii pro data sheet the virtex-ii pro data sheet contains the following modules: ? virtex-ii pro and virtex-ii pro x platform fpgas: introduction and overview (module 1) ? virtex-ii pro and virtex-ii pro x platform fpgas: functional description (module 2) ? virtex-ii pro and virtex-ii pro x platform fpgas: dc and switching characteristics (module 3) ? virtex-ii pro and virtex-ii pro x platform fpgas: pinout information (module 4) 10/10/05 4.5 ? changed xc2vpx70 variable baud rate specification to fixed-rate operation at 4.25 gb/s. 03/05/07 4.6 no changes in module 2 for this revision. 11/05/07 4.7 ? updated copyright notice and legal disclaimer. ? debug interface, page 19 , and boundary-scan (jtag, ieee 1532) mode, page 57 : updated ieee 1149.1 compliance statement. 06/21/11 5.0 added product not recommended for new designs banner. date version revision ? 2000?2011 xilinx, inc. all rights reserved. xilinx, the xilinx logo, the brand window, and other designated brands included h erein are trademarks of xilinx, inc. powerpc is a trademark of ibm corp. and is used under license. all ot her trademarks are the property of their respective owners. ds083 (v5.0) june 21, 2011 www.xilinx.com module 3 of 4 product specification 1 product not recommended for new designs virtex-ii pro (1) electrical characteristics virtex?-ii pro devices are provided in -7, -6, and -5 speed grades, with -7 having the highest performance. virtex-ii pro dc and ac characteristics are specified for both commercial and industrial grades. except the operat- ing temperature range or unless otherwise noted, all the dc and ac electrical parameters are the same for a particular speed grade (that is, the timing characteristics of a -6 speed grade industrial device are the same as for a -6 speed grade commercial device). however, only selected speed grades and/or devices might be available in the industrial range. all supply voltage and junction temperature specifications are representative of worst-case conditions. the parame- ters included are common to popular designs and typical applications. contact xilinx for design considerations requiring more detailed information. all specifications are subject to change without notice. virtex-ii pro dc characteristics 5 9 virtex-ii pro and virtex-ii pro x platform fpgas: dc and switching characteristics ds083 (v5.0) june 21, 2011 product specification 1. unless otherwise noted, "virtex-ii pro" refers to members of the virtex-ii pro and/or virtex-ii pro x families. r ta bl e 1 : absolute maximum ratings symbol description (1) virtex-ii pro x virtex-ii pro units v ccint internal supply voltage relative to gnd ?0.5 to 1.6 v v ccaux auxiliary supply voltage relative to gnd ?0.5 to 3.0 v v cco output drivers supply voltage relative to gnd ?0.5 to 3.75 v v batt key memory battery backup supply ?0.5 to 4.05 v v ref input reference voltage ?0.3 to 3.75 v v in 3.3v i/o input voltage relative to g nd (user and dedicated i/os) ?0.3 to 4.05 (3) v 2.5v or below i/o input voltage relative to gnd (user and dedicated i/os) ?0.5 to v cco + 0.5 v v ts voltage applied to 3-state 3.3v output (user and dedicated i/os) ?0.3 to 4.05 (3) v voltage applied to 3-state 2.5v or below output (user and dedicated i/os) ?0.5 to v cco + 0.5 v avccauxrx receive auxilliary supply voltage relative to gnda (analog ground) ?0.5 to 2.0 ?0.5 to 3.0 v avccauxtx transmit auxilliary supply voltage relative to gnda (analog ground) ?0.5 to 3.0 ?0.5 to 3.0 v v trx terminal receive supply voltage relative to gnd ?0.5 to 3.0 ?0.5 to 3.0 v v ttx terminal transmit supply voltage relative to gnd ?0.5 to 1.6 ?0.5 to 3.0 v t stg storage temperature (ambient) ?65 to +150 ? c t sol maximum soldering temperature (2) all regular fg/ff flip-chip packages +220 ? c pb-free fgg256 wire-bond package n/a +260 ? c pb-free fgg456 and fgg676 wire-bond packages n/a +250 ? c t j maximum junction temperature (2) +125 ? c notes: 1. stresses beyond those listed under absolute maximum ratings might cause permanent damage to the device. these are stress ratings only, and functional operation of the device at these or any other conditions beyond those listed under operating condi tions is not implied. exposure to absolute maximum ratings conditio ns for extended periods of time might affect device reliability. 2. for soldering guidelines and thermal considerations, see the device packaging and thermal characteristics guide information on the xilinx website. 3. 3.3v i/o absolute maximum limit applied to dc and ac signals. refer to xapp659 for more details. virtex-ii pro and virtex-ii pro x platform fpgas: dc and switching characteristics r ds083 (v5.0) june 21, 2011 www.xilinx.com module 3 of 4 product specification 2 product not recommended for new designs ta bl e 2 : recommended operating conditions symbol description grade virtex-ii pro x virtex-ii pro units min max min max v ccint internal supply voltag e relative to gnd, t j =0 ? c to +85 ? c comm. 1.425 1.575 1.425 1.575 v internal supply voltag e relative to gnd, t j = ?40 ? c to +100 ? c indus. 1.425 1.575 1.425 1.575 v v ccaux (1) auxiliary supply voltage relative to gnd, t j =0 ? c to +85 ? c comm. 2.375 2.625 2.375 2.625 v auxiliary supply voltage relative to gnd, t j =?40 ? c to +100 ? c indus. 2.375 2.625 2.375 2.625 v v cco (2,3) supply voltage relative to gnd, t j =0 ? c to +85 ? c comm. 1.2 3.45 (5) 1.2 3.45 (5) v supply voltage relative to gnd, t j = ?40 ? c to +100 ? c indus. 1.2 3.45 (5) 1.2 3.45 (5) v v in 3.3v supply voltage relative to gnd, t j =0 ? c to +85 ? c comm. gnd ? 0.2 3.45 (5) gnd ? 0.2 3.45 (5) v 3.3v supply voltage relative to gnd, t j = ?40 ? c to +100 ? c indus. gnd ? 0.2 3.45 (5) gnd ? 0.2 3.45 (5) v 2.5v and below supply voltage relative to gnd, t j =0 ? c to +85 ? c comm. gnd ? 0.2 v cco + 0.2 gnd ? 0.2 v cco + 0.2 v 2.5v and below supply voltage relative to gnd, t j =?40 ? c to +100 ? c indus. gnd ? 0.2 v cco + 0.2 gnd ? 0.2 v cco + 0.2 v v batt (4) battery voltage relative to gnd, t j =0 ? c to +85 ? c comm. 1.0 3.6 1.0 3.6 v battery voltage relative to gnd, t j =?40 ? c to +100 ? c indus. 1.0 3.6 1.0 3.6 v avccauxrx (6) auxilliary receive supply voltage relative to gnda comm. 1.425 (7) 1.575 (7) 2.375 2.625 v indus. 1.425 (7) 1.575 (7) 2.375 2.625 v avccauxtx (6) auxilliary transmit supply voltage relative to gnda comm. 2.375 2.625 2.375 2.625 v indus. 2.375 2.625 2.375 2.625 v v trx terminal receive supply voltage relative to gnd comm. 0 2.625 1.6 2.625 v indus. 0 2.625 1.6 2.625 v v ttx terminal transmit supply voltage relative to gnd comm. 1.425 1.575 1.6 2.625 v indus. 1.425 1.575 1.6 2.625 v notes: 1. recommended maximum voltage droop for v ccaux is 10 mv/ms. 2. configuration data is retained even if v cco drops to 0v. 3. for 3.3v i/o operation, refer to xapp659 , available on the xilinx website at www.xilinx.com . 4. if battery is not used, connect v batt to gnd or v ccaux . 5. for pci and pci-x, refer to xapp653 , available on the xilinx website at www.xilinx.com . 6. important! the rocketio transceivers have certain power guidelines that must be met, even if unused in the design. please refer to the section entitled ?powering the rocketio transceivers? in the rocketio transceiver user guide or rocketio x transceiver user guide for more details. 7. for non-8b/10b-encoded data, the specification for avccauxrx is 1.8v 5% (1.71 ? 1.89v). virtex-ii pro and virtex-ii pro x platform fpgas: dc and switching characteristics r ds083 (v5.0) june 21, 2011 www.xilinx.com module 3 of 4 product specification 3 product not recommended for new designs notes: 1. characterized, not tested. 2. battery supply current (i batt ): 3. total dissipation of fully operational pma and pcs combined. this power is the average power supply dissipation per mgt. the averaging was done by simultaneously turning on all eight transceivers and dividing the total power supply dissipation by eight . ta bl e 3 : dc characteristics over re commended operating conditions symbol description virtex-ii pro x virtex-ii pro units min typ max min typ max v drint data retention v ccint voltage (below which configuration data might be lost) 1.25 1.25 v v dri data retention v ccaux voltage (below which configuration data might be lost) 2.0 2.0 v i ref v ref current per pin 10 10 ? a i l input or output leakage current per pin (sample-tested) 10 10 ? a c in input capacitance (sample-tested) 10 10 pf i rpu pad pull-up (when selected) @ v in = 0v, v cco = 2.5v (sample tested) 150 150 ? a i rpd pad pull-down (when selected) @ v in = 2.5v (sample-tested) 150 150 ? a i batt (1) battery supply current note (2) note (2) na i ccauxtx operating avccauxtx supply current 115 60 105 ma i ccauxrx operating avccauxrx supply current 85 35 75 ma i ttx operating i ttx supply current when transmitter is ac-coupled 55 30 ma operating i ttx supply current when transmitter is dc-coupled n/a n/a n/a 15 ma i trx operating i trx supply current when receiver is ac-coupled 15 0 ma operating i trx supply current when receiver is dc-coupled n/a n/a n/a 15 p cpu power dissipation of powerpc ? 405 processor block 0.9 0.9 mw/ mhz p rxtx (3) power dissipation of mgt @ 1.25 gb/s per channel n/a n/a n/a 230 mw power dissipation of mgt @ 2.5 gb/s per channel 290 310 mw power dissipation of mgt @ 3.125 gb/s per channel 310 350 mw power dissipation of mgt @ 4.25 gb/s per channel 450 n/a n/a n/a mw power dissipation of mgt @ 6.25 gb/s per channel 525 n/a n/a n/a mw device unpowered device powered units 25c: < 50 < 10 na 85c: n/a < 10 na virtex-ii pro and virtex-ii pro x platform fpgas: dc and switching characteristics r ds083 (v5.0) june 21, 2011 www.xilinx.com module 3 of 4 product specification 4 product not recommended for new designs ta bl e 4 : quiescent supply current symbol description device typ (1) max units i ccintq quiescent v ccint supply current xc2vp2 20 300 ma xc2vp4 30 400 ma xc2vp7 35 500 ma xc2vp20 40 600 ma xc2vpx20 40 600 ma xc2vp30 50 800 ma xc2vp40 60 1050 ma xc2vp50 70 1250 ma xc2vp70 85 1700 ma xc2vpx70 85 1700 ma xc2vp100 100 2200 ma i ccoq quiescent v cco supply current xc2vp2 1.0 8.0 ma xc2vp4 1.0 8.0 ma xc2vp7 1.0 8.0 ma xc2vp20 1.25 10 ma xc2vpx20 1.25 10 ma xc2vp30 1.25 10 ma xc2vp40 1.25 10 ma xc2vp50 1.5 12 ma xc2vp70 1.5 12 ma xc2vpx70 1.5 12 ma xc2vp100 1.75 15 ma i ccauxq quiescent v ccaux supply current xc2vp2 5 50 ma xc2vp4 5 50 ma xc2vp7 5 50 ma xc2vp20 10 75 ma xc2vpx20 10 75 ma xc2vp30 10 75 ma xc2vp40 10 75 ma xc2vp50 20 100 ma xc2vp70 20 100 ma xc2vpx70 20 100 ma xc2vp100 20 125 ma notes: 1. typical values are specified at nominal voltage, 25 c. 2. quiescent current parameter values are specified for commercial grade. for industrial grade values, multiply commercial grade values by 1.5. 3. with no output current loads, no active input pull- up resistors, all i/o pins are 3-state and floating. 4. if dci or differential signaling is used, more accurate quie scent current estimates can be obtained by using the power estima tor or xpower?. virtex-ii pro and virtex-ii pro x platform fpgas: dc and switching characteristics r ds083 (v5.0) june 21, 2011 www.xilinx.com module 3 of 4 product specification 5 product not recommended for new designs power-on power supply requirements xilinx fpgas require a certai n amount of supply current during power-on to insure proper device initialization. the actual current consumed depends on the power-on ramp rate of the power supply. the v ccint power supply must ramp on, monotonically, no faster than 200 ? s and no slower than 50 ms. ramp-on is defined as: 0 v dc to minimum supply voltages (see ta bl e 2 ). v ccaux and v cco can power on at any ramp rate. power supplies can be turned on in any sequence. ta b l e 5 shows the minimum current required by virtex-ii pro devices for proper power-on and configuration. if the current minimums shown in ta bl e 5 are met, the device powers on properly after all three supplies have passed through their power-on reset threshold voltages. once initialized and configured, use the power calculator to estimate current drain on these supplies. for more information on v ccaux , v cco , and configuration mode, refer to chapter 3 in the virtex-ii pro platform fpga user guide . general power s upply requirements proper decoupling of all fpga power supplies is essential. consult xilinx application note xapp623 for detailed infor- mation on power distribution system design. v ccaux powers critical resources in the fpga. therefore, this supply voltage is especially susceptible to power supply noise. v ccaux can share a power plane with v cco , but only if v cco does not have excessive noise. staying within simultaneously switching output (sso) limits is essential for keeping power supply noise to a minimum. refer to xapp689 , ?managing ground bounce in large fpgas,? to determine the number of simultaneously switching outputs allowed per bank at the package level. changes in v ccaux voltage beyond 200 mv peak-to-peak should take place at a rate no faster than 10 mv per milli- second. recommended practices that can help reduce jitter and period distortion are descri bed in xilinx answer record 13756. ta bl e 5 : power-on current for virtex-ii pro devices symbol device units xc2vp2 xc2vp4 xc2vp7 xc2vp20 xc2vpx20 xc2vp30 xc2vp40 xc2vp50 xc2vp70 xc2vpx70 xc2vp100 i ccintmin 500 500 500 600 600 800 1050 1250 1700 1700 2200 ma i ccauxmin 250 250 250 250 250 250 250 250 250 250 250 ma i ccomin 100 100 100 100 100 100 100 100 100 100 100 ma notes: 1. power-on current parameter values are specified for commercia l grade. for industrial grade values, multiply commercial grade values by 1.5. 2. i ccomin values listed here apply to the entire device (all banks). virtex-ii pro and virtex-ii pro x platform fpgas: dc and switching characteristics r ds083 (v5.0) june 21, 2011 www.xilinx.com module 3 of 4 product specification 6 product not recommended for new designs selectio-ultra dc i nput and output levels values for v il and v ih are recommended input voltages. values for i ol and i oh are guaranteed over the recom- mended operating conditions at the v ol and v oh test points. only selected standards are tested. these are cho- sen to ensure that all standards meet their specifications. the selected standards are tested at minimum v cco with the respective v ol and v oh voltage levels shown. other standards are sa mple tested. ldt dc specifi cations (ldt_25) ta bl e 6 : dc input and output levels iostandard attribute v il v ih v ol v oh i ol i oh v, min v, max v, min v, max v, max v, min ma ma lvttl ?0.2 0.8 2.0 3.45 0.4 2.4 24 ?24 lvcmos33 ?0.2 0.8 2.0 3.45 0.4 v cco ?0.4 24 ?24 lvcmos25 ?0.2 0.7 1.7 v cco + 0.4 0.4 v cco ?0.4 24 ?24 lvcmos18 ?0.2 30% v cco 70% v cco v cco + 0.4 0.4 v cco ?0.45 16 ?16 lvcmos15 ?0.2 30% v cco 70% v cco v cco + 0.4 0.4 v cco ?0.45 16 ?16 pci33_3 ?0.2 30% v cco 50% v cco 3.6 10% v cco 90% v cco pci66_3 ?0.2 30% v cco 50% v cco 3.6 10% v cco 90% v cco pcix ?0.2 note (1) note (1) note (1) note (1) note (1) note (1) note (1) gtlp ?0.2 v ref ?0.1 v ref + 0.1 v cco + 0.4 0.6 n/a 36 n/a gtl ?0.2 v ref ?0.05 v ref + 0.05 v cco + 0.4 0.4 n/a 40 n/a hstl_i ?0.2 v ref ?0.1 v ref + 0.1 v cco + 0.4 0.4 (2) v cco ?0.4 8 (2) ?8 (2) hstl_ii ?0.2 v ref ?0.1 v ref + 0.1 v cco + 0.4 0.4 (2) v cco ?0.4 16 (2) ?16 (2) hstl_iii ?0.2 v ref ?0.1 v ref + 0.1 v cco + 0.4 0.4 (2) v cco ?0.4 24 (2) ?8 (2) hstl_iv ?0.2 v ref ?0.1 v ref + 0.1 v cco + 0.4 0.4 (2) v cco ?0.4 48 (2) ?8 (2) sstl2_i ?0.2 v ref ?0.15 v ref +0.15 v cco + 0.3 v tt ?0.61 v tt + 0.61 8.1 ?8.1 sstl2_ii ?0.2 v ref ?0.15 v ref +0.15 v cco + 0.3 v tt ?0.81 v tt + 0.81 16.2 ?16.2 sstl18_i ?0.2 v ref ?0.125 v ref + 0.125 v cco +0.3 v tt ?0.61 v tt + 0.61 6.7 ?6.7 sstl18_ii ?0.2 v ref ?0.125 v ref + 0.125 v cco +0.3 v tt ?0.61 v tt + 0.61 13.4 ?13.4 notes: 1. tested according to relevant specifications. 2. this applies to 1.5v and 1.8v hstl. ta bl e 7 : ldt dc specifications dc parameter symbol conditions min typ max units supply voltage v cco 2.38 2.5 2.63 v differential output voltage v od r t = 100 ohm across q and q signals 495 600 715 mv change in v od magnitude ? v od ?15 15 mv output common mode voltage v ocm r t = 100 ohm across q and q signals 495 600 715 mv change in v os magnitude ? v ocm ?15 15 mv input differential voltage v id 200 600 1000 mv change in v id magnitude ? v id ?15 15 mv input common mode voltage v icm 440 600 780 mv change in v icm magnitude ? v icm ?15 15 mv virtex-ii pro and virtex-ii pro x platform fpgas: dc and switching characteristics r ds083 (v5.0) june 21, 2011 www.xilinx.com module 3 of 4 product specification 7 product not recommended for new designs lvds dc specifications (lvds_25) extended lvds dc specifications (lvdsext_25) lvpecl dc specifications (lvpecl_25) these values are valid when driving a 100 ? differential load only, i.e., a 100 ? resistor between the two receiver pins. the v oh levels are 200 mv below standard lvpecl levels and are compatible with devices tolerant of lower common-mode ranges. ta b l e 1 0 summarizes the dc output specifications of lvpecl. fo r more information on using lvpecl , see the virtex-ii pro platform fpga user guide . ta bl e 8 : lvds dc specifications dc parameter symbol conditions min typ max units supply voltage v cco 2.38 2.5 2.63 v output high voltage for q and q v oh r t = 100 ? across q and q signals 1.602 v output low voltage for q and q v ol r t = 100 ? across q and q signals 0.898 v differential output voltage (q ? q ), q = high (q ?q), q = high v odiff r t = 100 ? across q and q signals 247 350 454 mv output common-mode voltage v ocm r t = 100 ? across q and q signals 1.125 1.250 1.375 v differential input voltage (q ? q ), q = high (q ?q), q = high v idiff common-mode input voltage = 1.25v 100 350 600 mv input common-mode voltage v icm differential input voltage = ? 350 mv 0.3 1.2 2.2 v ta bl e 9 : extended lvds dc specifications dc parameter symbol conditions min typ max units supply voltage v cco 2.38 2.5 2.63 v output high voltage for q and q v oh r t = 100 ? across q and q signals 1.785 v output low voltage for q and q v ol r t = 100 ? across q and q signals 0.715 v differential output voltage (q ? q ), q = high (q ?q), q = high v odiff r t = 100 ? across q and q signals 440 820 mv output common-mode voltage v ocm r t = 100 ? across q and q signals 1.125 1.250 1.375 v differential input voltage (q ? q ), q = high (q ?q), q = high v idiff common-mode input voltage = 1.25v 100 1000 mv input common-mode voltage v icm differential input voltage = ? 350 mv 0.3 1.2 2.2 v ta bl e 1 0 : lvpecl dc specifications dc parameter v cco = 2.375v v cco = 2.5v v cco = 2.625v units min max min max min max v oh 1.35 1.495 1.475 1.62 1.6 1.745 v v ol 0.565 0.755 0.69 0.88 0.815 1.005 v v ih 0.8 2.0 0.8 2.0 0.8 2.0 v v il 0.5 1.7 0.5 1.7 0.5 1.7 v differential input voltage 0.100 1.5 0.100 1.5 0.100 1.5 v virtex-ii pro and virtex-ii pro x platform fpgas: dc and switching characteristics r ds083 (v5.0) june 21, 2011 www.xilinx.com module 3 of 4 product specification 8 product not recommended for new designs rocketio dc input and output levels ta bl e 1 1 : rocketio x input/output voltage specifications parameter symbol conditions min typ max units peak-to-peak differential input voltage (1) dv in 250 2000 mv single-ended output voltage swing (2,3) dv out 0 400 900 mv peak-to-peak differ ential output voltage (2,3) dv ppout 0 800 1800 mv notes: 1. see table 24, page 15 , for minimum eye sensitivity. 2. output swing levels are selectable using txdownlevel attribute. refer to the rocketio x transceiver user guide for details. 3. output preemphasis levels are selectable using the txemphlevel attribute. refer to the rocketio x transceiver user guide for details. ta bl e 1 2 : rocketio input/output voltage specifications parameter symbol conditions min typ max units peak-to-peak differential input voltage dv in 175 2000 mv differential input impedance dimp in termination_imp = 50 90 125 ? termination_imp = 75 135 187.5 ? single-ended output voltage swing (1,2) dv out 400 800 mv peak-to-peak differ ential output voltage (1,2) dv ppout 800 800 1600 mv notes: 1. output swing levels are selectable usin g tx_diff_ctrl attribute. refer to the rocketio transceiver user guide for details. 2. output preemphasis levels are selectable at 10% (default), 20%, 25%, and 33% using the tx_preemphasis attribute. refer to the rocketio transceiver user guide for details. figure 1: single-ended output voltage swing 0 +v txp txn dv out ds083-3_04_120302 figure 2: peak-to-peak differential output voltage 0 +v ?v txp?txn dv ppout ds083-3_05_120302 virtex-ii pro and virtex-ii pro x platform fpgas: dc and switching characteristics r ds083 (v5.0) june 21, 2011 www.xilinx.com module 3 of 4 product specification 9 product not recommended for new designs virtex-ii pro performance characteristics this section provides the performance characteristics of some common functions and designs implemented in virtex-ii pro devices. the numbers reported here are fully characterized worst-case values. note that these values are subject to the sa me guidelines as virtex-ii pro switching characteristics (speed files). ta b l e 1 3 provides pin-to-pin values (in nanoseconds) including iob delays; that is, delay through the device from input pin to output pin. in the case of multiple inputs and out- puts, the worst delay is reported. ta bl e 1 3 : pin-to-pin performance description device used & speed grade pin-to-pin performance (with i/o delays) units basic functions: 16-bit address decoder xc2vp20ff1152-6 7.20 ns 32-bit address decoder xc2vp20ff1152-6 8.08 ns 64-bit address decoder xc2vp20ff1152-6 8.15 ns 4:1 mux xc2vp20ff1152-6 3.85 ns 8:1 mux xc2vp20ff1152-6 7.24 ns 16:1 mux xc2vp20ff1152-6 7.30 ns 32:1 mux xc2vp20ff1152-6 7.64 ns combinatorial (pad to lut to pad) xc2vp20ff1152-6 3.26 ns memory: block ram pad to setup xc2vp20ff1152-6 1.72 ns clock to pad xc2vp20ff1152-6 6.63 ns distributed ram pad to setup xc2vp20ff1152-6 1.78 ns clock to pad xc2vp20ff1152-6 4.12 ns virtex-ii pro and virtex-ii pro x platform fpgas: dc and switching characteristics r ds083 (v5.0) june 21, 2011 www.xilinx.com module 3 of 4 product specification 10 product not recommended for new designs ta bl e 1 4 shows internal (register-to-register) performance. values are reported in mhz. ta bl e 1 4 : register-to-register performance description device used & speed grade register-to-register performance units basic functions: 16-bit address decoder xc2vp20ff1152-6 547 mhz 32-bit address decoder xc2vp20ff1152-6 392 mhz 64-bit address decoder xc2vp20ff1152-6 310 mhz 4:1 mux xc2vp20ff1152-6 710 mhz 8:1 mux xc2vp20ff1152-6 609 mhz 16:1 mux xc2vp20ff1152-6 472 mhz 32:1 mux xc2vp20ff1152-6 400 mhz register to lut to register xc2vp20ff1152-6 1046 mhz 8-bit adder xc2vp20ff1152-6 337 mhz 16-bit adder xc2vp20ff1152-6 334 mhz 32-bit adder xc2vp20ff1152-6 252 mhz 64-bit adder xc2vp20ff1152-6 202 mhz 128-bit adder xc2vp20ff1152-6 131 mhz 24-bit counter xc2vp20ff1152-6 309 mhz 64-bit counter xc2vp20ff1152-6 207 mhz 64-bit accumulator xc2vp20ff1152-6 150 mhz multiplier 18x18 (with block ram inputs) xc2vp20ff1152-6 135 mhz multiplier 18x18 (with register inputs) xc2vp20ff1152-6 147 mhz memory: block ram single-port 4096 x 4 bits xc2vp20ff1152-6 355 mhz distributed ram single-port 16 x 8-bit xc2vp20ff1152-6 555 mhz single-port 32 x 8-bit xc2vp20ff1152-6 557 mhz single-port 64 x 8-bit xc2vp20ff1152-6 408 mhz single-port 128 x 8-bit xc2vp20ff1152-6 336 mhz dual-port 16 x 8-bit xc2vp20ff1152-6 549 mhz dual-port 32 x 8-bit xc2vp20ff1152-6 460 mhz dual-port 64 x 8-bit xc2vp20ff1152-6 407 mhz virtex-ii pro and virtex-ii pro x platform fpgas: dc and switching characteristics r ds083 (v5.0) june 21, 2011 www.xilinx.com module 3 of 4 product specification 11 product not recommended for new designs virtex-ii pro switching characteristics switching characteristics are specified on a per-speed-grade basis and can be designated as advance, preliminary, or production. note that virtex-ii pro perfor- mance characteristics are subject to these guidelines, as well. each designation is defined as follows: advance : these speed files are based on simulations only and are typically available soon after device design specifi- cations are frozen. although speed grades with this desig- nation are considered relatively stable and conservative, some under-reporting might still occur. preliminary : these speed files are based on complete es (engineering sample) silicon ch aracterization. devices and speed grades with this designation are intended to give a better indication of the expected performance of production silicon. the probability of under -reporting delays is greatly reduced as compared to advance data. production : these speed files are released once enough production silicon of a particular device family member has been characterized to provide full correlation between speed files and devices over numerous production lots. there is no under-reporting of delays, and customers receive formal notification of any subsequent changes. typ- ically, the slowest speed grades transition to production before faster speed grades. since individual family members are produced at different times, the migration from one category to another depends completely on the status of the fabrication process for each device. ta bl e 1 5 correlates the current status of each virtex-ii pro device with a corresponding speed file desig- nation. all specifications are always representative of worst-case supply voltage and junction temperature conditions. testing of switching characteristics all devices are 100% functionally tested. internal timing parameters are derived from measuring internal test pat- terns. listed below are representative values. for more specific, more precise, and worst-case guaranteed data, use the values reported by the static timing analyzer (trce in the xilinx development syst em) and back-ann otate to the simulation net list. unless ot herwise noted, values apply to all virtex-ii pro devices. powerpc switching characteristics table 15: virtex-ii pro device speed grade designations device speed grade designations advance preliminary production xc2vp2 -7, -6, -5 xc2vp4 -7, -6, -5 xc2vp7 -7, -6, -5 xc2vp20 -7, -6, -5 xc2vpx20 -6, -5 xc2vp30 -7, -6, -5 xc2vp40 -7, -6, -5 xc2vp50 -7, -6, -5 xc2vp70 -7, -6, -5 xc2vpx70 -6, -5 xc2vp100 -6, -5 ta bl e 1 6 : processor clocks absolute ac characteristics speed grade -7 -6 -5 description min max min max min max units cpmc405clock frequency 0 400 (1) 0350 (1) 0300mhz jtagc405tck frequency (2) 020001750150mhz plbclk (3) 040003500300mhz bramdsocmclk (3) 040003500300mhz bramisocmclk (3) 040003500300mhz notes: 1. important! when cpmc405clock runs at speeds greater than 350 mhz in -7 commercial grade dual-processor devices, or greater than 300 mhz in -6 industrial grade dual-processor de vices, users must implement the technology presented in xapp755 , ?powerpc 405 clock macro for -7(c) and -6(i) speed grade dual-processor devices.? refer to ta b l e 1 , m o d u l e 1 to identify dual-processor devices. 2. the theoretical maximum frequency of this clock is one-half the cpmc405clock. however, the achievable maximum is dependent on the system, and will be much less. 3. the theoretical maximum frequency of these clocks is equal to the cpmc405clock. however, the achievable maximum is dependent on the syst em. please see powerpc 405 processor block reference guide and xapp640 for more information. virtex-ii pro and virtex-ii pro x platform fpgas: dc and switching characteristics r ds083 (v5.0) june 21, 2011 www.xilinx.com module 3 of 4 product specification 12 product not recommended for new designs ta bl e 1 7 : processor block switching characteristics speed grade description symbol -7 -6 -5 units setup and hold relative to clock (cpmc405clock) device control register bus control inputs t pcck _dcr/t pckc _dcr 0.38/?0.18 0.44/?0. 20 0.48/?0.23 ns, min device control register bus data inputs t pdck _dcr/t pckd _dcr 0.65/?0.01 0.75/?0. 01 0.82/?0.02 ns, min clock and power management control inputs t pcck _cpm/t pckc _cpm 0.16/ 0.03 0.19/ 0. 03 0.20/ 0.03 ns, min reset control inputs t pcck _rst/t pckc _rst 0.16/ 0.03 0.19/ 0. 03 0.20/ 0.03 ns, min debug control inputs t pcck _dbg/t pckc _dbg 0.27/ 0.30 0.31/ 0. 35 0.34/ 0.38 ns, min trace control inputs t pcck _trc/t pckc _trc 1.37/?0.41 1.57/?0. 48 1.73/?0.52 ns, min external interrupt controller control inputs t pcck _eic/t pckc _eic 0.57/?0.22 0.66/?0. 25 0.72/?0.27 ns, min clock to out device control register bus control outputs t pckco _dcr 1.32 1.52 1.67 ns, max device control regist er bus address outputs t pckao _dcr 1.72 1.98 2.17 ns, max device control register bus data outputs t pckdo _dcr 1.76 2.02 2.22 ns, max clock and power management control outputs t pckco _cpm 1.26 1.45 1.59 ns, max reset control outputs t pckco _rst 1.32 1.51 1.66 ns, max debug control outputs t pckco _dbg 1.94 2.22 2.44 ns, max trace control outputs t pckco _trc 1.35 1.56 1.71 ns, max clock cpmc405clock minimum pulse width, high t cpwh 1.25 1.42 1.66 ns, min cpmc405clock minimum pulse width, low t cpwl 1.25 1.42 1.66 ns, min ta bl e 1 8 : processor block plb switching characteristics speed grade description symbol -7 -6 -5 units setup and hold relati ve to clock (plbclk) processor local bus(icu/dcu) control inputs t pcck _plb/t pckc _plb 0.98/ 0.18 1.12/ 0.21 1.23/ 0.23 ns, min processor local bus (icu/dcu) data inputs t pdck _plb/t pckd _plb 0.62/ 0.16 0.71/ 0.18 0.78/ 0.20 ns, min clock to out processor local bus(icu/dcu) control outputs t pckco _plb 1.34 1.54 1.69 ns, max processor local bus(icu/dcu) address bus outputs t pckao _plb 1.16 1.34 1.47 ns, max processor local bus(icu/dcu) data bus outputs t pckdo _plb 1.44 1.65 1.81 ns, max virtex-ii pro and virtex-ii pro x platform fpgas: dc and switching characteristics r ds083 (v5.0) june 21, 2011 www.xilinx.com module 3 of 4 product specification 13 product not recommended for new designs ta bl e 1 9 : processor block jtag switching characteristics speed grade description symbol -7 -6 -5 units setup and hold relative to clock (jtagc405tck) jtag control inputs t pcck _jtag/ t pckc _jtag 0.80/ 0.70 0.80/ 0.70 0.88/ 0.77 ns, min jtag reset input t pcck _jtagrst/ t pckc _jtagrst 0.80/ 0.70 0.80/ 0.70 0.88/ 0.77 ns, min clock to out jtag control outputs t pckco _jtag 1.34 1.54 1.69 ns, max ta bl e 2 0 : powerpc 405 data-side on-chip memory switching characteristics speed grade description symbol -7 -6 -5 units setup and hold relative to clock (bramdsocmclk) data-side on-chip memo ry data bus inputs t pdck _dsocm/ t pckd _dsocm 0.73/ 0.83 0.84/ 0.95 0.92/ 1.05 ns, min clock to out data-side on-chip memory control outputs t pckco _dsocm 1.58 1.82 1.99 ns, max data-side on-chip memory address bus outputs t pckao _dsocm 1.46 1.68 1.84 ns, max data-side on-chip memory data bus outputs t pckdo _dsocm 0.90 1.03 1.13 ns, max ta bl e 2 1 : powerpc 405 instruction-side on-chi p memory switching characteristics speed grade description symbol -7 -6 -5 units setup and hold relative to clock (bramisocmclk) instruction-side on-chip memory data bus inputs t pdck _isocm/ t pckd _isocm 0.81/ 0.68 0.93/ 0.78 1.02/ 0.86 ns, min clock to out instruction-side on-chip memory control outputs t pckco _isocm 1.33 1.53 1.68 ns, max instruction-side on-chip memory address bus outputs t pckao _isocm 1.52 1.75 1.92 ns, max instruction-side on-chip memory data bus outputs t pckdo _isocm 1.35 1.55 1.70 ns, max virtex-ii pro and virtex-ii pro x platform fpgas: dc and switching characteristics r ds083 (v5.0) june 21, 2011 www.xilinx.com module 3 of 4 product specification 14 product not recommended for new designs rocketio switching characteristics ta bl e 2 2 : rocketio x reference clock switching characteristics all speed grades description symbol conditions min typ max units reference clock frequency range (1) f gclk 62.5 425 mhz reference clock frequency tolerance f gtol 350 ppm reference clock rise time t rclk 20% ? 80% 75 ps reference clock fall time t fclk 20% ? 80% 75 ps reference clock duty cycle t dcref 45 50 55 % reference clock total jitter, peak-peak t gjtt 3.125 gb/s ? 6.25 gb/s 30 ps 2.488 gb/s ? 3.125 gb/s 40 ps clock recovery frequency acquisition time, from power-up to high state of pmarxlock t lock 100 s clock recovery phase acquisition time, from data to high state of pmarxlock t phase 40 60 s notes: 1. brefclk should be used for all serial bit rates up to the maximum shown. ta bl e 2 3 : rocketio reference clock switching characteristics all speed grades description symbol conditions min typ max units reference clock frequency range (1) f gclk full rate operation 50 156.25 mhz half rate operation (2) (2x oversampling) 60 100 mhz reference clock frequency tolerance f gtol 100 ppm reference clock rise time t rclk 20% ? 80% 600 1000 ps reference clock fall time t fclk 20% ? 80% 600 1000 ps reference clock duty cycle t dcref 45 50 55 % reference clock total jitter, peak-peak (3) t gjtt 2.501 gb/s ? 3.125 gb/s 40 ps 1.061 gb/s ? 2.5 gb/s 50 ps ? 1.06 gb/s 120 ps clock recovery frequency acquisition time t lock 10 s clock recovery phase acquisition time t phase 960 bits (4) notes: 1. brefclk/brefclk2 can be used for all serial bit rates up to t he maximum shown. refclk/refclk2 can be used for serial bit rate s up to 2.5 gb/s (refclk = 125 mhz). all other parameters apply equally to refclk, refclk2, brefclk, and brefclk2 except as noted. 2. for serial rates under 1 gb/s, the 3x (or greater) oversampling te chniques described in xapp572 are required to meet the transmit jitter and receive jitter tolerance specifications defined in this data sheet. 3. measured at the package pin. for refer ence clock frequencies equal to or above 125 mhz, brefclk/brefclk2 must be used. 4. 8b/10b-type bitstream. figure 3: reference clock timing parameters ds083-3_01_120302 80% 20% t fclk t rclk virtex-ii pro and virtex-ii pro x platform fpgas: dc and switching characteristics r ds083 (v5.0) june 21, 2011 www.xilinx.com module 3 of 4 product specification 15 product not recommended for new designs ta bl e 2 4 : rocketio x receiver switching characteristics (1) description symbol conditions min typ max units receive total jitter tolerance using default equalization and prbs-15 pattern t jtol 2.488 gb/s 0.80 0.65 ui (2) 3.125 gb/s 0.80 0.65 ui 4.25 gb/s 0.80 0.65 ui 6.25 gb/s 0.80 0.65 ui receive random jitter tolerance t rjtol 2.488 gb/s 0.30 ui 3.125 gb/s 0.30 ui 4.25 gb/s 0.30 ui 6.25 gb/s 0.30 ui receive sinusoidal jitter tolerance measured at 70 mhz t sjtol 2.488 gb/s 0.30 0.15 ui 3.125 gb/s 0.30 0.15 ui 4.25 gb/s 0.30 0.15 ui 6.25 gb/s 0.30 0.15 ui receive deterministi c jitter tolerance t djtol 2.488 gb/s 0.55 0.45 ui 3.125 gb/s 0.55 0.45 ui 4.25 gb/s 0.55 0.45 ui 6.25 gb/s 0.50 0.45 ui receive latency (3) t rxlat 25 34 (4) rxusrclk cycles rxusrclk duty cycle t rxdc 45 50 55 % rxusrclk2 duty cycle t rx2dc 45 50 55 % differential receive input sensitivity v eye 120 250 mv notes: 1. the xc2vpx70 operates at a fixed 4.25 gb/s baud rate. 2. ui = unit interval 3. receive latency delay rxp/rxn to rxdata. refer to rocketio x transceiver user guide for more information on calculating latency. 4. this maximum may occur when certain c onditions are present and clock correction and channel bonding are enabled. if these fun ctions are both disabled, the maximum will be near the typical values. virtex-ii pro and virtex-ii pro x platform fpgas: dc and switching characteristics r ds083 (v5.0) june 21, 2011 www.xilinx.com module 3 of 4 product specification 16 product not recommended for new designs ta bl e 2 5 : rocketio receiver switching characteristics description symbol conditions min typ max units receive total jitter tolerance t jtol 2.126 gb/s ? 3.125 gb/s 0.65 ui (1) 1.0626 gb/s ? 2.125 gb/s 0.65 ui 1.0 gb/s ? 1.0625 gb/s 0.68 ui 600 mb/s ? 999 mb/s 0.68 (2) ui receive deterministi c jitter tolerance t djtol 2.126 gb/s ? 3.125 gb/s 0.41 ui 1.0626 gb/s ? 2.125 gb/s 0.43 ui 1.0 gb/s ? 1.0625 gb/s 0.47 ui 600 mb/s ? 999 mb/s 0.47 (2) receive latency (3) t rxlat 25 42 (4) rxusrclk cycles rxusrclk duty cycle t rxdc 45 50 55 % rxusrclk2 duty cycle t rx2dc 45 50 55 % notes: 1. ui = unit interval 2. the oversampling techniques described in xapp572 are required to meet these specificat ions for serial rates less than 1 gb/s. 3. receive latency delay rxp/rxn to rxdata. refer to rocketio transceiver user guide for more information on calculating latency. 4. this maximum may occur when certain c onditions are present and clock correction and channel bonding are enabled. if these fun ctions are both disabled, the maximum will be near the typical values. figure 4: rocketio receive latency (maximum) ds083-3_02_082301 rxdata[16:0] rxp/rxn rxusrclk2 t rxlat data arrives data originates 0 1 41 42 12 . . . . . 20 821 822 . . . . . . . . . 840 841 842 21 22 . . . . . 820 virtex-ii pro and virtex-ii pro x platform fpgas: dc and switching characteristics r ds083 (v5.0) june 21, 2011 www.xilinx.com module 3 of 4 product specification 17 product not recommended for new designs ta bl e 2 6 : rocketio x transmitter switching characteristics (1) description symbol conditions brefclk frequency min typ max units serial data rate f gtx 2.488 6.25 gb/s serial data output total jitter (p-p) (3) t tj 2.488 gb/s 0.15 0.20 ui (2) 3.125 gb/s 0.14 0.19 ui 4.25 gb/s 0.39 0.48 ui 6.25 gb/s 0.42 0.54 ui serial data output deterministic jitter (p-p) (3) t dj 2.488 gb/s 155.52 mhz 0.03 0.17 ui 3.125 gb/s 156.25 mhz 0.03 0.17 ui 4.25 gb/s 212.5 mhz 0.14 0.26 ui 6.25 gb/s 312.5 mhz 0.17 0.35 ui serial data output random jitter (p-p) (3,4) t rj 2.488 gb/s 155.52 mhz 0.12 0.18 ui 3.125 gb/s 156.25 mhz 0.12 0.20 ui 4.25 gb/s 212.5 mhz 0.25 0.39 ui 6.25 gb/s 312.5 mhz 0.25 0.39 ui tx rise time t rtx 20% ? 80% @ 2.500 gb/s 60 ps tx fall time t ftx 60 ps transmit latency (5) t txlat 14 19 txusr clk cycles txusrclk duty cycle t txdc 45 50 55 % txusrclk2 duty cycle t tx2dc 45 50 55 % notes: 1. the xc2vpx70 operates at a fixed 4.25 gb/s baud rate. 2. ui = unit interval 3. total jitter t tj = t dj + t rj 4. t rj specifications are wideband and include low-frequency jitter components (also referred to as wander ).t rj specified is peak-to-peak, estimated at ber=10 ?12 using the bathtub method. 5. transmit latency delay txdata to txp/txn. refer to rocketio x transceiver user guide for more information on calculating latency. virtex-ii pro and virtex-ii pro x platform fpgas: dc and switching characteristics r ds083 (v5.0) june 21, 2011 www.xilinx.com module 3 of 4 product specification 18 product not recommended for new designs ta bl e 2 7 : rocketio transmitter switching characteristics description symbol conditions min typ max units serial data rate, full-speed clock f gtx flipchip packages 1.0 3.125 (1) gb/s wirebond packages 1.0 2.5 (1) gb/s serial data rate, half-speed clock (3) (2x oversampling) flipchip packages 0.600 1.0 gb/s wirebond packages 0.600 1.0 gb/s serial data output deterministic jitter t dj 2.126 gb/s ? 3.125 gb/s 0.17 ui (2) 1.0626 gb/s ? 2.125 gb/s 0.08 ui 1.0 gb/s ? 1.0625 gb/s 0.05 ui 600 mb/s ? 999 mb/s 0.08 (4) ui serial data output random jitter t rj 2.126 gb/s ? 3.125 gb/s 0.18 ui 1.0626 gb/s ? 2.125 gb/s 0.19 ui 1.0 gb/s ? 1.0625 gb/s 0.18 ui 600 mb/s ? 999 mb/s 0.18 (4) ui tx rise time t rtx 20% ? 80% 120 ps tx fall time t ftx 120 ps transmit latency (5) t txlat including crc 14 17 txusr clk cycles excluding crc 8 11 txusrclk duty cycle t txdc 45 50 55 % txusrclk2 duty cycle t tx2dc 45 50 55 % notes: 1. serial data rate in the -5 speed grade is limited to 2.0 gb/s in both wirebond and flipchip packages. 2. ui = unit interval 3. for serial rates under 1 gb/s, the 3x (or greater) oversampling techniques described in xapp572 are required to meet the transmit jitter and receive jitter tolerance specificat ions defined in this data sheet. 4. the oversampling techniques described in xapp572 are required to meet these specificat ions for serial rates less than 1 gb/s. 5. transmit latency delay txdata to txp/txn. refer to rocketio transceiver user guide for more information on calculating latency. figure 5: rocketio transmit latency (maximum, including crc) ds083-3_03_082301 txp/txn txdata[16:0] txusrclk2 t txlat data originates 1 0 2 1 . . . . . 16 17 20 321 322 . . . . . . . . . 340 341 342 21 22 . . . . . 320 data arrives virtex-ii pro and virtex-ii pro x platform fpgas: dc and switching characteristics r ds083 (v5.0) june 21, 2011 www.xilinx.com module 3 of 4 product specification 19 product not recommended for new designs ta bl e 2 8 : rocketio x fabric interface characteristics description symbol all speed grades units min typ max tx/rxusrclk frequency f txrxuclk 125.00 212.50 mhz tx/rxusrclk2 frequency f txrxuclk2 62.50 250.00 mhz ta bl e 2 9 : rocketio x rxusrclk switching characteristics speed grade description symbol -7 -6 -5 units setup and hold relative to clock (rxusrclk) chbondi control inputs t gcck _chbi/t gckc _chbi ns, min clock to out chbondo control outputs t gckco _chbo ns, max clock rxusrclk minimum pulse width, high t gpwh _rx ns, min rxusrclk minimum pulse width, low t gpwl _rx ns, min ta bl e 3 0 : rocketio rxusrclk swit ching characteristics speed grade description symbol -7 -6 -5 units setup and hold relative to clock (rxusrclk) chbondi control inputs t gcck _chbi/t gckc _chbi 0.00/ 0.12 0.00/ 0.12 0.00/ 0.14 ns, min clock to out chbondo control outputs t gckco _chbo 0.50 0.50 0.55 ns, max clock rxusrclk minimum pulse width, high t gpwh _rx 2.83 2.83 4.50 ns, min rxusrclk minimum pulse width, low t gpwl _rx 2.83 2.83 4.50 ns, min ta bl e 3 1 : rocketio x rxusrclk2 switching characteristics speed grade description symbol -7 -6 -5 units setup and hold relative to clock (rxusrclk2) rxreset control input t gcck _rrst/t gckc _rrst ns, min rxpolarity control input t gcck _rpol/t gckc _rpol ns, min enchansync control input t gcck _ecsy/t gckc _ecsy ns, min rxblocksync64b66euse control input t gcck _blksnc/t gckc _blksnc ns, min rxcommadetuse control input t gcck _cmdt/t gcck _cmdt ns, min rxignorebtf control input t gcck _ibtf/t gcck _ibtf ns, min rxdatawidth control input t gcck _rdatw/t gcck _rdatw ns, min virtex-ii pro and virtex-ii pro x platform fpgas: dc and switching characteristics r ds083 (v5.0) june 21, 2011 www.xilinx.com module 3 of 4 product specification 20 product not recommended for new designs rxdec64b66buse rxdec8b10buse control input t gcck _rdec/t gcck _rdec ns, min rxdescram64b66buse control input t gcck _rdes/t gcck _rdes ns, min rxintdatawidth control input t gcck _ridatw/t gcck _ridatw ns, min rxslide control input t gcck _rxslide/t gcck _rxslide ns, min clock to out pmarxlock status output t gckst _plck ns, max rxnotintable status outputs t gckst _rnit ns, max rxdisperr status outputs t gckst _rderr ns, max rxchariscomma status outputs t gckst _rcmch ns, max rxrealign status output t gckst _align ns, max rxcommadet status output t gckst _cmdt ns, max rxlossofsync status outputs t gckst _rlos ns, max rxclkcorcnt status outputs t gckst _rcccnt ns, max rxbufstatus status outputs t gckst _rbsta ns, max chbonddone status output t gckst _chbd ns, max rxcharisk status outputs t gckst _rkch ns, max rxrundisp status outputs t gckst _rrdis ns, max rxdata data outputs t gckdo _rdat ns, max clock rxusrclk2 minimum pulse width, high t rx2pwh ns, min rxusrclk2 minimum pulse width, low t rx2pwl ns, min ta bl e 3 1 : rocketio x rxusrclk2 swit ching characteristics (continued) speed grade description symbol -7 -6 -5 units ta bl e 3 2 : rocketio rxusrclk2 s witching characteristics speed grade description symbol -7 -6 -5 units setup and hold relative to clock (rxusrclk2) rxreset control input t gcck _rrst/t gckc _rrst 0.02/ 0.00 0.02/ 0.00 0.02/ 0.00 ns, min rxpolarity control input t gcck _rpol/t gckc _rpol 0.02/ 0.00 0.02/ 0.00 0.02/ 0.00 ns, min enchansync control input t gcck _ecsy/t gckc _ecsy 0.02/ 0.00 0.02/ 0.00 0.02/ 0.00 ns, min clock to out rxnotintable status outputs t gckst _rnit 0.50 0.50 0.55 ns, max rxdisperr status outputs t gckst _rderr 0.50 0.50 0.55 ns, max rxchariscomma status outputs t gckst _rcmch 0.50 0.50 0.55 ns, max rxrealign status output t gckst _align 0.41 0.41 0.46 ns, max rxcommadet status output t gckst _cmdt 0.41 0.41 0.46 ns, max rxlossofsync status outputs t gckst _rlos 0.50 0.50 0.55 ns, max rxclkcorcnt status outputs t gckst _rcccnt 0.41 0.41 0.46 ns, max virtex-ii pro and virtex-ii pro x platform fpgas: dc and switching characteristics r ds083 (v5.0) june 21, 2011 www.xilinx.com module 3 of 4 product specification 21 product not recommended for new designs rxbufstatus status outputs t gckst _rbsta 0.45 0.45 0.50 ns, max rxcheckingcrc status output t gckst _rccrc 0.36 0.40 0.44 ns, max rxcrcerr status output t gckst _rcrce 0.36 0.40 0.44 ns, max chbonddone status output t gckst _chbd 0.50 0.50 0.55 ns, max rxcharisk status outputs t gckst _rkch 0.50 0.50 0.55 ns, max rxrundisp status outputs t gckst _rrdis 0.50 0.50 0.55 ns, max rxdata data outputs t gckdo _rdat 0.50 0.50 0.55 ns, max clock rxusrclk2 minimum pulse width, high t gpwh _rx2 1.42 1.42 2.25 ns, min rxusrclk2 minimum pulse width, low t gpwl _rx2 1.42 1.42 2.25 ns, min ta bl e 3 2 : rocketio rxusrclk2 swit ching characteristics (continued) speed grade description symbol -7 -6 -5 units ta bl e 3 3 : rocketio x txusrclk2 switching characteristics speed grade description symbol -7 -6 -5 units setup and hold relative to clock (txusrclk2) txbypass8b10b control inputs t gcck _tbyp/t gckc _tbyp ns, min txpolarity control input t gcck _tpol/t gckc _tpol ns, min txinhibit control inputs t gcck _tinh/t gckc _tinh ns, min loopback control inputs t gcck _lbk/t gckc _lbk ns, min txreset control input t gcck _trst/t gckc _trst ns, min txcharisk control inputs t gcck _tkch/t gckc _tkch ns, min txchardispmode control inputs t gcck _tcdm/t gckc _tcdm ns, min txchardispval control inputs t gcck _tcdv/t gckc _tcdv ns, min txdatawidth control inputs t gcck _tdatw/t gcck _tdatw ns, min txenc64b66buse txenc8b10buse control inputs t gcck _tenc/t gcck _tenc ns, min txintdatawidth control inputs t gcck _tidatw/t gcck _tidatw ns, min txgearbox64b66buse control inputs t gcck _txgear/t gcck _txgear ns, min txscram64b66buse control inputs t gcck _txscbl/t gcck _txscbl ns, min refclksel refclkbsel control inputs t gcck _rfcksl/t gcck _rfcksl ns, min txdata data inputs t gdck _tdat/t gckd _tdat ns, min clock to out txbuferr status output t gckst _tberr ns, max txkerr status outputs t gckst _tkerr ns, max txrundisp status outputs t gckst _trdis ns, max clock txusrclk2 minimum pulse width, high t gpwh _tx2 ns, min txusrclk2 minimum pulse width, low t gpwl _tx2 ns, min virtex-ii pro and virtex-ii pro x platform fpgas: dc and switching characteristics r ds083 (v5.0) june 21, 2011 www.xilinx.com module 3 of 4 product specification 22 product not recommended for new designs ta bl e 3 4 : rocketio txusrclk2 switching characteristics speed grade description symbol -7 -6 -5 units setup and hold relative to clock (txusrclk2) configenable control input t gcck _cfgen/t gckc _cfgen 0.35/ 0.10 0.35/ 0.10 0.39/ 0.11 ns, min txbypass8b10b control inputs t gcck _tbyp/t gckc _tbyp 0.02/ 0.00 0.02/ 0.00 0.02/ 0.00 ns, min txforcecrcerr control input t gcck _tcrce/t gckc _tcrce 0.39/ 0.12 0.44/ 0.14 0.49/ 0.15 ns, min txpolarity control input t gcck _tpol/t gckc _tpol 0.02/ 0.00 0.02/ 0.00 0.02/ 0.00 ns, min txinhibit control inputs t gcck _tinh/t gckc _tinh 0.02/ 0.00 0.02/ 0.00 0.02/ 0.00 ns, min loopback control inputs t gcck _lbk/t gckc _lbk 0.02/ 0.00 0.02/ 0.00 0.02/ 0.00 ns, min txreset control input t gcck _trst/t gckc _trst 0.02/ 0.10 0.02/ 0.10 0.02/ 0.11 ns, min txcharisk control inputs t gcck _tkch/t gckc _tkch 0.02/ 0.00 0.02/ 0.00 0.02/ 0.00 ns, min txchardispmode control inputs t gcck _tcdm/t gckc _tcdm 0.02/ 0.00 0.02/ 0.00 0.02/ 0.00 ns, min txchardispval control inputs t gcck _tcdv/t gckc _tcdv 0.02/ 0.00 0.02/ 0.00 0.02/ 0.00 ns, min configin data input t gdck _cfgin/t gckd _cfgin 0.35/ 0.10 0.35/ 0.10 0.39/ 0.11 ns, min txdata data inputs t gdck _tdat/t gckd _tdat 0.02/ 0.00 0.02/ 0.00 0.02/ 0.00 ns, min clock to out txbuferr status output t gckst _tberr 0.54 0.54 0.60 ns, max txkerr status outputs t gckst _tkerr 0.41 0.41 0.46 ns, max txrundisp status outputs t gckst _trdis 0.41 0.41 0.46 ns, max configout data output t gckdo _cfgout 0.25 0.25 0.28 ns, max clock txusrclk2 minimum pulse width, high t gpwh _tx2 1.42 1.42 2.25 ns, min txusrclk2 minimum pulse width, low t gpwl _tx2 1.42 1.42 2.25 ns, min virtex-ii pro and virtex-ii pro x platform fpgas: dc and switching characteristics r ds083 (v5.0) june 21, 2011 www.xilinx.com module 3 of 4 product specification 23 product not recommended for new designs iob input switching characteristics input delays associated with the pad are specified for lvcmos 2.5v levels. for other standards, adjust the delays with the values shown in iob input switching characteri stics standard adjustments . ta bl e 3 5 : iob input switching characteristics speed grade description symbol device -7 -6 -5 units propagation delays pad to i output, no delay t iopi all 0.84 0.87 0.91 ns, max pad to i output, with delay t iopid xc2vp2 1.84 1.94 2.06 ns, max xc2vp4 1.84 1.94 2.06 ns, max xc2vp7 1.84 1.94 2.06 ns, max xc2vp20 2.14 2.23 2.37 ns, max xc2vpx20 2.14 2.23 2.37 ns, max xc2vp30 2.14 2.26 2.46 ns, max xc2vp40 2.54 2.67 2.81 ns, max xc2vp50 2.54 2.68 2.87 ns, max xc2vp70 2.54 2.72 2.91 ns, max xc2vpx70 2.54 2.72 2.91 ns, max xc2vp100 n/a 4.71 4.80 ns, max propagation delays pad to output iq via transparent latch, no delay t iopli all 0.86 0.89 0.93 ns, max pad to output iq via transparent latch, with delay t ioplid xc2vp2 2.30 2.62 2.97 ns, max xc2vp4 2.57 2.89 3.23 ns, max xc2vp7 2.50 2.84 3.17 ns, max xc2vp20 2.65 3.04 3.42 ns, max xc2vpx20 2.65 3.04 3.42 ns, max xc2vp30 2.69 3.12 3.51 ns, max xc2vp40 3.30 3.63 4.03 ns, max xc2vp50 3.86 4.10 4.45 ns, max xc2vp70 4.00 4.25 4.57 ns, max xc2vpx70 4.00 4.25 4.57 ns, max xc2vp100 n/a 6.50 7.06 ns, max clock clk to output iq t iockiq all 0.60 0.60 0.67 ns, max virtex-ii pro and virtex-ii pro x platform fpgas: dc and switching characteristics r ds083 (v5.0) june 21, 2011 www.xilinx.com module 3 of 4 product specification 24 product not recommended for new designs setup and hold tim es with respect to clock at iob input register pad, no delay t iopick /t ioickp all 0.84/?0.61 0.86/?0.63 0.90/?0.67 ns, min pad, with delay t iopickd /t ioickpd xc2vp2 2.28/?1.89 2.60/?2.15 2.95/?2.43 ns, max xc2vp4 2.55/?2.10 2.87/?2.36 3.21/?2.65 ns, max xc2vp7 2.48/?2.05 2.82/?2.32 3.15/?2.60 ns, max xc2vp20 2.63/?2.05 3.02/?2.35 3.40/?2.66 ns, max xc2vpx20 2.63/?2.05 3.02/ ?2.35 3.40/?2.66 ns, max xc2vp30 2.67/?2.07 3.09/?2.42 3.49/?2.73 ns, max xc2vp40 3.28/?2.56 3.61/?2.83 4.01/?3.15 ns, max xc2vp50 3.84/?3.02 4.08/?3.21 4.42/?3.48 ns, max xc2vp70 3.98/?3.13 4.23/?3.33 4.55/?3.58 ns, max xc2vpx70 3.98/?3.13 4.23/ ?3.33 4.55/?3.58 ns, max xc2vp100 n/a 6.48/?5.13 7.04/?5.57 ns, max ice input t ioiceck /t iockice all 0.39/ 0.01 0.44/ 0.01 0.49/ 0.01 ns, min sr input (iff, synchronous) t iosrcki all 0.52 0.57 0.75 ns, min set/reset delays sr input to iq (asynchronous) t iosriq all 1.13 1.27 1.42 ns, max gsr to output iq t gsrq all 5.87 6.75 7.43 ns, max notes: 1. input timing for lvcmos25 is measured at 1.25v. for other i/o standards, see ta bl e 3 9 . ta bl e 3 5 : iob input switching characteristics (continued) speed grade description symbol device -7 -6 -5 units virtex-ii pro and virtex-ii pro x platform fpgas: dc and switching characteristics r ds083 (v5.0) june 21, 2011 www.xilinx.com module 3 of 4 product specification 25 product not recommended for new designs iob input switching character istics standard adjustments ta bl e 3 6 gives all standard-specific data input delay adjustments. ta bl e 3 6 : iob input switching characteristics standard adjustments description iostandard attribute timing parameter speed grade units -7 -6 -5 lvttl (low-voltage transistor-transistor logic) lvttl t ilvttl 0.07 0.08 0.09 ns lvcmos (low-voltage cmos ), 3.3v lvcmos33 t ilvcmos33 0.04 0.05 0.05 ns lv c m o s, 2 . 5 v lv c m o s 2 5 t ilvcmos25 0.00 0.00 0.00 ns lv c m o s, 1 . 8 v lv c m o s 1 8 t ilvcmos18 0.29 0.33 0.36 ns lv c m o s, 1 . 5 v lv c m o s 1 5 t ilvcmos15 0.36 0.41 0.45 ns lvds (low-voltage differential signaling), 2.5v lvds_25 t ilvds_25 0.31 0.36 0.40 ns lvdsext (lvds extended mode), 2.5v lvdsext_25 t ilvdsext_25 0.33 0.37 0.41 ns ulvds (ultra lvds), 2.5v ulvds_25 t iulvds_25 0.31 0.36 0.40 ns blvds (bus lvds), 2.5v blvds_25 t iblvds_25 0.00 0.00 0.00 ns ldt (hypertransport), 2.5v ldt_25 t ildt_25 0.31 0.36 0.40 ns lvpecl (low-voltage positive emitter-coupled logic), 2.5v lvpecl_25 t ilvpecl_25 0.69 0.80 0.88 ns pci (peripheral component interface), 33 mhz, 3.3v pci33_3 t ipci33_3 0.14 0.16 0.18 ns pci, 66 mhz, 3.3v pci66_3 t ipci66_3 0.15 0.17 0.19 ns pci-x, 133 mhz, 3.3v pcix t ipcix 0.12 0.13 0.15 ns gtl (gunning transceiver logic) gtl t igtl 0.59 0.68 0.74 ns gtl plus gtlp t igtlp 0.63 0.72 0.79 ns hstl (high-speed transceiver logic), class i hstl_i t ihstl_i 0.59 0.68 0.75 ns hstl, class ii hstl_ii t ihstl_ii 0.59 0.68 0.75 ns hstl, class iii hstl_iii t ihstl_iii 0.57 0.66 0.72 ns hstl, class iv hstl_iv t ihstl_iv 0.58 0.67 0.74 ns hstl, class i, 1.8v hstl_i_18 t ihstl_i_18 0.57 0.65 0.72 ns hstl, class ii, 1.8v hstl_ii_18 t ihstl_ii_18 0.55 0.63 0.69 ns hstl, class iii, 1.8v hstl_iii_18 t ihstl_iii_18 0.56 0.64 0.70 ns hstl, class iv, 1.8v hstl_iv_18 t ihstl_iv_18 0.57 0.65 0.71 ns sstl (stub series terminated logic), class i, 1.8v sstl18_i t isstl18_i 0.62 0.72 0.79 ns sstl, class ii, 1.8v sstl18_ii t isstl18_ii 0.64 0.73 0.81 ns sstl, class i, 2.5v sstl2_i t isstl2_i 0.62 0.72 0.79 ns sstl, class ii, 2.5v sstl2_ii t isstl2_ii 0.64 0.73 0.81 ns lvdci (low-voltage digitally controlled impedance), 3.3v lvdci_33 t ilvdci_33 ?0.05 ?0.05 ?0.06 ns lvdci, 2.5v lvdci_25 t ilvdci_25 0.00 0.00 0.00 ns lvdci, 1.8v lvdci_18 t ilvdci_18 0.07 0.09 0.09 ns lvdci, 1.5v lvdci_15 t ilvdci_15 0.13 0.15 0.17 ns lvdci, 2.5v, half-impedance lvdci_dv2_25 t ilvdci_dv2_25 0.00 0.00 0.00 ns lvdci, 1.8v, half-impedance lvdci_dv2_18 t ilvdci_dv2_18 0.07 0.09 0.09 ns lvdci, 1.5v, half-impedance lvdci_dv2_15 t ilvdci_dv2_15 0.13 0.15 0.17 ns hslvdci (high-speed low-volt age dci), 1.5v hslvdci_15 t ihslvdci_15 0.59 0.68 0.75 ns virtex-ii pro and virtex-ii pro x platform fpgas: dc and switching characteristics r ds083 (v5.0) june 21, 2011 www.xilinx.com module 3 of 4 product specification 26 product not recommended for new designs hslvdci, 1.8v hslvdci_18 t ihslvdci_18 0.59 0.68 0.75 ns hslvdci, 2.5v hslvdci_25 t ihslvdci_25 0.59 0.68 0.75 ns hslvdci, 3.3v hslvdci_33 t ihslvdci_33 0.59 0.68 0.75 ns gtl (gunning transceiver logic) with dci gtl_dci t igtl_dci 0.49 0.57 0.62 ns gtl plus with dci gtlp_dci t igtlp_dci 0.27 0.31 0.35 ns hstl (high-speed transceiver logic), class i, with dci hstl_i_dci t ihstl_i_dci 0.27 0.31 0.35 ns hstl, class ii, with dci hstl_ii_dci t ihstl_ii_dci 0.27 0.31 0.35 ns hstl, class iii, wi th dci hstl_iii_dci t ihstl_iii_dci 0.27 0.31 0.35 ns hstl, class iv, with dci hstl_iv_dci t ihstl_iv_dci 0.27 0.31 0.35 ns hstl, class i, 1.8v, with dci hstl_i_dci_18 t ihstl_i_dci_18 0.27 0.31 0.35 ns hstl, class ii, 1.8v, with dci hstl_ii_dci_18 t ihstl_ii_dci_18 0.27 0.31 0.35 ns hstl, class iii, 1.8v, with dci hstl_iii_dci_18 t ihstl_iii_dci_18 0.27 0.31 0.35 ns hstl, class iv, 1.8v, with dci hstl_iv_dci_18 t ihstl_iv_dci_18 0.27 0.31 0.35 ns sstl (stub series terminated logic), class i, 1.8v, with dci sstl18_i_dci t isstl18_i_dci 0.62 0.72 0.79 ns sstl, class ii, 1.8v, with dci sstl18_ii_dci t isstl18_ii_dci 0.64 0.73 0.81 ns sstl, class i, 2.5v, with dci sstl2_i_dci t isstl2_i_dci 0.17 0.20 0.22 ns sstl, class ii, 2.5v, with dci sstl2_ii_dci t isstl2_ii_dci 0.17 0.20 0.22 ns lvds, 2.5v, with dci lvds_25_dci t ilvds_25_dci 0.31 0.36 0.40 ns lvdsext, 2.5v, with dci lvdsext_25_dci t ilvdsext_25_dci 0.33 0.37 0.41 ns lvds, 2.5v, with differential termination (dt) lvds_25_dt t ilvds_25_dt 0.31 0.36 0.40 ns lvdsext, 2.5v, with dt lvdsext_25_dt t ilvdsext_25_dt 0.33 0.37 0.41 ns ulvds, 2.5v, with dt ulvds_25_dt t iulvds_25_dt 0.31 0.36 0.40 ns ldt, 2.5v, with dt ldt_25_dt t ildt_25_dt 0.31 0.36 0.40 ns ta bl e 3 6 : iob input switching characteristics standard adjustments (continued) description iostandard attribute timing parameter speed grade units -7 -6 -5 virtex-ii pro and virtex-ii pro x platform fpgas: dc and switching characteristics r ds083 (v5.0) june 21, 2011 www.xilinx.com module 3 of 4 product specification 27 product not recommended for new designs iob output switchin g characteristics output delays terminating at a pad are specified for lvcmos25 with 12 ma drive and fast slew rate. for other standards, adjust the delays with the values shown in iob output switching characteristics standard adjustments . ta bl e 3 7 : iob output switching characteristics speed grade description symbol -7 -6 -5 units propagation delays o input to pad t ioop 1.58 1.68 1.85 ns, max o input to pad via transparent latch t ioolp 1.65 1.82 1.99 ns, max 3-state delays t input to pad high-impedance (2) t iothz 1.23 1.35 1.51 ns, max t input to valid data on pad t iotp 1.51 1.63 1.78 ns, max t input to pad high-impedance via transparent latch (2) t iotlphz 1.08 1.22 1.36 ns, max t input to valid data on pad via transparent latch t iotlpon 1.56 1.69 1.85 ns, max gts to pad high-impedance (2) t gts 4.11 4.73 5.20 ns, max sequential delays clock clk to pad t iockp 1.59 1.76 1.93 ns, max clock clk to pad high-impedance (synchronous) (2) t iockhz 1.39 1.55 1.73 ns, max clock clk to valid data on pad (synchronous) t iockon 1.67 1.82 2.00 ns, max setup and hold times before/after clock clk o input t ioock /t iocko 0.23/ 0.12 0.26/ 0.14 0.29/ 0.15 ns, min oce input t iooceck /t iockoce 0.39/ 0.01 0.44/ 0.01 0.49/ 0.01 ns, min sr input (off) t iosrcko /t iockosr 0.52/ 0.00 0.57/ 0.00 0.75/ 0.00 ns, min 3?state setup times, t input t iotck /t iockt 0.23/ 0.12 0.26/ 0.14 0.29/ 0.15 ns, min 3-state setup times, tce input t iotceck /t iocktce 0.39/ 0.01 0.44/ 0.01 0.49/ 0.01 ns, min 3-state setup times, sr input (tff) t iosrckt /t iocktsr 0.52/ 0.00 0.57/ 0.00 0.75/ 0.00 ns, min set/reset delays minimum pulse width, sr inputs (asynchronous) t rpw 0.37 0.40 0.45 ns, min sr input to pad (asynchronous) t iosrp 2.33 2.56 2.83 ns, max sr input to pad high-impedance (asynchronous) (2) t iosrhz 1.97 2.16 2.41 ns, max sr input to valid data on pad (asynchronous) t iosron 2.24 2.44 2.69 ns, max gsr to pad t iogsrq 5.87 6.75 7.43 ns, max notes: 1. a zero ?0? hold time listing indicates no hold time or a negative hold time. negative values can not be guaranteed ?best-case ?, but if a ?0? is listed, there is no positive hold time. 2. the 3-state turn-off delays should not be adjusted. virtex-ii pro and virtex-ii pro x platform fpgas: dc and switching characteristics r ds083 (v5.0) june 21, 2011 www.xilinx.com module 3 of 4 product specification 28 product not recommended for new designs iob output switching charac teristics standard adjustments ta bl e 3 8 gives all standard-specific adjustments for output delays terminating at pads, based on standard capacitive load, c ref . output delays terminating at a pad are specified for lvcmos25 with 12 ma drive and fast slew rate. for other standards, adjust the delays by the values shown. ta bl e 3 8 : iob output switching characteristics standard adjustments description iostandard attribute timing parameter speed grade units -7 -6 -5 lvttl (low-voltage transistor-transistor logic), slow, 2 ma lvttl_s2 t olvttl_s2 5.42 6.24 6.86 ns lv t t l , s l ow, 4 m a lv t t l _ s 4 t olvttl_s4 3.09 3.55 3.91 ns lv t t l , s l ow, 6 m a lv t t l _ s 6 t olvttl_s6 2.26 2.60 2.86 ns lv t t l , s l ow, 8 m a lv t t l _ s 8 t olvttl_s8 1.47 1.69 1.86 ns lvttl, slow, 12 ma lvttl_s12 t olvttl_s12 1.02 1.18 1.29 ns lvttl, slow, 16 ma lvttl_s16 t olvttl_s16 0.46 0.53 0.58 ns lvttl, slow, 24 ma lvttl_s24 t olvttl_s24 0.37 0.42 0.47 ns lv t t l , fa s t , 2 m a lv t t l _ f 2 t olvttl_f2 4.42 5.09 5.59 ns lv t t l , fa s t , 4 m a lv t t l _ f 4 t olvttl_f4 1.95 2.24 2.46 ns lv t t l , fa s t , 6 m a lv t t l _ f 6 t olvttl_f6 1.10 1.26 1.39 ns lv t t l , fa s t , 8 m a lv t t l _ f 8 t olvttl_f8 0.40 0.46 0.51 ns lvttl, fast, 12 ma lvttl_f12 t olvttl_f12 0.24 0.27 0.30 ns lvttl, fast, 16 ma lvttl_f16 t olvttl_f16 0.05 0.06 0.07 ns lvttl, fast, 24 ma lvttl_f24 t olvttl_f24 ?0.01 ?0.01 ?0.01 ns lvcmos (low-voltage cmos), 3.3v, slow, 2 ma lvcmos33_s2 t olvcmos33_s2 5.42 6.23 6.86 ns lvcmos, 3.3v, slow, 4 ma lvcmos33_s4 t olvcmos33_s4 3.14 3.61 3.97 ns lvcmos, 3.3v, slow, 6 ma lvcmos33_s6 t olvcmos33_s6 2.26 2.60 2.86 ns lvcmos, 3.3v, slow, 8 ma lvcmos33_s8 t olvcmos33_s8 1.47 1.69 1.86 ns lvcmos, 3.3v, slow, 12 ma lvcmos33_s12 t olvcmos33_s12 1.03 1.18 1.30 ns lvcmos, 3.3v, slow, 16 ma lvcmos33_s16 t olvcmos33_s16 0.45 0.52 0.57 ns lvcmos, 3.3v, slow, 24 ma lvcmos33_s24 t olvcmos33_s24 0.39 0.44 0.49 ns lvcmos, 3.3v, fast, 2 ma lvcmos33_f2 t olvcmos33_f2 4.46 5.13 5.64 ns lvcmos, 3.3v, fast, 4 ma lvcmos33_f4 t olvcmos33_f4 1.96 2.25 2.48 ns lvcmos, 3.3v, fast, 6 ma lvcmos33_f6 t olvcmos33_f6 1.11 1.28 1.40 ns lvcmos, 3.3v, fast, 8 ma lvcmos33_f8 t olvcmos33_f8 0.41 0.47 0.52 ns lvcmos, 3.3v, fast, 12 ma lvcmos33_f12 t olvcmos33_f12 0.23 0.26 0.28 ns lvcmos, 3.3v, fast, 16 ma lvcmos33_f16 t olvcmos33_f16 0.02 0.02 0.03 ns lvcmos, 3.3v, fast, 24 ma lvcmos33_f24 t olvcmos33_f24 ?0.07 ?0.08 ?0.09 ns lvcmos, 2.5v, slow, 2 ma lvcmos25_s2 t olvcmos25_s2 4.12 4.74 5.21 ns lvcmos, 2.5v, slow, 4 ma lvcmos25_s4 t olvcmos25_s4 2.43 2.80 3.07 ns lvcmos, 2.5v, slow, 6 ma lvcmos25_s6 t olvcmos25_s6 1.76 2.02 2.22 ns lvcmos, 2.5v, slow, 8 ma lvcmos25_s8 t olvcmos25_s8 1.04 1.19 1.31 ns lvcmos, 2.5v, slow, 12 ma lvcmos25_s12 t olvcmos25_s12 0.76 0.87 0.96 ns lvcmos, 2.5v, slow, 16 ma lvcmos25_s16 t olvcmos25_s16 0.41 0.47 0.52 ns lvcmos, 2.5v, slow, 24 ma lvcmos25_s24 t olvcmos25_s24 0.23 0.26 0.28 ns lvcmos, 2.5v, fast, 2 ma lvcmos25_f2 t olvcmos25_f2 3.29 3.78 4.16 ns lvcmos, 2.5v, fast, 4 ma lvcmos25_f4 t olvcmos25_f4 1.31 1.50 1.65 ns virtex-ii pro and virtex-ii pro x platform fpgas: dc and switching characteristics r ds083 (v5.0) june 21, 2011 www.xilinx.com module 3 of 4 product specification 29 product not recommended for new designs lvcmos, 2.5v, fast, 6 ma lvcmos25_f6 t olvcmos25_f6 0.62 0.71 0.78 ns lvcmos, 2.5v, fast, 8 ma lvcmos25_f8 t olvcmos25_f8 0.20 0.23 0.25 ns lvcmos, 2.5v, fast, 12 ma lvcmos25_f12 t olvcmos25_f12 0.00 0.00 0.00 ns lvcmos, 2.5v, fast, 16 ma lvcmos25_f16 t olvcmos25_f16 ?0.03 ?0.03 ?0.04 ns lvcmos, 2.5v, fast, 24 ma lvcmos25_f24 t olvcmos25_f24 ?0.15 ?0.15 ?0.15 ns lvcmos, 1.8v, slow, 2 ma lvcmos18_s2 t olvcmos18_s2 4.20 4.83 5.31 ns lvcmos, 1.8v, slow, 4 ma lvcmos18_s4 t olvcmos18_s4 2.76 3.18 3.49 ns lvcmos, 1.8v, slow, 6 ma lvcmos18_s6 t olvcmos18_s6 1.91 2.20 2.41 ns lvcmos, 1.8v, slow, 8 ma lvcmos18_s8 t olvcmos18_s8 1.92 2.20 2.42 ns lvcmos, 1.8v, slow, 12 ma lvcmos18_s12 t olvcmos18_s12 1.58 1.81 1.99 ns lvcmos, 1.8v, slow, 16 ma lvcmos18_s16 t olvcmos18_s16 0.76 0.87 0.96 ns lvcmos, 1.8v, fast, 2 ma lvcmos18_f2 t olvcmos18_f2 2.34 2.69 2.95 ns lvcmos, 1.8v, fast, 4 ma lvcmos18_f4 t olvcmos18_f4 0.71 0.81 0.89 ns lvcmos, 1.8v, fast, 6 ma lvcmos18_f6 t olvcmos18_f6 0.50 0.57 0.63 ns lvcmos, 1.8v, fast, 8 ma lvcmos18_f8 t olvcmos18_f8 0.48 0.55 0.61 ns lvcmos, 1.8v, fast, 12 ma lvcmos18_f12 t olvcmos18_f12 0.30 0.34 0.38 ns lvcmos, 1.8v, fast, 16 ma lvcmos18_f16 t olvcmos18_f16 0.11 0.12 0.13 ns lvcmos, 1.5v, slow, 2 ma lvcmos15_s2 t olvcmos15_s2 6.19 7.12 7.83 ns lvcmos, 1.5v, slow, 4 ma lvcmos15_s4 t olvcmos15_s4 4.28 4.93 5.42 ns lvcmos, 1.5v, slow, 6 ma lvcmos15_s6 t olvcmos15_s6 2.81 3.24 3.56 ns lvcmos, 1.5v, slow, 8 ma lvcmos15_s8 t olvcmos15_s8 2.55 2.93 3.23 ns lvcmos, 1.5v, slow, 12 ma lvcmos15_s12 t olvcmos15_s12 1.31 1.51 1.66 ns lvcmos, 1.5v, slow, 16 ma lvcmos15_s16 t olvcmos15_s16 1.28 1.47 1.62 ns lvcmos, 1.5v, fast, 2 ma lvcmos15_f2 t olvcmos15_f2 2.26 2.60 2.86 ns lvcmos, 1.5v, fast, 4 ma lvcmos15_f4 t olvcmos15_f4 1.66 1.90 2.09 ns lvcmos, 1.5v, fast, 6 ma lvcmos15_f6 t olvcmos15_f6 0.65 0.75 0.82 ns lvcmos, 1.5v, fast, 8 ma lvcmos15_f8 t olvcmos15_f8 0.94 1.08 1.19 ns lvcmos, 1.5v, fast, 12 ma lvcmos15_f12 t olvcmos15_f12 0.25 0.29 0.32 ns lvcmos, 1.5v, fast, 16 ma lvcmos15_f16 t olvcmos15_f16 0.28 0.32 0.35 ns lvds (low-voltage differential signaling), 2.5v lvds_25 t olvds_25 0.01 0.01 0.01 ns lvdsext (lvds extended mode), 2.5v lvdsext_25 t olvdsext_25 0.13 0.15 0.16 ns ulvds (ultra lvds), 2.5v ulvds_25 t oulvds_25 0.13 0.14 0.16 ns blvds (bus lvds), 2.5v blvds_25 t oblvds_25 0.00 0.00 0.00 ns ldt (hypertransport), 2.5v ldt_25 t oldt_25 0.13 0.14 0.16 ns lvpecl (low-voltage positive emitter-coupled logic), 2.5v lvpecl_25 t olvpecl_25 0.17 0.19 0.21 ns pci (peripheral component interface), 33 mhz, 3.3v pci33_3 t opci33_3 0.83 0.93 1.01 ns pci, 66 mhz, 3.3v pci66_3 t opci66_3 0.89 0.97 1.05 ns pci-x, 133 mhz, 3.3v pcix t opcix 0.92 1.02 1.10 ns gtl (gunning transceiver logic) gtl t ogtl 0.08 0.10 0.11 ns gtl plus gtlp t ogtlp 0.04 0.05 0.06 ns hstl (high-speed transceiver logic), class i hstl_i t ohstl_i 0.56 0.64 0.70 ns ta bl e 3 8 : iob output switching characteristics standard adjustments (continued) description iostandard attribute timing parameter speed grade units -7 -6 -5 virtex-ii pro and virtex-ii pro x platform fpgas: dc and switching characteristics r ds083 (v5.0) june 21, 2011 www.xilinx.com module 3 of 4 product specification 30 product not recommended for new designs hstl, class ii hstl_ii t ohstl_ii 0.30 0.35 0.38 ns hstl, class iii hstl_iii t ohstl_iiii 0.31 0.35 0.39 ns hstl, class iv hstl_iv t ohstl_iv 0.15 0.17 0.19 ns hstl, class i, 1.8v hstl_i_18 t ohstl_i_18 0.56 0.64 0.70 ns hstl, class ii, 1.8v hstl_ii_18 t ohstl_ii_18 0.30 0.35 0.38 ns hstl, class iii, 1.8v hstl_iii_18 t ohstl_iiii_18 0.36 0.41 0.45 ns hstl, class iv, 1.8v hstl_iv_18 t ohstl_iv_18 0.19 0.22 0.24 ns sstl (stub series terminated logic), class i, 1.8v sstl18_i t osstl18_i 0.80 0.92 1.01 ns sstl, class ii, 1.8v sstl18_ii t osstl18_ii 0.45 0.51 0.56 ns sstl, class i, 2.5v sstl2_i t osstl2_i 0.63 0.72 0.79 ns sstl, class ii, 2.5v sstl2_ii t osstl2_ii 0.22 0.25 0.27 ns lvdci (low-voltage digitally controlled impedance), 3.3v lvdci_33 t olvdci_33 0.72 0.83 0.91 ns lvdci, 2.5v lvdci_25 t olvdci_25 0.56 0.64 0.71 ns lvdci, 1.8v lvdci_18 t olvdci_18 0.65 0.75 0.82 ns lvdci, 1.5v lvdci_15 t olvdci_15 1.00 1.15 1.26 ns lvdci, 2.5v, half-impedance lvdci_dv2_25 t olvdci_dv2_25 0.06 0.07 0.08 ns lvdci, 1.8v, half-impedance lvdci_dv2_18 t olvdci_dv2_18 0.30 0.34 0.38 ns lvdci, 1.5v, half-impedance lvdci_dv2_15 t olvdci_dv2_15 0.60 0.69 0.76 ns hslvdci (high-speed low-volt age dci), 1.5v hslvdci_15 t ohslvdci_15 1.00 1.15 1.26 ns hslvdci, 1.8v hslvdci_18 t ohslvdci_18 0.65 0.75 0.82 ns hslvdci, 2.5v hslvdci_25 t ohslvdci_25 0.56 0.64 0.71 ns hslvdci, 3.3v hslvdci_33 t ohslvdci_33 0.72 0.83 0.91 ns gtl (gunning transceiver logic) with dci gtl_dci t ogtl_dci 1.21 1.39 1.53 ns gtl plus with dci gtlp_dci t ogtlp_dci 0.05 0.06 0.07 ns hstl (high-speed transceiver logic), class i, with dci hstl_i_dci t ohstl_i_dci 0.55 0.63 0.69 ns hstl, class ii, with dci hstl_ii_dci t ohstl_ii_dci 0.47 0.54 0.60 ns hstl, class iii, wi th dci hstl_iii_dci t ohstl_iii_dci 0.31 0.36 0.40 ns hstl, class iv, with dci hstl_iv_dci t ohstl_iv_dci 1.81 2.08 2.29 ns hstl, class i, 1.8v, with dci hstl_i_dci_18 t ohstl_i_dci_18 0.55 0.63 0.70 ns hstl, class ii, 1.8v, with dci hstl_ii_dci_18 t ohstl_ii_dci_18 0.24 0.28 0.31 ns hstl, class iii, 1.8v, with dci hstl_iii_dci_18 t ohstl_iii_dci_18 0.35 0.40 0.44 ns hstl, class iv, 1.8v, with dci hstl_iv_dci_18 t ohstl_iv_dci_18 1.48 1.70 1.87 ns sstl (stub series terminated logic), class i, 1.8v, with dci sstl18_i_dci t osstl18_i_dci 0.54 0.62 0.68 ns sstl, class ii, 1.8v, with dci sstl18_ii_dci t osstl18_ii_dci 0.24 0.28 0.31 ns sstl, class i, 2.5v, with dci sstl2_i_dci t osstl2_i_dci 0.48 0.56 0.61 ns sstl, class ii, 2.5v, with dci sstl2_ii_dci t osstl2_ii_dci 0.48 0.56 0.61 ns ta bl e 3 8 : iob output switching characteristics standard adjustments (continued) description iostandard attribute timing parameter speed grade units -7 -6 -5 virtex-ii pro and virtex-ii pro x platform fpgas: dc and switching characteristics r ds083 (v5.0) june 21, 2011 www.xilinx.com module 3 of 4 product specification 31 product not recommended for new designs i/o standard adjustment measurement methodology input delay measurements ta bl e 3 9 shows the test setup parameters used for measuring input standard adjustments (see table 36, page 25 ). ta bl e 3 9 : input delay measurement methodology description iostandard attribute v l (1,2) v h (1,2) v meas (1,4,5) v ref (1,3,5) lvttl (low-voltage transistor-transistor logic) lvttl 0 3.3 1.65 ? lvcmos (low-voltage cmos), 3.3v lvcmos33 0 3.3 1.65 ? lvcmos, 2.5v lvcmos25 0 2.5 1.25 ? lvcmos, 1.8v lvcmos18 0 1.8 0.9 ? lvcmos, 1.5v lvcmos15 0 1.5 0.75 ? pci (peripheral component interface), 33 mhz, 3.3v pci33_3 per pci specification ? pci, 66 mhz, 3.3v pci66_3 per pci specification ? pci-x, 133 mhz, 3.3v pcix per pci-x specification ? gtl (gunning transceiver logic) gtl v ref ?0.2 v ref +0.2 v ref 0.80 gtl plus gtlp v ref ?0.2 v ref +0.2 v ref 1.0 hstl (high-speed transceiver logic) , class i & ii hstl_i, hstl_ii v ref ?0.5 v ref +0.5 v ref 0.75 hstl, class iii & iv hstl_iii, hstl_iv v ref ?0.5 v ref +0.5 v ref 0.90 hstl, class i & ii, 1.8v hstl_i_18, hstl_ii_18 v ref ?0.5 v ref +0.5 v ref 0.90 hstl, class iii & iv, 1.8v hstl_iii_18, hstl_iv_18 v ref ?0.5 v ref +0.5 v ref 1.08 sstl (stub terminated tnscvr logic), class i & ii, 2.5v sstl2_i, sstl2_ii v ref ?0.75 v ref +0.75 v ref 1.25 sstl, class i & ii, 1.8v sstl18_i, sstl18_ii v ref ?0.5 v ref +0.5 v ref 0.9 lvds (low-voltage differential signaling), 2.5v lvds_25 1.2 ? 0.125 1.2 + 0.125 1.2 lvdsext (lvds extended mode), 2.5v lvdsext_25 1.2 ? 0.125 1.2 + 0.125 1.2 ulvds (ultra lvds), 2.5v ulvds_25 0.6 ? 0.125 0.6 + 0.125 0.6 ldt (hypertransport), 2.5v ldt_25 0.6 ? 0.125 0.6 + 0.125 0.6 lvpecl (low-voltage positive emitter-coupled logic), 2.5v lvpecl_25 1.15 ? 0.3 1.15 + 0.3 1.15 notes: 1. input delay measurement methodology parameters for lvdci and hslvdc i are the same as for lvcmos standards of the same voltage . parameters for all other dci standards are the same as for the corresponding non-dci standards. 2. input waveform switches between v l and v h . 3. measurements are made at typical, minimum, and maximum v ref values. reported delays reflect worst case of these measurements. v ref values listed are typical. see virtex-ii pro platform fpga user guide for min/max specifications. 4. input voltage level from which measurement starts. 5. note that this is an input voltage re ference that bears no relation to the v ref / v meas parameters found in ibis models and/or noted in figure 6 . virtex-ii pro and virtex-ii pro x platform fpgas: dc and switching characteristics r ds083 (v5.0) june 21, 2011 www.xilinx.com module 3 of 4 product specification 32 product not recommended for new designs output delay measurements output delays are measured using a tektronix p6245 tds500/600 probe (< 1 pf) across approximately 4" of fr4 microstrip trace. standard termination was used for all test- ing. (see virtex-ii pro platform fpga user guide for details.) the propagation delay of the 4" trace is character- ized separately and subtracted from the final measurement, and is therefore not included in the generalized test setup shown in figure 6 . measurements and test conditions are reflected in the ibis models except where the ibis format precludes it. (ibis models can be found on the web at http://sup- port.xilinx.com/support/sw_ibis.htm .) parameters v ref , r ref , c ref , and v meas fully describe the test conditions for each i/o standard. the most accurate prediction of prop- agation delay in any given application can be obtained through ibis simulation, using the following method: 1. simulate the output driver of choice into the generalized test setup, using values from ta bl e 4 0 . 2. record the time to v meas . 3. simulate the output driver of choice into the actual pcb trace and load, using the appropriate ibis model or capacitance value to represent the load. 4. record the time to v meas . 5. compare the results of steps 2 and 4. the increase or decrease in delay should be added to or subtracted from the i/o output standard adjustment value ( ta bl e 3 8 ) to yield the actual worst-case propagation delay (clock-to-input) of the pcb trace. figure 6: generalized test setup v ref r ref v meas (voltage level at which delay measurement is taken) c ref (probe capacitance) fpga output ds083-3_06a_092503 ta bl e 4 0 : output delay measurement methodology description iostandard attribute r ref ( ? ) c ref (1) (pf) v meas (v) v ref (v) lvttl (low-voltage transistor-transistor logic) lvttl (all) 1m 0 1.65 0 lvcmos (low-voltage cmos ), 3.3v lv c m o s 3 3 1 m 0 1 . 6 5 0 lv c m o s, 2 . 5 v lv c m o s 2 5 1 m 0 1 . 2 5 0 lv c m o s, 1 . 8 v lvcmos18 1m 0 0.9 0 lv c m o s, 1 . 5 v lv c m o s 1 5 1 m 0 0 . 7 5 0 pci (peripheral component interface), 33 mhz, 3.3v pci33_3 (rising edge) 25 10 (2) 0.94 0 pci33_3 (falling edge) 25 10 (2) 2.03 3.3 pci, 66 mhz, 3.3v pci66_3 (rising edge) 25 10 (2) 0.94 0 pci66_3 (falling edge) 25 10 (2) 2.03 3.3 pci-x, 133 mhz, 3.3v pcix (rising edge) 25 10 (3) 0.94 0 pcix (falling edge 25 10 (3) 2.03 3.3 gtl (gunning transceiver logic) gtl 25 0 0.8 1.2 gtl plus gtlp 25 0 1.0 1.5 hstl (high-speed transceiver logic), class i hstl_i 50 0 v ref 0.75 hstl, class ii hstl_ii 25 0 v ref 0.75 hstl, class iii hstl_iii 50 0 0.9 1.5 hstl, class iv hstl_iv 25 0 0.9 1.5 hstl, class i, 1.8v hstl_i_18 50 0 v ref 0.9 hstl, class ii, 1.8v hstl_ii_18 25 0 v ref 0.9 hstl, class iii, 1.8v hstl_iii_18 50 0 1.1 1.8 hstl, class iv, 1.8v hstl_iv_18 25 0 1.1 1.8 virtex-ii pro and virtex-ii pro x platform fpgas: dc and switching characteristics r ds083 (v5.0) june 21, 2011 www.xilinx.com module 3 of 4 product specification 33 product not recommended for new designs sstl (stub series terminated logic), class i, 1.8v sstl18_i 50 0 v ref 0.9 sstl, class ii, 1.8v sstl18_ii 25 0 v ref 0.9 sstl, class i, 2.5v sstl2_i 50 0 v ref 1.25 sstl, class ii, 2.5v sstl2_ii 25 0 v ref 1.25 lvds (low-voltage differential signaling), 2.5v lv d s _ 2 5 5 0 0 v ref 1.2 lvdsext (lvds extended mode), 2.5v lvdsext_25 50 0 v ref 1.2 blvds (bus lvds), 2.5v blvds_25 1m 0 1.2 0 ldt (hypertransport), 2.5v ldt_25 50 0 v ref 0.6 lvpecl (low-voltage positive emitter-coupled logic), 2.5v lvpecl_25 1m 0 1.23 0 lvdci/hslvdci (low-voltage digitally controlled impedance), 3.3v lvdci_33 1m 0 1.65 0 lvdci/hslvdci, 2.5v lvdci_25 1m 0 1.25 0 lvdci/hslvdci, 1.8v lvdci_18 1m 0 0.9 0 lvdci/hslvdci, 1.5v lvdci_15 1m 0 0.75 0 hstl (high-speed transceiver logic), class i & ii, with dci hstl_i_dci, hstl_ii_dci 50 0 v ref 0.75 hstl, class iii & iv, with dci hstl_iii_dci, hstl_iv_dci 50 0 0.9 1.5 hstl, class i & ii, 1.8v, with dci hstl_i_dci_18, hstl_ii_dci_18 50 0 v ref 0.9 hstl, class iii & iv, 1.8v, with dci hstl_iii_dci_18, hs tl_iv_dci_18 50 0 1.1 1.8 sstl (stub series termi.logic), class i & ii, 1.8v, with dci sstl18_i_dci, sstl18_ii_dci 50 0 v ref 0.9 sstl, class i & ii, 2.5v, with dci sstl2_i_dci, sstl2_ii_dci 50 0 v ref 1.25 gtl (gunning transceiver logic) with dci gtl_dci 50 0 0.8 1.2 gtl plus with dci gtlp_dci 50 0 1.0 1.5 notes: 1. c ref is the capacitance of the probe, nominally 0 pf. 2. measured as per pci specification. 3. measured as per pci-x specification. ta bl e 4 0 : output delay measurement methodology description iostandard attribute r ref ( ? ) c ref (1) (pf) v meas (v) v ref (v) virtex-ii pro and virtex-ii pro x platform fpgas: dc and switching characteristics r ds083 (v5.0) june 21, 2011 www.xilinx.com module 3 of 4 product specification 34 product not recommended for new designs clock distribution swit ching characteristics clb switching characteristics delays originating at f/g inputs vary s lightly according to the input used (see figure 34 in module 2). the values listed below are worst-case. precise values are provided by the timing analyzer. ta bl e 4 1 : clock distribution switching characteristics description symbol speed grade units -7 -6 -5 global clock buffer i input to o output t gio 0.05 0.057 0.064 ns, max global clock buffer s input setup/hold to i1 an i2 inputs t gsi /t gis 0.49/?0.10 0.54/?0.12 0.60/?0.13 ns, max ta bl e 4 2 : clb switching characteristics speed grade description symbol - 7 - 6 -5 units combinatorial delays 4-input function: f/g inputs to x/y outputs t ilo 0.28 0.32 0.36 ns, max 5-input function: f/g inputs to f5 output t if5 0.59 0.65 0.73 ns, max 5-input function: f/g inputs to x output t if5x 0.63 0.70 0.79 ns, max fxina or fxinb inputs to y output via muxfx t ifxy 0.29 0.32 0.36 ns, max fxina input to fx output via muxfx t inafx 0.29 0.32 0.36 ns, max fxinb input to fx output via muxfx t inbfx 0.29 0.32 0.36 ns, max sopin input to sopout output via orcy t sopsop 0.11 0.13 0.14 ns, max incremental delay routing through transparent latch to xq/yq outputs t ifnctl 0.23 0.24 0.27 ns, max sequential delays ff clock clk to xq/yq outputs t cko 0.37 0.38 0.42 ns, max latch clock clk to xq/yq outputs t cklo 0.54 0.57 0.64 ns, max setup and hold times before/after clock clk bx/by inputs t dick /t ckdi 0.21/?0.04 0.24/?0.05 0.27/?0.06 ns, min dy inputs t dyc k /t ckdy 0.00/ 0.12 0.00/ 0.14 0.00/ 0.15 ns, min dx inputs t dxck /t ckdx 0.00/ 0.12 0.00/ 0.14 0.00/ 0.15 ns, min ce input t ceck /t ckce 0.27/ 0.01 0.34/ 0.01 0.47/ 0.01 ns, min sr/by inputs (synchronous) t rck/ t ckr 0.55/?0.01 0.60/?0.01 0.78/?0.01 ns, min clock clk minimum pulse width, high t ch 0.37 0.40 0.45 ns, min minimum pulse width, low t cl 0.37 0.40 0.45 ns, min set/reset minimum pulse width, sr/by inputs (asynchronous) t rpw 0.37 0.40 0.45 ns, min delay from sr/by inputs to xq/yq outputs (asynchronous) t rq 1.09 1.25 1.40 ns, max toggle frequency (for export control) f tog 1350 1200 1050 mhz notes: 1. a zero ?0? hold time listing indicates no hold time or a negative hold time. negative values can not be guaranteed ?best-case ?, but if a ?0? is listed, there is no positive hold time. virtex-ii pro and virtex-ii pro x platform fpgas: dc and switching characteristics r ds083 (v5.0) june 21, 2011 www.xilinx.com module 3 of 4 product specification 35 product not recommended for new designs clb distributed ram sw itching characteristics clb shift register swit ching characteristics ta bl e 4 3 : clb distributed ram swit ching characteristics speed grade description symbol - 7 - 6 -5 units sequential delays clock clk to x/y outputs (we active) in 16 x 1 mode t shcko16 1.25 1.38 1.54 ns, max clock clk to x/y outputs (we active) in 32 x 1 mode t shcko32 1.57 1.75 1.95 ns, max clock clk to f5 output t shckof5 1.52 1.68 1.88 ns, max setup and hold times before/after clock clk bx/by data inputs (din) t ds /t dh 0.38/?0.07 0.41/?0.07 0.46/?0.08 ns, min f/g address inputs t as /t ah 0.42/ 0.00 0.47/ 0.00 0.52/ 0.00 ns, min sr input t wes /t weh 0.22/ 0.04 0.24/ 0.05 0.26/ 0.05 ns, min clock clk minimum pulse width, high t wph 0.63 0.72 0.79 ns, min minimum pulse width, low t wpl 0.63 0.72 0.79 ns, min minimum clock period to meet address write cycle time t wc 1.25 1.44 1.58 ns, min notes: 1. a zero ?0? hold time listing indicates no hold time or a negative hold time. negative values cannot be guaranteed ?best-case? , but if a ?0? is listed, there is no positive hold time. ta bl e 4 4 : clb shift register swit ching characteristics speed grade description symbol -7 -6 -5 units sequential delays clock clk to x/y outputs t reg 2.78 3.12 3.49 ns, max clock clk to x/y outputs t reg32 3.10 3.49 3.90 ns, max clock clk to xb output via mc15 lut output t regxb 2.84 3.18 3.55 ns, max clock clk to yb output via mc15 lut output t regyb 2.55 2.88 3.21 ns, max clock clk to shiftout t cksh 2.50 2.83 3.15 ns, max clock clk to f5 output t regf5 3.05 3.42 3.83 ns, max setup and hold times before/after clock clk bx/by data inputs (din) t srlds /t srldh 0.70/?0.16 0.77/?0.18 0.98/?0.21 ns, min sr input t wss /t wsh 0.27/ 0.01 0.34/ 0.01 0.47/ 0.01 ns, min clock clk minimum pulse width, high t srph 0.63 0.72 0.79 ns, min minimum pulse width, low t srpl 0.63 0.72 0.79 ns, min notes: 1. a zero ?0? hold time listing indicates no hold time or a negative hold time. negative values cannot be guaranteed ?best-case? , but if a ?0? is listed, there is no positive hold time. virtex-ii pro and virtex-ii pro x platform fpgas: dc and switching characteristics r ds083 (v5.0) june 21, 2011 www.xilinx.com module 3 of 4 product specification 36 product not recommended for new designs multiplier switching characteristics ta bl e 4 5 : multiplier switching characteristics speed grade description symbol -7 -6 -5 units propagation delay to output pin input to pin35 t mult_p35 4.08 4.64 5.19 ns, max input to pin34 t mult_p34 3.99 4.55 5.09 ns, max input to pin33 t mult_p33 3.90 4.45 4.99 ns, max input to pin32 t mult_p32 3.80 4.36 4.88 ns, max input to pin31 t mult_p31 3.71 4.27 4.78 ns, max input to pin30 t mult_p30 3.62 4.17 4.67 ns, max input to pin29 t mult_p29 3.53 4.08 4.57 ns, max input to pin28 t mult_p28 3.43 3.99 4.46 ns, max input to pin27 t mult_p27 3.34 3.89 4.36 ns, max input to pin26 t mult_p26 3.25 3.80 4.26 ns, max input to pin25 t mult_p25 3.16 3.71 4.15 ns, max input to pin24 t mult_p24 3.06 3.61 4.05 ns, max input to pin23 t mult_p23 2.97 3.52 3.94 ns, max input to pin22 t mult_p22 2.88 3.43 3.84 ns, max input to pin21 t mult_p21 2.79 3.34 3.73 ns, max input to pin20 t mult_p20 2.70 3.24 3.63 ns, max input to pin19 t mult_p19 2.60 3.15 3.53 ns, max input to pin18 t mult_p18 2.51 3.06 3.42 ns, max input to pin17 t mult_p17 2.42 2.96 3.32 ns, max input to pin16 t mult_p16 2.34 2.86 3.21 ns, max input to pin15 t mult_p15 2.27 2.76 3.09 ns, max input to pin14 t mult_p14 2.19 2.67 2.98 ns, max input to pin13 t mult_p13 2.12 2.57 2.87 ns, max input to pin12 t mult_p12 2.04 2.47 2.76 ns, max input to pin11 t mult_p11 1.96 2.37 2.65 ns, max input to pin10 t mult_p10 1.89 2.27 2.54 ns, max input to pin9 t mult_p9 1.81 2.17 2.43 ns, max input to pin8 t mult_p8 1.74 2.07 2.32 ns, max input to pin7 t mult_p7 1.66 1.97 2.21 ns, max input to pin6 t mult_p6 1.59 1.87 2.09 ns, max input to pin5 t mult_p5 1.51 1.77 1.98 ns, max input to pin4 t mult_p4 1.44 1.67 1.87 ns, max input to pin3 t mult_p3 1.36 1.57 1.76 ns, max input to pin2 t mult_p2 1.28 1.47 1.65 ns, max input to pin1 t mult_p1 1.21 1.37 1.54 ns, max input to pin0 t mult_p0 1.13 1.27 1.43 ns, max virtex-ii pro and virtex-ii pro x platform fpgas: dc and switching characteristics r ds083 (v5.0) june 21, 2011 www.xilinx.com module 3 of 4 product specification 37 product not recommended for new designs ta bl e 4 6 : pipelined multiplier switching characteristics description symbol speed grade units -7 -6 -5 setup and hold times before/after clock data inputs t mulidck /t mulckid 1.86/ 0.00 2.06/ 0.00 2.31/ 0.00 ns, max clock enable t mulidck_ce /t mulckid_ce 0.23/ 0.00 0.25/ 0.00 0.28/ 0.00 ns, max reset t mulidck_rst /t mulckid_rst 0.21/?0.09 0.24/?0.09 0.26/?0.10 ns, max clock to output pin clock to pin35 t multck_p35 2.45 2.92 3.27 ns, max clock to pin34 t multck_p34 2.36 2.82 3.16 ns, max clock to pin33 t multck_p33 2.28 2.72 3.05 ns, max clock to pin32 t multck_p32 2.20 2.62 2.93 ns, max clock to pin31 t multck_p31 2.12 2.52 2.82 ns, max clock to pin30 t multck_p30 2.03 2.42 2.71 ns, max clock to pin29 t multck_p29 1.95 2.32 2.60 ns, max clock to pin28 t multck_p28 1.87 2.22 2.48 ns, max clock to pin27 t multck_p27 1.79 2.12 2.37 ns, max clock to pin26 t multck_p26 1.70 2.02 2.26 ns, max clock to pin25 t multck_p25 1.62 1.92 2.15 ns, max clock to pin24 t multck_p24 1.54 1.82 2.03 ns, max clock to pin23 t multck_p23 1.46 1.71 1.92 ns, max clock to pin22 t multck_p22 1.37 1.61 1.81 ns, max clock to pin21 t multck_p21 1.29 1.51 1.69 ns, max clock to pin20 t multck_p20 1.21 1.41 1.58 ns, max clock to pin19 t multck_p19 1.13 1.31 1.47 ns, max clock to pin18 t multck_p18 1.04 1.21 1.36 ns, max clock to pin17 t multck_p17 0.96 1.11 1.24 ns, max clock to pin16 t multck_p16 0.88 1.01 1.13 ns, max clock to pin15 t multck_p15 0.80 0.91 1.02 ns, max clock to pin14 t multck_p14 0.71 0.81 0.91 ns, max clock to pin13 t multck_p13 0.63 0.71 0.79 ns, max clock to pin12 t multck_p12 0.63 0.71 0.79 ns, max clock to pin11 t multck_p11 0.63 0.71 0.79 ns, max clock to pin10 t multck_p10 0.63 0.71 0.79 ns, max clock to pin9 t multck_p9 0.63 0.71 0.79 ns, max clock to pin8 t multck_p8 0.63 0.71 0.79 ns, max clock to pin7 t multck_p7 0.63 0.71 0.79 ns, max clock to pin6 t multck_p6 0.63 0.71 0.79 ns, max clock to pin5 t multck_p5 0.63 0.71 0.79 ns, max clock to pin4 t multck_p4 0.63 0.71 0.79 ns, max clock to pin3 t multck_p3 0.63 0.71 0.79 ns, max clock to pin2 t multck_p2 0.63 0.71 0.79 ns, max clock to pin1 t multck_p1 0.63 0.71 0.79 ns, max clock to pin0 t multck_p0 0.63 0.71 0.79 ns, max virtex-ii pro and virtex-ii pro x platform fpgas: dc and switching characteristics r ds083 (v5.0) june 21, 2011 www.xilinx.com module 3 of 4 product specification 38 product not recommended for new designs block selectram+ swit ching characteristics tbuf switching characteristics ta bl e 4 7 : block selectram+ switching characteristics speed grade description symbol -7 -6 -5 units sequential delays clock clk to dout output t bcko 1.41 1.50 1.68 ns, max setup and hold tim es before clock clk addr inputs t back /t bcka 0.27/ 0.22 0.31/ 0.25 0.35/ 0.28 ns, min din inputs t bdck /t bckd 0.20/ 0.22 0.23/ 0.25 0.26/ 0.28 ns, min en input t beck /t bcke 0.28/ 0.00 0.32/ 0.00 0.35/ 0.00 ns, min rst input t brck /t bckr 0.28/ 0.00 0.32/ 0.00 0.35/ 0.00 ns, min wen input t bwck /t bckw 0.33/ 0.00 0.35/ 0.00 0.39/ 0.00 ns, min clock clk clka to clkb setup time for different ports t bccs 1.0 1.0 1.0 ns, min minimum pulse width, high t bpwh 1.17 1.30 1.50 ns, min minimum pulse width, low t bpwl 1.17 1.30 1.50 ns, min notes: 1. a zero ?0? hold time listing indicates no hold time or a negative hold time. negative values can not be guaranteed ?best-case ?, but if a ?0? is listed, there is no positive hold time. ta bl e 4 8 : tbuf switching characteristics speed grade description symbol -7 -6 -5 units combinatorial delays in input to out output t io 0.88 1.01 1.12 ns, max tri input to out output high-impedance t off 0.48 0.55 0.61 ns, max tri input to valid data on out output t on 0.48 0.55 0.61 ns, max virtex-ii pro and virtex-ii pro x platform fpgas: dc and switching characteristics r ds083 (v5.0) june 21, 2011 www.xilinx.com module 3 of 4 product specification 39 product not recommended for new designs configuration timing configuration memory clearing parameters power-up timing of configuration signals is shown in figure 7 ; corresponding timing characteristics are listed in ta b l e 4 9 . figure 7: configuration power-up timing ta bl e 4 9 : power-up timing characteristics description figure references symbol value units power-on reset 1 t por t pl + 2 ms, max program latency 2 t pl 4 ? s per frame, max cclk (output) delay 3 t icck 0.25 ? s, min 4.00 ? s, max program pulse width t program 300 ns, min notes: 1. the m2, m1, and m0 mode pins should be set at a constant dc voltage level, either through pull-up or pull-down resistors, or tied directly to ground or v ccaux . the mode pins should not be toggled during and after configuration. t pl t icck ds083-3_07_012004 t por init_b prog_b v cc *can be either 0 or 1, but must not toggle during and after configuration. m0, m1, m2* (required) cclk (output or input) 1 2 3 virtex-ii pro and virtex-ii pro x platform fpgas: dc and switching characteristics r ds083 (v5.0) june 21, 2011 www.xilinx.com module 3 of 4 product specification 40 product not recommended for new designs master/slave serial mode parameters clock timing for slave serial configuration programming is shown in figure 8 , with master serial clock timing shown in figure 9 . programming parameters for both slave and master modes are given in ta bl e 5 0 . . figure 8: slave serial mode timing sequence figure 9: master serial mode timing sequence ta bl e 5 0 : master/slave serial mode timing characteristics description figure references symbol value units cclk din setup/hold, slave mode ( figure 8 )1/2 t dcc /t ccd 5.0/0.0 ns, min din setup/hold, master mode ( figure 9 )1/2 t dsck /t ckds 5.0/0.0 ns, min dout 3 t cco 12.0 ns, max high time 4 t cch 5.0 ns, min low time 5 t ccl 5.0 ns, min maximum start-up frequency f cc_startup 50 mhz, max maximum frequency f cc_serial 66 (1) mhz, max frequency tolerance, master mode with respect to nominal +45% ?30% notes: 1. if no provision is made in the desi gn to adjust the frequency of cclk, f cc_serial should not exceed f cc_startup . 4 t cch 3 t cco 5 t ccl 2 t ccd 1 t dcc serial din cclk serial dout ds083-3_08_111104 serial din cclk (output) serial dout 1 2 t ckds t dsck ds083-3_09_111104 virtex-ii pro and virtex-ii pro x platform fpgas: dc and switching characteristics r ds083 (v5.0) june 21, 2011 www.xilinx.com module 3 of 4 product specification 41 product not recommended for new designs master/slave selectmap parameters figure 10 is a generic timing diagram for data loading using selectmap. for other data loading diagrams, refer to the virtex-ii pro platform fpga user guide . figure 10: selectmap mode data loading sequence (generic) ta bl e 5 1 : selectmap mode write timing characteristics description device figure references symbol value units cclk data[0:7] setup/hold xc2vp2 1/2 t smdcc /t smccd 5.0/0.0 ns, min xc2vp4 5.0/0.0 ns, min xc2vp7 5.0/0.0 ns, min xc2vp20 5.0/0.0 ns, min xc2vpx20 5.0/0.0 ns, min xc2vp30 5.0/0.0 ns, min xc2vp40 5.0/0.0 ns, min xc2vp50 5.0/0.0 ns, min xc2vp70 6.0/0.0 ns, min xc2vpx70 6.0/0.0 ns, min xc2vp100 7.5/0.0 ns, min cs_b setup/hold 3/4 t smcscc /t smcccs 7.0/0.0 ns, min rdwr_b setup/hold 5/6 t smccw /t smwcc 7.0/0.0 ns, min busy propagation delay 7 t smckby 12.0 ns, max maximum start-up frequency f cc_startup 50 mhz, max maximum frequency f cc_selectmap 50 mhz, max maximum frequency with no handshake f ccnh 50 mhz, max ds083-3_10_012004 cclk no write write no write write data[0:7] cs_b rdwr_b 3 5 busy 4 6 7 t smcscc 1 t smdcc 2 t smccd t smcccs t smwcc t smckby t smccw virtex-ii pro and virtex-ii pro x platform fpgas: dc and switching characteristics r ds083 (v5.0) june 21, 2011 www.xilinx.com module 3 of 4 product specification 42 product not recommended for new designs jtag test access port sw itching characteristics characterization data for some of the most commonly requested timing parameters shown in figure 11 is listed in ta b l e 5 2 . fi figure 11: virtex-ii pro boundary scan port timing waveforms ta bl e 5 2 : boundary-scan port timing specifications description figure references symbol value units tck tms and tdi setup time 1 t taptck 5.5 ns, min tms and tdi hold times 2 t tcktap 2.0 ns, min falling edge to tdo output valid 3 t tcktdo 11.0 ns, max maximum frequency f tck 33.0 mhz, max ds083-3_11_012104 data to be captured data to be driven out tdo tck tdi tms data valid data valid t tcktdo t taptck t tcktap 1 2 3 virtex-ii pro and virtex-ii pro x platform fpgas: dc and switching characteristics r ds083 (v5.0) june 21, 2011 www.xilinx.com module 3 of 4 product specification 43 product not recommended for new designs virtex-ii pro pin-to-pin output parameter guidelines all devices are 100% functionally tested. listed below are repr esentative values for typical pin locations and normal clock loading. values are expressed in nanoseconds unless otherwise noted. global clock input to output delay fo r lvcmos25, 12 ma, fast slew rate, with dcm ta bl e 5 3 : global clock input to output delay for lvcmos25, 12 ma, fast slew rate, with dcm speed grade description symbol device -7 -6 -5 units lvcmos25 global clock input to output delay using output flip-flop, 12 ma, fast slew rate, with dcm. for data output with different standards, adjust the delays with the values shown in iob output switching characteristics standard adjustments, page 28 . global clock and off with dcm t ickofdcm xc2vp2 1.55 1.59 1.62 ns xc2vp4 1.58 1.61 1.65 ns xc2vp7 1.63 1.68 1.72 ns xc2vp20 1.68 1.74 1.79 ns xc2vpx20 1.68 1.74 1.79 ns xc2vp30 1.68 1.75 1.80 ns xc2vp40 1.71 1.86 1.92 ns xc2vp50 1.80 2.00 2.07 ns xc2vp70 1.87 2.07 2.24 ns xc2vpx70 1.87 2.07 2.24 ns xc2vp100 n/a 2.38 2.45 ns notes: 1. listed above are representative values where one global clock input drives one vertical clock line in each accessible column, and where all accessible iob and clb flip-flops are clocked by the global clock net. 2. output timing is measured at 50% v cc threshold with test setup shown in figure 6 . for other i/o standards, see ta b l e 4 0 . 3. dcm output jitter is already included in the timing calculation. virtex-ii pro and virtex-ii pro x platform fpgas: dc and switching characteristics r ds083 (v5.0) june 21, 2011 www.xilinx.com module 3 of 4 product specification 44 product not recommended for new designs global clock input to output delay fo r lvcmos25, 12 ma, fast slew rate, without dcm ta bl e 5 4 : global clock input to output delay for lvcmos25, 12 ma, fast slew rate, without dcm speed grade description symbol device -7 -6 -5 units lvcmos25 global clock input to output delay using output flip-flop, 12 ma, fast slew rate, without dcm. for data output with different standards, adjust the delays with the values shown in iob output switching characteristics standard adjustments, page 28 . global clock and off without dcm t ickof xc2vp2 3.19 3.52 3.82 ns xc2vp4 3.39 3.91 4.27 ns xc2vp7 3.59 4.00 4.36 ns xc2vp20 3.62 4.08 4.46 ns xc2vpx20 3.62 4.08 4.46 ns xc2vp30 3.73 4.12 4.50 ns xc2vp40 3.89 4.28 4.67 ns xc2vp50 4.00 4.43 4.84 ns xc2vp70 4.38 4.87 5.33 ns xc2vpx70 4.38 4.87 5.33 ns xc2vp100 n/a 5.32 5.82 ns notes: 1. listed above are representative values where one global clock input drives one vertical clock line in each accessible column, and where all accessible iob and clb flip-flops are clocked by the global clock net. 2. output timing is measured at 50% v cc threshold with test setup shown in figure 6 . for other i/o standards, see ta b l e 4 0 . 3. dcm output jitter is already included in the timing calculation. virtex-ii pro and virtex-ii pro x platform fpgas: dc and switching characteristics r ds083 (v5.0) june 21, 2011 www.xilinx.com module 3 of 4 product specification 45 product not recommended for new designs virtex-ii pro pin-to-pin input parameter guidelines all devices are 100% functionally tested. listed below are repr esentative values for typical pin locations and normal clock loading. values are expressed in nanoseconds unless otherwise noted global clock set-up and hold for lvcmos25 standard, with dcm ta bl e 5 5 : global clock set-up and hold for lvcmos25 standard, with dcm speed grade description symbol device -7 -6 -5 units input setup and hold time relative to global clock input signal for lvcmos25 standard. (1) for data input with different standards, adjust the setup time delay by the values shown in iob input switching characteristics standard adjustments, page 25 . no delay global clock and iff (2) with dcm t psdcm /t phdcm xc2vp2 1.54/?0.58 1.54/?0.57 1.54/?0.56 ns xc2vp4 1.59/?0.59 1.59/?0.58 1.59/?0.57 ns xc2vp7 1.66/?0.61 1.66/?0.59 1.66/?0.57 ns xc2vp20 1.68/?0.53 1.68/?0.53 1.68/?0.50 ns xc2vpx20 1.68/?0.53 1.6 8/?0.53 1.68/?0.50 ns xc2vp30 1.81/?0.74 1.81/?0.74 1.81/?0.71 ns xc2vp40 1.85/?0.65 1.85/?0.64 1.85/?0.60 ns xc2vp50 1.85/?0.57 1.85/?0.54 1.85/?0.50 ns xc2vp70 1.86/?0.45 1.86/?0.39 1.86/?0.30 ns xc2vpx70 1.86/?0.45 1.8 6/?0.39 1.86/?0.30 ns xc2vp100 n/a 1.86/?0.35 1.87/?0.28 ns notes: 1. setup time is measured relative to the global clock input sig nal with the fastest route and the lightest load. hold time is m easured relative to the global clock input signal with the slowest route and heaviest load. 2. these measurements include: - clk0 and clk180 dcm jitter - worst-case duty-cycle distortion using clk0 and clk180, t dcd_clk180 . 3. iff = input flip-flop or latch virtex-ii pro and virtex-ii pro x platform fpgas: dc and switching characteristics r ds083 (v5.0) june 21, 2011 www.xilinx.com module 3 of 4 product specification 46 product not recommended for new designs global clock set-up and hold for lvcmos25 standard, without dcm , ta bl e 5 6 : global clock set-up and hold for lvcmos25 standard, without dcm speed grade description symbol device -7 -6 -5 units input setup and hold time relative to global clock input signal for lvcmos25 standard. for data input with different standards, adjust the setup time delay by the values shown in iob input switching characteristics standard adjustments, page 25 . full delay global clock and iff without dcm t psfd /t phfd xc2vp2 1.80/?0.44 1.85/?0.41 1.96/?0.43 ns xc2vp4 1.82/?0.53 1.83/?0.31 1.90/?0.29 ns xc2vp7 1.80/?0.34 1.81/?0.24 1.88/?0.19 ns xc2vp20 1.76/?0.24 1.83/?0.17 1.92/?0.15 ns xc2vpx20 1.76/?0.24 1.8 3/?0.17 1.92/?0.15 ns xc2vp30 1.75/?0.22 1.92/?0.26 1.99/?0.23 ns xc2vp40 2.25/?0.54 2.40/?0.56 2.49/?0.54 ns xc2vp50 2.93/?1.02 2.98/?0.93 3.00/?0.83 ns xc2vp70 2.79/?0.72 2.79/?0.55 2.78/?0.41 ns xc2vpx70 2.79/?0.72 2.7 9/?0.55 2.78/?0.41 ns xc2vp100 n/a 5.58/?2.35 5.60/?2.35 ns notes: 1. iff = input flip-flop or latch 2. setup time is measured relative to the global clock input sig nal with the fastest route and the lightest load. hold time is m easured relative to the global clock input signal with the slowest route and heaviest load. 3. a zero ?0? hold time listing indicates no hold time or a negative hold time. negative values can not be guaranteed ?best-case ?, but if a ?0? is listed, there is no positive hold time. virtex-ii pro and virtex-ii pro x platform fpgas: dc and switching characteristics r ds083 (v5.0) june 21, 2011 www.xilinx.com module 3 of 4 product specification 47 product not recommended for new designs dcm timing parameters all devices are 100% functionally tested. because of the dif- ficulty in directly measuring many internal timing parame- ters, those parameters are derived from benchmark timing patterns. the following guidelines reflect worst-case values across the recommended operating conditions. all output jitter and phase specifications are determined through sta- tistical measurement at the package pins. operating frequency ranges e ta bl e 5 7 : operating frequency ranges speed grade description symbol constraints -7 -6 -5 units output clocks (low frequency mode) clk0, clk90, clk180, cl k270 clkout_freq_1x_lf_min 24.00 24.00 24.00 mhz clkout_freq_1x_lf_max 270.00 210.00 180.00 mhz clk2x, clk2x180 (5,6) clkout_freq_2x_lf_min 48.00 48.00 48.00 mhz clkout_freq_2x_lf_max 450.00 420.00 360.00 mhz clkdv clkout_freq_dv_lf_min 1.50 1.50 1.50 mhz clkout_freq_dv_lf_max 140.00 140.00 120.00 mhz clkfx, clkfx180 clkout_freq_fx_lf_min 24.00 24.00 24.00 mhz clkout_freq_fx_lf_max 240.00 240.00 210.00 mhz input clocks (low frequency mode) clkin (using dll outputs) (1,3,4) clkin_freq_dll_lf_min 24.00 24.00 24.00 mhz clkin_freq_dll_lf_max 270.00 210.00 180.00 mhz clkin (using clkfx outputs) (2,3,4) clkin_freq_fx_lf_min 1.00 1.00 1.00 mhz clkin_freq_fx_lf_max 240.00 240.00 210.00 mhz psclk psclk_freq_lf_min 0.01 0.01 0.01 mhz psclk_freq_lf_max 450.00 420.00 360.00 mhz output clocks (high frequency mode) clk0, clk180 (6) clkout_freq_1x_hf_min 48.00 48.00 48.00 mhz clkout_freq_1x_hf_max 450.00 420.00 360.00 mhz clkdv clkout_freq_dv_hf_min 3.00 3.00 3.00 mhz clkout_freq_dv_hf_max 280.00 280.00 240.00 mhz clkfx, clkfx180 clkout_freq_fx_hf_min 210.00 210.00 210.00 mhz clkout_freq_fx_hf_max 320.00 320.00 270.00 mhz input clocks (high frequency mode) clkin (using dll outputs) (1,3,4,6) clkin_freq_dll_hf_min 48.00 48.00 48.00 mhz clkin_freq_dll_hf_max 450.00 420.00 360.00 mhz clkin (using clkfx outputs) (2,3,4) clkin_freq_fx_hf_min 50.00 50.00 50.00 mhz clkin_freq_fx_hf_max 320.00 320.00 270.00 mhz psclk psclk_freq_hf_ min 0.01 0.01 0.01 mhz psclk_freq_hf_max 450.00 420.00 360.00 mhz notes: 1. ?dll outputs? is used here to describe the outputs: cl k0, clk90, clk180, clk270, clk2x, clk2x180, and clkdv. 2. if both dll and clkfx outputs are used, fo llow the more restrictive specification. 3. if the clkin_divide_by_2 at tribute of the dcm is used, then double these values. 4. if the clkin_divide_by _2 attribute of the dcm is used and clkin frequency > 40 0 mhz, clkin duty cycle must be within 5% (45/55 to 55/45). 5. clk2x and clk2x180 may not be used as the input to the clkfb pin. see the virtex-ii pro platform fpga user guide for more information. 6. for the xc2vp100 -6 device only, clock macros for corner dcms (x0y0, x5y0, x0y1, x5y1) are required to operate at maximum clock frequency. see xapp685 for implementation examples. virtex-ii pro and virtex-ii pro x platform fpgas: dc and switching characteristics r ds083 (v5.0) june 21, 2011 www.xilinx.com module 3 of 4 product specification 48 product not recommended for new designs input clock tolerances ta bl e 5 8 : input clock tolerances description symbol constraints f clkin speed grade units ?7 ?6 ?5 min max min max min max input clock low/high pulse width psclk psclk_pulse < 1mhz 25.00 25.00 25.00 ns psclk and clkin (3) psclk_pulse and clkin_pulse 1 ? 10 mhz 25.00 25.00 25.00 ns 10 ? 25 mhz 10.00 10.00 10.00 ns 25 ? 50 mhz 5.00 5.00 5.00 ns 50 ? 100 mhz 3.00 3.00 3.00 ns 100 ? 150 mhz 2.40 2.40 2.40 ns 150 ? 200 mhz 2.00 2.00 2.00 ns 200 ? 250 mhz 1.80 1.80 1.80 ns 250 ? 300 mhz 1.50 1.50 1.50 ns 300 ? 350 mhz 1.30 1.30 1.30 ns 350 ? 400 mhz 1.15 1.15 1.15 ns > 400 mhz 1.05 1.05 1.05 ns input clock cycle-cycle jitter (low frequency mode) clkin (using dll outputs) (1) clkin_cyc_jitt_dll_lf 300 300 300 ps clkin (using clkfx outputs) (2) clkin_cyc_jitt_fx_lf 300 300 300 ps input clock cycle-cycle jitter (high frequency mode) clkin (using dll outputs) (1) clkin_cyc_jitt_dll_hf 150 150 150 ps clkin (using clkfx outputs) (2) clkin_cyc_jitt_fx_hf 150 150 150 ps input clock period jitter (low frequency mode) clkin (using dll outputs) (1) clkin_per_jitt_dll_lf 1 1 1 ns clkin (using clkfx outputs) (2) clkin_per_jitt_fx_lf 1 1 1 ns input clock period jitter (high frequency mode) clkin (using dll outputs) (1) clkin_per_jitt_dll_hf 1 1 1 ns clkin (using clkfx outputs) (2) clkin_per_jitt_fx_hf 1 1 1 ns feedback clock path delay variation clkfb off-chip feedback clkfb_delay_var_ext 1 1 1 ns notes: 1. ?dll outputs? is used here to describe the outputs: clk0, clk90, clk180, clk270, clk2x, clk2x180, and clkdv. 2. if both dll and clkfx outputs are used, follow the more restrictive specification. 3. if dcm phase shift feature is used and clkin frequency > 200 mh z, clkin duty cycle must be within 5% (45/55 to 55/45). virtex-ii pro and virtex-ii pro x platform fpgas: dc and switching characteristics r ds083 (v5.0) june 21, 2011 www.xilinx.com module 3 of 4 product specification 49 product not recommended for new designs output clock jitter output clock phase alignment ta bl e 5 9 : output clock jitter description symbol constraints speed grade units ?7 ?6 ?5 clock synthesis period jitter clk0 clkout_per_jitt_0 100 100 100 ps clk90 clkout_per_jitt_90 150 150 150 ps clk180 clkout_per_jitt_180 150 150 150 ps clk270 clkout_per_jitt_270 150 150 150 ps clk2x, clk2x180 clkout_per_jitt_2x 200 200 200 ps clkdv (integer division) clkout_per_jitt_dv1 150 150 150 ps clkdv (non-integer division) clkout_per_jitt_dv2 300 300 300 ps clkfx, clkfx180 clkout_per_jitt_fx note (1) note (1) note (1) ps notes: 1. use the jitter calculator on the xilinx website ( http://www.xilinx.com/applicat ions/web_ds_v2/jitter_calc.htm ) for clkfx and clkfx180 output jitter. ta bl e 6 0 : output clock phase alignment description symbol constraints speed grade units ?7 ?6 ?5 phase offset between clkin and clkfb clkin/clkfb clkin_clkfb_phase 50 50 50 ps phase offset between any dcm outputs all clk* outputs clkout_phase 140 140 140 ps duty cycle precision dll outputs (1) clkout_duty_cycle_dll (2) 150 150 150 ps clkfx outputs clkout_duty_cycle_fx 100 100 100 ps notes: 1. ?dll outputs? is used here to describe the outputs: cl k0, clk90, clk180, clk270, clk2x, clk2x180, and clkdv. 2. clkout_duty_cycle_dll applies to the 1x clock out puts (clk0, clk90, clk180, and clk270) only if duty_cycle_correction = true. 3. specification also applies to psclk. virtex-ii pro and virtex-ii pro x platform fpgas: dc and switching characteristics r ds083 (v5.0) june 21, 2011 www.xilinx.com module 3 of 4 product specification 50 product not recommended for new designs miscellaneous timing parameters frequency synthesis parameter cross-reference ta bl e 6 1 : miscellaneous timing parameters speed grade description symbol constraints f clkin -7 -6 -5 units time required to achieve lock using dll outputs (1) lock_dll: lock_dll_60 > 60mhz 20.00 20.00 20.00 us lock_dll_50_60 50 - 60 mhz 25.00 25.00 25.00 us lock_dll_40_50 40 - 50 mhz 50.00 50.00 50.00 us lock_dll_30_40 30 - 40 mhz 90.00 90.00 90.00 us lock_dll_24_30 24 - 30 mhz 120.00 120.00 120.00 us using clkfx outputs lock_fx_min 10.00 10.00 10.00 ms lock_fx_max 10.00 10.00 10.00 ms additional lock time with fine phase shifting lock_dll_fine_shift 50.00 50.00 50.00 us fine phase shifting absolute shifting range fine_shift_range 10.00 10.00 10.00 ns delay lines tap delay resolution dcm_tap_min 30.00 30.00 30.00 ps dcm_tap_max 50.00 50.00 50.00 ps notes: 1. ?dll outputs? is used here to describe the outputs: cl k0, clk90, clk180, clk270, clk2x, clk2x180, and clkdv. ta bl e 6 2 : frequency synthesis attribute min max clkfx_multiply 2 32 clkfx_divide 1 32 ta bl e 6 3 : parameter cross-reference libraries guide data sheet dll_clkout_{min|max}_lf clkout_freq_{1x|2x|dv}_lf dfs_clkout_{min|max}_lf clkout_freq_fx_lf dll_clkin_{min|max}_lf clkin_freq_dll_lf dfs_clkin_{min|max}_lf clkin_freq_fx_lf dll_clkout_{min|max}_hf clkout_freq_{1x|dv}_hf dfs_clkout_{min|max}_hf clkout_freq_fx_hf dll_clkin_{min|max}_hf clkin_freq_dll_hf dfs_clkin_{min|max}_hf clkin_freq_fx_hf virtex-ii pro and virtex-ii pro x platform fpgas: dc and switching characteristics r ds083 (v5.0) june 21, 2011 www.xilinx.com module 3 of 4 product specification 51 product not recommended for new designs source-synchronous switching characteristics the parameters in this section provide the necessary values for calculating timing budgets for virtex-ii pro source-synchronous transmitter and receiver data-valid windows. ta bl e 6 4 : duty cycle distortion and clock-tree skew description symbol device speed grade units ? 7 ? 6 ? 5 duty cycle distortion (1) t dcd_local all 0.10 0.10 0.20 ns t dcd_clk180 0.10 0.11 0.13 ns clock tree skew (2) t ckskew xc2vp2 0.13 0.13 0.13 ns xc2vp4 0.13 0.13 0.13 ns xc2vp7 0.13 0.13 0.13 ns xc2vp20 0.20 0.21 0.22 ns xc2vpx20 0.20 0.21 0.22 ns xc2vp30 0.20 0.22 0.24 ns xc2vp40 0.33 0.34 0.35 ns xc2vp50 0.40 0.41 0.42 ns xc2vp70 0.54 0.59 0.64 ns xc2vpx70 0.54 0.59 0.64 ns xc2vp100 n/a 0.79 0.87 ns notes: 1. these parameters represent the worst-case duty cycle distortion observable at the pins of the device using lvds output buffer s. for cases where other i/o sta ndards are used, ibis can be used to calculate an y additional duty cycle di stortion that might be caus ed by asymmetrical rise/fall times. t dcd_local applies to cases where the dedicated path from the dcm to the bufg is bypassed and where local (iob) inversion is used to provide the negative-edge clock to the ddr element in the i/o. users must follow the implementation guidelines containe d in xapp685 for these specifications to apply. t dcd_clk180 applies to cases where the clk180 output of the dcm is used to provide the negative-edge clock to the ddr element in the i/o. 2. this value represents the worst-case clock-tree skew observab le between sequential i/o elements. significantly less clock-tre e skew exists for i/o registers that are close to each other and fed by the same or adjacent clock-tree branches. use the xilinx fpga_ editor and timing analyzer tools to evaluate clock skew specific to your application. virtex-ii pro and virtex-ii pro x platform fpgas: dc and switching characteristics r ds083 (v5.0) june 21, 2011 www.xilinx.com module 3 of 4 product specification 52 product not recommended for new designs ta bl e 6 5 : package skew description symbol device/package value units package skew (1) t pkgskew xc2vp2ff672 104 ps xc2vp4ff672 102 ps xc2vp7ff672 92 ps xc2vp7ff896 101 ps xc2vp20ff896 93 ps xc2vpx20ff896 93 ps xc2vp20ff1152 106 ps xc2vp30ff896 86 ps xc2vp30ff1152 112 ps xc2vp40ff1152 92 ps xc2vp40ff1148 100 ps xc2vp50ff1152 88 ps xc2vp50ff1148 101 ps xc2vp50ff1517 97 ps xc2vp70ff1517 95 ps xc2vp70ff1704 101 ps xc2vpx70ff1704 101 ps xc2vp100ff1704 86 ps xc2vp100ff1696 100 ps notes: 1. these values represent the worst-case skew between any two balls of the package: shortest flight time to longest flight time from pad to ball (7.1ps per mm). 2. package trace length information is available for these device/package combinations. this information can be used to deskew t he package. ta bl e 6 6 : sample window description symbol device speed grade units ? 7 ? 6 ? 5 sampling error at receiver pins (1) t samp all 0.50 0.50 0.50 ns notes: 1. this parameter indicates the total sampling error of virtex-ii pro ddr input registers across voltage, temperature, and process. the characterization methodology uses the dcm to c apture the ddr input registers? edges of operation. 2. these measurements include: - clk0 and clk180 dcm jitter - worst-case duty-cycle distortion, t dcd_clk180 - dcm accuracy (phase offset) - dcm phase shift resolution these measurements do not include package or clock tree skew. virtex-ii pro and virtex-ii pro x platform fpgas: dc and switching characteristics r ds083 (v5.0) june 21, 2011 www.xilinx.com module 3 of 4 product specification 53 product not recommended for new designs source synchronous timing budgets this section describes how to use the parameters provided in the source-synchronous switching characteristics sec- tion to develop system-specific timing budgets. the follow- ing analysis provides informat ion necessary for determining virtex-ii pro contributions to an overall system timing analy- sis; no assumptions are made about the effects of inter-symbol interference or pcb skew. virtex-ii pro transmitter data-valid window (t x ) t x is the minimum aggregate valid data period for a source-synchronous data bus at the pins of the device and is calculated as follows: t x = data period - [jitter (1) + duty cycle distortion (2) + tckskew (3) + tpkgskew (4) ] notes: 1. jitter values and accumulation methodology to be provided in a future release of this document. the absolute period jitter values found in the dcm timing parameters section of the particular dcm output clock used to clock the iob ff can be used for a best case analysis. 2. this value depends on the clocking methodology used. see note1 for ta b l e 6 4 . 3. this value represents the worst-case clock-tree skew observable between sequential i/o elements. significantly less clock-tree skew exists for i/o registers that are close to each other and fed by the same or adjacent clock-tree branches. use the xilinx fpga_editor and timing analyzer tools to evaluate clock skew specific to your application. 4. these values represent the worst-case skew between any two balls of the package: shortest flight time to longest flight time from pad to ball. ta bl e 6 7 : example pin-to-pin setup/hold: source-synchronous configuration description symbol device speed grade units ? 7 ? 6 ? 5 example data input set-up and hold times relative to a forwarded clock input pin, (1) using dcm and global clock buffer. values represent an 18-bit bus located in banks 2, 3, 6, or 7 and grouped to one horizontal global clock line. trace must be used to determine the actual values for any given design. for situations where clock and data inputs conform to different standards, adjust the setup and hold values accordingly using the values shown in iob input switching characteristics standard adjustments, page 25 . no delay global clock and iff (2) with dcm t psdcm_0 /t phdcm_0 xc2vp2 0.23/0.39 0. 21/0.42 0.21/0.42 ns xc2vp4 0.26/0.37 0. 24/0.40 0.24/0.41 ns xc2vp7 0.18/ 0.36 0.18/ 0.40 0.18/ 0.41 ns xc2vp20 0.14/ 0.41 0.13/ 0.42 0.12/ 0.44 ns xc2vpx20 0.14/ 0.41 0.13/ 0.42 0.12/ 0.44 ns xc2vp30 0.29/ 0.25 0.31/ 0.24 0.31/ 0.24 ns xc2vp40 0.25/ 0.30 0.26/ 0.29 0.27/ 0.29 ns xc2vp50 0.18/ 0.36 0.18/ 0.38 0.17/ 0.39 ns xc2vp70 0.18/ 0.37 0.18/ 0.38 0.18/ 0.38 ns xc2vpx70 0.18/ 0.37 0.18/ 0.38 0.18/ 0.38 ns xc2vp100 n/a 0.18/ 0.33 0.19/ 0.37 ns notes: 1. the timing values were measured using the fine-phase ad justment feature of the dcm. these measurements include: - clk0 and clk180 dcm jitter - worst-case duty-cycle distor tion using clk0 and clk180, t dcd_clk180 package skew is not included in these measurements. 2. iff = input flip-flop virtex-ii pro and virtex-ii pro x platform fpgas: dc and switching characteristics r ds083 (v5.0) june 21, 2011 www.xilinx.com module 3 of 4 product specification 54 product not recommended for new designs virtex-ii pro receiver data-valid window (r x ) r x is the required minimum aggregate valid data period for a source-synchronous data bus at the pins of the device and is calculated as follows: r x = [tsamp (1) + tckskew (2) + tpkgskew (3) ] notes: 1. this parameter indicates th e total sampling error of virtex-ii pro ddr input registers across voltage, temperature, and process. the characterization methodology uses the dcm to capture the ddr input registers? edges of operation. these measurements include: - clk0 and clk180 dcm ji tter in a quiet system - worst-case duty-cycle distortion - dcm accuracy (phase offset) - dcm phase shift resolution. these measurements do not include package or clock tree skew. 2. this value represents the worst-case clock-tree skew observable between sequential i/o elements. significantly less clock-tree skew exists for i/o registers that are close to each other and fed by the same or adjacent clock-tree branches. use the xilinx fpga_editor and timing analyzer tools to evaluate clock skew specific to your application. 3. these values represent the worst-case skew between any two balls of the package: shortest flight time to longest flight time from pad to ball. revision history this section records the change history for this module of the data sheet. date version revision 01/31/02 1.0 initial xilinx release. 06/17/02 2.0 ? added new virtex-ii pro family members. ? added timing parameters from speedsfile v1.62 . ? added ta b l e 4 6 , pipelined multiplier switching characteristics . ? added 3.3v-vs-2.5v table entries for some parameters. 09/03/02 2.1 ? added source-synchronous swit ching characteristics section. ? added absolute max ratings for 3.3v-vs-2.5v parameters in ta b l e 1 . ? added recommended operating conditions for v in and rocketio footnote to ta bl e 2 . ? updated sstl2 values in ta bl e 6 . added sstl18 values: ta b l e 6 , ta bl e 3 9 , ta b l e 3 2 . [ ta bl e 3 2 removed in v2.8.] ? added ta b l e 1 0 , which contains lvpecl dc specifications. 09/27/02 2.2 added section general power supply requirements . 11/20/02 2.3 updated parametric information in: ? ta b l e 1 : increase absolute max rating for v cco , v ref , v in , and v ts from 3.6v to 3.75v. delete cautionary footnotes related to voltage overshoot/undershoot. ? ta b l e 2 : delete v cco specifications for 2.5v and below operation. delete footnote referencing special information for 3.3v operation. add footnote for pci/pci-x. ? ta b l e 3 : add i batt . delete i l specifications for 2.5v and below operation. ? ta b l e 4 : add typical quiescent supply curr ents for xc2vp4 and xc2vp7 only ? ta b l e 6 : correct i ol and i oh for sstl2 i. add rows for lvttl, lvcmos33, and pci-x. correct max v ih from v cco to 3.6v. ? ta b l e 7 : correct min/max v od , v ocm , and v icm ? ta b l e 1 0 : reformat lvpecl dc specifications to match virtex-ii data sheet format ? ta b l e 1 2 : correct parameter name from differential output voltage to single-ended output voltage swing. ? ta b l e 1 6 : add cpmc405clock max frequencies ? ta b l e 2 7 : add footnote regarding serial data rate limitation in -5 part. ? ta b l e 3 9 : add rows for lvttl, lvcmos33, and pci-x. ? ta b l e 3 2 : add lvttl, lvcmos33, and pci-x. correct all capacitive load values (except pci/pci-x) to 0 pf. [ ta b l e 3 2 removed in v2.8.] ? ta b l e 5 1 : correct cclk max frequencies 11/25/02 2.4 ta b l e 1 : correct lower limit of voltage range of v in and v ts from ?0.3v to ?0.5v for 3.3v. virtex-ii pro and virtex-ii pro x platform fpgas: dc and switching characteristics r ds083 (v5.0) june 21, 2011 www.xilinx.com module 3 of 4 product specification 55 product not recommended for new designs 12/03/02 2.5 updated parametric information in: ? ta b l e 1 : correct lower limit of voltage range of v in and v ts from ?0.5v to ?0.3v for 3.3v. ? ta b l e 2 : add footnote (2) regarding v ccaux voltage droop. renumbered other notes. ? ta b l e 1 2 : add waveform diagrams ( figure 1 and figure 2 ) illustrating dv out (single-ended) and dv ppout (differential). ? ta b l e 2 3 : indicate refclk upper frequency limitation; relate refclk parameters to refclk2, brefclk, and brefclk2; correct t rclk and t fclk values and unit of measurement. ? ta b l e 6 0 : add qualifying footnote to clkout_duty_cycle_dll . 01/20/03 2.6 updated parametric information in: ? ta b l e 1 2 : correct dv in min (200 mv to 175 mv) and dv in max (1000 mv to 2000 mv). ? ta b l e 2 3 : correct t rclk /t fclk typ (400 ps to 600 ps) and max (600 ps to 1000 ps). add footnote (2) to qualify max t gjtt parameter. ? ta b l e 5 9 : correct hyperlink in footnote (1) to point directly to answer record 13645. ? move clock parameters from ta b l e 1 8 , ta bl e 1 9 , ta bl e 2 0 , and ta bl e 2 1 to ta b l e 1 6 . 03/24/03 2.7 ? added/updated timing parameters from speedsfile v1.76 . ? ta b l e 2 : delete first table footnote and renumber all others. ? ta b l e 3 : add "sample-tested" to i l . remove "device" column, unnecessary. ? ta b l e 8 : update v ocm (typ) to 1.250v. ? ta b l e 1 0 : update lvpecl_25 dc parameters. ? ta b l e 2 3 : update f gclk frequency ranges. break out t gjtt by operating speed. ? ta b l e 2 7 : update f gtx frequency ranges. correct t dj to 0.17 ui, t rj to o.18 ui. ? ta b l e 3 9 : update v ref (typ) for hstl class i/ii from 1.08v to 0.90v. ? ta b l e 4 3 , ta bl e 4 4 : correct parameter name "ce input (ws)" to "sr input". ? ta b l e 6 4 : break out t dcd_clk0 by device type. 05/27/03 2.8 ? updated time and frequency parameters as per speedsfile v1.78 . ? ta b l e 3 : added values for i ref , i l , i rpu , i rpd ? corrected i ccintq ( ta bl e 4 ) and i ccintmin ( ta bl e 5 ) for xc2vp20 to 600 ma. ? ta b l e 4 : updated/added typ and max quiescent current values for xc2vp7 and xc2vp20. added footnote specifying parameters are for commercial grade parts. ? ta b l e 5 : added footnote specifying parameters are for commercial grade parts. ? ta b l e 6 : corrected v ih (max) for lvttl and lvcmos33 standards from 3.6v to 3.45v. changed v il (min) for all standards to ?0.2v. corrected v il (max) for lvcmos15 and lvcmos18 from 20% v cco to 30% v cco . ? ta b l e 1 0 : corrected lvpecl_25 min and max values for v ih and v il . added explanatory text above table. ? ta b l e 1 3 and ta bl e 1 4 (pin-pin and reg-reg performance): changed device specified from xc2vp7ff672-6 to xc2vp20ff1152-6. ? ta b l e 1 5 : updated to show devices xc2vp7 and xc2vp20 as preliminary for the -6 speed grade and production for the -5 speed grade. ? removed former table 32, standard capacitive loads. ? ta b l e 5 2 : updated t ta p t c k from 4.0 ns to 5.5 ns. ? ta b l e 5 9 : modified footnote referenced at clkfx/clkfx180 to point to the online jitter calculator. ? added figure 6 and accompanying procedure for measuring standard adjustments. 05/27/03 (cont?d) 2.8 (cont?d) ? ta b l e 1 : footnote (2) rewritten to specify ?one or more banks.? ? ta b l e 5 7 : some dcm parameters were erroneously missing from v2.8 (single-module version) due to a document compilation error. the concatenated full data sheet version was not affected. these parameters have been restored. date version revision virtex-ii pro and virtex-ii pro x platform fpgas: dc and switching characteristics r ds083 (v5.0) june 21, 2011 www.xilinx.com module 3 of 4 product specification 56 product not recommended for new designs 08/25/03 2.9 ? updated time and frequency parameters as per speedsfile v1.81 . ? ta b l e 1 : footnote (2) rewritten to specify ?one or more banks.? ? ta b l e 2 : added footnote referring to xapp659 for 3.3v i/o operation. ? ta b l e 5 3 and ta bl e 5 4 : revised test setup footnote to refer to figure 6 . previously specified a capacitive load parameter. ? ta b l e 5 7 : due to a document compilation error in v2.8, some dcm parameters were erroneously omitted from the full data sheet file (all four modules concatenated), though not from the stand-alone module 3 file. the omitted parameters have been restored. ? ta b l e 6 4 and ta bl e 6 6 : corrected parameters to expression in picoseconds, as labeled. previously expressed in nanoseconds, but labeled picoseconds. ? figure 6: added note to figure regarding termination resistors. ? ta b l e 5 : added i ccintmin for xc2vp30 device. 09/10/03 2.10 ? figure 7 : changed representation of mode pins m0, m1, and m2 indicating that they must be held to a constant dc level during and after configuration. ? ta b l e 4 9 : added footnote indicating that mode pins m0, m1, and m2 must be held to a constant dc level during and after configuration. 10/14/03 2.11 ? ta b l e 1 : deleted footnote (2), which had derated the absolute maximum t j when one or more banks operated at 3.3v. changed t j description from ?operating junction temperature? to ?maximum junction temperature?. added new footnote (2) linking to website for package thermal data. ? ta b l e 4 and ta b l e 5 : filled in power-on and quiesce nt current parameters for all devices through xc2vp70. added industrial grade multiplier specification to footnote (1) in both tables. ? in section general power supply requirements , replaced reference to answer record 11713 with reference to xapp689 regarding handling of simultaneously switching outputs (sso). ? in section i/o standard adjustment measurement methodology : - ta b l e 3 9 renamed input delay measurement methodology . added footnotes. - added new ta bl e 4 0 , output delay measurement methodology . - replaced figure 6 , generalized test setup , with new drawing. - revised and extended text describing output delay measurement procedure. ? ta b l e 5 8 : for input clock low/high pulse width, psclk and clkin, changed existing footnote (2) to new footnote (3). 11/10/03 2.12 ? ta b l e 1 : changed 3.3v absolute max v in and v ts from 3.75v to 4.05v. added footnote referring to xapp659 . ? ta b l e 4 : removed min column from table. 12/05/03 3.0 ? xc2vp2 through xc2vp70 speed grades -5, -6, and -7, and xc2vp100 speed grades -5 and -6, updated and released to production status as per speedsfile v1.83 . featured changes: - speedsfile parameter values for -7 speed grade added for devices xc2vp2-xc2vp70. - ta b l e 1 3 and ta bl e 1 4 : pin-to-pin and register-to_register performance parameter values added. - ta b l e 6 4 : new parameter t dcd_local (and footnote) replaces t dcd_clk0 . - all remaining source-synchronous parameter values added ( ta bl e 6 4 & following). date version revision virtex-ii pro and virtex-ii pro x platform fpgas: dc and switching characteristics r ds083 (v5.0) june 21, 2011 www.xilinx.com module 3 of 4 product specification 57 product not recommended for new designs 12/05/03 (cont?d) 3.0 (cont?d) ? non-speedsfile parameter values added or updated: ? ta b l e 3 : i batt . ? ta b l e 4 : for xc2vp100, i ccintq , i ccoq , and i ccauxq . ? ta b l e 5 : for xc2vp100, i ccintmin . ? ta b l e 1 7 : t cpwl and t cpwh . ? ta b l e 2 5 : added explanatory footnote to t rxlat (mgt receiver latency) max value. ? ta b l e 5 7 : added footnote (3) regarding use of clkin_divide_by_2 attribute. 02/19/04 3.1 ? updated time and frequency parameters as per speedsfile v1.85 . ? ta b l e 2 , recommended oper ating conditions : revised footnotes (4) and (6). ? ta b l e 4 , quiescent supply current : added footnote (1) and updated typical parameters. ? ta b l e 1 0 , lvpecl dc specifications : added parameter values for maximum differential input voltage (lvpecl). ? ta b l e 1 4 , register-to-register performance : removed reference to a number of designs for which test data is no longer provided. ? ta b l e 1 6 , processor clocks absolute ac characteristics : added footnote (1) referring to xapp755. ? added ta b l e 4 1 , clock distribution switching characteristics . ? revised section configuration timing, page 39 through page 41 , and jtag test access port switching characteristics, page 42 , with improved timing diagrams, parameter tables, and organization. ? ta b l e 5 0 , master/slave serial mode timing characteristics , and ta b l e 5 1 , selectmap mode write timing characteristics : added parameter f cc_startup . ? ta b l e 5 1 , selectmap mode write timing characteristics : broke out t smdcc /t smccd , data[0:7] setup/hold time, by device, and added new parameter specifications for xc2vp70 and xc2vp100 devices. ? ta b l e 5 7 , operating frequency ranges : added callouts for existing footnote (3) to the four clkin parameters. added new footnote (4) to the four clkin parameters. added new footnote (5) to clk2x, clk2x180 . added new footnote (6) to clk2x, clk2x180; clk0, clk180; and clkin (using dll outputs). 03/09/04 3.1.1 ? recompiled for back ward compatibility with acrobat 4 and above. no content changes. 04/22/04 3.2 ? ta b l e 2 , recommended oper ating conditions : corrected vttx/vtrx lower voltage limit from 1.8v to 1.6v. ? ta b l e 5 , power-on current for virtex-ii pro devices : added footnote (2) stating that listed i ccomin values apply to the entire device (all banks). ? ta b l e 4 0 , output delay measurement methodology : corrected v meas for lvttl from 1.4v to 1.65v. ? ta b l e 5 7 , operating frequency ranges : corrected clkout_freq_1x_lf_max and clkin_freq_dll_lf_max for -7 devices from 210 mhz to 270 mhz. ? ta b l e 6 5 , package skew : removed xc2vp40ff1517. 06/30/04 4.0 merged in ds110-3 (module 3 of virtex-ii pro x data sheet). this merge added numerous previously unpublished rocketio x mgt parameters . specifications in this revision are from speedsfile v1.86 . date version revision virtex-ii pro and virtex-ii pro x platform fpgas: dc and switching characteristics r ds083 (v5.0) june 21, 2011 www.xilinx.com module 3 of 4 product specification 58 product not recommended for new designs 11/17/04 4.1 ? figure 8 , figure 9 : corrected t cco / dout to refer to the falling edge of cclk. ? ta b l e 2 3 : added footnote (4) to t phase indicating an 8b/10b-type bitstream. corrected t lock from typ to max specification. additional description of ?2x oversampling? added to half-rate operation condition for f gclk , and added footnote (2) requiring use of oversampling technique s in xapp572 for serial bit rates under 1gb/s. ? ta b l e 2 5 : converted bit rate conditions for jitter parameters into four ranges. added footnote (2) requiring use of oversampling techniques in x app572 for serial bit rates under 1 gb/s. ? ta b l e 2 7 : additional description of ?2x oversampling? added to half-speed clock description for f ggtx . converted bit rate conditions for jitter parameters into four ranges. added footnotes (3) and (4) requiring use of oversampling techniques in xapp572 for serial bit rates under 1 gb/s. ? ta b l e 4 0 : changed capacitance c ref for all pci/pci-x standards from 0 pf to 10 pf. ? ta b l e 4 9 : added min/max specifications for t icck . ? section power-on power supply requirements, page 5 : added word ?monotonically? to description of v ccint ramp-on requirements. removed requirement that v ccaux must be powered on before or with v cco . 03/01/05 4.2 ? updated values in virtex-ii pro performance characteristics and virtex-ii pro switching characteristics tables, based on values extracted from speedsfile version 1.90 . ? ta b l e 1 and ta b l e 2 : corrected vccauxtx and vccauxrx to avccauxtx and avccauxrx respectively. ? ta b l e 3 : further clarified p rxtx (mgt power dissipation) by explaining measurement method in footnote (3). ? ta b l e 5 : added power-on curr ent specifications for xc2vpx70 device. ? ta b l e 2 2 : changed f gtol from 100 ppm to 350 ppm. ? ta b l e 2 2 and ta bl e 2 3 : changed t gjtt bit rate qualifiers from fixed bit rates to bit rate ranges. ? ta b l e 3 6 , ta bl e 3 8 , ta b l e 3 9 , and ta b l e 4 0 : restructured these i/o-related tables to include descriptions, as well as the actual iostandard attr ibutes (used in the xilinx ice? software) for all i/o standards. ? ta b l e 3 6 : rearranged i/o standards in a more logical order. ? ta b l e 3 7 : added parameter t rpw (minimum pulse width, sr input). ? ta b l e 3 8 : changed ?csl? to ?c ref ? to agree with figure 6 and ta b l e 4 0 . rearranged i/o standards in a more logical order. ? ta b l e 3 9 : added footnote defining equivalents for dci standards. ? ta b l e 4 0 : added footnotes (2) and (3) to pci/pci-x capacitive load (c ref ) values. ? ta b l e 4 7 : added parameter t bccs , clka to clkb setup time. ? ta b l e 5 0 : added footnote (1) indicating that f cc_serial should not exceed f cc_startup if cclk frequency is not adjustable. ? ta b l e 5 2 : t tcktdo corrected from a ?min? to a ?max? specification. 06/20/05 4.3 ? ta b l e 1 2 : added specifications for differential input impedance. date version revision virtex-ii pro and virtex-ii pro x platform fpgas: dc and switching characteristics r ds083 (v5.0) june 21, 2011 www.xilinx.com module 3 of 4 product specification 59 product not recommended for new designs notice of disclaimer the xilinx hardware fpga and cpld devices referred to herein (?products?) are subject to the terms and conditions of the xilinx limite d warranty which can be viewed at http://www.xilinx.com/warranty.htm . this limited warranty does not extend to any use of products in an application or environment that is not within the specifications stated in the xilinx data sheet. all specifications are subject to change without notice. products are not designed or intended to be fail-safe or for use in any application requiring fail-safe performance, such as life-support or safety devic es or systems, or any other application that invokes the potential risks of death, personal injury, or property or environmental damage (?critical applications?). use of products in critical applications is at the sole risk of customer, subject to applicable laws and regulations. virtex-ii pro data sheet the virtex-ii pro data sheet contains the following modules: ? virtex-ii pro and virtex-ii pro x platform fpgas: introduction and overview (module 1) ? virtex-ii pro and virtex-ii pro x platform fpgas: functional description (module 2) ? virtex-ii pro and virtex-ii pro x platform fpgas: dc and switching characteristics (module 3) ? virtex-ii pro and virtex-ii pro x platform fpgas: pinout information (module 4) 09/15/05 4.4 ? ta b l e 2 : added footnote (7) to avccauxrx for rocketio x (1.8v for all non-8b/10b-encoded data). ? ta b l e 3 : - power dissipation for 10.3125 gb/s deleted. -max i ccauxtx and i ccauxrx specifications added for virtex-ii pro. ? ta b l e 1 1 : added specification for minimum p-p differential input voltage. ? ta b l e 2 2 : -f gclk : changed high end of range to 425 mhz. -t gjtt : changed measurement units to picoseconds and added maximum specifications for two bit rate ranges. -t lock : changed measurement units to microseconds and adderd typical specification. -t phase : changed measurement units to microseconds and adderd typical and maximum specifications. ? ta b l e 2 4 : - all parameters: deleted specifications for 10.3125 gb/s. -t rjtol : added typical specifications. -t jtol , t sjtol , and t ddjtol : added typical and maximum specifications. ? ta b l e 2 6 : restructured table. total jitter parameter added. all jitter parameters respecified. ? ta b l e 2 8 : restructured table and added new specifications. 10/10/05 4.5 ? changed xc2vpx70 variable baud rate specification to fixed-rate operation at 4.25 gb/s. ? ta b l e 1 5 : removed -7 designations for xc2vpx20 and xc2vpx70 devices. 03/05/07 4.6 no changes in module 3 for this revision. 11/05/07 4.7 updated copyright notice and legal disclaimer. 06/21/11 5.0 added product not recommended for new designs banner. changed i trx typical value in ta b l e 3 . date version revision ? 2000?2011 xilinx, inc. all rights reserved. xilinx, the xilinx logo, the brand window, and other designated brands included h erein are trademarks of xilinx, inc. powerpc is a trademark of ibm corp. and is used under license. all ot her trademarks are the property of their respective owners. ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 1 product not recommended for new designs this document provides virtex?-ii pro device/package combinations, maximum i/os, an d virtex-ii pro pin defini- tions, followed by pinout tables, for these packages: ? fg256/fgg256 fine-pitch bga package ? fg456/fgg456 fine-pitch bga package ? fg676/fgg676 fine-pitch bga package ? ff672 flip-chip fine-pitch bga package ? ff896 flip-chip fine-pitch bga package ? ff1152 flip-chip fine-pitch bga package ? ff1148 flip-chip fine-pitch bga package ? ff1517 flip-chip fine-pitch bga package ? ff1704 flip-chip fine-pitch bga package ? ff1696 flip-chip fine-pitch bga package for device pinout diagrams and layout guidelines, refer to the virtex-ii pro platform fpga user guide . ascii package pinout files are also availabl e for download from the xilinx website ( www.xilinx.com ). virtex-ii pro device/package combinations and maximum i/os (1) wire-bond and flip-chip packages are available. ta b l e 1 and ta bl e 2 show the maximum number of user i/os possible in wire-bond and flip-chip packages, respectively. ? fg denotes wire-bond fine-pitch bga (1.00 mm pitch). ? fgg denotes pb-free wire-bond fine-pitch bga (1.00 mm pitch). ? ff denotes flip-chip fine-pitch bga (1.00 mm pitch) . ta bl e 3 shows the number of available i/os, the number of rocketio? (or rocketio x) multi-gigabit transceiver (mgt) pins, and the number of differential i/o pairs for each virtex-ii pro device/package combination. the number of i/os per package includes all user i/os except the fifteen control pins (cclk, done, m0, m1, m2, prog_b, pwrdwn_b, tck, tdi, tdo, tms, hswap_en, dxn, dxp, and rsvd), the nine (per transceiver) rocketio mgt pins (txp, txn, rxp, rxn, avccauxtx, avccauxrx, vttx, vtrx, and gnda), and for virtex-ii pro x devices only, the two brefclkn/ brefclkp differential clock input pairs (four pins). the virtex-ii pro x devices are highlighted in bold type. 3 0 2 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information ds083 (v5.0) june 21, 2011 product specification r 1. unless otherwise noted, "virtex-ii pro" refers to members of the virtex-ii pro and/or virtex-ii pro x families. ta b l e 1 : wire-bond packages information package (1) fg256/ fgg256 fg456/ fgg456 fg676/ fgg676 pitch (mm) 1.00 1.00 1.00 size (mm) 17 x 17 23 x 23 26 x 26 maximum i/os 140 248 412 notes: 1. wire-bond packages include fgg nnn pb-free versions. see virtex-ii pro ordering examples (module 1) . ta bl e 2 : flip-chip packages information package ff672 ff896 ff1152 ff1148 ff1517 ff1704 ff1696 pitch (mm) 1.00 1.00 1.00 1.00 1.00 1.00 1.00 size (mm) 27 x 27 31 x 31 35 x 35 35 x 35 40 x 40 42.5 x 42.5 42.5 x 42.5 maximum i/os 396 556 644 812 964 1040 1200 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 2 product not recommended for new designs ta bl e 3 : virtex-ii pro available i/os and rocketio mgt pins per device/package combination virtex-ii pro device user i/os & rocketio mgt pins virtex-ii pro package (1) fg256/ fgg256 fg456/ fgg456 fg676/ fgg456 ff672 ff896 ff1152 ff1148 ff1517 ff1704 ff1696 xc2vp2 available user i/os 140 156 -204 - - - - - - rocketio mgt pins 36 36 -36 - - - - - - differential i/o pairs 68 76 -100 - - - - - - xc2vp4 available user i/os 140 248 -348 - - - - - - rocketio mgt pins 36 36 -36 - - - - - - differential i/o pairs 68 122 -172 - - - - - - xc2vp7 available user i/os -248 - 396 396 - - - - - rocketio mgt pins -72 -7272 - - - - - differential i/o pairs -122 - 196 196 - - - - - xc2vp20 available user i/os - -404 - 556 564 - - - - rocketio mgt pins - -72 -7272 - - - - differential i/o pairs - -196 - 272 276 - - - - xc2vpx20 available user i/os - - - -552 - - - - - rocketio x mgt pins - - - -72 - - - - - differential i/o pairs - - - -270 - - - - - xc2vp30 available user i/os - -416 - 556 644 - - - - rocketio mgt pins - -72 -7272 - - - - differential i/o pairs - -202 - 272 316 - - - - xc2vp40 available user i/os - -416 - - 692 804 - - - rocketio mgt pins - -72 - -1080 - - - differential i/o pairs - -202 - - 340 396 - - - xc2vp50 available user i/os - - - - 692 812 852 - - rocketio mgt pins - - - - 1440144 - - differential i/o pairs - - - - 340 400 420 - - virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 3 product not recommended for new designs xc2vp70 available user i/os - - - - - - 964 996 - rocketio mgt pins - - - - - - 144 180 - differential i/o pairs - - - - - - 476 492 - xc2vpx70 available user i/os - - - - - - -992 - rocketio x mgt pins - - - - - - -180 - differential i/o pairs - - - - - - -490 - xc2vp100 available user i/os - - - - - - - 1040 1164 rocketio mgt pins - - - - - - -1800 differential i/o pairs - - - - - - - 512 572 notes: 1. wire-bond packages include fgg nnn pb-free versions. see virtex-ii pro ordering examples (module 1) ta bl e 3 : virtex-ii pro available i/os and rocketio mgt pins per device/package combination (continued) virtex-ii pro device user i/os & rocketio mgt pins virtex-ii pro package (1) fg256/ fgg256 fg456/ fgg456 fg676/ fgg456 ff672 ff896 ff1152 ff1148 ff1517 ff1704 ff1696 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 4 product not recommended for new designs virtex-ii pro pin definitions this section describes the pinouts for virtex-ii pro devices in the following packages: ? fg256/fgg256, fg456/fgg456, and fg676/fgg676: wire-bond fine-pitch bga of 1.00 mm pitch ? ff672, ff896, ff1148, ff1152, ff1517, ff1696, and ff1704: flip-chip fine-pitch bga of 1.00 mm pitch all of the devices supported in a particular package are pin- out-compatible and are listed in the same table (one table per package). pins that are not available for smaller devices are listed in right-hand columns. each device is split into eight i/o banks to allow for flexibility in the choice of i/o standards. global pins, including jtag, configuration, and power/ground pins, are listed at the end of each table. ta b l e 4 provides definitions for all pin types. all virtex-ii pro pinout tables are available on the distribu- tion cd-rom, or on the web (at http://www.xilinx.com ). pin definitions ta bl e 4 provides a description of each pin type listed in virtex-ii pro pinout tables. ta bl e 4 : virtex-ii pro pin definitions pin name direction description user i/o pins: io_lxxy_# input/output/ bidirectional all user i/o pins are capable of differential signalling and can implement lvds, ulvds, blvds, lvpecl, or ldt pairs. each user i/o is labeled ? io_lxxy_# ?, where: io indicates a user i/o pin. lxxy indicates a differential pair, with xx a unique pair in the bank and y = p/n for the positive and negative sides of the differential pair. # indicates the bank number (0 through 7) dual-function pins: io_lxxy_#/zzz the dual-function pins are labelled ? io_lxxy_#/ zzz ?, where " zzz" can be one of the following pins: per bank - vrp, vrn, or vref globally - gclkx(s/p), busy/dout, init_b, d0/din ? d7, rdwr_b, or cs_b these dual functions are defined in the following section: "zzz" (dual function) definitions: d0/din, d1, d2, d3, d4, d5, d6, d7 input/output ? in selectmap mode, d0 through d7 are configuration data pins. these pins become user i/os after configuration, unless the selectmap port is retained. ? in bit-serial modes, din (d0) is the single-data input. this pin becomes a user i/o after configuration. cs_b input in selectmap mode, this is the active-low chip select signal. the pin becomes a user i/o after configuration, unless the selectmap port is retained. rdwr_b input in selectmap mode, this is the active-low write enable signal. the pin becomes a user i/o after configuration, unless the selectmap port is retained. busy/dout output ? in selectmap mode, busy controls the rate at which configuration data is loaded. the pin becomes a user i/o after configuration, unless the selectmap port is retained. ? in bit-serial modes, dout provides preamble and configuration data to downstream devices in a daisy-chain. the pin becomes a user i/o after configuration. init_b bidirectional (open-drain) when low, this pin indicates that the configuration memory is being cleared. when held low, the start of configuration is delayed. during configuration, a low on this output indicates that a configuration data error has occurred. the pin becomes a user i/o after configuration. virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 5 product not recommended for new designs gclkx (s/p) input/output these are clock input pins that connect to global clock buffers. these pins become regular user i/os when not needed for clocks. these pins can be used to clock the rocketio transceiver. see the rocketio transceiver user guide for design guidelines and brefclk-specific pins, by device. vrp input this pin is for the dci voltage reference resistor of p transistor (per bank). vrn input this pin is for the dci voltage reference resistor of n transistor (per bank). v ref input these are input threshold voltage pins. they become user i/os when an external threshold voltage is not needed (per bank). dedicated pins: (1) cclk input/output configuration clock. output in master mode or input in slave mode. prog_b input active low asynchronous reset to configuration logic. this pin has a permanent weak pull-up resistor. done input/output done is a bidirectional signal with an optional internal pull-up resistor. as an output, this pin indicates completion of the configuration process. as an input, a low level on done can be configured to delay the start-up sequence. m2, m1, m0 input configuration mode selection. pin is biased by v ccaux (must be 2.5v). these pins should not connect to 3.3v unless 100 ? series resistors are used. the mode pins are not to be toggled (changed) while in operation during and after configuration. hswap_en input enable i/o pull-ups during configuration. tck input boundary scan clock. this pin is 3.3v compatible. tdi input boundary scan data input. this pin is 3.3v compatible. tdo output (open-drain) boundary scan data output. pin is open-drain and can be pulled up to 3.3v. it is recommended that the external pull-up be greater than 200 ? . there is no internal pull-up. tms input boundary scan mode select. this pin is 3.3v compatible. pwrdwn_b input (unsupported) active low power-down pin (unsupported). driving this pin low can adversely affect device operation and configuration. pwrdwn_b is internally pulled high, which is its default state. it does not require an external pull-up. other pins: dxn, dxp n/a temperature-sensing di ode pins (anode: dxp, cathode: dxn). v batt input decryptor key memory backup supply. (connect to v ccaux or gnd if battery not used.) rsvd n/a reserved pin - do not connect. v cco input power-supply pins for the output drivers (per bank). v ccaux input power-supply pins for auxiliary circuits. v ccint input power-supply pins for the internal core logic. gnd input ground. avccauxrx# input analog power supply for receive circuitry of the rocketio mgt (2.5v). avccauxtx# input analog power supply for transmit circuitry of the rocketio mgt (2.5v). brefclkn, brefclkp (2) input differential clock input that clocks the rocketio x mgts populating the same side of the chip (top or bottom). can also drive dcms for rocketio x mgt use. ta bl e 4 : virtex-ii pro pin definitions (continued) pin name direction description virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 6 product not recommended for new designs brefclk pin definiti ons (rocketio only) these dedicated clocks use the same clock inputs for all packages: for detailed information about using brefclk/brefclk2, in cluding routing considerations and pin numbers for all package types, refer to chapter 2, "digital design considerations," in the rocketio transceiver user guide . vtrxpad# input receive termination supply for the rocketio multi-gigabit transceiver (1.8v - 2.8v). vttxpad# input transmit termination supply for the rocketio multi-gigabit transceiver (1.8v - 2.8v). gnda# input ground for the analog circuitry of the rocketio multi-gigabit transceiver. rxppad# input positive differential receive port of the rocketio multi-gigabit transceiver. rxnpad# input negative differential receive port of the rocketio multi-gigabit transceiver. txppad# output positive differential transmit port of the rocketio multi-gigabit transceiver. txnpad# output negative differential transmit port of the rocketio multi-gigabit transceiver. notes: 1. all dedicated pins (jtag and c onfiguration) are powered by v ccaux (independent of the bank v cco voltage). 2. virtex-ii pro x devices xc2vpx20 and xc2vpx70 only. each brefcl k(n/p) differential clock input pair takes the place of one regular virtex-ii pro dual-function io/gclkx(s/p) pair on each side of the chip (top or bottom). for rocketio brefclk, see secti on brefclk pin definiti ons (rocketio only) immediately following. top brefclk pgclk4s bottom brefclk pgclk6p ngclk5p ngclk7s brefclk2 pgclk2s brefclk2 pgclk0p ngclk3p ngclk1s ta bl e 4 : virtex-ii pro pin definitions (continued) pin name direction description virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 7 product not recommended for new designs fg256/fgg256 fine-pitch bga package as shown in ta bl e 5 , xc2vp2 and xc2vp4 virtex-ii pro devices are available in the fg256/fgg256 fine-pitch bga package. the pins in each of these devices are identical. following this table are the fg256/fgg256 fine-pitch bga package specifications (1.00mm pitch) . ta bl e 5 : fg256/fgg256 ? xc2vp2 and xc2vp4 bank pin description pin number 0 io_l01n_0/vrp_0 c2 0 io_l01p_0/vrn_0 c3 0 io_l02n_0 b3 0 io_l02p_0 c4 0 io_l03n_0 a2 0 io_l03p_0/vref_0 a3 0 io_l06n_0 d5 0 io_l06p_0 c5 0 io_l07p_0 d6 0 io_l09n_0 e6 0 io_l09p_0/vref_0 e7 0 io_l69n_0 d7 0 io_l69p_0/vref_0 c7 0 io_l74n_0/gclk7p d8 0 io_l74p_0/gclk6s c8 0 io_l75n_0/gclk5p b8 0 io_l75p_0/gclk4s a8 1 io_l75n_1/gclk3p a9 1 io_l75p_1/gclk2s b9 1 io_l74n_1/gclk1p c9 1 io_l74p_1/gclk0s d9 1 io_l69n_1/vref_1 c10 1 io_l69p_1 d10 1 io_l09n_1/vref_1 e10 1 io_l09p_1 e11 1 io_l07n_1 d11 1 io_l06n_1 c12 1 io_l06p_1 d12 1 io_l03n_1/vref_1 a14 1 io_l03p_1 a15 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 8 product not recommended for new designs 1 io_l02n_1 c13 1 io_l02p_1 b14 1 io_l01n_1/vrp_1 c14 1 io_l01p_1/vrn_1 c15 2 io_l01n_2/vrp_2 e14 2 io_l01p_2/vrn_2 e15 2 io_l02n_2 e13 2 io_l02p_2 f12 2 io_l03n_2 f13 2 io_l03p_2 f14 2 io_l04n_2/vref_2 f15 2 io_l04p_2 f16 2 io_l06n_2 g13 2 io_l06p_2 g14 2 io_l85n_2 g15 2 io_l85p_2 g16 2 io_l86n_2 g12 2 io_l86p_2 h13 2 io_l88n_2/vref_2 h14 2 io_l88p_2 h15 2 io_l90n_2 h16 2 io_l90p_2 j16 3 io_l90n_3 j15 3 io_l90p_3 j14 3 io_l89n_3 j13 3 io_l89p_3 k12 3 io_l87n_3/vref_3 k16 3 io_l87p_3 k15 3 io_l85n_3 k14 3 io_l85p_3 k13 3 io_l06n_3 l16 3 io_l06p_3 l15 3 io_l05n_3 l14 ta bl e 5 : fg256/fgg256 ? xc2vp2 and xc2vp4 bank pin description pin number virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 9 product not recommended for new designs 3 io_l05p_3 l13 3 io_l03n_3/vref_3 l12 3 io_l03p_3 m13 3 io_l02n_3 m16 3 io_l02p_3 n16 3 io_l01n_3/vrp_3 m15 3 io_l01p_3/vrn_3 m14 4 io_l01n_4/busy/dout (1) p15 4 io_l01p_4/init_b p14 4 io_l02n_4/d0/din (1) r14 4 io_l02p_4/d1 p13 4 io_l03n_4/d2 t15 4 io_l03p_4/d3 t14 4 io_l06n_4/vrp_4 n12 4 io_l06p_4/vrn_4 p12 4 io_l07p_4/vref_4 n11 4 io_l09n_4 m11 4 io_l09p_4/vref_4 m10 4 io_l69n_4 n10 4 io_l69p_4/vref_4 p10 4 io_l74n_4/gclk3s n9 4 io_l74p_4/gclk2p p9 4 io_l75n_4/gclk1s r9 4 io_l75p_4/gclk0p t9 5 io_l75n_5/gclk7s t8 5 io_l75p_5/gclk6p r8 5 io_l74n_5/gclk5s p8 5 io_l74p_5/gclk4p n8 5 io_l69n_5/vref_5 p7 5 io_l69p_5 n7 5 io_l09n_5/vref_5 m7 5 io_l09p_5 m6 5 io_l07n_5/vref_5 n6 ta bl e 5 : fg256/fgg256 ? xc2vp2 and xc2vp4 bank pin description pin number virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 10 product not recommended for new designs 5 io_l06n_5/vrp_5 p5 5 io_l06p_5/vrn_5 n5 5 io_l03n_5/d4 t3 5 io_l03p_5/d5 t2 5 io_l02n_5/d6 p4 5 io_l02p_5/d7 r3 5 io_l01n_5/rdwr_b p3 5 io_l01p_5/cs_b p2 6 io_l01p_6/vrn_6 m3 6 io_l01n_6/vrp_6 m2 6 io_l02p_6 n1 6 io_l02n_6 m1 6 io_l03p_6 m4 6 io_l03n_6/vref_6 l5 6 io_l05p_6 l4 6 io_l05n_6 l3 6 io_l06p_6 l2 6 io_l06n_6 l1 6 io_l85p_6 k4 6 io_l85n_6 k3 6 io_l87p_6 k2 6 io_l87n_6/vref_6 k1 6 io_l89p_6 k5 6 io_l89n_6 j4 6 io_l90p_6 j3 6 io_l90n_6 j2 7 io_l90p_7 j1 7 io_l90n_7 h1 7 io_l88p_7 h2 7 io_l88n_7/vref_7 h3 7 io_l86p_7 h4 7 io_l86n_7 g5 7 io_l85p_7 g1 ta bl e 5 : fg256/fgg256 ? xc2vp2 and xc2vp4 bank pin description pin number virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 11 product not recommended for new designs 7 io_l85n_7 g2 7 io_l06p_7 g3 7 io_l06n_7 g4 7 io_l04p_7 f1 7 io_l04n_7/vref_7 f2 7 io_l03p_7 f3 7 io_l03n_7 f4 7 io_l02p_7 f5 7 io_l02n_7 e4 7 io_l01p_7/vrn_7 e2 7 io_l01n_7/vrp_7 e3 0 vcco_0 f8 0 vcco_0 f7 0 vcco_0 e8 1 vcco_1 f9 1 vcco_1 f10 1 vcco_1 e9 2 vcco_2 h12 2 vcco_2 h11 2 vcco_2 g11 3 vcco_3 k11 3 vcco_3 j12 3 vcco_3 j11 4 vcco_4 m9 4 vcco_4 l9 4 vcco_4 l10 5 vcco_5 m8 5 vcco_5 l8 5 vcco_5 l7 6 vcco_6 k6 6 vcco_6 j6 6 vcco_6 j5 7 vcco_7 h6 7 vcco_7 h5 ta bl e 5 : fg256/fgg256 ? xc2vp2 and xc2vp4 bank pin description pin number virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 12 product not recommended for new designs 7 vcco_7 g6 n/a cclk n15 n/a prog_b d1 n/a done p16 n/a m0 n3 n/a m1 n2 n/a m2 p1 n/a tck d16 n/a tdi e1 n/a tdo e16 n/a tms c16 n/a pwrdwn_b n14 n/a hswap_en c1 n/a rsvd d14 n/a vbatt d15 n/a dxp d2 n/a dxn d3 n/a avccauxtx6 b5 n/a vttxpad6 b4 n/a txnpad6 a4 n/a txppad6 a5 n/a gnda6 c6 n/a rxppad6 a6 n/a rxnpad6 a7 n/a vtrxpad6 b6 n/a avccauxrx6 b7 n/a avccauxtx7 b11 n/a vttxpad7 b10 n/a txnpad7 a10 n/a txppad7 a11 n/a gnda7 c11 n/a rxppad7 a12 n/a rxnpad7 a13 n/a vtrxpad7 b12 ta bl e 5 : fg256/fgg256 ? xc2vp2 and xc2vp4 bank pin description pin number virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 13 product not recommended for new designs n/a avccauxrx7 b13 n/a avccauxrx18 r13 n/a vtrxpad18 r12 n/a rxnpad18 t13 n/a rxppad18 t12 n/a gnda18 p11 n/a txppad18 t11 n/a txnpad18 t10 n/a vttxpad18 r10 n/a avccauxtx18 r11 n/a avccauxrx19 r7 n/a vtrxpad19 r6 n/a rxnpad19 t7 n/a rxppad19 t6 n/a gnda19 p6 n/a txppad19 t5 n/a txnpad19 t4 n/a vttxpad19 r4 n/a avccauxtx19 r5 n/a vccint n4 n/a vccint n13 n/a vccint m5 n/a vccint m12 n/a vccint e5 n/a vccint e12 n/a vccint d4 n/a vccint d13 n/a vccaux r16 n/a vccaux r1 n/a vccaux b16 n/a vccaux b1 n/a gnd t16 n/a gnd t1 n/a gnd r2 ta bl e 5 : fg256/fgg256 ? xc2vp2 and xc2vp4 bank pin description pin number virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 14 product not recommended for new designs n/a gnd r15 n/a gnd l6 n/a gnd l11 n/a gnd k9 n/a gnd k8 n/a gnd k7 n/a gnd k10 n/a gnd j9 n/a gnd j8 n/a gnd j7 n/a gnd j10 n/a gnd h9 n/a gnd h8 n/a gnd h7 n/a gnd h10 n/a gnd g9 n/a gnd g8 n/a gnd g7 n/a gnd g10 n/a gnd f6 n/a gnd f11 n/a gnd b2 n/a gnd b15 n/a gnd a16 n/a gnd a1 notes: 1. see ta b l e 4 for an explanation of the signals available on this pin. ta bl e 5 : fg256/fgg256 ? xc2vp2 and xc2vp4 bank pin description pin number virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 15 product not recommended for new designs fg256/fgg256 fine-pitch bga pack age specifications (1.00mm pitch) figure 1: fg256/fgg256 fine-pitch bga package specifications virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 16 product not recommended for new designs fg456/fgg456 fine-pitch bga package as shown in ta bl e 6 , xc2vp2, xc2vp4, and xc2vp7 virtex-ii pro device s are available in the fg456/fgg456 fine-pitch bga package. the pins in these devices are same, except for the differences shown in the "no connects" column. following this table are the fg456/fgg456 fine-pitch bga package specifications (1.00mm pitch) . ta bl e 6 : fg456/fgg456 ? xc2vp2, xc2vp4, and xc2vp7 bank pin description pin number no connects xc2vp2 xc2vp4 xc2vp7 0 io_l01n_0/vrp_0 d5 0 io_l01p_0/vrn_0 d6 0 io_l02n_0 e6 0 io_l02p_0 e7 0 io_l03n_0 d7 0 io_l03p_0/vref_0 c7 0 io_l05_0/no_pair e8 0 io_l06n_0 d8 0 io_l06p_0 c8 0 io_l07n_0 f9 0 io_l07p_0 e9 0 io_l09n_0 d9 0 io_l09p_0/vref_0 d10 0 io_l67n_0 f10 0 io_l67p_0 e10 0 io_l69n_0 c10 0 io_l69p_0/vref_0 b11 0 io_l74n_0/gclk7p f11 0 io_l74p_0/gclk6s e11 0 io_l75n_0/gclk5p d11 0 io_l75p_0/gclk4s c11 1 io_l75n_1/gclk3p c12 1 io_l75p_1/gclk2s d12 1 io_l74n_1/gclk1p e12 1 io_l74p_1/gclk0s f12 1 io_l69n_1/vref_1 b12 1 io_l69p_1 c13 1 io_l67n_1 e13 1 io_l67p_1 f13 1 io_l09n_1/vref_1 d13 1 io_l09p_1 d14 1 io_l07n_1 e14 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 17 product not recommended for new designs 1 io_l07p_1 f14 1 io_l06n_1 c15 1 io_l06p_1 d15 1 io_l05_1/no_pair e15 1 io_l03n_1/vref_1 c16 1 io_l03p_1 d16 1 io_l02n_1 e16 1 io_l02p_1 e17 1 io_l01n_1/vrp_1 d17 1 io_l01p_1/vrn_1 d18 2 io_l01n_2/vrp_2 c21 2 io_l01p_2/vrn_2 c22 2 io_l02n_2 d21 2 io_l02p_2 d22 2 io_l03n_2 e19 2 io_l03p_2 e20 2 io_l04n_2/vref_2 e21 2 io_l04p_2 e22 2 io_l06n_2 f19 2 io_l06p_2 f20 2 io_l43n_2 f21 nc 2 io_l43p_2 f22 nc 2 io_l46n_2/vref_2 f18 nc 2 io_l46p_2 g18 nc 2 io_l48n_2 g19 nc 2 io_l48p_2 g20 nc 2 io_l49n_2 g21 nc 2 io_l49p_2 g22 nc 2 io_l50n_2 h19 nc 2 io_l50p_2 h20 nc 2 io_l52n_2/vref_2 h21 nc 2 io_l52p_2 h22 nc 2 io_l54n_2 h18 nc 2 io_l54p_2 j17 nc 2 io_l55n_2 j19 nc 2 io_l55p_2 j20 nc ta bl e 6 : fg456/fgg456 ? xc2vp2, xc2vp4, and xc2vp7 bank pin description pin number no connects xc2vp2 xc2vp4 xc2vp7 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 18 product not recommended for new designs 2 io_l56n_2 j21 nc 2 io_l56p_2 j22 nc 2 io_l58n_2/vref_2 j18 nc 2 io_l58p_2 k18 nc 2 io_l60n_2 k19 nc 2 io_l60p_2 k20 nc 2 io_l85n_2 k21 2 io_l85p_2 k22 2 io_l86n_2 k17 2 io_l86p_2 l17 2 io_l88n_2/vref_2 l18 2 io_l88p_2 l19 2 io_l90n_2 l20 2 io_l90p_2 l21 3 io_l90n_3 m21 3 io_l90p_3 m20 3 io_l89n_3 m19 3 io_l89p_3 m18 3 io_l87n_3/vref_3 m17 3 io_l87p_3 n17 3 io_l85n_3 n22 3 io_l85p_3 n21 3 io_l60n_3 n20 nc 3 io_l60p_3 n19 nc 3 io_l59n_3 n18 nc 3 io_l59p_3 p18 nc 3 io_l57n_3/vref_3 p22 nc 3 io_l57p_3 p21 nc 3 io_l55n_3 p20 nc 3 io_l55p_3 p19 nc 3 io_l54n_3 p17 nc 3 io_l54p_3 r18 nc 3 io_l53n_3 r22 nc 3 io_l53p_3 r21 nc 3 io_l51n_3/vref_3 r20 nc 3 io_l51p_3 r19 nc ta bl e 6 : fg456/fgg456 ? xc2vp2, xc2vp4, and xc2vp7 bank pin description pin number no connects xc2vp2 xc2vp4 xc2vp7 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 19 product not recommended for new designs 3 io_l49n_3 t22 nc 3 io_l49p_3 t21 nc 3 io_l48n_3 t20 nc 3 io_l48p_3 t19 nc 3 io_l47n_3 t18 nc 3 io_l47p_3 u18 nc 3 io_l45n_3/vref_3 u22 nc 3 io_l45p_3 u21 nc 3 io_l43n_3 u20 nc 3 io_l43p_3 u19 nc 3 io_l06n_3 v22 3 io_l06p_3 v21 3 io_l05n_3 v20 3 io_l05p_3 v19 3 io_l03n_3/vref_3 w22 3 io_l03p_3 w21 3 io_l02n_3 y22 3 io_l02p_3 y21 3 io_l01n_3/vrp_3 aa22 3 io_l01p_3/vrn_3 ab21 4 io_l01n_4/busy/dout (1) w18 4 io_l01p_4/init_b w17 4 io_l02n_4/d0/din (1) v17 4 io_l02p_4/d1 v16 4 io_l03n_4/d2 w16 4 io_l03p_4/d3 y16 4 io_l05_4/no_pair v15 4 io_l06n_4/vrp_4 w15 4 io_l06p_4/vrn_4 y15 4 io_l07n_4 u14 4 io_l07p_4/vref_4 v14 4 io_l09n_4 w14 4 io_l09p_4/vref_4 w13 4 io_l67n_4 u13 4 io_l67p_4 v13 4 io_l69n_4 y13 ta bl e 6 : fg456/fgg456 ? xc2vp2, xc2vp4, and xc2vp7 bank pin description pin number no connects xc2vp2 xc2vp4 xc2vp7 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 20 product not recommended for new designs 4 io_l69p_4/vref_4 aa12 4 io_l74n_4/gclk3s u12 4 io_l74p_4/gclk2p v12 4 io_l75n_4/gclk1s w12 4 io_l75p_4/gclk0p y12 5 io_l75n_5/gclk7s y11 5 io_l75p_5/gclk6p w11 5 io_l74n_5/gclk5s v11 5 io_l74p_5/gclk4p u11 5 io_l69n_5/vref_5 aa11 5 io_l69p_5 y10 5 io_l67n_5 v10 5 io_l67p_5 u10 5 io_l09n_5/vref_5 w10 5 io_l09p_5 w9 5 io_l07n_5/vref_5 v9 5 io_l07p_5 u9 5 io_l06n_5/vrp_5 y8 5 io_l06p_5/vrn_5 w8 5 io_l05_5/no_pair v8 5 io_l03n_5/d4 y7 5 io_l03p_5/d5 w7 5 io_l02n_5/d6 v7 5 io_l02p_5/d7 v6 5 io_l01n_5/rdwr_b w6 5 io_l01p_5/cs_b w5 6 io_l01p_6/vrn_6 ab2 6 io_l01n_6/vrp_6 aa1 6 io_l02p_6 y2 6 io_l02n_6 y1 6 io_l03p_6 w2 6 io_l03n_6/vref_6 w1 6 io_l05p_6 v4 6 io_l05n_6 v3 6 io_l06p_6 v2 ta bl e 6 : fg456/fgg456 ? xc2vp2, xc2vp4, and xc2vp7 bank pin description pin number no connects xc2vp2 xc2vp4 xc2vp7 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 21 product not recommended for new designs 6 io_l06n_6 v1 6 io_l43p_6 u4 nc 6 io_l43n_6 u3 nc 6 io_l45p_6 u2 nc 6 io_l45n_6/vref_6 u1 nc 6 io_l47p_6 u5 nc 6 io_l47n_6 t5 nc 6 io_l48p_6 t4 nc 6 io_l48n_6 t3 nc 6 io_l49p_6 t2 nc 6 io_l49n_6 t1 nc 6 io_l51p_6 r4 nc 6 io_l51n_6/vref_6 r3 nc 6 io_l53p_6 r2 nc 6 io_l53n_6 r1 nc 6 io_l54p_6 r5 nc 6 io_l54n_6 p6 nc 6 io_l55p_6 p4 nc 6 io_l55n_6 p3 nc 6 io_l57p_6 p2 nc 6 io_l57n_6/vref_6 p1 nc 6 io_l59p_6 p5 nc 6 io_l59n_6 n5 nc 6 io_l60p_6 n4 nc 6 io_l60n_6 n3 nc 6 io_l85p_6 n2 6 io_l85n_6 n1 6 io_l87p_6 n6 6 io_l87n_6/vref_6 m6 6 io_l89p_6 m5 6 io_l89n_6 m4 6 io_l90p_6 m3 6 io_l90n_6 m2 7 io_l90p_7 l2 7 io_l90n_7 l3 7 io_l88p_7 l4 ta bl e 6 : fg456/fgg456 ? xc2vp2, xc2vp4, and xc2vp7 bank pin description pin number no connects xc2vp2 xc2vp4 xc2vp7 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 22 product not recommended for new designs 7 io_l88n_7/vref_7 l5 7 io_l86p_7 l6 7 io_l86n_7 k6 7 io_l85p_7 k1 7 io_l85n_7 k2 7 io_l60p_7 k3 nc 7 io_l60n_7 k4 nc 7 io_l58p_7 k5 nc 7 io_l58n_7/vref_7 j5 nc 7 io_l56p_7 j1 nc 7 io_l56n_7 j2 nc 7 io_l55p_7 j3 nc 7 io_l55n_7 j4 nc 7 io_l54p_7 j6 nc 7 io_l54n_7 h5 nc 7 io_l52p_7 h1 nc 7 io_l52n_7/vref_7 h2 nc 7 io_l50p_7 h3 nc 7 io_l50n_7 h4 nc 7 io_l49p_7 g1 nc 7 io_l49n_7 g2 nc 7 io_l48p_7 g3 nc 7 io_l48n_7 g4 nc 7 io_l46p_7 g5 nc 7 io_l46n_7/vref_7 f5 nc 7 io_l43p_7 f1 nc 7 io_l43n_7 f2 nc 7 io_l06p_7 f3 7 io_l06n_7 f4 7 io_l04p_7 e1 7 io_l04n_7/vref_7 e2 7 io_l03p_7 e3 7 io_l03n_7 e4 7 io_l02p_7 d1 7 io_l02n_7 d2 7 io_l01p_7/vrn_7 c1 7 io_l01n_7/vrp_7 c2 ta bl e 6 : fg456/fgg456 ? xc2vp2, xc2vp4, and xc2vp7 bank pin description pin number no connects xc2vp2 xc2vp4 xc2vp7 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 23 product not recommended for new designs 0 vcco_0 g9 0 vcco_0 g11 0 vcco_0 g10 0 vcco_0 f8 0 vcco_0 f7 1 vcco_1 g14 1 vcco_1 g13 1 vcco_1 g12 1 vcco_1 f16 1 vcco_1 f15 2 vcco_2 l16 2 vcco_2 k16 2 vcco_2 j16 2 vcco_2 h17 2 vcco_2 g17 3 vcco_3 t17 3 vcco_3 r17 3 vcco_3 p16 3 vcco_3 n16 3 vcco_3 m16 4 vcco_4 u16 4 vcco_4 u15 4 vcco_4 t14 4 vcco_4 t13 4 vcco_4 t12 5 vcco_5 u8 5 vcco_5 u7 5 vcco_5 t9 5 vcco_5 t11 5 vcco_5 t10 6 vcco_6 t6 6 vcco_6 r6 6 vcco_6 p7 6 vcco_6 n7 6 vcco_6 m7 7 vcco_7 l7 ta bl e 6 : fg456/fgg456 ? xc2vp2, xc2vp4, and xc2vp7 bank pin description pin number no connects xc2vp2 xc2vp4 xc2vp7 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 24 product not recommended for new designs 7 vcco_7 k7 7 vcco_7 j7 7 vcco_7 h6 7 vcco_7 g6 n/a cclk w20 n/a prog_b b1 n/a done y18 n/a m0 y4 n/a m1 w3 n/a m2 y5 n/a tck b22 n/a tdi d3 n/a tdo d20 n/a tms a21 n/a pwrdwn_b y19 n/a hswap_en a2 n/a rsvd c18 n/a vbatt c19 n/a dxp c4 n/a dxn c5 n/a avccauxtx4 b4 nc nc n/a vttxpad4 b3 nc nc n/a txnpad4 a3 nc nc n/a txppad4 a4 nc nc n/a gnda4 c6 nc nc n/a rxppad4 a5 nc nc n/a rxnpad4 a6 nc nc n/a vtrxpad4 b5 nc nc n/a avccauxrx4 b6 nc nc n/a avccauxtx6 b8 n/a vttxpad6 b7 n/a txnpad6 a7 n/a txppad6 a8 n/a gnda6 c9 n/a rxppad6 a9 n/a rxnpad6 a10 ta bl e 6 : fg456/fgg456 ? xc2vp2, xc2vp4, and xc2vp7 bank pin description pin number no connects xc2vp2 xc2vp4 xc2vp7 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 25 product not recommended for new designs n/a vtrxpad6 b9 n/a avccauxrx6 b10 n/a avccauxtx7 b14 n/a vttxpad7 b13 n/a txnpad7 a13 n/a txppad7 a14 n/a gnda7 c14 n/a rxppad7 a15 n/a rxnpad7 a16 n/a vtrxpad7 b15 n/a avccauxrx7 b16 n/a avccauxtx9 b18 nc nc n/a vttxpad9 b17 nc nc n/a txnpad9 a17 nc nc n/a txppad9 a18 nc nc n/a gnda9 c17 nc nc n/a rxppad9 a19 nc nc n/a rxnpad9 a20 nc nc n/a vtrxpad9 b19 nc nc n/a avccauxrx9 b20 nc nc n/a avccauxrx16 aa20 nc nc n/a vtrxpad16 aa19 nc nc n/a rxnpad16 ab20 nc nc n/a rxppad16 ab19 nc nc n/a gnda16 y17 nc nc n/a txppad16 ab18 nc nc n/a txnpad16 ab17 nc nc n/a vttxpad16 aa17 nc nc n/a avccauxtx16 aa18 nc nc n/a avccauxrx18 aa16 n/a vtrxpad18 aa15 n/a rxnpad18 ab16 n/a rxppad18 ab15 n/a gnda18 y14 n/a txppad18 ab14 n/a txnpad18 ab13 n/a vttxpad18 aa13 ta bl e 6 : fg456/fgg456 ? xc2vp2, xc2vp4, and xc2vp7 bank pin description pin number no connects xc2vp2 xc2vp4 xc2vp7 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 26 product not recommended for new designs n/a avccauxtx18 aa14 n/a avccauxrx19 aa10 n/a vtrxpad19 aa9 n/a rxnpad19 ab10 n/a rxppad19 ab9 n/a gnda19 y9 n/a txppad19 ab8 n/a txnpad19 ab7 n/a vttxpad19 aa7 n/a avccauxtx19 aa8 n/a avccauxrx21 aa6 nc nc n/a vtrxpad21 aa5 nc nc n/a rxnpad21 ab6 nc nc n/a rxppad21 ab5 nc nc n/a gnda21 y6 nc nc n/a txppad21 ab4 nc nc n/a txnpad21 ab3 nc nc n/a vttxpad21 aa3 nc nc n/a avccauxtx21 aa4 nc nc n/a vccint u6 n/a vccint u17 n/a vccint t8 n/a vccint t7 n/a vccint t16 n/a vccint t15 n/a vccint r7 n/a vccint r16 n/a vccint h7 n/a vccint h16 n/a vccint g8 n/a vccint g7 n/a vccint g16 n/a vccint g15 n/a vccint f6 n/a vccint f17 n/a vccaux m22 ta bl e 6 : fg456/fgg456 ? xc2vp2, xc2vp4, and xc2vp7 bank pin description pin number no connects xc2vp2 xc2vp4 xc2vp7 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 27 product not recommended for new designs n/a vccaux l1 n/a vccaux b21 n/a vccaux b2 n/a vccaux ab11 n/a vccaux aa21 n/a vccaux aa2 n/a vccaux a12 n/a gnd y3 n/a gnd y20 n/a gnd w4 n/a gnd w19 n/a gnd v5 n/a gnd v18 n/a gnd p9 n/a gnd p14 n/a gnd p13 n/a gnd p12 n/a gnd p11 n/a gnd p10 n/a gnd n9 n/a gnd n14 n/a gnd n13 n/a gnd n12 n/a gnd n11 n/a gnd n10 n/a gnd m9 n/a gnd m14 n/a gnd m13 n/a gnd m12 n/a gnd m11 n/a gnd m10 n/a gnd m1 n/a gnd l9 n/a gnd l22 n/a gnd l14 n/a gnd l13 n/a gnd l12 ta bl e 6 : fg456/fgg456 ? xc2vp2, xc2vp4, and xc2vp7 bank pin description pin number no connects xc2vp2 xc2vp4 xc2vp7 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 28 product not recommended for new designs n/a gnd l11 n/a gnd l10 n/a gnd k9 n/a gnd k14 n/a gnd k13 n/a gnd k12 n/a gnd k11 n/a gnd k10 n/a gnd j9 n/a gnd j14 n/a gnd j13 n/a gnd j12 n/a gnd j11 n/a gnd j10 n/a gnd e5 n/a gnd e18 n/a gnd d4 n/a gnd d19 n/a gnd c3 n/a gnd c20 n/a gnd ab22 n/a gnd ab12 n/a gnd ab1 n/a gnd a22 n/a gnd a11 n/a gnd a1 notes: 1. see ta b l e 4 for an explanation of the signals available on this pin. ta bl e 6 : fg456/fgg456 ? xc2vp2, xc2vp4, and xc2vp7 bank pin description pin number no connects xc2vp2 xc2vp4 xc2vp7 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 29 product not recommended for new designs fg456/fgg456 fine-pitch bga pack age specifications (1.00mm pitch) figure 2: fg456/fgg456 fine-pitch bga package specifications virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 30 product not recommended for new designs fg676/fgg676 fine-pitch bga package as shown in ta b l e 7 , xc2vp20, xc2vp30, and xc2vp40 virtex-ii pro devices are available in the fg676/fgg676 fine-pitch bga package. the pins in these devices are the same, except for the differences shown in the "no connects" column. following this table are the fg676/fgg676 fine-pitch bga package specifications (1.00mm pitch) . ta bl e 7 : fg676/fgg676 ? xc2vp20, xc2vp30, and xc2vp40 bank pin description pin number no connects xc2vp20 xc2vp30 xc2vp40 0 io_l01n_0/vrp_0 e5 0 io_l01p_0/vrn_0 d5 0 io_l02n_0 e6 0 io_l02p_0 d6 0 io_l03n_0 g7 0 io_l03p_0/vref_0 f7 0 io_l05_0/no_pair e7 0 io_l06n_0 d7 0 io_l06p_0 c7 0 io_l07n_0 h8 0 io_l07p_0 g8 0 io_l09n_0 f8 0 io_l09p_0/vref_0 e8 0 io_l37n_0 b8 0 io_l37p_0 a8 0 io_l39n_0 h9 0 io_l39p_0 g9 0 io_l43n_0 f9 0 io_l43p_0 e9 0 io_l45n_0 d9 0 io_l45p_0/vref_0 c9 0 io_l46n_0 h10 0 io_l46p_0 h11 0 io_l48n_0 e10 0 io_l48p_0 e11 0 io_l49n_0 d10 0 io_l49p_0 c10 0 io_l50_0/no_pair g11 0 io_l53_0/no_pair f11 0 io_l54n_0 j12 0 io_l54p_0 h12 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 31 product not recommended for new designs 0 io_l55n_0 g12 0 io_l55p_0 f12 0 io_l57n_0 e12 0 io_l57p_0/vref_0 f13 0 io_l67n_0 d12 0 io_l67p_0 c12 0 io_l69n_0 j13 0 io_l69p_0/vref_0 h13 0 io_l74n_0/gclk7p e13 0 io_l74p_0/gclk6s d13 0 io_l75n_0/gclk5p c13 0 io_l75p_0/gclk4s b13 1 io_l75n_1/gclk3p b14 1 io_l75p_1/gclk2s c14 1 io_l74n_1/gclk1p d14 1 io_l74p_1/gclk0s e14 1 io_l69n_1/vref_1 h14 1 io_l69p_1 j14 1 io_l67n_1 c15 1 io_l67p_1 d15 1 io_l57n_1/vref_1 f14 1 io_l57p_1 e15 1 io_l55n_1 f15 1 io_l55p_1 g15 1 io_l54n_1 h15 1 io_l54p_1 j15 1 io_l53_1/no_pair f16 1 io_l50_1/no_pair g16 1 io_l49n_1 c17 1 io_l49p_1 d17 1 io_l48n_1 e16 1 io_l48p_1 e17 1 io_l46n_1 h16 1 io_l46p_1 h17 ta bl e 7 : fg676/fgg676 ? xc2vp20, xc2vp30, and xc2vp40 bank pin description pin number no connects xc2vp20 xc2vp30 xc2vp40 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 32 product not recommended for new designs 1 io_l45n_1/vref_1 c18 1 io_l45p_1 d18 1 io_l43n_1 e18 1 io_l43p_1 f18 1 io_l39n_1 g18 1 io_l39p_1 h18 1 io_l37n_1 a19 1 io_l37p_1 b19 1 io_l09n_1/vref_1 e19 1 io_l09p_1 f19 1 io_l07n_1 g19 1 io_l07p_1 h19 1 io_l06n_1 c20 1 io_l06p_1 d20 1 io_l05_1/no_pair e20 1 io_l03n_1/vref_1 f20 1 io_l03p_1 g20 1 io_l02n_1 d21 1 io_l02p_1 e21 1 io_l01n_1/vrp_1 d22 1 io_l01p_1/vrn_1 e22 2 io_l01n_2/vrp_2 c25 2 io_l01p_2/vrn_2 c26 2 io_l02n_2 d25 2 io_l02p_2 d26 2 io_l03n_2 e23 2 io_l03p_2 f22 2 io_l04n_2/vref_2 e25 2 io_l04p_2 e26 2 io_l06n_2 f21 2 io_l06p_2 g21 2 io_l24n_2 f23 nc 2 io_l24p_2 f24 nc 2 io_l31n_2 f25 ta bl e 7 : fg676/fgg676 ? xc2vp20, xc2vp30, and xc2vp40 bank pin description pin number no connects xc2vp20 xc2vp30 xc2vp40 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 33 product not recommended for new designs 2 io_l31p_2 f26 2 io_l32n_2 g22 2 io_l32p_2 h22 2 io_l34n_2/vref_2 g23 2 io_l34p_2 g24 2 io_l36n_2 g25 2 io_l36p_2 g26 2 io_l37n_2 h20 2 io_l37p_2 h21 2 io_l38n_2 h25 2 io_l38p_2 h26 2 io_l40n_2/vref_2 j19 2 io_l40p_2 j20 2 io_l42n_2 j21 2 io_l42p_2 j22 2 io_l43n_2 j23 2 io_l43p_2 j24 2 io_l44n_2 j25 2 io_l44p_2 j26 2 io_l46n_2/vref_2 k19 2 io_l46p_2 l19 2 io_l48n_2 k22 2 io_l48p_2 k23 2 io_l49n_2 k24 2 io_l49p_2 l24 2 io_l50n_2 k25 2 io_l50p_2 k26 2 io_l52n_2/vref_2 l20 2 io_l52p_2 m20 2 io_l54n_2 l21 2 io_l54p_2 l22 2 io_l55n_2 l25 2 io_l55p_2 l26 2 io_l56n_2 m18 2 io_l56p_2 m19 ta bl e 7 : fg676/fgg676 ? xc2vp20, xc2vp30, and xc2vp40 bank pin description pin number no connects xc2vp20 xc2vp30 xc2vp40 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 34 product not recommended for new designs 2 io_l58n_2/vref_2 m21 2 io_l58p_2 n21 2 io_l60n_2 m22 2 io_l60p_2 m23 2 io_l85n_2 m25 2 io_l85p_2 m26 2 io_l86n_2 n18 2 io_l86p_2 n19 2 io_l88n_2/vref_2 n22 2 io_l88p_2 n23 2 io_l90n_2 n24 2 io_l90p_2 n25 3 io_l90n_3 p25 3 io_l90p_3 p24 3 io_l89n_3 p23 3 io_l89p_3 p22 3 io_l87n_3/vref_3 p19 3 io_l87p_3 p18 3 io_l85n_3 r26 3 io_l85p_3 r25 3 io_l60n_3 r23 3 io_l60p_3 r22 3 io_l59n_3 p21 3 io_l59p_3 r21 3 io_l57n_3/vref_3 r19 3 io_l57p_3 r18 3 io_l55n_3 t26 3 io_l55p_3 t25 3 io_l54n_3 t22 3 io_l54p_3 t21 3 io_l53n_3 r20 3 io_l53p_3 t20 3 io_l51n_3/vref_3 u26 3 io_l51p_3 u25 ta bl e 7 : fg676/fgg676 ? xc2vp20, xc2vp30, and xc2vp40 bank pin description pin number no connects xc2vp20 xc2vp30 xc2vp40 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 35 product not recommended for new designs 3 io_l49n_3 t24 3 io_l49p_3 u24 3 io_l48n_3 u23 3 io_l48p_3 u22 3 io_l47n_3 t19 3 io_l47p_3 u19 3 io_l45n_3/vref_3 v26 3 io_l45p_3 v25 3 io_l43n_3 v24 3 io_l43p_3 v23 3 io_l42n_3 v22 3 io_l42p_3 v21 3 io_l41n_3 v20 3 io_l41p_3 v19 3 io_l39n_3/vref_3 w26 3 io_l39p_3 w25 3 io_l37n_3 w21 3 io_l37p_3 w20 3 io_l36n_3 y26 3 io_l36p_3 y25 3 io_l35n_3 y24 3 io_l35p_3 y23 3 io_l33n_3/vref_3 w22 3 io_l33p_3 y22 3 io_l31n_3 aa26 3 io_l31p_3 aa25 3 io_l24n_3 aa24 nc 3 io_l24p_3 aa23 nc 3 io_l23n_3 y21 nc 3 io_l23p_3 aa21 nc 3 io_l06n_3 ab26 3 io_l06p_3 ab25 3 io_l05n_3 aa22 3 io_l05p_3 ab23 3 io_l03n_3/vref_3 ac26 ta bl e 7 : fg676/fgg676 ? xc2vp20, xc2vp30, and xc2vp40 bank pin description pin number no connects xc2vp20 xc2vp30 xc2vp40 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 36 product not recommended for new designs 3 io_l03p_3 ac25 3 io_l02n_3 ac24 3 io_l02p_3 ad25 3 io_l01n_3/vrp_3 ad26 3 io_l01p_3/vrn_3 ae26 4 io_l01n_4/busy/dout (1) ab22 4 io_l01p_4/init_b ac22 4 io_l02n_4/d0/din (1) ab21 4 io_l02p_4/d1 ac21 4 io_l03n_4/d2 y20 4 io_l03p_4/d3 aa20 4 io_l05_4/no_pair ab20 4 io_l06n_4/vrp_4 ac20 4 io_l06p_4/vrn_4 ad20 4 io_l07n_4 w19 4 io_l07p_4/vref_4 y19 4 io_l09n_4 aa19 4 io_l09p_4/vref_4 ab19 4 io_l37n_4 ae19 4 io_l37p_4 af19 4 io_l39n_4 w18 4 io_l39p_4 y18 4 io_l43n_4 aa18 4 io_l43p_4 ab18 4 io_l45n_4 ac18 4 io_l45p_4/vref_4 ad18 4 io_l46n_4 w17 4 io_l46p_4 w16 4 io_l48n_4 ab17 4 io_l48p_4 ab16 4 io_l49n_4 ac17 4 io_l49p_4 ad17 4 io_l50_4/no_pair y16 4 io_l53_4/no_pair aa16 ta bl e 7 : fg676/fgg676 ? xc2vp20, xc2vp30, and xc2vp40 bank pin description pin number no connects xc2vp20 xc2vp30 xc2vp40 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 37 product not recommended for new designs 4 io_l54n_4 v15 4 io_l54p_4 w15 4 io_l55n_4 y15 4 io_l55p_4 aa15 4 io_l57n_4 ab15 4 io_l57p_4/vref_4 aa14 4 io_l67n_4 ac15 4 io_l67p_4 ad15 4 io_l69n_4 v14 4 io_l69p_4/vref_4 w14 4 io_l74n_4/gclk3s ab14 4 io_l74p_4/gclk2p ac14 4 io_l75n_4/gclk1s ad14 4 io_l75p_4/gclk0p ae14 5 io_l75n_5/gclk7s ae13 5 io_l75p_5/gclk6p ad13 5 io_l74n_5/gclk5s ac13 5 io_l74p_5/gclk4p ab13 5 io_l69n_5/vref_5 w13 5 io_l69p_5 v13 5 io_l67n_5 ad12 5 io_l67p_5 ac12 5 io_l57n_5/vref_5 aa13 5 io_l57p_5 ab12 5 io_l55n_5 aa12 5 io_l55p_5 y12 5 io_l54n_5 w12 5 io_l54p_5 v12 5 io_l53_5/no_pair aa11 5 io_l50_5/no_pair y11 5 io_l49n_5 ad10 5 io_l49p_5 ac10 5 io_l48n_5 ab11 5 io_l48p_5 ab10 ta bl e 7 : fg676/fgg676 ? xc2vp20, xc2vp30, and xc2vp40 bank pin description pin number no connects xc2vp20 xc2vp30 xc2vp40 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 38 product not recommended for new designs 5 io_l46n_5 w11 5 io_l46p_5 w10 5 io_l45n_5/vref_5 ad9 5 io_l45p_5 ac9 5 io_l43n_5 ab9 5 io_l43p_5 aa9 5 io_l39n_5 y9 5 io_l39p_5 w9 5 io_l37n_5 af8 5 io_l37p_5 ae8 5 io_l09n_5/vref_5 ab8 5 io_l09p_5 aa8 5 io_l07n_5/vref_5 y8 5 io_l07p_5 w8 5 io_l06n_5/vrp_5 ad7 5 io_l06p_5/vrn_5 ac7 5 io_l05_5/no_pair ab7 5 io_l03n_5/d4 aa7 5 io_l03p_5/d5 y7 5 io_l02n_5/d6 ac6 5 io_l02p_5/d7 ab6 5 io_l01n_5/rdwr_b ac5 5 io_l01p_5/cs_b ab5 6 io_l01p_6/vrn_6 ae1 6 io_l01n_6/vrp_6 ad1 6 io_l02p_6 ad2 6 io_l02n_6 ac3 6 io_l03p_6 ac2 6 io_l03n_6/vref_6 ac1 6 io_l05p_6 ab4 6 io_l05n_6 aa5 6 io_l06p_6 ab2 6 io_l06n_6 ab1 6 io_l23p_6 aa6 nc ta bl e 7 : fg676/fgg676 ? xc2vp20, xc2vp30, and xc2vp40 bank pin description pin number no connects xc2vp20 xc2vp30 xc2vp40 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 39 product not recommended for new designs 6 io_l23n_6 y6 nc 6 io_l24p_6 aa4 nc 6 io_l24n_6 aa3 nc 6 io_l31p_6 aa2 6 io_l31n_6 aa1 6 io_l33p_6 y5 6 io_l33n_6/vref_6 w5 6 io_l35p_6 y4 6 io_l35n_6 y3 6 io_l36p_6 y2 6 io_l36n_6 y1 6 io_l37p_6 w7 6 io_l37n_6 w6 6 io_l39p_6 w2 6 io_l39n_6/vref_6 w1 6 io_l41p_6 v8 6 io_l41n_6 v7 6 io_l42p_6 v6 6 io_l42n_6 v5 6 io_l43p_6 v4 6 io_l43n_6 v3 6 io_l45p_6 v2 6 io_l45n_6/vref_6 v1 6 io_l47p_6 u8 6 io_l47n_6 t8 6 io_l48p_6 u5 6 io_l48n_6 u4 6 io_l49p_6 u3 6 io_l49n_6 t3 6 io_l51p_6 u2 6 io_l51n_6/vref_6 u1 6 io_l53p_6 t7 6 io_l53n_6 r7 6 io_l54p_6 t6 6 io_l54n_6 t5 ta bl e 7 : fg676/fgg676 ? xc2vp20, xc2vp30, and xc2vp40 bank pin description pin number no connects xc2vp20 xc2vp30 xc2vp40 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 40 product not recommended for new designs 6 io_l55p_6 t2 6 io_l55n_6 t1 6 io_l57p_6 r9 6 io_l57n_6/vref_6 r8 6 io_l59p_6 r6 6 io_l59n_6 p6 6 io_l60p_6 r5 6 io_l60n_6 r4 6 io_l85p_6 r2 6 io_l85n_6 r1 6 io_l87p_6 p9 6 io_l87n_6/vref_6 p8 6 io_l89p_6 p5 6 io_l89n_6 p4 6 io_l90p_6 p3 6 io_l90n_6 p2 7 io_l90p_7 n2 7 io_l90n_7 n3 7 io_l88p_7 n4 7 io_l88n_7/vref_7 n5 7 io_l86p_7 n8 7 io_l86n_7 n9 7 io_l85p_7 m1 7 io_l85n_7 m2 7 io_l60p_7 m4 7 io_l60n_7 m5 7 io_l58p_7 n6 7 io_l58n_7/vref_7 m6 7 io_l56p_7 m8 7 io_l56n_7 m9 7 io_l55p_7 l1 7 io_l55n_7 l2 7 io_l54p_7 l5 7 io_l54n_7 l6 ta bl e 7 : fg676/fgg676 ? xc2vp20, xc2vp30, and xc2vp40 bank pin description pin number no connects xc2vp20 xc2vp30 xc2vp40 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 41 product not recommended for new designs 7 io_l52p_7 m7 7 io_l52n_7/vref_7 l7 7 io_l50p_7 k1 7 io_l50n_7 k2 7 io_l49p_7 l3 7 io_l49n_7 k3 7 io_l48p_7 k4 7 io_l48n_7 k5 7 io_l46p_7 l8 7 io_l46n_7/vref_7 k8 7 io_l44p_7 j1 7 io_l44n_7 j2 7 io_l43p_7 j3 7 io_l43n_7 j4 7 io_l42p_7 j5 7 io_l42n_7 j6 7 io_l40p_7 j7 7 io_l40n_7/vref_7 j8 7 io_l38p_7 h1 7 io_l38n_7 h2 7 io_l37p_7 h6 7 io_l37n_7 h7 7 io_l36p_7 g1 7 io_l36n_7 g2 7 io_l34p_7 g3 7 io_l34n_7/vref_7 g4 7 io_l32p_7 h5 7 io_l32n_7 g5 7 io_l31p_7 f1 7 io_l31n_7 f2 7 io_l24p_7 f3 nc 7 io_l24n_7 f4 nc 7 io_l06p_7 g6 7 io_l06n_7 f6 7 io_l04p_7 e1 ta bl e 7 : fg676/fgg676 ? xc2vp20, xc2vp30, and xc2vp40 bank pin description pin number no connects xc2vp20 xc2vp30 xc2vp40 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 42 product not recommended for new designs 7 io_l04n_7/vref_7 e2 7 io_l03p_7 f5 7 io_l03n_7 e4 7 io_l02p_7 d1 7 io_l02n_7 d2 7 io_l01p_7/vrn_7 c1 7 io_l01n_7/vrp_7 c2 0vcco_0 c5 0vcco_0 c8 0vcco_0 d11 0vcco_0 j10 0vcco_0 j11 0vcco_0 k12 0vcco_0 k13 1vcco_1 c19 1vcco_1 c22 1vcco_1 d16 1vcco_1 j16 1vcco_1 j17 1vcco_1 k14 1vcco_1 k15 2vcco_2 e24 2vcco_2 h24 2vcco_2 k18 2vcco_2 l18 2vcco_2 l23 2vcco_2 m17 2vcco_2 n17 3vcco_3 p17 3vcco_3 r17 3vcco_3 t18 3vcco_3 t23 3vcco_3 u18 3vcco_3 w24 ta bl e 7 : fg676/fgg676 ? xc2vp20, xc2vp30, and xc2vp40 bank pin description pin number no connects xc2vp20 xc2vp30 xc2vp40 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 43 product not recommended for new designs 3 vcco_3 ab24 4vcco_4 u14 4vcco_4 u15 4vcco_4 v16 4vcco_4 v17 4vcco_4 ac16 4 vcco_4 ad19 4 vcco_4 ad22 5vcco_5 u12 5vcco_5 u13 5vcco_5 v10 5vcco_5 v11 5vcco_5 ac11 5vcco_5 ad5 5vcco_5 ad8 6vcco_6 p10 6vcco_6 r10 6vcco_6 t4 6vcco_6 t9 6vcco_6 u9 6vcco_6 w3 6 vcco_6 ab3 7vcco_7 e3 7vcco_7 h3 7vcco_7 k9 7vcco_7 l4 7vcco_7 l9 7vcco_7 m10 7vcco_7 n10 n/a prog_b b1 n/a hswap_en b3 n/a dxp a3 n/a dxn c4 n/a avccauxtx4 b5 ta bl e 7 : fg676/fgg676 ? xc2vp20, xc2vp30, and xc2vp40 bank pin description pin number no connects xc2vp20 xc2vp30 xc2vp40 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 44 product not recommended for new designs n/a vttxpad4 b4 n/a txnpad4 a4 n/a txppad4 a5 n/a gnda4 c6 n/a rxppad4 a6 n/a rxnpad4 a7 n/a vtrxpad4 b6 n/a avccauxrx4 b7 n/a avccauxtx6 b10 n/a vttxpad6 b9 n/a txnpad6 a9 n/a txppad6 a10 n/a gnda6 c11 n/a rxppad6 a11 n/a rxnpad6 a12 n/a vtrxpad6 b11 n/a avccauxrx6 b12 n/a avccauxtx7 b16 n/a vttxpad7 b15 n/a txnpad7 a15 n/a txppad7 a16 n/a gnda7 c16 n/a rxppad7 a17 n/a rxnpad7 a18 n/a vtrxpad7 b17 n/a avccauxrx7 b18 n/a avccauxtx9 b21 n/a vttxpad9 b20 n/a txnpad9 a20 n/a txppad9 a21 n/a gnda9 c21 n/a rxppad9 a22 n/a rxnpad9 a23 n/a vtrxpad9 b22 n/a avccauxrx9 b23 ta bl e 7 : fg676/fgg676 ? xc2vp20, xc2vp30, and xc2vp40 bank pin description pin number no connects xc2vp20 xc2vp30 xc2vp40 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 45 product not recommended for new designs n/a rsvd c23 n/a vbatt a24 n/a tms b24 n/a tck b26 n/a tdo d24 n/a cclk ae24 n/a pwrdwn_b af24 n/a done ad23 n/a avccauxrx16 ae23 n/a vtrxpad16 ae22 n/a rxnpad16 af23 n/a rxppad16 af22 n/a gnda16 ad21 n/a txppad16 af21 n/a txnpad16 af20 n/a vttxpad16 ae20 n/a avccauxtx16 ae21 n/a avccauxrx18 ae18 n/a vtrxpad18 ae17 n/a rxnpad18 af18 n/a rxppad18 af17 n/a gnda18 ad16 n/a txppad18 af16 n/a txnpad18 af15 n/a vttxpad18 ae15 n/a avccauxtx18 ae16 n/a avccauxrx19 ae12 n/a vtrxpad19 ae11 n/a rxnpad19 af12 n/a rxppad19 af11 n/a gnda19 ad11 n/a txppad19 af10 n/a txnpad19 af9 n/a vttxpad19 ae9 n/a avccauxtx19 ae10 ta bl e 7 : fg676/fgg676 ? xc2vp20, xc2vp30, and xc2vp40 bank pin description pin number no connects xc2vp20 xc2vp30 xc2vp40 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 46 product not recommended for new designs n/a avccauxrx21 ae7 n/a vtrxpad21 ae6 n/a rxnpad21 af7 n/a rxppad21 af6 n/a gnda21 ad6 n/a txppad21 af5 n/a txnpad21 af4 n/a vttxpad21 ae4 n/a avccauxtx21 ae5 n/a m2 ad4 n/a m0 af3 n/a m1 ae3 n/a tdi d3 n/a vccint g10 n/a vccint g13 n/a vccint g14 n/a vccint g17 n/a vccint j9 n/a vccint j18 n/a vccint k7 n/a vccint k10 n/a vccint k11 n/a vccint k16 n/a vccint k17 n/a vccint k20 n/a vccint l10 n/a vccint l17 n/a vccint n7 n/a vccint n20 n/a vccint p7 n/a vccint p20 n/a vccint t10 n/a vccint t17 n/a vccint u7 ta bl e 7 : fg676/fgg676 ? xc2vp20, xc2vp30, and xc2vp40 bank pin description pin number no connects xc2vp20 xc2vp30 xc2vp40 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 47 product not recommended for new designs n/a vccint u10 n/a vccint u11 n/a vccint u16 n/a vccint u17 n/a vccint u20 n/a vccint v9 n/a vccint v18 n/a vccint y10 n/a vccint y13 n/a vccint y14 n/a vccint y17 n/a vccaux a2 n/a vccaux a13 n/a vccaux a14 n/a vccaux a25 n/a vccaux n1 n/a vccaux n26 n/a vccaux p1 n/a vccaux p26 n/a vccaux af2 n/a vccaux af13 n/a vccaux af14 n/a vccaux af25 n/a gnd a1 n/a gnd a26 n/a gnd b2 n/a gnd b25 n/a gnd c3 n/a gnd c24 n/a gnd d4 n/a gnd d8 n/a gnd d19 n/a gnd d23 n/a gnd f10 n/a gnd f17 ta bl e 7 : fg676/fgg676 ? xc2vp20, xc2vp30, and xc2vp40 bank pin description pin number no connects xc2vp20 xc2vp30 xc2vp40 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 48 product not recommended for new designs n/a gnd h4 n/a gnd h23 n/a gnd k6 n/a gnd k21 n/a gnd l11 n/a gnd l12 n/a gnd l13 n/a gnd l14 n/a gnd l15 n/a gnd l16 n/a gnd m3 n/a gnd m11 n/a gnd m12 n/a gnd m13 n/a gnd m14 n/a gnd m15 n/a gnd m16 n/a gnd m24 n/a gnd n11 n/a gnd n12 n/a gnd n13 n/a gnd n14 n/a gnd n15 n/a gnd n16 n/a gnd p11 n/a gnd p12 n/a gnd p13 n/a gnd p14 n/a gnd p15 n/a gnd p16 n/a gnd r3 n/a gnd r11 n/a gnd r12 n/a gnd r13 n/a gnd r14 ta bl e 7 : fg676/fgg676 ? xc2vp20, xc2vp30, and xc2vp40 bank pin description pin number no connects xc2vp20 xc2vp30 xc2vp40 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 49 product not recommended for new designs n/a gnd r15 n/a gnd r16 n/a gnd r24 n/a gnd t11 n/a gnd t12 n/a gnd t13 n/a gnd t14 n/a gnd t15 n/a gnd t16 n/a gnd u6 n/a gnd u21 n/a gnd w4 n/a gnd w23 n/a gnd aa10 n/a gnd aa17 n/a gnd ac4 n/a gnd ac8 n/a gnd ac19 n/a gnd ac23 n/a gnd ad3 n/a gnd ad24 n/a gnd ae2 n/a gnd ae25 n/a gnd af1 n/a gnd af26 notes: 1. see ta b l e 4 for an explanation of the signals available on this pin. ta bl e 7 : fg676/fgg676 ? xc2vp20, xc2vp30, and xc2vp40 bank pin description pin number no connects xc2vp20 xc2vp30 xc2vp40 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 50 product not recommended for new designs fg676/fgg676 fine-pitch bga pack age specifications (1.00mm pitch) figure 3: fg676/fgg676 fine-pitch bga package specifications d s 0 83 _4_0 3 _05 3 111 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 51 product not recommended for new designs ff672 flip-chip fine-pitch bga package as shown in ta b l e 8 , xc2vp2, xc2vp4, and xc2vp7 virtex-ii pro device s are available in the ff672 flip-chip fine-pitch bga package. pins in each of these devices are the same, except for differences shown in the "no connects" column. following this table are the ff672 flip-chip fine-pitch bga package specifications (1.00mm pitch) . ta bl e 8 : ff672 ? xc2vp2, xc2vp4, and xc2vp7 bank pin description pin number no connects xc2vp2 xc2vp4 xc2vp7 0 io_l01n_0/vrp_0 b24 0 io_l01p_0/vrn_0 a24 0 io_l02n_0 d21 0 io_l02p_0 c21 0 io_l03n_0 e20 0 io_l03p_0/vref_0 d20 0 io_l05_0/no_pair f19 0 io_l06n_0 e19 0 io_l06p_0 e18 0 io_l07n_0 d19 0 io_l07p_0 c19 0 io_l08n_0 b19 0 io_l08p_0 a19 0 io_l09n_0 g18 0 io_l09p_0/vref_0 f18 0 io_l37n_0 d18 nc nc 0 io_l37p_0 c18 nc nc 0 io_l38n_0 g17 nc nc 0 io_l38p_0 h16 nc nc 0 io_l39n_0 f17 nc nc 0 io_l39p_0 f16 nc nc 0 io_l43n_0 e17 nc nc 0 io_l43p_0 d17 nc nc 0 io_l44n_0 g16 nc nc 0 io_l44p_0 g15 nc nc 0 io_l45n_0 e16 nc nc 0 io_l45p_0/vref_0 d16 nc nc 0 io_l67n_0 f15 0 io_l67p_0 e15 0 io_l68n_0 d15 0 io_l68p_0 c15 0 io_l69n_0 h15 0 io_l69p_0/vref_0 h14 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 52 product not recommended for new designs 0 io_l73n_0 g14 0 io_l73p_0 f14 0 io_l74n_0/gclk7p e14 0 io_l74p_0/gclk6s d14 0 io_l75n_0/gclk5p c14 0 io_l75p_0/gclk4s b14 1 io_l75n_1/gclk3p b13 1 io_l75p_1/gclk2s c13 1 io_l74n_1/gclk1p d13 1 io_l74p_1/gclk0s e13 1 io_l73n_1 f13 1 io_l73p_1 g13 1 io_l69n_1/vref_1 h13 1 io_l69p_1 h12 1 io_l68n_1 c12 1 io_l68p_1 d12 1 io_l67n_1 e12 1 io_l67p_1 f12 1 io_l45n_1/vref_1 d11 nc nc 1 io_l45p_1 e11 nc nc 1 io_l44n_1 g12 nc nc 1 io_l44p_1 g11 nc nc 1 io_l43n_1 d10 nc nc 1 io_l43p_1 e10 nc nc 1 io_l39n_1 f11 nc nc 1 io_l39p_1 f10 nc nc 1 io_l38n_1 h11 nc nc 1 io_l38p_1 g10 nc nc 1 io_l37n_1 c9 nc nc 1 io_l37p_1 d9 nc nc 1 io_l09n_1/vref_1 f9 1 io_l09p_1 g9 1 io_l08n_1 a8 1 io_l08p_1 b8 1 io_l07n_1 c8 1 io_l07p_1 d8 ta bl e 8 : ff672 ? xc2vp2, xc2vp4, and xc2vp7 bank pin description pin number no connects xc2vp2 xc2vp4 xc2vp7 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 53 product not recommended for new designs 1 io_l06n_1 e9 1 io_l06p_1 e8 1 io_l05_1/no_pair f8 1 io_l03n_1/vref_1 d7 1 io_l03p_1 e7 1 io_l02n_1 c6 1 io_l02p_1 d6 1 io_l01n_1/vrp_1 a3 1 io_l01p_1/vrn_1 b3 2 io_l01n_2/vrp_2 c4 2 io_l01p_2/vrn_2 d3 2 io_l02n_2 a2 2 io_l02p_2 b1 2 io_l03n_2 c2 2 io_l03p_2 c1 2 io_l04n_2/vref_2 d2 2 io_l04p_2 d1 2 io_l05n_2 e4 2 io_l05p_2 e3 2 io_l06n_2 e2 2 io_l06p_2 e1 2 io_l40n_2/vref_2 f5 nc nc nc 2 io_l40p_2 f4 nc nc nc 2 io_l42n_2 f3 nc nc nc 2 io_l42p_2 f2 nc nc nc 2 io_l43n_2 g6 nc 2 io_l43p_2 g5 nc 2 io_l44n_2 g4 nc 2 io_l44p_2 g3 nc 2 io_l45n_2 f1 nc 2 io_l45p_2 g1 nc 2 io_l46n_2/vref_2 h6 nc 2 io_l46p_2 h5 nc 2 io_l47n_2 h4 nc 2 io_l47p_2 h3 nc 2 io_l48n_2 h2 nc ta bl e 8 : ff672 ? xc2vp2, xc2vp4, and xc2vp7 bank pin description pin number no connects xc2vp2 xc2vp4 xc2vp7 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 54 product not recommended for new designs 2 io_l48p_2 h1 nc 2 io_l49n_2 j7 nc 2 io_l49p_2 j6 nc 2 io_l50n_2 j5 nc 2 io_l50p_2 j4 nc 2 io_l51n_2 j3 nc 2 io_l51p_2 j2 nc 2 io_l52n_2/vref_2 k6 nc 2 io_l52p_2 k5 nc 2 io_l53n_2 k4 nc 2 io_l53p_2 k3 nc 2 io_l54n_2 j1 nc 2 io_l54p_2 k1 nc 2 io_l55n_2 k7 nc 2 io_l55p_2 l8 nc 2 io_l56n_2 l7 nc 2 io_l56p_2 m7 nc 2 io_l57n_2 l6 nc 2 io_l57p_2 l5 nc 2 io_l58n_2/vref_2 l4 nc 2 io_l58p_2 l3 nc 2 io_l59n_2 l2 nc 2 io_l59p_2 l1 nc 2 io_l60n_2 m8 nc 2 io_l60p_2 n8 nc 2 io_l85n_2 m6 2 io_l85p_2 m5 2 io_l86n_2 m4 2 io_l86p_2 m3 2 io_l87n_2 m2 2 io_l87p_2 m1 2 io_l88n_2/vref_2 n7 2 io_l88p_2 n6 2 io_l89n_2 n5 2 io_l89p_2 n4 2 io_l90n_2 n3 2 io_l90p_2 n2 ta bl e 8 : ff672 ? xc2vp2, xc2vp4, and xc2vp7 bank pin description pin number no connects xc2vp2 xc2vp4 xc2vp7 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 55 product not recommended for new designs 3 io_l90n_3 p2 3 io_l90p_3 p3 3 io_l89n_3 p4 3 io_l89p_3 p5 3 io_l88n_3 p6 3 io_l88p_3 p7 3 io_l87n_3/vref_3 r1 3 io_l87p_3 r2 3 io_l86n_3 r3 3 io_l86p_3 r4 3 io_l85n_3 r5 3 io_l85p_3 r6 3 io_l60n_3 p8 nc 3 io_l60p_3 r8 nc 3 io_l59n_3 t1 nc 3 io_l59p_3 t2 nc 3 io_l58n_3 t3 nc 3 io_l58p_3 t4 nc 3 io_l57n_3/vref_3 t5 nc 3 io_l57p_3 t6 nc 3 io_l56n_3 r7 nc 3 io_l56p_3 t7 nc 3 io_l55n_3 t8 nc 3 io_l55p_3 u7 nc 3 io_l54n_3 u1 nc 3 io_l54p_3 v1 nc 3 io_l53n_3 u3 nc 3 io_l53p_3 u4 nc 3 io_l52n_3 u5 nc 3 io_l52p_3 u6 nc 3 io_l51n_3/vref_3 v2 nc 3 io_l51p_3 v3 nc 3 io_l50n_3 v4 nc 3 io_l50p_3 v5 nc 3 io_l49n_3 v6 nc 3 io_l49p_3 v7 nc ta bl e 8 : ff672 ? xc2vp2, xc2vp4, and xc2vp7 bank pin description pin number no connects xc2vp2 xc2vp4 xc2vp7 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 56 product not recommended for new designs 3 io_l48n_3 w1 nc 3 io_l48p_3 w2 nc 3 io_l47n_3 w3 nc 3 io_l47p_3 w4 nc 3 io_l46n_3 w5 nc 3 io_l46p_3 w6 nc 3 io_l45n_3/vref_3 y1 nc 3 io_l45p_3 aa1 nc 3 io_l44n_3 y3 nc 3 io_l44p_3 y4 nc 3 io_l43n_3 y5 nc 3 io_l43p_3 y6 nc 3 io_l42n_3 aa2 nc nc nc 3 io_l42p_3 aa3 nc nc nc 3 io_l41n_3 aa4 nc nc nc 3 io_l41p_3 aa5 nc nc nc 3 io_l39n_3/vref_3 ab1 nc nc nc 3 io_l39p_3 ab2 nc nc nc 3 io_l06n_3 ab3 3 io_l06p_3 ab4 3 io_l05n_3 ac1 3 io_l05p_3 ac2 3 io_l04n_3 ad1 3 io_l04p_3 ad2 3 io_l03n_3/vref_3 ae1 3 io_l03p_3 af2 3 io_l02n_3 ac3 3 io_l02p_3 ad4 3 io_l01n_3/vrp_3 ae3 3 io_l01p_3/vrn_3 af3 4 io_l01n_4/busy/dout (1) ac6 4 io_l01p_4/init_b ad6 4 io_l02n_4/d0/din (1) ab7 4 io_l02p_4/d1 ac7 4 io_l03n_4/d2 aa7 4 io_l03p_4/d3 aa8 ta bl e 8 : ff672 ? xc2vp2, xc2vp4, and xc2vp7 bank pin description pin number no connects xc2vp2 xc2vp4 xc2vp7 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 57 product not recommended for new designs 4 io_l05_4/no_pair y8 4 io_l06n_4/vrp_4 ab8 4 io_l06p_4/vrn_4 ab9 4 io_l07n_4 ac8 4 io_l07p_4/vref_4 ad8 4 io_l08n_4 ae8 4 io_l08p_4 af8 4 io_l09n_4 y9 4 io_l09p_4/vref_4 aa9 4 io_l37n_4 ac9 nc nc 4 io_l37p_4 ad9 nc nc 4 io_l38n_4 y10 nc nc 4 io_l38p_4 w11 nc nc 4 io_l39n_4 aa10 nc nc 4 io_l39p_4 aa11 nc nc 4 io_l43n_4 ab10 nc nc 4 io_l43p_4 ac10 nc nc 4 io_l44n_4 y11 nc nc 4 io_l44p_4 y12 nc nc 4 io_l45n_4 ab11 nc nc 4 io_l45p_4/vref_4 ac11 nc nc 4 io_l67n_4 aa12 4 io_l67p_4 ab12 4 io_l68n_4 ac12 4 io_l68p_4 ad12 4 io_l69n_4 w12 4 io_l69p_4/vref_4 w13 4 io_l73n_4 y13 4 io_l73p_4 aa13 4 io_l74n_4/gclk3s ab13 4 io_l74p_4/gclk2p ac13 4 io_l75n_4/gclk1s ad13 4 io_l75p_4/gclk0p ae13 5 io_l75n_5/gclk7s ae14 5 io_l75p_5/gclk6p ad14 5 io_l74n_5/gclk5s ac14 ta bl e 8 : ff672 ? xc2vp2, xc2vp4, and xc2vp7 bank pin description pin number no connects xc2vp2 xc2vp4 xc2vp7 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 58 product not recommended for new designs 5 io_l74p_5/gclk4p ab14 5 io_l73n_5 aa14 5 io_l73p_5 y14 5 io_l69n_5/vref_5 w14 5 io_l69p_5 w15 5 io_l68n_5 ad15 5 io_l68p_5 ac15 5 io_l67n_5 ab15 5 io_l67p_5 aa15 5 io_l45n_5/vref_5 ac16 nc nc 5 io_l45p_5 ab16 nc nc 5 io_l44n_5 y15 nc nc 5 io_l44p_5 y16 nc nc 5 io_l43n_5 ac17 nc nc 5 io_l43p_5 ab17 nc nc 5 io_l39n_5 aa16 nc nc 5 io_l39p_5 aa17 nc nc 5 io_l38n_5 w16 nc nc 5 io_l38p_5 y17 nc nc 5 io_l37n_5 ad18 nc nc 5 io_l37p_5 ac18 nc nc 5 io_l09n_5/vref_5 aa18 5 io_l09p_5 y18 5 io_l08n_5 af19 5 io_l08p_5 ae19 5 io_l07n_5/vref_5 ad19 5 io_l07p_5 ac19 5 io_l06n_5/vrp_5 ab18 5 io_l06p_5/vrn_5 ab19 5 io_l05_5/no_pair y19 5 io_l03n_5/d4 aa19 5 io_l03p_5/d5 aa20 5 io_l02n_5/d6 ac20 5 io_l02p_5/d7 ab20 5 io_l01n_5/rdwr_b ad21 5 io_l01p_5/cs_b ac21 ta bl e 8 : ff672 ? xc2vp2, xc2vp4, and xc2vp7 bank pin description pin number no connects xc2vp2 xc2vp4 xc2vp7 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 59 product not recommended for new designs 6 io_l01p_6/vrn_6 af24 6 io_l01n_6/vrp_6 ae24 6 io_l02p_6 ad23 6 io_l02n_6 ac24 6 io_l03p_6 ae26 6 io_l03n_6/vref_6 af25 6 io_l04p_6 ad25 6 io_l04n_6 ad26 6 io_l05p_6 ac25 6 io_l05n_6 ac26 6 io_l06p_6 ab23 6 io_l06n_6 ab24 6 io_l39p_6 ab25 nc nc nc 6 io_l39n_6/vref_6 ab26 nc nc nc 6 io_l41p_6 aa22 nc nc nc 6 io_l41n_6 aa23 nc nc nc 6 io_l42p_6 aa24 nc nc nc 6 io_l42n_6 aa25 nc nc nc 6 io_l43p_6 y21 nc 6 io_l43n_6 y22 nc 6 io_l44p_6 y23 nc 6 io_l44n_6 y24 nc 6 io_l45p_6 aa26 nc 6 io_l45n_6/vref_6 y26 nc 6 io_l46p_6 w21 nc 6 io_l46n_6 w22 nc 6 io_l47p_6 w23 nc 6 io_l47n_6 w24 nc 6 io_l48p_6 w25 nc 6 io_l48n_6 w26 nc 6 io_l49p_6 v20 nc 6 io_l49n_6 v21 nc 6 io_l50p_6 v22 nc 6 io_l50n_6 v23 nc 6 io_l51p_6 v24 nc 6 io_l51n_6/vref_6 v25 nc 6 io_l52p_6 u21 nc ta bl e 8 : ff672 ? xc2vp2, xc2vp4, and xc2vp7 bank pin description pin number no connects xc2vp2 xc2vp4 xc2vp7 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 60 product not recommended for new designs 6 io_l52n_6 u22 nc 6 io_l53p_6 u23 nc 6 io_l53n_6 u24 nc 6 io_l54p_6 v26 nc 6 io_l54n_6 u26 nc 6 io_l55p_6 u20 nc 6 io_l55n_6 t19 nc 6 io_l56p_6 t20 nc 6 io_l56n_6 r20 nc 6 io_l57p_6 t21 nc 6 io_l57n_6/vref_6 t22 nc 6 io_l58p_6 t23 nc 6 io_l58n_6 t24 nc 6 io_l59p_6 t25 nc 6 io_l59n_6 t26 nc 6 io_l60p_6 r19 nc 6 io_l60n_6 p19 nc 6 io_l85p_6 r21 6 io_l85n_6 r22 6 io_l86p_6 r23 6 io_l86n_6 r24 6 io_l87p_6 r25 6 io_l87n_6/vref_6 r26 6 io_l88p_6 p20 6 io_l88n_6 p21 6 io_l89p_6 p22 6 io_l89n_6 p23 6 io_l90p_6 p24 6 io_l90n_6 p25 7 io_l90p_7 n25 7 io_l90n_7 n24 7 io_l89p_7 n23 7 io_l89n_7 n22 7 io_l88p_7 n21 7 io_l88n_7/vref_7 n20 7 io_l87p_7 m26 ta bl e 8 : ff672 ? xc2vp2, xc2vp4, and xc2vp7 bank pin description pin number no connects xc2vp2 xc2vp4 xc2vp7 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 61 product not recommended for new designs 7 io_l87n_7 m25 7 io_l86p_7 m24 7 io_l86n_7 m23 7 io_l85p_7 m22 7 io_l85n_7 m21 7 io_l60p_7 n19 nc 7 io_l60n_7 m19 nc 7 io_l59p_7 l26 nc 7 io_l59n_7 l25 nc 7 io_l58p_7 l24 nc 7 io_l58n_7/vref_7 l23 nc 7 io_l57p_7 l22 nc 7 io_l57n_7 l21 nc 7 io_l56p_7 m20 nc 7 io_l56n_7 l20 nc 7 io_l55p_7 l19 nc 7 io_l55n_7 k20 nc 7 io_l54p_7 k26 nc 7 io_l54n_7 j26 nc 7 io_l53p_7 k24 nc 7 io_l53n_7 k23 nc 7 io_l52p_7 k22 nc 7 io_l52n_7/vref_7 k21 nc 7 io_l51p_7 j25 nc 7 io_l51n_7 j24 nc 7 io_l50p_7 j23 nc 7 io_l50n_7 j22 nc 7 io_l49p_7 j21 nc 7 io_l49n_7 j20 nc 7 io_l48p_7 h26 nc 7 io_l48n_7 h25 nc 7 io_l47p_7 h24 nc 7 io_l47n_7 h23 nc 7 io_l46p_7 h22 nc 7 io_l46n_7/vref_7 h21 nc 7 io_l45p_7 g26 nc 7 io_l45n_7 f26 nc ta bl e 8 : ff672 ? xc2vp2, xc2vp4, and xc2vp7 bank pin description pin number no connects xc2vp2 xc2vp4 xc2vp7 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 62 product not recommended for new designs 7 io_l44p_7 g24 nc 7 io_l44n_7 g23 nc 7 io_l43p_7 g22 nc 7 io_l43n_7 g21 nc 7 io_l42p_7 f25 nc nc nc 7 io_l42n_7 f24 nc nc nc 7 io_l40p_7 f23 nc nc nc 7 io_l40n_7/vref_7 f22 nc nc nc 7 io_l06p_7 e26 7 io_l06n_7 e25 7 io_l05p_7 e24 7 io_l05n_7 e23 7 io_l04p_7 d26 7 io_l04n_7/vref_7 d25 7 io_l03p_7 c26 7 io_l03n_7 c25 7 io_l02p_7 b26 7 io_l02n_7 a25 7 io_l01p_7/vrn_7 d24 7 io_l01n_7/vrp_7 c23 0 vcco_0 c17 0 vcco_0 c20 0 vcco_0 h17 0 vcco_0 h18 0 vcco_0 j14 0 vcco_0 j15 0 vcco_0 j16 1 vcco_1 c7 1 vcco_1 h9 1 vcco_1 c10 1 vcco_1 h10 1 vcco_1 j11 1 vcco_1 j12 1 vcco_1 j13 2 vcco_2 g2 2 vcco_2 j8 ta bl e 8 : ff672 ? xc2vp2, xc2vp4, and xc2vp7 bank pin description pin number no connects xc2vp2 xc2vp4 xc2vp7 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 63 product not recommended for new designs 2 vcco_2 k2 2 vcco_2 k8 2 vcco_2 l9 2 vcco_2 m9 2 vcco_2 n9 3 vcco_3 p9 3 vcco_3 r9 3 vcco_3 t9 3 vcco_3 u2 3 vcco_3 u8 3 vcco_3 v8 3 vcco_3 y2 4 vcco_4 w9 4 vcco_4 ad7 4 vcco_4 v11 4 vcco_4 v12 4 vcco_4 v13 4 vcco_4 w10 4 vcco_4 ad10 5 vcco_5 v14 5 vcco_5 v15 5 vcco_5 v16 5 vcco_5 w17 5 vcco_5 w18 5 vcco_5 ad17 5 vcco_5 ad20 6 vcco_6 p18 6 vcco_6 r18 6 vcco_6 t18 6 vcco_6 u19 6 vcco_6 u25 6 vcco_6 v19 6 vcco_6 y25 7 vcco_7 g25 7 vcco_7 j19 7 vcco_7 k19 7 vcco_7 k25 ta bl e 8 : ff672 ? xc2vp2, xc2vp4, and xc2vp7 bank pin description pin number no connects xc2vp2 xc2vp4 xc2vp7 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 64 product not recommended for new designs 7 vcco_7 l18 7 vcco_7 m18 7 vcco_7 n18 n/a cclk w7 n/a prog_b d22 n/a done ab6 n/a m0 ac22 n/a m1 w20 n/a m2 ab21 n/a tck g8 n/a tdi h20 n/a tdo h7 n/a tms f7 n/a pwrdwn_b ac5 n/a hswap_en e21 n/a rsvd d5 n/a vbatt e6 n/a dxp f20 n/a dxn g19 n/a avccauxtx7 b11 n/a vttxpad7 b12 n/a txnpad7 a12 n/a txppad7 a11 n/a gnda7 c11 n/a rxppad7 a10 n/a rxnpad7 a9 n/a vtrxpad7 b10 n/a avccauxrx7 b9 n/a avccauxtx9 b6 nc nc n/a vttxpad9 b7 nc nc n/a txnpad9 a7 nc nc n/a txppad9 a6 nc nc n/a gnda9 c5 nc nc n/a rxppad9 a5 nc nc n/a rxnpad9 a4 nc nc n/a vtrxpad9 b5 nc nc ta bl e 8 : ff672 ? xc2vp2, xc2vp4, and xc2vp7 bank pin description pin number no connects xc2vp2 xc2vp4 xc2vp7 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 65 product not recommended for new designs n/a avccauxrx9 b4 nc nc n/a avccauxrx16 ae4 nc nc n/a vtrxpad16 ae5 nc nc n/a rxnpad16 af4 nc nc n/a rxppad16 af5 nc nc n/a gnda16 ad5 nc nc n/a txppad16 af6 nc nc n/a txnpad16 af7 nc nc n/a vttxpad16 ae7 nc nc n/a avccauxtx16 ae6 nc nc n/a avccauxrx18 ae9 n/a vtrxpad18 ae10 n/a rxnpad18 af9 n/a rxppad18 af10 n/a gnda18 ad11 n/a txppad18 af11 n/a txnpad18 af12 n/a vttxpad18 ae12 n/a avccauxtx18 ae11 n/a avccauxtx4 b22 nc nc n/a vttxpad4 b23 nc nc n/a txnpad4 a23 nc nc n/a txppad4 a22 nc nc n/a gnda4 c22 nc nc n/a rxppad4 a21 nc nc n/a rxnpad4 a20 nc nc n/a vtrxpad4 b21 nc nc n/a avccauxrx4 b20 nc nc n/a avccauxtx6 b17 n/a vttxpad6 b18 n/a txnpad6 a18 n/a txppad6 a17 n/a gnda6 c16 n/a rxppad6 a16 n/a rxnpad6 a15 n/a vtrxpad6 b16 n/a avccauxrx6 b15 ta bl e 8 : ff672 ? xc2vp2, xc2vp4, and xc2vp7 bank pin description pin number no connects xc2vp2 xc2vp4 xc2vp7 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 66 product not recommended for new designs n/a avccauxrx19 ae15 n/a vtrxpad19 ae16 n/a rxnpad19 af15 n/a rxppad19 af16 n/a gnda19 ad16 n/a txppad19 af17 n/a txnpad19 af18 n/a vttxpad19 ae18 n/a avccauxtx19 ae17 n/a avccauxrx21 ae20 nc nc n/a vtrxpad21 ae21 nc nc n/a rxnpad21 af20 nc nc n/a rxppad21 af21 nc nc n/a gnda21 ad22 nc nc n/a txppad21 af22 nc nc n/a txnpad21 af23 nc nc n/a vttxpad21 ae23 nc nc n/a avccauxtx21 ae22 nc nc n/a vccint h8 n/a vccint j9 n/a vccint k9 n/a vccint u9 n/a vccint v9 n/a vccint w8 n/a vccint h19 n/a vccint j10 n/a vccint j17 n/a vccint j18 n/a vccint k11 n/a vccint k16 n/a vccint k18 n/a vccint l10 n/a vccint l17 n/a vccint t10 n/a vccint t17 n/a vccint u11 ta bl e 8 : ff672 ? xc2vp2, xc2vp4, and xc2vp7 bank pin description pin number no connects xc2vp2 xc2vp4 xc2vp7 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 67 product not recommended for new designs n/a vccint u16 n/a vccint u18 n/a vccint v10 n/a vccint v17 n/a vccint v18 n/a vccint w19 n/a vccaux b2 n/a vccaux n1 n/a vccaux p1 n/a vccaux a13 n/a vccaux a14 n/a vccaux ae2 n/a vccaux b25 n/a vccaux n26 n/a vccaux p26 n/a vccaux ae25 n/a vccaux af13 n/a vccaux af14 n/a gnd c3 n/a gnd d4 n/a gnd e5 n/a gnd f6 n/a gnd g7 n/a gnd y7 n/a gnd aa6 n/a gnd ab5 n/a gnd ac4 n/a gnd ad3 n/a gnd c24 n/a gnd d23 n/a gnd e22 n/a gnd f21 n/a gnd g20 n/a gnd k10 n/a gnd k12 n/a gnd k13 n/a gnd k14 ta bl e 8 : ff672 ? xc2vp2, xc2vp4, and xc2vp7 bank pin description pin number no connects xc2vp2 xc2vp4 xc2vp7 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 68 product not recommended for new designs n/a gnd k15 n/a gnd k17 n/a gnd l11 n/a gnd l12 n/a gnd l13 n/a gnd l14 n/a gnd l15 n/a gnd l16 n/a gnd m10 n/a gnd m11 n/a gnd m12 n/a gnd m13 n/a gnd m14 n/a gnd m15 n/a gnd m16 n/a gnd m17 n/a gnd n10 n/a gnd n11 n/a gnd n12 n/a gnd n13 n/a gnd n14 n/a gnd n15 n/a gnd n16 n/a gnd n17 n/a gnd p10 n/a gnd p11 n/a gnd p12 n/a gnd p13 n/a gnd p14 n/a gnd p15 n/a gnd p16 n/a gnd p17 n/a gnd r10 n/a gnd r11 n/a gnd r12 n/a gnd r13 n/a gnd r14 ta bl e 8 : ff672 ? xc2vp2, xc2vp4, and xc2vp7 bank pin description pin number no connects xc2vp2 xc2vp4 xc2vp7 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 69 product not recommended for new designs n/a gnd r15 n/a gnd r16 n/a gnd r17 n/a gnd t11 n/a gnd t12 n/a gnd t13 n/a gnd t14 n/a gnd t15 n/a gnd t16 n/a gnd u10 n/a gnd u12 n/a gnd u13 n/a gnd u14 n/a gnd u15 n/a gnd u17 n/a gnd y20 n/a gnd aa21 n/a gnd ab22 n/a gnd ac23 n/a gnd ad24 notes: 1. see ta b l e 4 for an explanation of the signals available on this pin. ta bl e 8 : ff672 ? xc2vp2, xc2vp4, and xc2vp7 bank pin description pin number no connects xc2vp2 xc2vp4 xc2vp7 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 70 product not recommended for new designs ff672 flip-chip fine-pitch bga pack age specifications (1.00mm pitch) ff896 flip-chip fine-pitch bga package as shown in ta b l e 9 , xc2vp7, xc2vp20, and xc2vp30 virtex-ii pro devices are available in the ff896 flip-chip fine-pitch bga package. pins in each of these devices are the same, except for differences shown in the "no connects" column. following this table are the ff896 flip-chip fine-pitch bga package specifications (1.00mm pitch) . figure 4: ff672 flip-chip fine-pitch bga package specifications virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 71 product not recommended for new designs ta bl e 9 : ff896 ? xc2vp7, xc2vp20, xc2vpx20, and xc2vp30 bank pin description pin number no connects virtex-ii pro devices xc2vpx20 (if different) xc2vp7 xc2vp20, xc2vpx20 xc2vp30 0 io_l01n_0/vrp_0 e25 0 io_l01p_0/vrn_0 e24 0 io_l02n_0 f24 0 io_l02p_0 f23 0 io_l03n_0 e23 0 io_l03p_0/vref_0 e22 0 io_l05_0/no_pair g23 0 io_l06n_0 h22 0 io_l06p_0 g22 0 io_l07n_0 f22 0 io_l07p_0 f21 0 io_l08n_0 d24 0 io_l08p_0 c24 0 io_l09n_0 h21 0 io_l09p_0/vref_0 g21 0 io_l37n_0 e21 0 io_l37p_0 d21 0 io_l38n_0 d23 0 io_l38p_0 c23 0 io_l39n_0 h20 0 io_l39p_0 g20 0 io_l43n_0 e20 0 io_l43p_0 d20 0 io_l44n_0 b23 0 io_l44p_0 a23 0 io_l45n_0 h19 0 io_l45p_0/vref_0 g19 0 io_l46n_0 e19 nc 0 io_l46p_0 e18 nc 0 io_l47n_0 c22 nc 0 io_l47p_0 b22 nc 0 io_l48n_0 f20 nc 0 io_l48p_0 f19 nc 0 io_l49n_0 g17 nc 0 io_l49p_0 f17 nc 0 io_l50_0/no_pair b21 nc virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 72 product not recommended for new designs 0 io_l53_0/no_pair a21 nc 0 io_l54n_0 h18 nc 0 io_l54p_0 g18 nc 0 io_l56n_0 c21 nc 0 io_l56p_0 c20 nc 0 io_l57n_0 j17 nc 0 io_l57p_0/vref_0 h17 nc 0 io_l67n_0 e17 0 io_l67p_0 d17 0 io_l68n_0 d18 0 io_l68p_0 c18 0 io_l69n_0 j16 0 io_l69p_0/vref_0 h16 0 io_l73n_0 e16 0 io_l73p_0 d16 0 io_l74n_0/gclk7p c16 0 io_l74p_0/gclk6s b16 0 io_l75n_0/gclk5p brefclkn g16 0 io_l75p_0/gclk4s brefclkp f16 1 io_l75n_1/gclk3p f15 1 io_l75p_1/gclk2s g15 1 io_l74n_1/gclk1p b15 1 io_l74p_1/gclk0s c15 1 io_l73n_1 d15 1 io_l73p_1 e15 1 io_l69n_1/vref_1 h15 1 io_l69p_1 j15 1 io_l68n_1 c13 1 io_l68p_1 d13 1 io_l67n_1 d14 1 io_l67p_1 e14 1 io_l57n_1/vref_1 h14 nc 1 io_l57p_1 j14 nc 1 io_l56n_1 c11 nc 1 io_l56p_1 c10 nc ta bl e 9 : ff896 ? xc2vp7, xc2vp20, xc2vpx20, and xc2vp30 bank pin description pin number no connects virtex-ii pro devices xc2vpx20 (if different) xc2vp7 xc2vp20, xc2vpx20 xc2vp30 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 73 product not recommended for new designs 1 io_l54n_1 g13 nc 1 io_l54p_1 h13 nc 1 io_l53_1/no_pair a10 nc 1 io_l50_1/no_pair b10 nc 1 io_l49n_1 f14 nc 1 io_l49p_1 g14 nc 1 io_l48n_1 f12 nc 1 io_l48p_1 f11 nc 1 io_l47n_1 b9 nc 1 io_l47p_1 c9 nc 1 io_l46n_1 e13 nc 1 io_l46p_1 e12 nc 1 io_l45n_1/vref_1 g12 1 io_l45p_1 h12 1 io_l44n_1 a8 1 io_l44p_1 b8 1 io_l43n_1 d11 1 io_l43p_1 e11 1 io_l39n_1 g11 1 io_l39p_1 h11 1 io_l38n_1 c8 1 io_l38p_1 d8 1 io_l37n_1 d10 1 io_l37p_1 e10 1 io_l09n_1/vref_1 g10 1 io_l09p_1 h10 1 io_l08n_1 c7 1 io_l08p_1 d7 1 io_l07n_1 f10 1 io_l07p_1 f9 1 io_l06n_1 g9 1 io_l06p_1 h9 1 io_l05_1/no_pair g8 1 io_l03n_1/vref_1 e9 1 io_l03p_1 e8 1 io_l02n_1 f8 ta bl e 9 : ff896 ? xc2vp7, xc2vp20, xc2vpx20, and xc2vp30 bank pin description pin number no connects virtex-ii pro devices xc2vpx20 (if different) xc2vp7 xc2vp20, xc2vpx20 xc2vp30 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 74 product not recommended for new designs 1 io_l02p_1 f7 1 io_l01n_1/vrp_1 e7 1 io_l01p_1/vrn_1 e6 2 io_l01n_2/vrp_2 a3 2 io_l01p_2/vrn_2 b3 2 io_l02n_2 g6 2 io_l02p_2 g5 2 io_l03n_2 c5 2 io_l03p_2 d5 2 io_l04n_2/vref_2 c2 2 io_l04p_2 c1 2 io_l05n_2 j8 2 io_l05p_2 j7 2 io_l06n_2 c4 2 io_l06p_2 d3 2 io_l31n_2 d2 nc 2 io_l31p_2 d1 nc 2 io_l32n_2 h6 nc 2 io_l32p_2 h5 nc 2 io_l33n_2 e4 nc 2 io_l33p_2 e3 nc 2 io_l34n_2/vref_2 e2 nc 2 io_l34p_2 e1 nc 2 io_l35n_2 k8 nc 2 io_l35p_2 k7 nc 2 io_l36n_2 f4 nc 2 io_l36p_2 f3 nc 2 io_l37n_2 f2 nc 2 io_l37p_2 f1 nc 2 io_l38n_2 j6 nc 2 io_l38p_2 j5 nc 2 io_l39n_2 g4 nc 2 io_l39p_2 g3 nc 2 io_l40n_2/vref_2 g2 nc 2 io_l40p_2 g1 nc ta bl e 9 : ff896 ? xc2vp7, xc2vp20, xc2vpx20, and xc2vp30 bank pin description pin number no connects virtex-ii pro devices xc2vpx20 (if different) xc2vp7 xc2vp20, xc2vpx20 xc2vp30 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 75 product not recommended for new designs 2 io_l41n_2 l8 nc 2 io_l41p_2 l7 nc 2 io_l42n_2 h4 nc 2 io_l42p_2 h3 nc 2 io_l43n_2 h2 2 io_l43p_2 j2 2 io_l44n_2 m8 2 io_l44p_2 m7 2 io_l45n_2 k6 2 io_l45p_2 k5 2 io_l46n_2/vref_2 j1 2 io_l46p_2 k1 2 io_l47n_2 m6 2 io_l47p_2 m5 2 io_l48n_2 j4 2 io_l48p_2 j3 2 io_l49n_2 k2 2 io_l49p_2 l2 2 io_l50n_2 n8 2 io_l50p_2 n7 2 io_l51n_2 k4 2 io_l51p_2 k3 2 io_l52n_2/vref_2 l1 2 io_l52p_2 m1 2 io_l53n_2 n6 2 io_l53p_2 n5 2 io_l54n_2 l5 2 io_l54p_2 l4 2 io_l55n_2 m2 2 io_l55p_2 n2 2 io_l56n_2 p9 2 io_l56p_2 r9 2 io_l57n_2 m4 2 io_l57p_2 m3 2 io_l58n_2/vref_2 n1 2 io_l58p_2 p1 ta bl e 9 : ff896 ? xc2vp7, xc2vp20, xc2vpx20, and xc2vp30 bank pin description pin number no connects virtex-ii pro devices xc2vpx20 (if different) xc2vp7 xc2vp20, xc2vpx20 xc2vp30 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 76 product not recommended for new designs 2 io_l59n_2 p8 2 io_l59p_2 p7 2 io_l60n_2 n4 2 io_l60p_2 n3 2 io_l85n_2 p3 2 io_l85p_2 p2 2 io_l86n_2 r8 2 io_l86p_2 r7 2 io_l87n_2 p5 2 io_l87p_2 p4 2 io_l88n_2/vref_2 r2 2 io_l88p_2 t2 2 io_l89n_2 r6 2 io_l89p_2 r5 2 io_l90n_2 r4 2 io_l90p_2 r3 3 io_l90n_3 u1 3 io_l90p_3 v1 3 io_l89n_3 t5 3 io_l89p_3 t6 3 io_l88n_3 t3 3 io_l88p_3 t4 3 io_l87n_3/vref_3 u2 3 io_l87p_3 u3 3 io_l86n_3 t7 3 io_l86p_3 t8 3 io_l85n_3 u4 3 io_l85p_3 u5 3 io_l60n_3 v2 3 io_l60p_3 w2 3 io_l59n_3 t9 3 io_l59p_3 u9 3 io_l58n_3 v3 3 io_l58p_3 v4 3 io_l57n_3/vref_3 w1 ta bl e 9 : ff896 ? xc2vp7, xc2vp20, xc2vpx20, and xc2vp30 bank pin description pin number no connects virtex-ii pro devices xc2vpx20 (if different) xc2vp7 xc2vp20, xc2vpx20 xc2vp30 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 77 product not recommended for new designs 3 io_l57p_3 y1 3 io_l56n_3 u7 3 io_l56p_3 u8 3 io_l55n_3 v5 3 io_l55p_3 v6 3 io_l54n_3 y2 3 io_l54p_3 aa2 3 io_l53n_3 v7 3 io_l53p_3 v8 3 io_l52n_3 w3 3 io_l52p_3 w4 3 io_l51n_3/vref_3 aa1 3 io_l51p_3 ab1 3 io_l50n_3 w5 3 io_l50p_3 w6 3 io_l49n_3 y4 3 io_l49p_3 y5 3 io_l48n_3 aa3 3 io_l48p_3 aa4 3 io_l47n_3 w7 3 io_l47p_3 w8 3 io_l46n_3 ab3 3 io_l46p_3 ab4 3 io_l45n_3/vref_3 ab2 3 io_l45p_3 ac2 3 io_l44n_3 aa5 3 io_l44p_3 aa6 3 io_l43n_3 ac3 3 io_l43p_3 ac4 3 io_l42n_3 ad1 nc 3 io_l42p_3 ad2 nc 3 io_l41n_3 y7 nc 3 io_l41p_3 y8 nc 3 io_l40n_3 ab5 nc 3 io_l40p_3 ab6 nc 3 io_l39n_3/vref_3 ae1 nc ta bl e 9 : ff896 ? xc2vp7, xc2vp20, xc2vpx20, and xc2vp30 bank pin description pin number no connects virtex-ii pro devices xc2vpx20 (if different) xc2vp7 xc2vp20, xc2vpx20 xc2vp30 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 78 product not recommended for new designs 3 io_l39p_3 ae2 nc 3 io_l38n_3 aa7 nc 3 io_l38p_3 aa8 nc 3 io_l37n_3 ad3 nc 3 io_l37p_3 ad4 nc 3 io_l36n_3 af1 nc 3 io_l36p_3 af2 nc 3 io_l35n_3 ac5 nc 3 io_l35p_3 ac6 nc 3 io_l34n_3 af3 nc 3 io_l34p_3 af4 nc 3 io_l33n_3/vref_3 ae3 nc 3 io_l33p_3 ae4 nc 3 io_l32n_3 ab7 nc 3 io_l32p_3 ab8 nc 3 io_l31n_3 ae5 nc 3 io_l31p_3 af6 nc 3 io_l06n_3 ag1 3 io_l06p_3 ag2 3 io_l05n_3 ad5 3 io_l05p_3 ad6 3 io_l04n_3 ag3 3 io_l04p_3 ah4 3 io_l03n_3/vref_3 ah1 3 io_l03p_3 ah2 3 io_l02n_3 ag5 3 io_l02p_3 ah5 3 io_l01n_3/vrp_3 aj3 3 io_l01p_3/vrn_3 ak3 4 io_l01n_4/busy/dout (1) ag6 4 io_l01p_4/init_b af7 4 io_l02n_4/d0/din (1) ac9 4 io_l02p_4/d1 ad9 4 io_l03n_4/d2 ag7 4 io_l03p_4/d3 ah7 ta bl e 9 : ff896 ? xc2vp7, xc2vp20, xc2vpx20, and xc2vp30 bank pin description pin number no connects virtex-ii pro devices xc2vpx20 (if different) xc2vp7 xc2vp20, xc2vpx20 xc2vp30 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 79 product not recommended for new designs 4 io_l05_4/no_pair ad8 4 io_l06n_4/vrp_4 ag8 4 io_l06p_4/vrn_4 ah8 4 io_l07n_4 ac10 4 io_l07p_4/vref_4 ad10 4 io_l08n_4 ae7 4 io_l08p_4 ae8 4 io_l09n_4 aj8 4 io_l09p_4/vref_4 ak8 4 io_l37n_4 ac11 4 io_l37p_4 ad11 4 io_l38n_4 af8 4 io_l38p_4 af9 4 io_l39n_4 af10 4 io_l39p_4 ag10 4 io_l43n_4 ac12 4 io_l43p_4 ad12 4 io_l44n_4 ae9 4 io_l44p_4 ae10 4 io_l45n_4 ah9 4 io_l45p_4/vref_4 aj9 4 io_l46n_4 ac13 nc 4 io_l46p_4 ad13 nc 4 io_l47n_4 ae11 nc 4 io_l47p_4 ae12 nc 4 io_l48n_4 ah10 nc 4 io_l48p_4 ah11 nc 4 io_l49n_4 ab14 nc 4 io_l49p_4 ac14 nc 4 io_l50_4/no_pair af11 nc 4 io_l53_4/no_pair ag11 nc 4 io_l54n_4 aj10 nc 4 io_l54p_4 ak10 nc 4 io_l56n_4 af12 nc 4 io_l56p_4 af13 nc 4 io_l57n_4 ag13 nc ta bl e 9 : ff896 ? xc2vp7, xc2vp20, xc2vpx20, and xc2vp30 bank pin description pin number no connects virtex-ii pro devices xc2vpx20 (if different) xc2vp7 xc2vp20, xc2vpx20 xc2vp30 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 80 product not recommended for new designs 4 io_l57p_4/vref_4 ah13 nc 4 io_l67n_4 ab15 4 io_l67p_4 ac15 4 io_l68n_4 ad14 4 io_l68p_4 ae14 4 io_l69n_4 af14 4 io_l69p_4/vref_4 ag14 4 io_l73n_4 ad15 4 io_l73p_4 ae15 4 io_l74n_4/gclk3s af15 4 io_l74p_4/gclk2p ag15 4 io_l75n_4/gclk1s ah15 4 io_l75p_4/gclk0p aj15 5 io_l75n_5/gclk7s br efclkn aj16 5 io_l75p_5/gclk6p brefclkp ah16 5 io_l74n_5/gclk5s ag16 5 io_l74p_5/gclk4p af16 5 io_l73n_5 ae16 5 io_l73p_5 ad16 5 io_l69n_5/vref_5 ag17 5 io_l69p_5 af17 5 io_l68n_5 ae17 5 io_l68p_5 ad17 5 io_l67n_5 ac16 5 io_l67p_5 ab16 5 io_l57n_5/vref_5 ah18 nc 5 io_l57p_5 ag18 nc 5 io_l56n_5 af18 nc 5 io_l56p_5 af19 nc 5 io_l54n_5 ak21 nc 5 io_l54p_5 aj21 nc 5 io_l53_5/no_pair ag20 nc 5 io_l50_5/no_pair af20 nc 5 io_l49n_5 ac17 nc 5 io_l49p_5 ab17 nc ta bl e 9 : ff896 ? xc2vp7, xc2vp20, xc2vpx20, and xc2vp30 bank pin description pin number no connects virtex-ii pro devices xc2vpx20 (if different) xc2vp7 xc2vp20, xc2vpx20 xc2vp30 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 81 product not recommended for new designs 5 io_l48n_5 ah20 nc 5 io_l48p_5 ah21 nc 5 io_l47n_5 ae19 nc 5 io_l47p_5 ae20 nc 5 io_l46n_5 ad18 nc 5 io_l46p_5 ac18 nc 5 io_l45n_5/vref_5 aj22 5 io_l45p_5 ah22 5 io_l44n_5 ae21 5 io_l44p_5 ae22 5 io_l43n_5 ad19 5 io_l43p_5 ac19 5 io_l39n_5 ag21 5 io_l39p_5 af21 5 io_l38n_5 af22 5 io_l38p_5 af23 5 io_l37n_5 ad20 5 io_l37p_5 ac20 5 io_l09n_5/vref_5 ak23 5 io_l09p_5 aj23 5 io_l08n_5 ae23 5 io_l08p_5 ae24 5 io_l07n_5/vref_5 ad21 5 io_l07p_5 ac21 5 io_l06n_5/vrp_5 ah23 5 io_l06p_5/vrn_5 ag23 5 io_l05_5/no_pair ad23 5 io_l03n_5/d4 ah24 5 io_l03p_5/d5 ag24 5 io_l02n_5/d6 ad22 5 io_l02p_5/d7 ac22 5 io_l01n_5/rdwr_b af24 5 io_l01p_5/cs_b ag25 6 io_l01p_6/vrn_6 ak28 6 io_l01n_6/vrp_6 aj28 ta bl e 9 : ff896 ? xc2vp7, xc2vp20, xc2vpx20, and xc2vp30 bank pin description pin number no connects virtex-ii pro devices xc2vpx20 (if different) xc2vp7 xc2vp20, xc2vpx20 xc2vp30 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 82 product not recommended for new designs 6 io_l02p_6 ah26 6 io_l02n_6 ag26 6 io_l03p_6 ah29 6 io_l03n_6/vref_6 ah30 6 io_l04p_6 ah27 6 io_l04n_6 ag28 6 io_l05p_6 ad25 6 io_l05n_6 ad26 6 io_l06p_6 ag29 6 io_l06n_6 ag30 6 io_l31p_6 af25 nc 6 io_l31n_6 ae26 nc 6 io_l32p_6 ab23 nc 6 io_l32n_6 ab24 nc 6 io_l33p_6 ae27 nc 6 io_l33n_6/vref_6 ae28 nc 6 io_l34p_6 af27 nc 6 io_l34n_6 af28 nc 6 io_l35p_6 ac25 nc 6 io_l35n_6 ac26 nc 6 io_l36p_6 af29 nc 6 io_l36n_6 af30 nc 6 io_l37p_6 ad27 nc 6 io_l37n_6 ad28 nc 6 io_l38p_6 aa23 nc 6 io_l38n_6 aa24 nc 6 io_l39p_6 ae29 nc 6 io_l39n_6/vref_6 ae30 nc 6 io_l40p_6 ab25 nc 6 io_l40n_6 ab26 nc 6 io_l41p_6 y23 nc 6 io_l41n_6 y24 nc 6 io_l42p_6 ad29 nc 6 io_l42n_6 ad30 nc 6 io_l43p_6 ac27 6 io_l43n_6 ac28 ta bl e 9 : ff896 ? xc2vp7, xc2vp20, xc2vpx20, and xc2vp30 bank pin description pin number no connects virtex-ii pro devices xc2vpx20 (if different) xc2vp7 xc2vp20, xc2vpx20 xc2vp30 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 83 product not recommended for new designs 6 io_l44p_6 aa25 6 io_l44n_6 aa26 6 io_l45p_6 ac29 6 io_l45n_6/vref_6 ab29 6 io_l46p_6 ab27 6 io_l46n_6 ab28 6 io_l47p_6 w23 6 io_l47n_6 w24 6 io_l48p_6 aa27 6 io_l48n_6 aa28 6 io_l49p_6 y26 6 io_l49n_6 y27 6 io_l50p_6 w25 6 io_l50n_6 w26 6 io_l51p_6 ab30 6 io_l51n_6/vref_6 aa30 6 io_l52p_6 w27 6 io_l52n_6 w28 6 io_l53p_6 v23 6 io_l53n_6 v24 6 io_l54p_6 aa29 6 io_l54n_6 y29 6 io_l55p_6 v25 6 io_l55n_6 v26 6 io_l56p_6 u23 6 io_l56n_6 u24 6 io_l57p_6 y30 6 io_l57n_6/vref_6 w30 6 io_l58p_6 v27 6 io_l58n_6 v28 6 io_l59p_6 u22 6 io_l59n_6 t22 6 io_l60p_6 w29 6 io_l60n_6 v29 6 io_l85p_6 u26 6 io_l85n_6 u27 ta bl e 9 : ff896 ? xc2vp7, xc2vp20, xc2vpx20, and xc2vp30 bank pin description pin number no connects virtex-ii pro devices xc2vpx20 (if different) xc2vp7 xc2vp20, xc2vpx20 xc2vp30 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 84 product not recommended for new designs 6 io_l86p_6 t23 6 io_l86n_6 t24 6 io_l87p_6 u28 6 io_l87n_6/vref_6 u29 6 io_l88p_6 t27 6 io_l88n_6 t28 6 io_l89p_6 t25 6 io_l89n_6 t26 6 io_l90p_6 v30 6 io_l90n_6 u30 7 io_l90p_7 r28 7 io_l90n_7 r27 7 io_l89p_7 r26 7 io_l89n_7 r25 7 io_l88p_7 t29 7 io_l88n_7/vref_7 r29 7 io_l87p_7 p27 7 io_l87n_7 p26 7 io_l86p_7 r24 7 io_l86n_7 r23 7 io_l85p_7 p29 7 io_l85n_7 p28 7 io_l60p_7 n28 7 io_l60n_7 n27 7 io_l59p_7 p24 7 io_l59n_7 p23 7 io_l58p_7 p30 7 io_l58n_7/vref_7 n30 7 io_l57p_7 m28 7 io_l57n_7 m27 7 io_l56p_7 r22 7 io_l56n_7 p22 7 io_l55p_7 n29 7 io_l55n_7 m29 7 io_l54p_7 l27 ta bl e 9 : ff896 ? xc2vp7, xc2vp20, xc2vpx20, and xc2vp30 bank pin description pin number no connects virtex-ii pro devices xc2vpx20 (if different) xc2vp7 xc2vp20, xc2vpx20 xc2vp30 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 85 product not recommended for new designs 7 io_l54n_7 l26 7 io_l53p_7 n26 7 io_l53n_7 n25 7 io_l52p_7 m30 7 io_l52n_7/vref_7 l30 7 io_l51p_7 k28 7 io_l51n_7 k27 7 io_l50p_7 n24 7 io_l50n_7 n23 7 io_l49p_7 l29 7 io_l49n_7 k29 7 io_l48p_7 j28 7 io_l48n_7 j27 7 io_l47p_7 m26 7 io_l47n_7 m25 7 io_l46p_7 k30 7 io_l46n_7/vref_7 j30 7 io_l45p_7 k26 7 io_l45n_7 k25 7 io_l44p_7 m24 7 io_l44n_7 m23 7 io_l43p_7 j29 7 io_l43n_7 h29 7 io_l42p_7 h28 nc 7 io_l42n_7 h27 nc 7 io_l41p_7 l24 nc 7 io_l41n_7 l23 nc 7 io_l40p_7 g30 nc 7 io_l40n_7/vref_7 g29 nc 7 io_l39p_7 g28 nc 7 io_l39n_7 g27 nc 7 io_l38p_7 j26 nc 7 io_l38n_7 j25 nc 7 io_l37p_7 f30 nc 7 io_l37n_7 f29 nc 7 io_l36p_7 f28 nc ta bl e 9 : ff896 ? xc2vp7, xc2vp20, xc2vpx20, and xc2vp30 bank pin description pin number no connects virtex-ii pro devices xc2vpx20 (if different) xc2vp7 xc2vp20, xc2vpx20 xc2vp30 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 86 product not recommended for new designs 7 io_l36n_7 f27 nc 7 io_l35p_7 k24 nc 7 io_l35n_7 k23 nc 7 io_l34p_7 e30 nc 7 io_l34n_7/vref_7 e29 nc 7 io_l33p_7 e28 nc 7 io_l33n_7 e27 nc 7 io_l32p_7 h26 nc 7 io_l32n_7 h25 nc 7 io_l31p_7 d30 nc 7 io_l31n_7 d29 nc 7 io_l06p_7 d28 7 io_l06n_7 c27 7 io_l05p_7 j24 7 io_l05n_7 j23 7 io_l04p_7 c30 7 io_l04n_7/vref_7 c29 7 io_l03p_7 d26 7 io_l03n_7 c26 7 io_l02p_7 g26 7 io_l02n_7 g25 7 io_l01p_7/vrn_7 b28 7 io_l01n_7/vrp_7 a28 0 vcco_0 k21 0 vcco_0 k20 0 vcco_0 k19 0 vcco_0 k18 0 vcco_0 k17 0 vcco_0 k16 0 vcco_0 j21 0 vcco_0 j20 0 vcco_0 j19 0 vcco_0 j18 1 vcco_1 k15 1 vcco_1 k14 ta bl e 9 : ff896 ? xc2vp7, xc2vp20, xc2vpx20, and xc2vp30 bank pin description pin number no connects virtex-ii pro devices xc2vpx20 (if different) xc2vp7 xc2vp20, xc2vpx20 xc2vp30 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 87 product not recommended for new designs 1 vcco_1 k13 1 vcco_1 k12 1 vcco_1 k11 1 vcco_1 k10 1 vcco_1 j13 1 vcco_1 j12 1 vcco_1 j11 1 vcco_1 j10 2 vcco_2 r10 2 vcco_2 p10 2 vcco_2 n10 2 vcco_2 n9 2 vcco_2 m10 2 vcco_2 m9 2 vcco_2 l10 2 vcco_2 l9 2 vcco_2 k9 2 vcco_2 j9 3 vcco_3 ab9 3 vcco_3 aa9 3 vcco_3 y10 3 vcco_3 y9 3 vcco_3 w10 3 vcco_3 w9 3 vcco_3 v10 3 vcco_3 v9 3 vcco_3 u10 3 vcco_3 t10 4 vcco_4 ab13 4 vcco_4 ab12 4 vcco_4 ab11 4 vcco_4 ab10 4 vcco_4 aa15 4 vcco_4 aa14 4 vcco_4 aa13 4 vcco_4 aa12 ta bl e 9 : ff896 ? xc2vp7, xc2vp20, xc2vpx20, and xc2vp30 bank pin description pin number no connects virtex-ii pro devices xc2vpx20 (if different) xc2vp7 xc2vp20, xc2vpx20 xc2vp30 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 88 product not recommended for new designs 4 vcco_4 aa11 4 vcco_4 aa10 5 vcco_5 ab21 5 vcco_5 ab20 5 vcco_5 ab19 5 vcco_5 ab18 5 vcco_5 aa21 5 vcco_5 aa20 5 vcco_5 aa19 5 vcco_5 aa18 5 vcco_5 aa17 5 vcco_5 aa16 6 vcco_6 ab22 6 vcco_6 aa22 6 vcco_6 y22 6 vcco_6 y21 6 vcco_6 w22 6 vcco_6 w21 6 vcco_6 v22 6 vcco_6 v21 6 vcco_6 u21 6 vcco_6 t21 7 vcco_7 r21 7 vcco_7 p21 7 vcco_7 n22 7 vcco_7 n21 7 vcco_7 m22 7 vcco_7 m21 7 vcco_7 l22 7 vcco_7 l21 7 vcco_7 k22 7 vcco_7 j22 n/a cclk ac7 n/a prog_b g24 n/a done ac8 ta bl e 9 : ff896 ? xc2vp7, xc2vp20, xc2vpx20, and xc2vp30 bank pin description pin number no connects virtex-ii pro devices xc2vpx20 (if different) xc2vp7 xc2vp20, xc2vpx20 xc2vp30 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 89 product not recommended for new designs n/a m0 ad24 n/a m1 ac24 n/a m2 ac23 n/a tck g7 n/a tdi f26 n/a tdo f5 n/a tms h8 n/a pwrdwn_b ad7 n/a hswap_en h23 n/a rsvd d6 n/a vbatt h7 n/a dxp h24 n/a dxn d25 n/a avccauxtx4 b26 n/a vttxpad4 b27 n/a txnpad4 a27 n/a txppad4 a26 n/a gnda4 c25 n/a rxppad4 a25 n/a rxnpad4 a24 n/a vtrxpad4 b25 n/a avccauxrx4 b24 n/a avccauxtx6 b19 n/a vttxpad6 b20 n/a txnpad6 a20 n/a txppad6 a19 n/a gnda6 c19 n/a rxppad6 a18 n/a rxnpad6 a17 n/a vtrxpad6 b18 n/a avccauxrx6 b17 n/a avccauxtx7 b13 n/a vttxpad7 b14 n/a txnpad7 a14 n/a txppad7 a13 n/a gnda7 c12 ta bl e 9 : ff896 ? xc2vp7, xc2vp20, xc2vpx20, and xc2vp30 bank pin description pin number no connects virtex-ii pro devices xc2vpx20 (if different) xc2vp7 xc2vp20, xc2vpx20 xc2vp30 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 90 product not recommended for new designs n/a rxppad7 a12 n/a rxnpad7 a11 n/a vtrxpad7 b12 n/a avccauxrx7 b11 n/a avccauxtx9 b6 n/a vttxpad9 b7 n/a txnpad9 a7 n/a txppad9 a6 n/a gnda9 c6 n/a rxppad9 a5 n/a rxnpad9 a4 n/a vtrxpad9 b5 n/a avccauxrx9 b4 n/a avccauxrx16 aj4 n/a vtrxpad16 aj5 n/a rxnpad16 ak4 n/a rxppad16 ak5 n/a gnda16 ah6 n/a txppad16 ak6 n/a txnpad16 ak7 n/a vttxpad16 aj7 n/a avccauxtx16 aj6 n/a avccauxrx18 aj11 n/a vtrxpad18 aj12 n/a rxnpad18 ak11 n/a rxppad18 ak12 n/a gnda18 ah12 n/a txppad18 ak13 n/a txnpad18 ak14 n/a vttxpad18 aj14 n/a avccauxtx18 aj13 n/a avccauxrx19 aj17 n/a vtrxpad19 aj18 n/a rxnpad19 ak17 n/a rxppad19 ak18 n/a gnda19 ah19 ta bl e 9 : ff896 ? xc2vp7, xc2vp20, xc2vpx20, and xc2vp30 bank pin description pin number no connects virtex-ii pro devices xc2vpx20 (if different) xc2vp7 xc2vp20, xc2vpx20 xc2vp30 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 91 product not recommended for new designs n/a txppad19 ak19 n/a txnpad19 ak20 n/a vttxpad19 aj20 n/a avccauxtx19 aj19 n/a avccauxrx21 aj24 n/a vtrxpad21 aj25 n/a rxnpad21 ak24 n/a rxppad21 ak25 n/a gnda21 ah25 n/a txppad21 ak26 n/a txnpad21 ak27 n/a vttxpad21 aj27 n/a avccauxtx21 aj26 n/a vccaux ak29 n/a vccaux ak16 n/a vccaux ak15 n/a vccaux ak2 n/a vccaux aj30 n/a vccaux aj1 n/a vccaux t30 n/a vccaux t1 n/a vccaux r30 n/a vccaux r1 n/a vccaux b30 n/a vccaux b1 n/a vccaux a29 n/a vccaux a16 n/a vccaux a15 n/a vccaux a2 n/a vccint y19 n/a vccint y18 n/a vccint y17 n/a vccint y16 n/a vccint y15 n/a vccint y14 ta bl e 9 : ff896 ? xc2vp7, xc2vp20, xc2vpx20, and xc2vp30 bank pin description pin number no connects virtex-ii pro devices xc2vpx20 (if different) xc2vp7 xc2vp20, xc2vpx20 xc2vp30 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 92 product not recommended for new designs n/a vccint y13 n/a vccint y12 n/a vccint w20 n/a vccint w11 n/a vccint v20 n/a vccint v11 n/a vccint u20 n/a vccint u11 n/a vccint t20 n/a vccint t11 n/a vccint r20 n/a vccint r11 n/a vccint p20 n/a vccint p11 n/a vccint n20 n/a vccint n11 n/a vccint m20 n/a vccint m11 n/a vccint l19 n/a vccint l18 n/a vccint l17 n/a vccint l16 n/a vccint l15 n/a vccint l14 n/a vccint l13 n/a vccint l12 n/a gnd ak22 n/a gnd ak9 n/a gnd aj29 n/a gnd aj2 n/a gnd ah28 n/a gnd ah17 n/a gnd ah14 n/a gnd ah3 n/a gnd ag27 n/a gnd ag22 ta bl e 9 : ff896 ? xc2vp7, xc2vp20, xc2vpx20, and xc2vp30 bank pin description pin number no connects virtex-ii pro devices xc2vpx20 (if different) xc2vp7 xc2vp20, xc2vpx20 xc2vp30 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 93 product not recommended for new designs n/a gnd ag19 n/a gnd ag12 n/a gnd ag9 n/a gnd ag4 n/a gnd af26 n/a gnd af5 n/a gnd ae25 n/a gnd ae18 n/a gnd ae13 n/a gnd ae6 n/a gnd ac30 n/a gnd ac1 n/a gnd y28 n/a gnd y25 n/a gnd y20 n/a gnd y11 n/a gnd y6 n/a gnd y3 n/a gnd w19 n/a gnd w18 n/a gnd w17 n/a gnd w16 n/a gnd w15 n/a gnd w14 n/a gnd w13 n/a gnd w12 n/a gnd v19 n/a gnd v18 n/a gnd v17 n/a gnd v16 n/a gnd v15 n/a gnd v14 n/a gnd v13 n/a gnd v12 n/a gnd u25 n/a gnd u19 ta bl e 9 : ff896 ? xc2vp7, xc2vp20, xc2vpx20, and xc2vp30 bank pin description pin number no connects virtex-ii pro devices xc2vpx20 (if different) xc2vp7 xc2vp20, xc2vpx20 xc2vp30 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 94 product not recommended for new designs n/a gnd u18 n/a gnd u17 n/a gnd u16 n/a gnd u15 n/a gnd u14 n/a gnd u13 n/a gnd u12 n/a gnd u6 n/a gnd t19 n/a gnd t18 n/a gnd t17 n/a gnd t16 n/a gnd t15 n/a gnd t14 n/a gnd t13 n/a gnd t12 n/a gnd r19 n/a gnd r18 n/a gnd r17 n/a gnd r16 n/a gnd r15 n/a gnd r14 n/a gnd r13 n/a gnd r12 n/a gnd p25 n/a gnd p19 n/a gnd p18 n/a gnd p17 n/a gnd p16 n/a gnd p15 n/a gnd p14 n/a gnd p13 n/a gnd p12 n/a gnd p6 n/a gnd n19 n/a gnd n18 ta bl e 9 : ff896 ? xc2vp7, xc2vp20, xc2vpx20, and xc2vp30 bank pin description pin number no connects virtex-ii pro devices xc2vpx20 (if different) xc2vp7 xc2vp20, xc2vpx20 xc2vp30 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 95 product not recommended for new designs n/a gnd n17 n/a gnd n16 n/a gnd n15 n/a gnd n14 n/a gnd n13 n/a gnd n12 n/a gnd m19 n/a gnd m18 n/a gnd m17 n/a gnd m16 n/a gnd m15 n/a gnd m14 n/a gnd m13 n/a gnd m12 n/a gnd l28 n/a gnd l25 n/a gnd l20 n/a gnd l11 n/a gnd l6 n/a gnd l3 n/a gnd h30 n/a gnd h1 n/a gnd f25 n/a gnd f18 n/a gnd f13 n/a gnd f6 n/a gnd e26 n/a gnd e5 n/a gnd d27 n/a gnd d22 n/a gnd d19 n/a gnd d12 n/a gnd d9 n/a gnd d4 n/a gnd c28 n/a gnd c17 ta bl e 9 : ff896 ? xc2vp7, xc2vp20, xc2vpx20, and xc2vp30 bank pin description pin number no connects virtex-ii pro devices xc2vpx20 (if different) xc2vp7 xc2vp20, xc2vpx20 xc2vp30 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 96 product not recommended for new designs n/a gnd c14 n/a gnd c3 n/a gnd b29 n/a gnd b2 n/a gnd a22 n/a gnd a9 notes: 1. see ta b l e 4 for an explanation of the signals available on this pin. ta bl e 9 : ff896 ? xc2vp7, xc2vp20, xc2vpx20, and xc2vp30 bank pin description pin number no connects virtex-ii pro devices xc2vpx20 (if different) xc2vp7 xc2vp20, xc2vpx20 xc2vp30 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 97 product not recommended for new designs ff896 flip-chip fine-pitch bga pack age specifications (1.00mm pitch) figure 5: ff896 flip-chip fine-pitch bga package specifications virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 98 product not recommended for new designs ff1152 flip-chip fine-pitch bga package as shown in ta bl e 1 0 , xc2vp20, xc2vp30, xc2vp40, and xc2vp50 virtex-ii pro devices are available in the ff1152 flip-chip fine-pitch bga package. pins in each of these devices are the same, except for the differences shown in the no connect column. following this table are the ff1152 flip-chip fine-pitch bga package specifications (1.00mm pitch) . ta bl e 1 0 : ff1152 ? xc2vp20, xc2vp30, xc2vp40, and xc2vp50 bank pin description pin number no connects xc2vp20 xc2vp30 xc2vp40 xc2vp50 0 io_l01n_0/vrp_0 e29 0 io_l01p_0/vrn_0 e28 0 io_l02n_0 h26 0 io_l02p_0 g26 0 io_l03n_0 h25 0 io_l03p_0/vref_0 g25 0 io_l05_0/no_pair j25 0 io_l06n_0 k24 0 io_l06p_0 j24 0 io_l07n_0 f26 0 io_l07p_0 e26 0 io_l08n_0 d30 0 io_l08p_0 d29 0 io_l09n_0 k23 0 io_l09p_0/vref_0 j23 0 io_l19n_0 f24 nc nc 0 io_l19p_0 e24 nc nc 0 io_l20n_0 d28 nc nc 0 io_l20p_0 c28 nc nc 0 io_l21n_0 h24 nc nc 0 io_l21p_0 g24 nc nc 0 io_l25n_0 g23 nc nc 0 io_l25p_0 f23 nc nc 0 io_l26n_0 e27 nc nc 0 io_l26p_0 d27 nc nc 0 io_l27n_0 k22 nc nc 0 io_l27p_0/vref_0 j22 nc nc 0 io_l37n_0 h22 0 io_l37p_0 g22 0 io_l38n_0 d26 0 io_l38p_0 c26 0 io_l39n_0 k21 0 io_l39p_0 j21 0 io_l43n_0 f22 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 99 product not recommended for new designs 0 io_l43p_0 e22 0 io_l44n_0 e25 0 io_l44p_0 d25 0 io_l45n_0 h21 0 io_l45p_0/vref_0 g21 0 io_l46n_0 d22 0 io_l46p_0 d23 0 io_l47n_0 d24 0 io_l47p_0 c24 0 io_l48n_0 k20 0 io_l48p_0 j20 0 io_l49n_0 f21 0 io_l49p_0 e21 0 io_l50_0/no_pair c21 0 io_l53_0/no_pair c22 0 io_l54n_0 l19 0 io_l54p_0 k19 0 io_l55n_0 g20 0 io_l55p_0 f20 0 io_l56n_0 d21 0 io_l56p_0 d20 0 io_l57n_0 j19 0 io_l57p_0/vref_0 h19 0 io_l67n_0 g19 0 io_l67p_0 f19 0 io_l68n_0 e19 0 io_l68p_0 d19 0 io_l69n_0 l18 0 io_l69p_0/vref_0 k18 0 io_l73n_0 g18 0 io_l73p_0 f18 0 io_l74n_0/gclk7p e18 0 io_l74p_0/gclk6s d18 0 io_l75n_0/gclk5p j18 0 io_l75p_0/gclk4s h18 1 io_l75n_1/gclk3p h17 1 io_l75p_1/gclk2s j17 ta bl e 1 0 : ff1152 ? xc2vp20, xc2vp30, xc2vp40, and xc2vp50 bank pin description pin number no connects xc2vp20 xc2vp30 xc2vp40 xc2vp50 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 100 product not recommended for new designs 1 io_l74n_1/gclk1p d17 1 io_l74p_1/gclk0s e17 1 io_l73n_1 f17 1 io_l73p_1 g17 1 io_l69n_1/vref_1 k17 1 io_l69p_1 l17 1 io_l68n_1 d16 1 io_l68p_1 e16 1 io_l67n_1 f16 1 io_l67p_1 g16 1 io_l57n_1/vref_1 h16 1 io_l57p_1 j16 1 io_l56n_1 d15 1 io_l56p_1 d14 1 io_l55n_1 f15 1 io_l55p_1 g15 1 io_l54n_1 k16 1 io_l54p_1 l16 1 io_l53_1/no_pair c13 1 io_l50_1/no_pair c14 1 io_l49n_1 e14 1 io_l49p_1 f14 1 io_l48n_1 j15 1 io_l48p_1 k15 1 io_l47n_1 c11 1 io_l47p_1 d11 1 io_l46n_1 d12 1 io_l46p_1 d13 1 io_l45n_1/vref_1 g14 1 io_l45p_1 h14 1 io_l44n_1 d10 1 io_l44p_1 e10 1 io_l43n_1 e13 1 io_l43p_1 f13 1 io_l39n_1 j14 1 io_l39p_1 k14 1 io_l38n_1 c9 1 io_l38p_1 d9 ta bl e 1 0 : ff1152 ? xc2vp20, xc2vp30, xc2vp40, and xc2vp50 bank pin description pin number no connects xc2vp20 xc2vp30 xc2vp40 xc2vp50 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 101 product not recommended for new designs 1 io_l37n_1 g13 1 io_l37p_1 h13 1 io_l27n_1/vref_1 j13 nc nc 1 io_l27p_1 k13 nc nc 1 io_l26n_1 d8 nc nc 1 io_l26p_1 e8 nc nc 1 io_l25n_1 f12 nc nc 1 io_l25p_1 g12 nc nc 1 io_l21n_1 g11 nc nc 1 io_l21p_1 h11 nc nc 1 io_l20n_1 c7 nc nc 1 io_l20p_1 d7 nc nc 1 io_l19n_1 e11 nc nc 1 io_l19p_1 f11 nc nc 1 io_l09n_1/vref_1 j12 1 io_l09p_1 k12 1 io_l08n_1 d6 1 io_l08p_1 d5 1 io_l07n_1 e9 1 io_l07p_1 f9 1 io_l06n_1 j11 1 io_l06p_1 k11 1 io_l05_1/no_pair j10 1 io_l03n_1/vref_1 g10 1 io_l03p_1 h10 1 io_l02n_1 g9 1 io_l02p_1 h9 1 io_l01n_1/vrp_1 e7 1 io_l01p_1/vrn_1 e6 2 io_l01n_2/vrp_2 d2 2 io_l01p_2/vrn_2 d1 2 io_l02n_2 f8 2 io_l02p_2 f7 2 io_l03n_2 e4 2 io_l03p_2 e3 2 io_l04n_2/vref_2 e2 2 io_l04p_2 e1 ta bl e 1 0 : ff1152 ? xc2vp20, xc2vp30, xc2vp40, and xc2vp50 bank pin description pin number no connects xc2vp20 xc2vp30 xc2vp40 xc2vp50 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 102 product not recommended for new designs 2 io_l05n_2 j8 2 io_l05p_2 j7 2 io_l06n_2 f5 2 io_l06p_2 f4 2 io_l15n_2 g4 nc 2 io_l15p_2 g3 nc 2 io_l16n_2/vref_2 g6 nc 2 io_l16p_2 g5 nc 2 io_l17n_2 f2 nc 2 io_l17p_2 f1 nc 2 io_l18n_2 l10 nc 2 io_l18p_2 l9 nc 2 io_l19n_2 h6 nc 2 io_l19p_2 h5 nc 2 io_l20n_2 g2 nc 2 io_l20p_2 g1 nc 2 io_l21n_2 j6 nc 2 io_l21p_2 j5 nc 2 io_l22n_2/vref_2 j4 nc 2 io_l22p_2 j3 nc 2 io_l23n_2 k8 nc 2 io_l23p_2 k7 nc 2 io_l24n_2 h4 nc 2 io_l24p_2 h3 nc 2 io_l31n_2 h2 2 io_l31p_2 h1 2 io_l32n_2 m10 2 io_l32p_2 m9 2 io_l33n_2 k5 2 io_l33p_2 k4 2 io_l34n_2/vref_2 j2 2 io_l34p_2 k2 2 io_l35n_2 l8 2 io_l35p_2 l7 2 io_l36n_2 l6 2 io_l36p_2 l5 2 io_l37n_2 k1 2 io_l37p_2 l1 ta bl e 1 0 : ff1152 ? xc2vp20, xc2vp30, xc2vp40, and xc2vp50 bank pin description pin number no connects xc2vp20 xc2vp30 xc2vp40 xc2vp50 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 103 product not recommended for new designs 2 io_l38n_2 n10 2 io_l38p_2 n9 2 io_l39n_2 m7 2 io_l39p_2 m6 2 io_l40n_2/vref_2 l2 2 io_l40p_2 m2 2 io_l41n_2 n8 2 io_l41p_2 n7 2 io_l42n_2 l4 2 io_l42p_2 l3 2 io_l43n_2 m4 2 io_l43p_2 m3 2 io_l44n_2 p10 2 io_l44p_2 p9 2 io_l45n_2 n6 2 io_l45p_2 n5 2 io_l46n_2/vref_2 m1 2 io_l46p_2 n1 2 io_l47n_2 p8 2 io_l47p_2 p7 2 io_l48n_2 n4 2 io_l48p_2 n3 2 io_l49n_2 n2 2 io_l49p_2 p2 2 io_l50n_2 r10 2 io_l50p_2 r9 2 io_l51n_2 p6 2 io_l51p_2 p5 2 io_l52n_2/vref_2 p4 2 io_l52p_2 p3 2 io_l53n_2 t11 2 io_l53p_2 u11 2 io_l54n_2 r7 2 io_l54p_2 r6 2 io_l55n_2 p1 2 io_l55p_2 r1 2 io_l56n_2 t10 2 io_l56p_2 t9 ta bl e 1 0 : ff1152 ? xc2vp20, xc2vp30, xc2vp40, and xc2vp50 bank pin description pin number no connects xc2vp20 xc2vp30 xc2vp40 xc2vp50 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 104 product not recommended for new designs 2 io_l57n_2 r4 2 io_l57p_2 r3 2 io_l58n_2/vref_2 r2 2 io_l58p_2 t2 2 io_l59n_2 t8 2 io_l59p_2 t7 2 io_l60n_2 t6 2 io_l60p_2 t5 2 io_l85n_2 t4 2 io_l85p_2 t3 2 io_l86n_2 u10 2 io_l86p_2 u9 2 io_l87n_2 u6 2 io_l87p_2 u5 2 io_l88n_2/vref_2 u2 2 io_l88p_2 v2 2 io_l89n_2 u8 2 io_l89p_2 u7 2 io_l90n_2 u4 2 io_l90p_2 u3 3 io_l90n_3 v3 3 io_l90p_3 v4 3 io_l89n_3 v7 3 io_l89p_3 v8 3 io_l88n_3 v5 3 io_l88p_3 v6 3 io_l87n_3/vref_3 w2 3 io_l87p_3 y2 3 io_l86n_3 v9 3 io_l86p_3 v10 3 io_l85n_3 w3 3 io_l85p_3 w4 3 io_l60n_3 y1 3 io_l60p_3 aa1 3 io_l59n_3 v11 3 io_l59p_3 w11 3 io_l58n_3 w5 ta bl e 1 0 : ff1152 ? xc2vp20, xc2vp30, xc2vp40, and xc2vp50 bank pin description pin number no connects xc2vp20 xc2vp30 xc2vp40 xc2vp50 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 105 product not recommended for new designs 3 io_l58p_3 w6 3 io_l57n_3/vref_3 y3 3 io_l57p_3 y4 3 io_l56n_3 w7 3 io_l56p_3 w8 3 io_l55n_3 y6 3 io_l55p_3 y7 3 io_l54n_3 aa2 3 io_l54p_3 ab2 3 io_l53n_3 w9 3 io_l53p_3 w10 3 io_l52n_3 aa3 3 io_l52p_3 aa4 3 io_l51n_3/vref_3 ab1 3 io_l51p_3 ac1 3 io_l50n_3 y9 3 io_l50p_3 y10 3 io_l49n_3 aa5 3 io_l49p_3 aa6 3 io_l48n_3 ab3 3 io_l48p_3 ab4 3 io_l47n_3 aa7 3 io_l47p_3 aa8 3 io_l46n_3 ab5 3 io_l46p_3 ab6 3 io_l45n_3/vref_3 ac2 3 io_l45p_3 ad2 3 io_l44n_3 aa9 3 io_l44p_3 aa10 3 io_l43n_3 ac3 3 io_l43p_3 ac4 3 io_l42n_3 ad1 3 io_l42p_3 ae1 3 io_l41n_3 ab7 3 io_l41p_3 ab8 3 io_l40n_3 ac6 3 io_l40p_3 ac7 3 io_l39n_3/vref_3 ad3 ta bl e 1 0 : ff1152 ? xc2vp20, xc2vp30, xc2vp40, and xc2vp50 bank pin description pin number no connects xc2vp20 xc2vp30 xc2vp40 xc2vp50 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 106 product not recommended for new designs 3 io_l39p_3 ad4 3 io_l38n_3 ab9 3 io_l38p_3 ab10 3 io_l37n_3 ad5 3 io_l37p_3 ad6 3 io_l36n_3 ae2 3 io_l36p_3 af2 3 io_l35n_3 ad7 3 io_l35p_3 ad8 3 io_l34n_3 ae4 3 io_l34p_3 ae5 3 io_l33n_3/vref_3 ag1 3 io_l33p_3 ag2 3 io_l32n_3 ac9 3 io_l32p_3 ac10 3 io_l31n_3 af3 3 io_l31p_3 af4 3 io_l24n_3 ah1 nc 3 io_l24p_3 ah2 nc 3 io_l23n_3 ae7 nc 3 io_l23p_3 ae8 nc 3 io_l22n_3 af5 nc 3 io_l22p_3 af6 nc 3 io_l21n_3/vref_3 ag3 nc 3 io_l21p_3 ag4 nc 3 io_l20n_3 ad9 nc 3 io_l20p_3 ad10 nc 3 io_l19n_3 ah3 nc 3 io_l19p_3 ah4 nc 3 io_l18n_3 aj1 nc 3 io_l18p_3 aj2 nc 3 io_l17n_3 af7 nc 3 io_l17p_3 af8 nc 3 io_l16n_3 ak1 nc 3 io_l16p_3 ak2 nc 3 io_l15n_3/vref_3 ag5 nc 3 io_l15p_3 ag6 nc 3 io_l06n_3 al1 ta bl e 1 0 : ff1152 ? xc2vp20, xc2vp30, xc2vp40, and xc2vp50 bank pin description pin number no connects xc2vp20 xc2vp30 xc2vp40 xc2vp50 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 107 product not recommended for new designs 3 io_l06p_3 al2 3 io_l05n_3 ag7 3 io_l05p_3 ah8 3 io_l04n_3 ah5 3 io_l04p_3 ah6 3 io_l03n_3/vref_3 ak3 3 io_l03p_3 ak4 3 io_l02n_3 aj7 3 io_l02p_3 aj8 3 io_l01n_3/vrp_3 aj4 3 io_l01p_3/vrn_3 aj5 4 io_l01n_4/busy/dout (1) al5 4 io_l01p_4/init_b al6 4 io_l02n_4/d0/din (1) ag9 4 io_l02p_4/d1 ah9 4 io_l03n_4/d2 ak6 4 io_l03p_4/d3 ak7 4 io_l05_4/no_pair af10 4 io_l06n_4/vrp_4 al7 4 io_l06p_4/vrn_4 am7 4 io_l07n_4 ae11 4 io_l07p_4/vref_4 af11 4 io_l08n_4 ag10 4 io_l08p_4 ah10 4 io_l09n_4 ak8 4 io_l09p_4/vref_4 al8 4 io_l19n_4 ae12 nc nc 4 io_l19p_4 af12 nc nc 4 io_l20n_4 aj9 nc nc 4 io_l20p_4 ak9 nc nc 4 io_l21n_4 al9 nc nc 4 io_l21p_4 am9 nc nc 4 io_l25n_4 ag11 nc nc 4 io_l25p_4 ah11 nc nc 4 io_l26n_4 ah12 nc nc 4 io_l26p_4 aj12 nc nc 4 io_l27n_4 ak10 nc nc ta bl e 1 0 : ff1152 ? xc2vp20, xc2vp30, xc2vp40, and xc2vp50 bank pin description pin number no connects xc2vp20 xc2vp30 xc2vp40 xc2vp50 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 108 product not recommended for new designs 4 io_l27p_4/vref_4 al10 nc nc 4 io_l37n_4 ae13 4 io_l37p_4 af13 4 io_l38n_4 ag13 4 io_l38p_4 ah13 4 io_l39n_4 aj11 4 io_l39p_4 ak11 4 io_l43n_4 ae14 4 io_l43p_4 af14 4 io_l44n_4 aj13 4 io_l44p_4 ak13 4 io_l45n_4 al11 4 io_l45p_4/vref_4 am11 4 io_l46n_4 ae15 4 io_l46p_4 af15 4 io_l47n_4 ag14 4 io_l47p_4 ah14 4 io_l48n_4 al13 4 io_l48p_4 al12 4 io_l49n_4 ad16 4 io_l49p_4 ae16 4 io_l50_4/no_pair aj14 4 io_l53_4/no_pair ak14 4 io_l54n_4 am14 4 io_l54p_4 am13 4 io_l55n_4 af16 4 io_l55p_4 ag16 4 io_l56n_4 ah15 4 io_l56p_4 aj15 4 io_l57n_4 al14 4 io_l57p_4/vref_4 al15 4 io_l67n_4 ad17 4 io_l67p_4 ae17 4 io_l68n_4 ah16 4 io_l68p_4 aj16 4 io_l69n_4 ak16 4 io_l69p_4/vref_4 al16 4 io_l73n_4 af17 ta bl e 1 0 : ff1152 ? xc2vp20, xc2vp30, xc2vp40, and xc2vp50 bank pin description pin number no connects xc2vp20 xc2vp30 xc2vp40 xc2vp50 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 109 product not recommended for new designs 4 io_l73p_4 ag17 4 io_l74n_4/gclk3s ah17 4 io_l74p_4/gclk2p aj17 4 io_l75n_4/gclk1s ak17 4 io_l75p_4/gclk0p al17 5 io_l75n_5/gclk7s al18 5 io_l75p_5/gclk6p ak18 5 io_l74n_5/gclk5s aj18 5 io_l74p_5/gclk4p ah18 5 io_l73n_5 ag18 5 io_l73p_5 af18 5 io_l69n_5/vref_5 al19 5 io_l69p_5 ak19 5 io_l68n_5 aj19 5 io_l68p_5 ah19 5 io_l67n_5 ae18 5 io_l67p_5 ad18 5 io_l57n_5/vref_5 al20 5 io_l57p_5 al21 5 io_l56n_5 aj20 5 io_l56p_5 ah20 5 io_l55n_5 ag19 5 io_l55p_5 af19 5 io_l54n_5 am22 5 io_l54p_5 am21 5 io_l53_5/no_pair ak21 5 io_l50_5/no_pair aj21 5 io_l49n_5 ae19 5 io_l49p_5 ad19 5 io_l48n_5 al23 5 io_l48p_5 al22 5 io_l47n_5 ah21 5 io_l47p_5 ag21 5 io_l46n_5 af20 5 io_l46p_5 ae20 5 io_l45n_5/vref_5 am24 5 io_l45p_5 al24 ta bl e 1 0 : ff1152 ? xc2vp20, xc2vp30, xc2vp40, and xc2vp50 bank pin description pin number no connects xc2vp20 xc2vp30 xc2vp40 xc2vp50 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 110 product not recommended for new designs 5 io_l44n_5 ak22 5 io_l44p_5 aj22 5 io_l43n_5 af21 5 io_l43p_5 ae21 5 io_l39n_5 ak24 5 io_l39p_5 aj24 5 io_l38n_5 ah22 5 io_l38p_5 ag22 5 io_l37n_5 af22 5 io_l37p_5 ae22 5 io_l27n_5/vref_5 al25 nc nc 5 io_l27p_5 ak25 nc nc 5 io_l26n_5 aj23 nc nc 5 io_l26p_5 ah23 nc nc 5 io_l25n_5 ah24 nc nc 5 io_l25p_5 ag24 nc nc 5 io_l21n_5 am26 nc nc 5 io_l21p_5 al26 nc nc 5 io_l20n_5 ak26 nc nc 5 io_l20p_5 aj26 nc nc 5 io_l19n_5 af23 nc nc 5 io_l19p_5 ae23 nc nc 5 io_l09n_5/vref_5 al27 5 io_l09p_5 ak27 5 io_l08n_5 ah25 5 io_l08p_5 ag25 5 io_l07n_5/vref_5 af24 5 io_l07p_5 ae24 5 io_l06n_5/vrp_5 am28 5 io_l06p_5/vrn_5 al28 5 io_l05_5/no_pair af25 5 io_l03n_5/d4 ak28 5 io_l03p_5/d5 ak29 5 io_l02n_5/d6 ah26 5 io_l02p_5/d7 ag26 5 io_l01n_5/rdwr_b al29 5 io_l01p_5/cs_b al30 ta bl e 1 0 : ff1152 ? xc2vp20, xc2vp30, xc2vp40, and xc2vp50 bank pin description pin number no connects xc2vp20 xc2vp30 xc2vp40 xc2vp50 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 111 product not recommended for new designs 6 io_l01p_6/vrn_6 aj30 6 io_l01n_6/vrp_6 aj31 6 io_l02p_6 aj27 6 io_l02n_6 aj28 6 io_l03p_6 ak31 6 io_l03n_6/vref_6 ak32 6 io_l04p_6 ah29 6 io_l04n_6 ah30 6 io_l05p_6 ah27 6 io_l05n_6 ag28 6 io_l06p_6 al33 6 io_l06n_6 al34 6 io_l15p_6 ag29 nc 6 io_l15n_6/vref_6 ag30 nc 6 io_l16p_6 ak33 nc 6 io_l16n_6 ak34 nc 6 io_l17p_6 af27 nc 6 io_l17n_6 af28 nc 6 io_l18p_6 aj33 nc 6 io_l18n_6 aj34 nc 6 io_l19p_6 ah31 nc 6 io_l19n_6 ah32 nc 6 io_l20p_6 ad25 nc 6 io_l20n_6 ad26 nc 6 io_l21p_6 ag31 nc 6 io_l21n_6/vref_6 ag32 nc 6 io_l22p_6 af29 nc 6 io_l22n_6 af30 nc 6 io_l23p_6 ae27 nc 6 io_l23n_6 ae28 nc 6 io_l24p_6 ah33 nc 6 io_l24n_6 ah34 nc 6 io_l31p_6 af31 6 io_l31n_6 af32 6 io_l32p_6 ac25 6 io_l32n_6 ac26 6 io_l33p_6 ag33 6 io_l33n_6/vref_6 ag34 ta bl e 1 0 : ff1152 ? xc2vp20, xc2vp30, xc2vp40, and xc2vp50 bank pin description pin number no connects xc2vp20 xc2vp30 xc2vp40 xc2vp50 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 112 product not recommended for new designs 6 io_l34p_6 ae30 6 io_l34n_6 ae31 6 io_l35p_6 ad27 6 io_l35n_6 ad28 6 io_l36p_6 af33 6 io_l36n_6 ae33 6 io_l37p_6 ad29 6 io_l37n_6 ad30 6 io_l38p_6 ab25 6 io_l38n_6 ab26 6 io_l39p_6 ad31 6 io_l39n_6/vref_6 ad32 6 io_l40p_6 ac28 6 io_l40n_6 ac29 6 io_l41p_6 ab27 6 io_l41n_6 ab28 6 io_l42p_6 ae34 6 io_l42n_6 ad34 6 io_l43p_6 ac31 6 io_l43n_6 ac32 6 io_l44p_6 aa25 6 io_l44n_6 aa26 6 io_l45p_6 ad33 6 io_l45n_6/vref_6 ac33 6 io_l46p_6 ab29 6 io_l46n_6 ab30 6 io_l47p_6 aa27 6 io_l47n_6 aa28 6 io_l48p_6 ab31 6 io_l48n_6 ab32 6 io_l49p_6 aa29 6 io_l49n_6 aa30 6 io_l50p_6 y25 6 io_l50n_6 y26 6 io_l51p_6 ac34 6 io_l51n_6/vref_6 ab34 6 io_l52p_6 aa31 6 io_l52n_6 aa32 ta bl e 1 0 : ff1152 ? xc2vp20, xc2vp30, xc2vp40, and xc2vp50 bank pin description pin number no connects xc2vp20 xc2vp30 xc2vp40 xc2vp50 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 113 product not recommended for new designs 6 io_l53p_6 w25 6 io_l53n_6 w26 6 io_l54p_6 ab33 6 io_l54n_6 aa33 6 io_l55p_6 y28 6 io_l55n_6 y29 6 io_l56p_6 w27 6 io_l56n_6 w28 6 io_l57p_6 y31 6 io_l57n_6/vref_6 y32 6 io_l58p_6 w29 6 io_l58n_6 w30 6 io_l59p_6 w24 6 io_l59n_6 v24 6 io_l60p_6 aa34 6 io_l60n_6 y34 6 io_l85p_6 w31 6 io_l85n_6 w32 6 io_l86p_6 v25 6 io_l86n_6 v26 6 io_l87p_6 y33 6 io_l87n_6/vref_6 w33 6 io_l88p_6 v29 6 io_l88n_6 v30 6 io_l89p_6 v27 6 io_l89n_6 v28 6 io_l90p_6 v31 6 io_l90n_6 v32 7 io_l90p_7 u32 7 io_l90n_7 u31 7 io_l89p_7 u28 7 io_l89n_7 u27 7 io_l88p_7 v33 7 io_l88n_7/vref_7 u33 7 io_l87p_7 u30 7 io_l87n_7 u29 7 io_l86p_7 u26 ta bl e 1 0 : ff1152 ? xc2vp20, xc2vp30, xc2vp40, and xc2vp50 bank pin description pin number no connects xc2vp20 xc2vp30 xc2vp40 xc2vp50 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 114 product not recommended for new designs 7 io_l86n_7 u25 7 io_l85p_7 t32 7 io_l85n_7 t31 7 io_l60p_7 t30 7 io_l60n_7 t29 7 io_l59p_7 t28 7 io_l59n_7 t27 7 io_l58p_7 t33 7 io_l58n_7/vref_7 r33 7 io_l57p_7 r32 7 io_l57n_7 r31 7 io_l56p_7 t26 7 io_l56n_7 t25 7 io_l55p_7 r34 7 io_l55n_7 p34 7 io_l54p_7 r29 7 io_l54n_7 r28 7 io_l53p_7 u24 7 io_l53n_7 t24 7 io_l52p_7 p32 7 io_l52n_7/vref_7 p31 7 io_l51p_7 p30 7 io_l51n_7 p29 7 io_l50p_7 r26 7 io_l50n_7 r25 7 io_l49p_7 p33 7 io_l49n_7 n33 7 io_l48p_7 n32 7 io_l48n_7 n31 7 io_l47p_7 p28 7 io_l47n_7 p27 7 io_l46p_7 n34 7 io_l46n_7/vref_7 m34 7 io_l45p_7 n30 7 io_l45n_7 n29 7 io_l44p_7 p26 7 io_l44n_7 p25 7 io_l43p_7 m32 ta bl e 1 0 : ff1152 ? xc2vp20, xc2vp30, xc2vp40, and xc2vp50 bank pin description pin number no connects xc2vp20 xc2vp30 xc2vp40 xc2vp50 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 115 product not recommended for new designs 7 io_l43n_7 m31 7 io_l42p_7 l32 7 io_l42n_7 l31 7 io_l41p_7 n28 7 io_l41n_7 n27 7 io_l40p_7 m33 7 io_l40n_7/vref_7 l33 7 io_l39p_7 m29 7 io_l39n_7 m28 7 io_l38p_7 n26 7 io_l38n_7 n25 7 io_l37p_7 l34 7 io_l37n_7 k34 7 io_l36p_7 l30 7 io_l36n_7 l29 7 io_l35p_7 l28 7 io_l35n_7 l27 7 io_l34p_7 k33 7 io_l34n_7/vref_7 j33 7 io_l33p_7 k31 7 io_l33n_7 k30 7 io_l32p_7 m26 7 io_l32n_7 m25 7 io_l31p_7 h34 7 io_l31n_7 h33 7 io_l24p_7 h32 nc 7 io_l24n_7 h31 nc 7 io_l23p_7 k28 nc 7 io_l23n_7 k27 nc 7 io_l22p_7 j32 nc 7 io_l22n_7/vref_7 j31 nc 7 io_l21p_7 j30 nc 7 io_l21n_7 j29 nc 7 io_l20p_7 g34 nc 7 io_l20n_7 g33 nc 7 io_l19p_7 h30 nc 7 io_l19n_7 h29 nc 7 io_l18p_7 l26 nc ta bl e 1 0 : ff1152 ? xc2vp20, xc2vp30, xc2vp40, and xc2vp50 bank pin description pin number no connects xc2vp20 xc2vp30 xc2vp40 xc2vp50 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 116 product not recommended for new designs 7 io_l18n_7 l25 nc 7 io_l17p_7 f34 nc 7 io_l17n_7 f33 nc 7 io_l16p_7 g30 nc 7 io_l16n_7/vref_7 g29 nc 7 io_l15p_7 g32 nc 7 io_l15n_7 g31 nc 7 io_l06p_7 f31 7 io_l06n_7 f30 7 io_l05p_7 j28 7 io_l05n_7 j27 7 io_l04p_7 e34 7 io_l04n_7/vref_7 e33 7 io_l03p_7 e32 7 io_l03n_7 e31 7 io_l02p_7 f28 7 io_l02n_7 f27 7 io_l01p_7/vrn_7 d34 7 io_l01n_7/vrp_7 d33 0 vcco_0 c29 0 vcco_0 e20 0 vcco_0 f25 0 vcco_0 l20 0 vcco_0 l21 0 vcco_0 l22 0 vcco_0 l23 0 vcco_0 m18 0 vcco_0 m19 0 vcco_0 m20 0 vcco_0 m21 0 vcco_0 m22 1 vcco_1 c6 1 vcco_1 e15 1 vcco_1 f10 1 vcco_1 l12 1 vcco_1 l13 1 vcco_1 l14 ta bl e 1 0 : ff1152 ? xc2vp20, xc2vp30, xc2vp40, and xc2vp50 bank pin description pin number no connects xc2vp20 xc2vp30 xc2vp40 xc2vp50 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 117 product not recommended for new designs 1 vcco_1 l15 1 vcco_1 m13 1 vcco_1 m14 1 vcco_1 m15 1 vcco_1 m16 1 vcco_1 m17 2 vcco_2 f3 2 vcco_2 k6 2 vcco_2 m11 2 vcco_2 n11 2 vcco_2 n12 2 vcco_2 p11 2 vcco_2 p12 2 vcco_2 r5 2 vcco_2 r11 2 vcco_2 r12 2 vcco_2 t12 2 vcco_2 u12 3 vcco_3 v12 3 vcco_3 w12 3 vcco_3 y5 3 vcco_3 y11 3 vcco_3 y12 3 vcco_3 aa11 3 vcco_3 aa12 3 vcco_3 ab11 3 vcco_3 ab12 3 vcco_3 ac11 3 vcco_3 ae6 3 vcco_3 aj3 4 vcco_4 ac13 4 vcco_4 ac14 4 vcco_4 ac15 4 vcco_4 ac16 4 vcco_4 ac17 4 vcco_4 ad12 4 vcco_4 ad13 4 vcco_4 ad14 ta bl e 1 0 : ff1152 ? xc2vp20, xc2vp30, xc2vp40, and xc2vp50 bank pin description pin number no connects xc2vp20 xc2vp30 xc2vp40 xc2vp50 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 118 product not recommended for new designs 4 vcco_4 ad15 4 vcco_4 aj10 4 vcco_4 ak15 4 vcco_4 am6 5 vcco_5 ac18 5 vcco_5 ac19 5 vcco_5 ac20 5 vcco_5 ac21 5 vcco_5 ac22 5 vcco_5 ad20 5 vcco_5 ad21 5 vcco_5 ad22 5 vcco_5 ad23 5 vcco_5 aj25 5 vcco_5 ak20 5 vcco_5 am29 6 vcco_6 v23 6 vcco_6 w23 6 vcco_6 y23 6 vcco_6 y24 6 vcco_6 y30 6 vcco_6 aa23 6 vcco_6 aa24 6 vcco_6 ab23 6 vcco_6 ab24 6 vcco_6 ac24 6 vcco_6 ae29 6 vcco_6 aj32 7 vcco_7 f32 7 vcco_7 k29 7 vcco_7 m24 7 vcco_7 n23 7 vcco_7 n24 7 vcco_7 p23 7 vcco_7 p24 7 vcco_7 r23 7 vcco_7 r24 7 vcco_7 r30 ta bl e 1 0 : ff1152 ? xc2vp20, xc2vp30, xc2vp40, and xc2vp50 bank pin description pin number no connects xc2vp20 xc2vp30 xc2vp40 xc2vp50 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 119 product not recommended for new designs 7 vcco_7 t23 7 vcco_7 u23 n/a cclk ae9 n/a prog_b j26 n/a done ae10 n/a m0 af26 n/a m1 ae26 n/a m2 ae25 n/a tck j9 n/a tdi h28 n/a tdo h7 n/a tms k10 n/a pwrdwn_b af9 n/a hswap_en k25 n/a rsvd g8 n/a vbatt k9 n/a dxp k26 n/a dxn g27 n/a avccauxtx2 b32 nc nc n/a vttxpad2 b33 nc nc n/a txnpad2 a33 nc nc n/a txppad2 a32 nc nc n/a gnda2 c30 nc nc n/a rxppad2 a31 nc nc n/a rxnpad2 a30 nc nc n/a vtrxpad2 b31 nc nc n/a avccauxrx2 b30 nc nc n/a avccauxtx4 b28 n/a vttxpad4 b29 n/a txnpad4 a29 n/a txppad4 a28 n/a gnda4 c27 n/a rxppad4 a27 n/a rxnpad4 a26 n/a vtrxpad4 b27 n/a avccauxrx4 b26 n/a avccauxtx5 b24 nc nc nc ta bl e 1 0 : ff1152 ? xc2vp20, xc2vp30, xc2vp40, and xc2vp50 bank pin description pin number no connects xc2vp20 xc2vp30 xc2vp40 xc2vp50 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 120 product not recommended for new designs n/a vttxpad5 b25 nc nc nc n/a txnpad5 a25 nc nc nc n/a txppad5 a24 nc nc nc n/a gnda5 c23 nc nc nc n/a rxppad5 a23 nc nc nc n/a rxnpad5 a22 nc nc nc n/a vtrxpad5 b23 nc nc nc n/a avccauxrx5 b22 nc nc nc n/a avccauxtx6 b20 n/a vttxpad6 b21 n/a txnpad6 a21 n/a txppad6 a20 n/a gnda6 c20 n/a rxppad6 a19 n/a rxnpad6 a18 n/a vtrxpad6 b19 n/a avccauxrx6 b18 n/a avccauxtx7 b16 n/a vttxpad7 b17 n/a txnpad7 a17 n/a txppad7 a16 n/a gnda7 c15 n/a rxppad7 a15 n/a rxnpad7 a14 n/a vtrxpad7 b15 n/a avccauxrx7 b14 n/a avccauxtx8 b12 nc nc nc n/a vttxpad8 b13 nc nc nc n/a txnpad8 a13 nc nc nc n/a txppad8 a12 nc nc nc n/a gnda8 c12 nc nc nc n/a rxppad8 a11 nc nc nc n/a rxnpad8 a10 nc nc nc n/a vtrxpad8 b11 nc nc nc n/a avccauxrx8 b10 nc nc nc n/a avccauxtx9 b8 n/a vttxpad9 b9 n/a txnpad9 a9 ta bl e 1 0 : ff1152 ? xc2vp20, xc2vp30, xc2vp40, and xc2vp50 bank pin description pin number no connects xc2vp20 xc2vp30 xc2vp40 xc2vp50 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 121 product not recommended for new designs n/a txppad9 a8 n/a gnda9 c8 n/a rxppad9 a7 n/a rxnpad9 a6 n/a vtrxpad9 b7 n/a avccauxrx9 b6 n/a avccauxtx11 b4 nc nc n/a vttxpad11 b5 nc nc n/a txnpad11 a5 nc nc n/a txppad11 a4 nc nc n/a gnda11 c5 nc nc n/a rxppad11 a3 nc nc n/a rxnpad11 a2 nc nc n/a vtrxpad11 b3 nc nc n/a avccauxrx11 b2 nc nc n/a avccauxrx14 an2 nc nc n/a vtrxpad14 an3 nc nc n/a rxnpad14 ap2 nc nc n/a rxppad14 ap3 nc nc n/a gnda14 am5 nc nc n/a txppad14 ap4 nc nc n/a txnpad14 ap5 nc nc n/a vttxpad14 an5 nc nc n/a avccauxtx14 an4 nc nc n/a avccauxrx16 an6 n/a vtrxpad16 an7 n/a rxnpad16 ap6 n/a rxppad16 ap7 n/a gnda16 am8 n/a txppad16 ap8 n/a txnpad16 ap9 n/a vttxpad16 an9 n/a avccauxtx16 an8 n/a avccauxrx17 an10 nc nc nc n/a vtrxpad17 an11 nc nc nc n/a rxnpad17 ap10 nc nc nc n/a rxppad17 ap11 nc nc nc n/a gnda17 am12 nc nc nc ta bl e 1 0 : ff1152 ? xc2vp20, xc2vp30, xc2vp40, and xc2vp50 bank pin description pin number no connects xc2vp20 xc2vp30 xc2vp40 xc2vp50 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 122 product not recommended for new designs n/a txppad17 ap12 nc nc nc n/a txnpad17 ap13 nc nc nc n/a vttxpad17 an13 nc nc nc n/a avccauxtx17 an12 nc nc nc n/a avccauxrx18 an14 n/a vtrxpad18 an15 n/a rxnpad18 ap14 n/a rxppad18 ap15 n/a gnda18 am15 n/a txppad18 ap16 n/a txnpad18 ap17 n/a vttxpad18 an17 n/a avccauxtx18 an16 n/a avccauxrx19 an18 n/a vtrxpad19 an19 n/a rxnpad19 ap18 n/a rxppad19 ap19 n/a gnda19 am20 n/a txppad19 ap20 n/a txnpad19 ap21 n/a vttxpad19 an21 n/a avccauxtx19 an20 n/a avccauxrx20 an22 nc nc nc n/a vtrxpad20 an23 nc nc nc n/a rxnpad20 ap22 nc nc nc n/a rxppad20 ap23 nc nc nc n/a gnda20 am23 nc nc nc n/a txppad20 ap24 nc nc nc n/a txnpad20 ap25 nc nc nc n/a vttxpad20 an25 nc nc nc n/a avccauxtx20 an24 nc nc nc n/a avccauxrx21 an26 n/a vtrxpad21 an27 n/a rxnpad21 ap26 n/a rxppad21 ap27 n/a gnda21 am27 n/a txppad21 ap28 n/a txnpad21 ap29 ta bl e 1 0 : ff1152 ? xc2vp20, xc2vp30, xc2vp40, and xc2vp50 bank pin description pin number no connects xc2vp20 xc2vp30 xc2vp40 xc2vp50 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 123 product not recommended for new designs n/a vttxpad21 an29 n/a avccauxtx21 an28 n/a avccauxrx23 an30 nc nc n/a vtrxpad23 an31 nc nc n/a rxnpad23 ap30 nc nc n/a rxppad23 ap31 nc nc n/a gnda23 am30 nc nc n/a txppad23 ap32 nc nc n/a txnpad23 ap33 nc nc n/a vttxpad23 an33 nc nc n/a avccauxtx23 an32 nc nc n/a vccint l11 n/a vccint l24 n/a vccint m12 n/a vccint m23 n/a vccint n13 n/a vccint n14 n/a vccint n15 n/a vccint n16 n/a vccint n17 n/a vccint n18 n/a vccint n19 n/a vccint n20 n/a vccint n21 n/a vccint n22 n/a vccint p13 n/a vccint p22 n/a vccint r13 n/a vccint r22 n/a vccint t13 n/a vccint t22 n/a vccint u13 n/a vccint u22 n/a vccint v13 n/a vccint v22 n/a vccint w13 n/a vccint w22 ta bl e 1 0 : ff1152 ? xc2vp20, xc2vp30, xc2vp40, and xc2vp50 bank pin description pin number no connects xc2vp20 xc2vp30 xc2vp40 xc2vp50 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 124 product not recommended for new designs n/a vccint y13 n/a vccint y22 n/a vccint aa13 n/a vccint aa22 n/a vccint ab13 n/a vccint ab14 n/a vccint ab15 n/a vccint ab16 n/a vccint ab17 n/a vccint ab18 n/a vccint ab19 n/a vccint ab20 n/a vccint ab21 n/a vccint ab22 n/a vccint ac12 n/a vccint ac23 n/a vccint ad11 n/a vccint ad24 n/a vccaux c3 n/a vccaux c4 n/a vccaux c17 n/a vccaux c18 n/a vccaux c31 n/a vccaux c32 n/a vccaux d3 n/a vccaux d32 n/a vccaux u1 n/a vccaux v1 n/a vccaux u34 n/a vccaux v34 n/a vccaux al3 n/a vccaux al32 n/a vccaux am3 n/a vccaux am4 n/a vccaux am17 n/a vccaux am18 n/a vccaux am31 n/a vccaux am32 ta bl e 1 0 : ff1152 ? xc2vp20, xc2vp30, xc2vp40, and xc2vp50 bank pin description pin number no connects xc2vp20 xc2vp30 xc2vp40 xc2vp50 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 125 product not recommended for new designs n/a gnd af34 n/a gnd b34 n/a gnd c1 n/a gnd c2 n/a gnd c10 n/a gnd c16 n/a gnd c19 n/a gnd c25 n/a gnd c33 n/a gnd c34 n/a gnd d4 n/a gnd d31 n/a gnd e5 n/a gnd e12 n/a gnd e23 n/a gnd e30 n/a gnd f6 n/a gnd f29 n/a gnd g7 n/a gnd g28 n/a gnd b1 n/a gnd h8 n/a gnd h12 n/a gnd h15 n/a gnd h20 n/a gnd j1 n/a gnd h27 n/a gnd af1 n/a gnd k3 n/a gnd k32 n/a gnd m5 n/a gnd m8 n/a gnd m27 n/a gnd m30 n/a gnd p14 n/a gnd p15 n/a gnd p16 ta bl e 1 0 : ff1152 ? xc2vp20, xc2vp30, xc2vp40, and xc2vp50 bank pin description pin number no connects xc2vp20 xc2vp30 xc2vp40 xc2vp50 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 126 product not recommended for new designs n/a gnd p17 n/a gnd p18 n/a gnd p19 n/a gnd p20 n/a gnd p21 n/a gnd r8 n/a gnd r14 n/a gnd r15 n/a gnd r16 n/a gnd r17 n/a gnd r18 n/a gnd r19 n/a gnd r20 n/a gnd r21 n/a gnd r27 n/a gnd t1 n/a gnd t14 n/a gnd t15 n/a gnd t16 n/a gnd t17 n/a gnd t18 n/a gnd t19 n/a gnd t20 n/a gnd t21 n/a gnd t34 n/a gnd u14 n/a gnd u15 n/a gnd u16 n/a gnd u17 n/a gnd u18 n/a gnd u19 n/a gnd u20 n/a gnd u21 n/a gnd v14 n/a gnd v15 n/a gnd v16 n/a gnd v17 n/a gnd v18 ta bl e 1 0 : ff1152 ? xc2vp20, xc2vp30, xc2vp40, and xc2vp50 bank pin description pin number no connects xc2vp20 xc2vp30 xc2vp40 xc2vp50 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 127 product not recommended for new designs n/a gnd v19 n/a gnd v20 n/a gnd v21 n/a gnd w1 n/a gnd w14 n/a gnd w15 n/a gnd w16 n/a gnd w17 n/a gnd w18 n/a gnd w19 n/a gnd w20 n/a gnd w21 n/a gnd w34 n/a gnd y8 n/a gnd y14 n/a gnd y15 n/a gnd y16 n/a gnd y17 n/a gnd y18 n/a gnd y19 n/a gnd y20 n/a gnd y21 n/a gnd y27 n/a gnd aa14 n/a gnd aa15 n/a gnd aa16 n/a gnd aa17 n/a gnd aa18 n/a gnd aa19 n/a gnd aa20 n/a gnd aa21 n/a gnd ac5 n/a gnd ac8 n/a gnd ac27 n/a gnd ac30 n/a gnd ae3 n/a gnd ae32 n/a gnd h23 ta bl e 1 0 : ff1152 ? xc2vp20, xc2vp30, xc2vp40, and xc2vp50 bank pin description pin number no connects xc2vp20 xc2vp30 xc2vp40 xc2vp50 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 128 product not recommended for new designs n/a gnd ag8 n/a gnd ag12 n/a gnd ag15 n/a gnd ag20 n/a gnd ag23 n/a gnd ag27 n/a gnd j34 n/a gnd ah7 n/a gnd ah28 n/a gnd aj6 n/a gnd aj29 n/a gnd ak5 n/a gnd ak12 n/a gnd ak23 n/a gnd ak30 n/a gnd al4 n/a gnd al31 n/a gnd am1 n/a gnd am2 n/a gnd am10 n/a gnd am16 n/a gnd am19 n/a gnd am25 n/a gnd am33 n/a gnd am34 n/a gnd an1 n/a gnd an34 notes: 1. see ta b l e 4 for an explanation of the signals available on this pin. ta bl e 1 0 : ff1152 ? xc2vp20, xc2vp30, xc2vp40, and xc2vp50 bank pin description pin number no connects xc2vp20 xc2vp30 xc2vp40 xc2vp50 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 129 product not recommended for new designs ff1152 flip-chip fine-pitc h bga package specificat ions (1.00mm pitch) figure 6: ff1152 flip-chip fine-pitch bga package specifications virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 130 product not recommended for new designs ff1148 flip-chip fine-pitch bga package as shown in ta bl e 1 1 , xc2vp40 and xc2vp50 virtex-ii pro devices are available in the ff1148 flip-chip fine-pitch bga package. pins in each of these devices are the same, except for the differences shown in the no connect column. following this table are the ff1148 flip-chip fine-pitch bga package specifications (1.00mm pitch) . ta bl e 1 1 : ff1148 ? xc2vp40 and xc2vp50 bank pin description pin number no connects xc2vp40 xc2vp50 0 io_l01n_0/vrp_0 e25 0 io_l01p_0/vrn_0 f25 0 io_l02n_0 j24 0 io_l02p_0 k24 0 io_l03n_0 c25 0 io_l03p_0/vref_0 d25 0 io_l05_0/no_pair g25 0 io_l06n_0 a25 0 io_l06p_0 b25 0 io_l07n_0 g24 0 io_l07p_0 g23 0 io_l08n_0 h23 0 io_l08p_0 h22 0 io_l09n_0 e24 0 io_l09p_0/vref_0 f24 0 io_l19n_0 c24 0 io_l19p_0 c23 0 io_l20n_0 j23 0 io_l20p_0 k23 0 io_l21n_0 a24 0 io_l21p_0 b24 0 io_l25n_0 e23 0 io_l25p_0 f23 0 io_l26n_0 k22 0 io_l26p_0 l22 0 io_l27n_0 d23 0 io_l27p_0/vref_0 d22 0 io_l37n_0 a23 0 io_l37p_0 b23 0 io_l38n_0 j21 0 io_l38p_0 j20 0 io_l39n_0 f22 0 io_l39p_0 g22 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 131 product not recommended for new designs 0 io_l43n_0 b22 0 io_l43p_0 c22 0 io_l44n_0 k21 0 io_l44p_0 l21 0 io_l45n_0 g21 0 io_l45p_0/vref_0 h21 0 io_l46n_0 e21 0 io_l46p_0 f21 0 io_l47n_0 k20 0 io_l47p_0 l20 0 io_l48n_0 c21 0 io_l48p_0 d21 0 io_l49n_0 a21 0 io_l49p_0 b21 0 io_l50_0/no_pair g20 0 io_l53_0/no_pair h19 0 io_l54n_0 e20 0 io_l54p_0 f20 0 io_l55n_0 c20 0 io_l55p_0 d19 0 io_l56n_0 k19 0 io_l56p_0 l19 0 io_l57n_0 a20 0 io_l57p_0/vref_0 b20 0 io_l66n_0 f19 nc 0 io_l66p_0/vref_0 g19 nc 0 io_l67n_0 b19 0 io_l67p_0 c19 0 io_l68n_0 h18 0 io_l68p_0 j18 0 io_l69n_0 f18 0 io_l69p_0/vref_0 g18 0 io_l73n_0 d18 0 io_l73p_0 e18 0 io_l74n_0/gclk7p k18 0 io_l74p_0/gclk6s l18 0 io_l75n_0/gclk5p b18 0 io_l75p_0/gclk4s c18 ta bl e 1 1 : ff1148 ? xc2vp40 and xc2vp50 bank pin description pin number no connects xc2vp40 xc2vp50 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 132 product not recommended for new designs 1 io_l75n_1/gclk3p c17 1 io_l75p_1/gclk2s b17 1 io_l74n_1/gclk1p l17 1 io_l74p_1/gclk0s k17 1 io_l73n_1 e17 1 io_l73p_1 d17 1 io_l69n_1/vref_1 g17 1 io_l69p_1 f17 1 io_l68n_1 j17 1 io_l68p_1 h17 1 io_l67n_1 c16 1 io_l67p_1 b16 1 io_l66n_1/vref_1 g16 nc 1 io_l66p_1 f16 nc 1 io_l57n_1/vref_1 b15 1 io_l57p_1 a15 1 io_l56n_1 l16 1 io_l56p_1 k16 1 io_l55n_1 d16 1 io_l55p_1 c15 1 io_l54n_1 f15 1 io_l54p_1 e15 1 io_l53_1/no_pair h16 1 io_l50_1/no_pair g15 1 io_l49n_1 b14 1 io_l49p_1 a14 1 io_l48n_1 d14 1 io_l48p_1 c14 1 io_l47n_1 l15 1 io_l47p_1 k15 1 io_l46n_1 f14 1 io_l46p_1 e14 1 io_l45n_1/vref_1 h14 1 io_l45p_1 g14 1 io_l44n_1 l14 1 io_l44p_1 k14 1 io_l43n_1 c13 ta bl e 1 1 : ff1148 ? xc2vp40 and xc2vp50 bank pin description pin number no connects xc2vp40 xc2vp50 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 133 product not recommended for new designs 1 io_l43p_1 b13 1 io_l39n_1 g13 1 io_l39p_1 f13 1 io_l38n_1 j15 1 io_l38p_1 j14 1 io_l37n_1 b12 1 io_l37p_1 a12 1 io_l27n_1/vref_1 d13 1 io_l27p_1 d12 1 io_l26n_1 l13 1 io_l26p_1 k13 1 io_l25n_1 f12 1 io_l25p_1 e12 1 io_l21n_1 b11 1 io_l21p_1 a11 1 io_l20n_1 k12 1 io_l20p_1 j12 1 io_l19n_1 c12 1 io_l19p_1 c11 1 io_l09n_1/vref_1 f11 1 io_l09p_1 e11 1 io_l08n_1 h13 1 io_l08p_1 h12 1 io_l07n_1 g12 1 io_l07p_1 g11 1 io_l06n_1 b10 1 io_l06p_1 a10 1 io_l05_1/no_pair g10 1 io_l03n_1/vref_1 d10 1 io_l03p_1 c10 1 io_l02n_1 k11 1 io_l02p_1 j11 1 io_l01n_1/vrp_1 f10 1 io_l01p_1/vrn_1 e10 2 io_l01n_2/vrp_2 b8 2 io_l01p_2/vrn_2 b9 2 io_l02n_2 c9 ta bl e 1 1 : ff1148 ? xc2vp40 and xc2vp50 bank pin description pin number no connects xc2vp40 xc2vp50 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 134 product not recommended for new designs 2 io_l02p_2 d9 2 io_l03n_2 b7 2 io_l03p_2 a7 2 io_l04n_2/vref_2 b6 2 io_l04p_2 a6 2 io_l05n_2 e8 2 io_l05p_2 d8 2 io_l06n_2 b4 2 io_l06p_2 a4 2 io_l07n_2 b3 2 io_l07p_2 a3 2 io_l08n_2 h7 2 io_l08p_2 h8 2 io_l09n_2 c6 2 io_l09p_2 c7 2 io_l10n_2/vref_2 c5 2 io_l10p_2 b5 2 io_l11n_2 k8 2 io_l11p_2 j8 2 io_l12n_2 c1 2 io_l12p_2 c2 2 io_l13n_2 e7 2 io_l13p_2 d7 2 io_l14n_2 j6 2 io_l14p_2 j7 2 io_l15n_2 d5 2 io_l15p_2 d6 2 io_l16n_2/vref_2 e4 2 io_l16p_2 d4 2 io_l17n_2 l9 2 io_l17p_2 k9 2 io_l18n_2 e3 2 io_l18p_2 d3 2 io_l19n_2 d1 2 io_l19p_2 d2 2 io_l20n_2 k7 2 io_l20p_2 l7 2 io_l21n_2 f6 ta bl e 1 1 : ff1148 ? xc2vp40 and xc2vp50 bank pin description pin number no connects xc2vp40 xc2vp50 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 135 product not recommended for new designs 2 io_l21p_2 e6 2 io_l22n_2/vref_2 f7 2 io_l22p_2 f8 2 io_l23n_2 m10 2 io_l23p_2 l10 2 io_l24n_2 g5 2 io_l24p_2 f5 2 io_l25n_2 f3 2 io_l25p_2 f4 2 io_l26n_2 m8 2 io_l26p_2 m9 2 io_l27n_2 f1 2 io_l27p_2 f2 2 io_l28n_2/vref_2 g6 2 io_l28p_2 g7 2 io_l29n_2 m7 2 io_l29p_2 n8 2 io_l30n_2 g3 2 io_l30p_2 h4 2 io_l31n_2 g1 2 io_l31p_2 g2 2 io_l32n_2 n10 2 io_l32p_2 n11 2 io_l33n_2 h5 2 io_l33p_2 h6 2 io_l34n_2/vref_2 h2 2 io_l34p_2 h3 2 io_l35n_2 n6 2 io_l35p_2 n7 2 io_l36n_2 k4 2 io_l36p_2 j4 2 io_l37n_2 j2 2 io_l37p_2 j3 2 io_l38n_2 p10 2 io_l38p_2 p11 2 io_l39n_2 k5 2 io_l39p_2 k6 2 io_l40n_2/vref_2 l3 ta bl e 1 1 : ff1148 ? xc2vp40 and xc2vp50 bank pin description pin number no connects xc2vp40 xc2vp50 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 136 product not recommended for new designs 2 io_l40p_2 k3 2 io_l41n_2 r9 2 io_l41p_2 p9 2 io_l42n_2 k1 2 io_l42p_2 k2 2 io_l43n_2 l5 2 io_l43p_2 l6 2 io_l44n_2 p7 2 io_l44p_2 p8 2 io_l45n_2 l1 2 io_l45p_2 l2 2 io_l46n_2/vref_2 m5 2 io_l46p_2 m6 2 io_l47n_2 r10 2 io_l47p_2 r11 2 io_l48n_2 m3 2 io_l48p_2 m4 2 io_l49n_2 m1 2 io_l49p_2 m2 2 io_l50n_2 r7 2 io_l50p_2 t8 2 io_l51n_2 p4 2 io_l51p_2 n4 2 io_l52n_2/vref_2 n2 2 io_l52p_2 n3 2 io_l53n_2 t10 2 io_l53p_2 t11 2 io_l54n_2 p5 2 io_l54p_2 p6 2 io_l55n_2 r3 2 io_l55p_2 p3 2 io_l56n_2 t6 2 io_l56p_2 t7 2 io_l57n_2 p1 2 io_l57p_2 p2 2 io_l58n_2/vref_2 r5 2 io_l58p_2 r6 2 io_l59n_2 u10 ta bl e 1 1 : ff1148 ? xc2vp40 and xc2vp50 bank pin description pin number no connects xc2vp40 xc2vp50 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 137 product not recommended for new designs 2 io_l59p_2 u11 2 io_l60n_2 r1 2 io_l60p_2 r2 2 io_l85n_2 t3 2 io_l85p_2 t4 2 io_l86n_2 u8 2 io_l86p_2 u9 2 io_l87n_2 u2 2 io_l87p_2 t2 2 io_l88n_2/vref_2 u4 2 io_l88p_2 u5 2 io_l89n_2 u6 2 io_l89p_2 u7 2 io_l90n_2 v3 2 io_l90p_2 u3 3 io_l90n_3 v6 3 io_l90p_3 v7 3 io_l89n_3 v10 3 io_l89p_3 v11 3 io_l88n_3 v4 3 io_l88p_3 v5 3 io_l87n_3/vref_3 v2 3 io_l87p_3 w2 3 io_l86n_3 v8 3 io_l86p_3 v9 3 io_l85n_3 w6 3 io_l85p_3 w7 3 io_l60n_3 w3 3 io_l60p_3 w4 3 io_l59n_3 w10 3 io_l59p_3 w11 3 io_l58n_3 y5 3 io_l58p_3 y6 3 io_l57n_3/vref_3 y3 3 io_l57p_3 aa3 3 io_l56n_3 w8 3 io_l56p_3 y7 ta bl e 1 1 : ff1148 ? xc2vp40 and xc2vp50 bank pin description pin number no connects xc2vp40 xc2vp50 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 138 product not recommended for new designs 3 io_l55n_3 y1 3 io_l55p_3 y2 3 io_l54n_3 aa5 3 io_l54p_3 aa6 3 io_l53n_3 y10 3 io_l53p_3 y11 3 io_l52n_3 aa4 3 io_l52p_3 ab4 3 io_l51n_3/vref_3 aa1 3 io_l51p_3 aa2 3 io_l50n_3 y9 3 io_l50p_3 aa9 3 io_l49n_3 ab6 3 io_l49p_3 ab7 3 io_l48n_3 ab2 3 io_l48p_3 ab3 3 io_l47n_3 aa10 3 io_l47p_3 aa11 3 io_l46n_3 ac5 3 io_l46p_3 ac6 3 io_l45n_3/vref_3 ac3 3 io_l45p_3 ac4 3 io_l44n_3 aa7 3 io_l44p_3 aa8 3 io_l43n_3 ac1 3 io_l43p_3 ac2 3 io_l42n_3 ad5 3 io_l42p_3 ad6 3 io_l41n_3 ab10 3 io_l41p_3 ab11 3 io_l40n_3 ad3 3 io_l40p_3 ae3 3 io_l39n_3/vref_3 ad1 3 io_l39p_3 ad2 3 io_l38n_3 ab8 3 io_l38p_3 ac7 3 io_l37n_3 ae5 3 io_l37p_3 ae6 ta bl e 1 1 : ff1148 ? xc2vp40 and xc2vp50 bank pin description pin number no connects xc2vp40 xc2vp50 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 139 product not recommended for new designs 3 io_l36n_3 ae4 3 io_l36p_3 af4 3 io_l35n_3 ac10 3 io_l35p_3 ad10 3 io_l34n_3 ae1 3 io_l34p_3 ae2 3 io_l33n_3/vref_3 af6 3 io_l33p_3 af7 3 io_l32n_3 ac8 3 io_l32p_3 ac9 3 io_l31n_3 af2 3 io_l31p_3 af3 3 io_l30n_3 ag5 3 io_l30p_3 ag6 3 io_l29n_3 ad9 3 io_l29p_3 ae9 3 io_l28n_3 ag4 3 io_l28p_3 ah3 3 io_l27n_3/vref_3 ag2 3 io_l27p_3 ag3 3 io_l26n_3 ad7 3 io_l26p_3 ae7 3 io_l25n_3 ah6 3 io_l25p_3 ah7 3 io_l24n_3 ah5 3 io_l24p_3 aj5 3 io_l23n_3 ae8 3 io_l23p_3 af8 3 io_l22n_3 ah1 3 io_l22p_3 ah2 3 io_l21n_3/vref_3 aj6 3 io_l21p_3 ak6 3 io_l20n_3 ag7 3 io_l20p_3 ag8 3 io_l19n_3 aj3 3 io_l19p_3 aj4 3 io_l18n_3 aj1 3 io_l18p_3 aj2 ta bl e 1 1 : ff1148 ? xc2vp40 and xc2vp50 bank pin description pin number no connects xc2vp40 xc2vp50 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 140 product not recommended for new designs 3 io_l17n_3 ah9 3 io_l17p_3 aj9 3 io_l16n_3 ak7 3 io_l16p_3 al7 3 io_l15n_3/vref_3 ak4 3 io_l15p_3 al4 3 io_l14n_3 aj7 3 io_l14p_3 aj8 3 io_l13n_3 ak3 3 io_l13p_3 al3 3 io_l12n_3 al5 3 io_l12p_3 al6 3 io_l11n_3 ak8 3 io_l11p_3 al8 3 io_l10n_3 al1 3 io_l10p_3 al2 3 io_l09n_3/vref_3 am6 3 io_l09p_3 am7 3 io_l08n_3 al9 3 io_l08p_3 am9 3 io_l07n_3 am5 3 io_l07p_3 an5 3 io_l06n_3 am1 3 io_l06p_3 am2 3 io_l05n_3 an8 3 io_l05p_3 an9 3 io_l04n_3 an6 3 io_l04p_3 ap6 3 io_l03n_3/vref_3 an4 3 io_l03p_3 ap4 3 io_l02n_3 an7 3 io_l02p_3 ap7 3 io_l01n_3/vrp_3 an3 3 io_l01p_3/vrn_3 ap3 4 io_l01n_4/busy/dout (1) ak10 4 io_l01p_4/init_b aj10 4 io_l02n_4/d0/din (1) af11 ta bl e 1 1 : ff1148 ? xc2vp40 and xc2vp50 bank pin description pin number no connects xc2vp40 xc2vp50 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 141 product not recommended for new designs 4 io_l02p_4/d1 ae11 4 io_l03n_4/d2 am10 4 io_l03p_4/d3 al10 4 io_l05_4/no_pair ah10 4 io_l06n_4/vrp_4 ap10 4 io_l06p_4/vrn_4 an10 4 io_l07n_4 ah11 4 io_l07p_4/vref_4 ah12 4 io_l08n_4 ag12 4 io_l08p_4 ag13 4 io_l09n_4 ak11 4 io_l09p_4/vref_4 aj11 4 io_l19n_4 am11 4 io_l19p_4 am12 4 io_l20n_4 af12 4 io_l20p_4 ae12 4 io_l21n_4 ap11 4 io_l21p_4 an11 4 io_l25n_4 ak12 4 io_l25p_4 aj12 4 io_l26n_4 ae13 4 io_l26p_4 ad13 4 io_l27n_4 al12 4 io_l27p_4/vref_4 al13 4 io_l37n_4 ap12 4 io_l37p_4 an12 4 io_l38n_4 af14 4 io_l38p_4 af15 4 io_l39n_4 aj13 4 io_l39p_4 ah13 4 io_l43n_4 an13 4 io_l43p_4 am13 4 io_l44n_4 ae14 4 io_l44p_4 ad14 4 io_l45n_4 ah14 4 io_l45p_4/vref_4 ag14 4 io_l46n_4 ak14 4 io_l46p_4 aj14 ta bl e 1 1 : ff1148 ? xc2vp40 and xc2vp50 bank pin description pin number no connects xc2vp40 xc2vp50 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 142 product not recommended for new designs 4 io_l47n_4 ae15 4 io_l47p_4 ad15 4 io_l48n_4 am14 4 io_l48p_4 al14 4 io_l49n_4 ap14 4 io_l49p_4 an14 4 io_l50_4/no_pair ah15 4 io_l53_4/no_pair ag16 4 io_l54n_4 ak15 4 io_l54p_4 aj15 4 io_l55n_4 am15 4 io_l55p_4 al16 4 io_l56n_4 ae16 4 io_l56p_4 ad16 4 io_l57n_4 ap15 4 io_l57p_4/vref_4 an15 4 io_l66n_4 aj16 nc 4 io_l66p_4/vref_4 ah16 nc 4 io_l67n_4 an16 4 io_l67p_4 am16 4 io_l68n_4 ag17 4 io_l68p_4 af17 4 io_l69n_4 aj17 4 io_l69p_4/vref_4 ah17 4 io_l73n_4 al17 4 io_l73p_4 ak17 4 io_l74n_4/gclk3s ae17 4 io_l74p_4/gclk2p ad17 4 io_l75n_4/gclk1s an17 4 io_l75p_4/gclk0p am17 5 io_l75n_5/gclk7s am18 5 io_l75p_5/gclk6p an18 5 io_l74n_5/gclk5s ad18 5 io_l74p_5/gclk4p ae18 5 io_l73n_5 ak18 5 io_l73p_5 al18 5 io_l69n_5/vref_5 ah18 ta bl e 1 1 : ff1148 ? xc2vp40 and xc2vp50 bank pin description pin number no connects xc2vp40 xc2vp50 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 143 product not recommended for new designs 5 io_l69p_5 aj18 5 io_l68n_5 af18 5 io_l68p_5 ag18 5 io_l67n_5 am19 5 io_l67p_5 an19 5 io_l66n_5/vref_5 ah19 nc 5 io_l66p_5 aj19 nc 5 io_l57n_5/vref_5 an20 5 io_l57p_5 ap20 5 io_l56n_5 ad19 5 io_l56p_5 ae19 5 io_l55n_5 al19 5 io_l55p_5 am20 5 io_l54n_5 aj20 5 io_l54p_5 ak20 5 io_l53_5/no_pair ag19 5 io_l50_5/no_pair ah20 5 io_l49n_5 an21 5 io_l49p_5 ap21 5 io_l48n_5 al21 5 io_l48p_5 am21 5 io_l47n_5 ad20 5 io_l47p_5 ae20 5 io_l46n_5 aj21 5 io_l46p_5 ak21 5 io_l45n_5/vref_5 ag21 5 io_l45p_5 ah21 5 io_l44n_5 ad21 5 io_l44p_5 ae21 5 io_l43n_5 am22 5 io_l43p_5 an22 5 io_l39n_5 ah22 5 io_l39p_5 aj22 5 io_l38n_5 af20 5 io_l38p_5 af21 5 io_l37n_5 an23 5 io_l37p_5 ap23 5 io_l27n_5/vref_5 al22 ta bl e 1 1 : ff1148 ? xc2vp40 and xc2vp50 bank pin description pin number no connects xc2vp40 xc2vp50 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 144 product not recommended for new designs 5 io_l27p_5 al23 5 io_l26n_5 ad22 5 io_l26p_5 ae22 5 io_l25n_5 aj23 5 io_l25p_5 ak23 5 io_l21n_5 an24 5 io_l21p_5 ap24 5 io_l20n_5 ae23 5 io_l20p_5 af23 5 io_l19n_5 am23 5 io_l19p_5 am24 5 io_l09n_5/vref_5 aj24 5 io_l09p_5 ak24 5 io_l08n_5 ag22 5 io_l08p_5 ag23 5 io_l07n_5/vref_5 ah23 5 io_l07p_5 ah24 5 io_l06n_5/vrp_5 an25 5 io_l06p_5/vrn_5 ap25 5 io_l05_5/no_pair ah25 5 io_l03n_5/d4 al25 5 io_l03p_5/d5 am25 5 io_l02n_5/d6 ae24 5 io_l02p_5/d7 af24 5 io_l01n_5/rdwr_b aj25 5 io_l01p_5/cs_b ak25 6 io_l01p_6/vrn_6 ap32 6 io_l01n_6/vrp_6 an32 6 io_l02p_6 ap28 6 io_l02n_6 an28 6 io_l03p_6 ap31 6 io_l03n_6/vref_6 an31 6 io_l04p_6 ap29 6 io_l04n_6 an29 6 io_l05p_6 an26 6 io_l05n_6 an27 6 io_l06p_6 am33 ta bl e 1 1 : ff1148 ? xc2vp40 and xc2vp50 bank pin description pin number no connects xc2vp40 xc2vp50 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 145 product not recommended for new designs 6 io_l06n_6 am34 6 io_l07p_6 an30 6 io_l07n_6 am30 6 io_l08p_6 am26 6 io_l08n_6 al26 6 io_l09p_6 am28 6 io_l09n_6/vref_6 am29 6 io_l10p_6 al33 6 io_l10n_6 al34 6 io_l11p_6 al27 6 io_l11n_6 ak27 6 io_l12p_6 al29 6 io_l12n_6 al30 6 io_l13p_6 al32 6 io_l13n_6 ak32 6 io_l14p_6 aj27 6 io_l14n_6 aj28 6 io_l15p_6 al31 6 io_l15n_6/vref_6 ak31 6 io_l16p_6 al28 6 io_l16n_6 ak28 6 io_l17p_6 aj26 6 io_l17n_6 ah26 6 io_l18p_6 aj33 6 io_l18n_6 aj34 6 io_l19p_6 aj31 6 io_l19n_6 aj32 6 io_l20p_6 ag27 6 io_l20n_6 ag28 6 io_l21p_6 ak29 6 io_l21n_6/vref_6 aj29 6 io_l22p_6 ah33 6 io_l22n_6 ah34 6 io_l23p_6 af27 6 io_l23n_6 ae27 6 io_l24p_6 aj30 6 io_l24n_6 ah30 6 io_l25p_6 ah28 ta bl e 1 1 : ff1148 ? xc2vp40 and xc2vp50 bank pin description pin number no connects xc2vp40 xc2vp50 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 146 product not recommended for new designs 6 io_l25n_6 ah29 6 io_l26p_6 ae28 6 io_l26n_6 ad28 6 io_l27p_6 ag32 6 io_l27n_6/vref_6 ag33 6 io_l28p_6 ah32 6 io_l28n_6 ag31 6 io_l29p_6 ae26 6 io_l29n_6 ad26 6 io_l30p_6 ag29 6 io_l30n_6 ag30 6 io_l31p_6 af32 6 io_l31n_6 af33 6 io_l32p_6 ac26 6 io_l32n_6 ac27 6 io_l33p_6 af28 6 io_l33n_6/vref_6 af29 6 io_l34p_6 ae33 6 io_l34n_6 ae34 6 io_l35p_6 ad25 6 io_l35n_6 ac25 6 io_l36p_6 af31 6 io_l36n_6 ae31 6 io_l37p_6 ae29 6 io_l37n_6 ae30 6 io_l38p_6 ac28 6 io_l38n_6 ab27 6 io_l39p_6 ad33 6 io_l39n_6/vref_6 ad34 6 io_l40p_6 ae32 6 io_l40n_6 ad32 6 io_l41p_6 ab24 6 io_l41n_6 ab25 6 io_l42p_6 ad29 6 io_l42n_6 ad30 6 io_l43p_6 ac33 6 io_l43n_6 ac34 6 io_l44p_6 aa27 ta bl e 1 1 : ff1148 ? xc2vp40 and xc2vp50 bank pin description pin number no connects xc2vp40 xc2vp50 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 147 product not recommended for new designs 6 io_l44n_6 aa28 6 io_l45p_6 ac31 6 io_l45n_6/vref_6 ac32 6 io_l46p_6 ac29 6 io_l46n_6 ac30 6 io_l47p_6 aa24 6 io_l47n_6 aa25 6 io_l48p_6 ab32 6 io_l48n_6 ab33 6 io_l49p_6 ab28 6 io_l49n_6 ab29 6 io_l50p_6 aa26 6 io_l50n_6 y26 6 io_l51p_6 aa33 6 io_l51n_6/vref_6 aa34 6 io_l52p_6 ab31 6 io_l52n_6 aa31 6 io_l53p_6 y24 6 io_l53n_6 y25 6 io_l54p_6 aa29 6 io_l54n_6 aa30 6 io_l55p_6 y33 6 io_l55n_6 y34 6 io_l56p_6 y28 6 io_l56n_6 w27 6 io_l57p_6 aa32 6 io_l57n_6/vref_6 y32 6 io_l58p_6 y29 6 io_l58n_6 y30 6 io_l59p_6 w24 6 io_l59n_6 w25 6 io_l60p_6 w31 6 io_l60n_6 w32 6 io_l85p_6 w28 6 io_l85n_6 w29 6 io_l86p_6 v26 6 io_l86n_6 v27 6 io_l87p_6 w33 ta bl e 1 1 : ff1148 ? xc2vp40 and xc2vp50 bank pin description pin number no connects xc2vp40 xc2vp50 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 148 product not recommended for new designs 6 io_l87n_6/vref_6 v33 6 io_l88p_6 v30 6 io_l88n_6 v31 6 io_l89p_6 v24 6 io_l89n_6 v25 6 io_l90p_6 v28 6 io_l90n_6 v29 7 io_l90p_7 u32 7 io_l90n_7 v32 7 io_l89p_7 u28 7 io_l89n_7 u29 7 io_l88p_7 u30 7 io_l88n_7/vref_7 u31 7 io_l87p_7 t33 7 io_l87n_7 u33 7 io_l86p_7 u26 7 io_l86n_7 u27 7 io_l85p_7 t31 7 io_l85n_7 t32 7 io_l60p_7 r33 7 io_l60n_7 r34 7 io_l59p_7 u24 7 io_l59n_7 u25 7 io_l58p_7 r29 7 io_l58n_7/vref_7 r30 7 io_l57p_7 p33 7 io_l57n_7 p34 7 io_l56p_7 t28 7 io_l56n_7 t29 7 io_l55p_7 p32 7 io_l55n_7 r32 7 io_l54p_7 p29 7 io_l54n_7 p30 7 io_l53p_7 t24 7 io_l53n_7 t25 7 io_l52p_7 n32 7 io_l52n_7/vref_7 n33 ta bl e 1 1 : ff1148 ? xc2vp40 and xc2vp50 bank pin description pin number no connects xc2vp40 xc2vp50 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 149 product not recommended for new designs 7 io_l51p_7 n31 7 io_l51n_7 p31 7 io_l50p_7 t27 7 io_l50n_7 r28 7 io_l49p_7 m33 7 io_l49n_7 m34 7 io_l48p_7 m31 7 io_l48n_7 m32 7 io_l47p_7 r24 7 io_l47n_7 r25 7 io_l46p_7 m29 7 io_l46n_7/vref_7 m30 7 io_l45p_7 l33 7 io_l45n_7 l34 7 io_l44p_7 p27 7 io_l44n_7 p28 7 io_l43p_7 l29 7 io_l43n_7 l30 7 io_l42p_7 k33 7 io_l42n_7 k34 7 io_l41p_7 p26 7 io_l41n_7 r26 7 io_l40p_7 k32 7 io_l40n_7/vref_7 l32 7 io_l39p_7 k29 7 io_l39n_7 k30 7 io_l38p_7 p24 7 io_l38n_7 p25 7 io_l37p_7 j32 7 io_l37n_7 j33 7 io_l36p_7 j31 7 io_l36n_7 k31 7 io_l35p_7 n28 7 io_l35n_7 n29 7 io_l34p_7 h32 7 io_l34n_7/vref_7 h33 7 io_l33p_7 h29 7 io_l33n_7 h30 ta bl e 1 1 : ff1148 ? xc2vp40 and xc2vp50 bank pin description pin number no connects xc2vp40 xc2vp50 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 150 product not recommended for new designs 7 io_l32p_7 n24 7 io_l32n_7 n25 7 io_l31p_7 g33 7 io_l31n_7 g34 7 io_l30p_7 h31 7 io_l30n_7 g32 7 io_l29p_7 n27 7 io_l29n_7 m28 7 io_l28p_7 g28 7 io_l28n_7/vref_7 g29 7 io_l27p_7 f33 7 io_l27n_7 f34 7 io_l26p_7 m26 7 io_l26n_7 m27 7 io_l25p_7 f31 7 io_l25n_7 f32 7 io_l24p_7 f30 7 io_l24n_7 g30 7 io_l23p_7 l25 7 io_l23n_7 m25 7 io_l22p_7 f27 7 io_l22n_7/vref_7 f28 7 io_l21p_7 e29 7 io_l21n_7 f29 7 io_l20p_7 l28 7 io_l20n_7 k28 7 io_l19p_7 d33 7 io_l19n_7 d34 7 io_l18p_7 d32 7 io_l18n_7 e32 7 io_l17p_7 k26 7 io_l17n_7 l26 7 io_l16p_7 d31 7 io_l16n_7/vref_7 e31 7 io_l15p_7 d29 7 io_l15n_7 d30 7 io_l14p_7 j28 7 io_l14n_7 j29 ta bl e 1 1 : ff1148 ? xc2vp40 and xc2vp50 bank pin description pin number no connects xc2vp40 xc2vp50 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 151 product not recommended for new designs 7 io_l13p_7 d28 7 io_l13n_7 e28 7 io_l12p_7 c33 7 io_l12n_7 c34 7 io_l11p_7 j27 7 io_l11n_7 k27 7 io_l10p_7 b30 7 io_l10n_7/vref_7 c30 7 io_l09p_7 c28 7 io_l09n_7 c29 7 io_l08p_7 h27 7 io_l08n_7 h28 7 io_l07p_7 a32 7 io_l07n_7 b32 7 io_l06p_7 a31 7 io_l06n_7 b31 7 io_l05p_7 d27 7 io_l05n_7 e27 7 io_l04p_7 a29 7 io_l04n_7/vref_7 b29 7 io_l03p_7 a28 7 io_l03n_7 b28 7 io_l02p_7 d26 7 io_l02n_7 c26 7 io_l01p_7/vrn_7 b26 7 io_l01n_7/vrp_7 b27 7 vcco_7 e33 7 vcco_7 r31 7 vcco_7 l31 7 vcco_7 g31 7 vcco_7 c31 7 vcco_7 r27 7 vcco_7 l27 7 vcco_7 g27 7 vcco_7 c27 7 vcco_7 j26 7 vcco_7 m24 ta bl e 1 1 : ff1148 ? xc2vp40 and xc2vp50 bank pin description pin number no connects xc2vp40 xc2vp50 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 152 product not recommended for new designs 7 vcco_7 u23 7 vcco_7 t23 7 vcco_7 r23 7 vcco_7 p23 7 vcco_7 n23 6 vcco_6 ak33 6 vcco_6 am31 6 vcco_6 ah31 6 vcco_6 ad31 6 vcco_6 y31 6 vcco_6 am27 6 vcco_6 ah27 6 vcco_6 ad27 6 vcco_6 y27 6 vcco_6 af26 6 vcco_6 ac24 6 vcco_6 ab23 6 vcco_6 aa23 6 vcco_6 y23 6 vcco_6 w23 6 vcco_6 v23 5 vcco_5 al24 5 vcco_5 ag24 5 vcco_5 ad23 5 vcco_5 ac22 5 vcco_5 ac21 5 vcco_5 al20 5 vcco_5 ag20 5 vcco_5 ac20 5 vcco_5 ac19 5 vcco_5 ac18 4 vcco_4 ac17 4 vcco_4 ac16 4 vcco_4 al15 4 vcco_4 ag15 4 vcco_4 ac15 4 vcco_4 ac14 4 vcco_4 ac13 ta bl e 1 1 : ff1148 ? xc2vp40 and xc2vp50 bank pin description pin number no connects xc2vp40 xc2vp50 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 153 product not recommended for new designs 4 vcco_4 ad12 4 vcco_4 al11 4 vcco_4 ag11 3 vcco_3 ab12 3 vcco_3 aa12 3 vcco_3 y12 3 vcco_3 w12 3 vcco_3 v12 3 vcco_3 ac11 3 vcco_3 af9 3 vcco_3 am8 3 vcco_3 ah8 3 vcco_3 ad8 3 vcco_3 y8 3 vcco_3 am4 3 vcco_3 ah4 3 vcco_3 ad4 3 vcco_3 y4 3 vcco_3 ak2 2 vcco_2 u12 2 vcco_2 t12 2 vcco_2 r12 2 vcco_2 p12 2 vcco_2 n12 2 vcco_2 m11 2 vcco_2 j9 2 vcco_2 r8 2 vcco_2 l8 2 vcco_2 g8 2 vcco_2 c8 2 vcco_2 r4 2 vcco_2 l4 2 vcco_2 g4 2 vcco_2 c4 2 vcco_2 e2 1 vcco_1 m17 1 vcco_1 m16 1 vcco_1 m15 ta bl e 1 1 : ff1148 ? xc2vp40 and xc2vp50 bank pin description pin number no connects xc2vp40 xc2vp50 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 154 product not recommended for new designs 1 vcco_1 h15 1 vcco_1 d15 1 vcco_1 m14 1 vcco_1 m13 1 vcco_1 l12 1 vcco_1 h11 1 vcco_1 d11 0 vcco_0 h24 0 vcco_0 d24 0 vcco_0 l23 0 vcco_0 m22 0 vcco_0 m21 0 vcco_0 m20 0 vcco_0 h20 0 vcco_0 d20 0 vcco_0 m19 0 vcco_0 m18 n/a cclk ag9 n/a prog_b g26 n/a done af10 n/a m0 ag25 n/a m1 ag26 n/a m2 af25 n/a tck g9 n/a tdi f26 n/a tdo f9 n/a tms h10 n/a pwrdwn_b ag10 n/a hswap_en h25 n/a rsvd h9 n/a vbatt j10 n/a dxp j25 n/a dxn h26 n/a vccint ad24 n/a vccint l24 n/a vccint ac23 ta bl e 1 1 : ff1148 ? xc2vp40 and xc2vp50 bank pin description pin number no connects xc2vp40 xc2vp50 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 155 product not recommended for new designs n/a vccint m23 n/a vccint ab22 n/a vccint aa22 n/a vccint y22 n/a vccint w22 n/a vccint v22 n/a vccint u22 n/a vccint t22 n/a vccint r22 n/a vccint p22 n/a vccint n22 n/a vccint ab21 n/a vccint n21 n/a vccint ab20 n/a vccint n20 n/a vccint ab19 n/a vccint n19 n/a vccint ab18 n/a vccint n18 n/a vccint ab17 n/a vccint n17 n/a vccint ab16 n/a vccint n16 n/a vccint ab15 n/a vccint n15 n/a vccint ab14 n/a vccint n14 n/a vccint ab13 n/a vccint aa13 n/a vccint y13 n/a vccint w13 n/a vccint v13 n/a vccint u13 n/a vccint t13 n/a vccint r13 n/a vccint p13 n/a vccint n13 n/a vccint ac12 ta bl e 1 1 : ff1148 ? xc2vp40 and xc2vp50 bank pin description pin number no connects xc2vp40 xc2vp50 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 156 product not recommended for new designs n/a vccint m12 n/a vccint ad11 n/a vccint l11 n/a vccaux an34 n/a vccaux ag34 n/a vccaux u34 n/a vccaux h34 n/a vccaux b34 n/a vccaux ap33 n/a vccaux a33 n/a vccaux ap27 n/a vccaux a27 n/a vccaux ap17 n/a vccaux a17 n/a vccaux ap8 n/a vccaux a8 n/a vccaux ap2 n/a vccaux a2 n/a vccaux an1 n/a vccaux ag1 n/a vccaux u1 n/a vccaux h1 n/a vccaux b1 n/a gnd ak34 n/a gnd af34 n/a gnd ab34 n/a gnd w34 n/a gnd v34 n/a gnd t34 n/a gnd n34 n/a gnd j34 n/a gnd e34 n/a gnd an33 n/a gnd b33 n/a gnd am32 n/a gnd c32 n/a gnd ap30 n/a gnd ak30 ta bl e 1 1 : ff1148 ? xc2vp40 and xc2vp50 bank pin description pin number no connects xc2vp40 xc2vp50 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 157 product not recommended for new designs n/a gnd af30 n/a gnd ab30 n/a gnd w30 n/a gnd t30 n/a gnd n30 n/a gnd j30 n/a gnd e30 n/a gnd a30 n/a gnd ap26 n/a gnd ak26 n/a gnd ab26 n/a gnd w26 n/a gnd t26 n/a gnd n26 n/a gnd e26 n/a gnd a26 n/a gnd ae25 n/a gnd k25 n/a gnd ap22 n/a gnd ak22 n/a gnd af22 n/a gnd j22 n/a gnd e22 n/a gnd a22 n/a gnd y21 n/a gnd w21 n/a gnd v21 n/a gnd u21 n/a gnd t21 n/a gnd r21 n/a gnd aa20 n/a gnd y20 n/a gnd w20 n/a gnd v20 n/a gnd u20 n/a gnd t20 n/a gnd r20 n/a gnd p20 ta bl e 1 1 : ff1148 ? xc2vp40 and xc2vp50 bank pin description pin number no connects xc2vp40 xc2vp50 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 158 product not recommended for new designs n/a gnd ap19 n/a gnd ak19 n/a gnd af19 n/a gnd aa19 n/a gnd y19 n/a gnd w19 n/a gnd v19 n/a gnd u19 n/a gnd t19 n/a gnd r19 n/a gnd p19 n/a gnd j19 n/a gnd e19 n/a gnd a19 n/a gnd ap18 n/a gnd aa18 n/a gnd y18 n/a gnd w18 n/a gnd v18 n/a gnd u18 n/a gnd t18 n/a gnd r18 n/a gnd p18 n/a gnd a18 n/a gnd aa17 n/a gnd y17 n/a gnd w17 n/a gnd v17 n/a gnd u17 n/a gnd t17 n/a gnd r17 n/a gnd p17 n/a gnd ap16 n/a gnd ak16 n/a gnd af16 n/a gnd aa16 n/a gnd y16 n/a gnd w16 ta bl e 1 1 : ff1148 ? xc2vp40 and xc2vp50 bank pin description pin number no connects xc2vp40 xc2vp50 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 159 product not recommended for new designs n/a gnd v16 n/a gnd u16 n/a gnd t16 n/a gnd r16 n/a gnd p16 n/a gnd j16 n/a gnd e16 n/a gnd a16 n/a gnd aa15 n/a gnd y15 n/a gnd w15 n/a gnd v15 n/a gnd u15 n/a gnd t15 n/a gnd r15 n/a gnd p15 n/a gnd y14 n/a gnd w14 n/a gnd v14 n/a gnd u14 n/a gnd t14 n/a gnd r14 n/a gnd ap13 n/a gnd ak13 n/a gnd af13 n/a gnd j13 n/a gnd e13 n/a gnd a13 n/a gnd ae10 n/a gnd k10 n/a gnd ap9 n/a gnd ak9 n/a gnd ab9 n/a gnd w9 n/a gnd t9 n/a gnd n9 n/a gnd e9 n/a gnd a9 ta bl e 1 1 : ff1148 ? xc2vp40 and xc2vp50 bank pin description pin number no connects xc2vp40 xc2vp50 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 160 product not recommended for new designs n/a gnd ap5 n/a gnd ak5 n/a gnd af5 n/a gnd ab5 n/a gnd w5 n/a gnd t5 n/a gnd n5 n/a gnd j5 n/a gnd e5 n/a gnd a5 n/a gnd am3 n/a gnd c3 n/a gnd an2 n/a gnd b2 n/a gnd ak1 n/a gnd af1 n/a gnd ab1 n/a gnd w1 n/a gnd v1 n/a gnd t1 n/a gnd n1 n/a gnd j1 n/a gnd e1 notes: 1. see ta b l e 4 for an explanation of the signals available on this pin. ta bl e 1 1 : ff1148 ? xc2vp40 and xc2vp50 bank pin description pin number no connects xc2vp40 xc2vp50 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 161 product not recommended for new designs ff1148 flip-chip fine-pitc h bga package specificat ions (1.00mm pitch) figure 7: ff1148 flip-chip fine-pitch bga package specifications virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 162 product not recommended for new designs ff1517 flip-chip fine-pitch bga package as shown in ta bl e 1 2 , xc2vp50 and xc2vp70 virtex-ii pro devices are available in the ff1517 flip-chip fine-pitch bga package. following this table are the ff1517 flip-chip fine-pitch bga package specifications (1.00mm pitch) . ta bl e 1 2 : ff1517 ? xc2vp50 and xc2vp70 bank pin description pin number no connects xc2vp50 xc2vp70 0 io_l01n_0/vrp_0 d31 0 io_l01p_0/vrn_0 e31 0 io_l02n_0 k30 0 io_l02p_0 j30 0 io_l03n_0 g30 0 io_l03p_0/vref_0 h30 0 io_l05_0/no_pair k28 0 io_l06n_0 e30 0 io_l06p_0 f30 0 io_l07n_0 c30 0 io_l07p_0 d30 0 io_l08n_0 j29 0 io_l08p_0 k29 0 io_l09n_0 g29 0 io_l09p_0/vref_0 h29 0 io_l19n_0 e29 0 io_l19p_0 f29 0 io_l20n_0 l28 0 io_l20p_0 l27 0 io_l21n_0 c29 0 io_l21p_0 d29 0 io_l25n_0 h28 0 io_l25p_0 j28 0 io_l26n_0 m27 0 io_l26p_0 m26 0 io_l27n_0 d28 0 io_l27p_0/vref_0 e28 0 io_l28n_0 h27 nc 0 io_l28p_0 j27 nc 0 io_l29n_0 j26 nc 0 io_l29p_0 k26 nc 0 io_l30n_0 f28 nc 0 io_l30p_0 g27 nc 0 io_l34n_0 d27 nc virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 163 product not recommended for new designs 0 io_l34p_0 e27 nc 0 io_l35n_0 l26 nc 0 io_l35p_0 l25 nc 0 io_l36n_0 g26 nc 0 io_l36p_0/vref_0 h26 nc 0 io_l37n_0 e26 0 io_l37p_0 f26 0 io_l38n_0 k25 0 io_l38p_0 k24 0 io_l39n_0 c26 0 io_l39p_0 d26 0 io_l43n_0 h25 0 io_l43p_0 j25 0 io_l44n_0 m25 0 io_l44p_0 m24 0 io_l45n_0 f25 0 io_l45p_0/vref_0 g25 0 io_l46n_0 c25 0 io_l46p_0 d25 0 io_l47n_0 l23 0 io_l47p_0 m22 0 io_l48n_0 h24 0 io_l48p_0 j24 0 io_l49n_0 e25 0 io_l49p_0 e24 0 io_l50_0/no_pair n23 0 io_l53_0/no_pair m23 0 io_l54n_0 h23 0 io_l54p_0 j23 0 io_l55n_0 f24 0 io_l55p_0 g23 0 io_l56n_0 k22 0 io_l56p_0 l22 0 io_l57n_0 c23 0 io_l57p_0/vref_0 d23 0 io_l58n_0 h22 0 io_l58p_0 j22 0 io_l59n_0 n22 ta bl e 1 2 : ff1517 ? xc2vp50 and xc2vp70 bank pin description pin number no connects xc2vp50 xc2vp70 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 164 product not recommended for new designs 0 io_l59p_0 n21 0 io_l60n_0 e23 0 io_l60p_0 f22 0 io_l64n_0 d22 0 io_l64p_0 e22 0 io_l65n_0 h21 0 io_l65p_0 h20 0 io_l66n_0 g22 0 io_l66p_0/vref_0 g21 0 io_l67n_0 d21 0 io_l67p_0 e21 0 io_l68n_0 j21 0 io_l68p_0 k21 0 io_l69n_0 c22 0 io_l69p_0/vref_0 c21 0 io_l73n_0 f21 0 io_l73p_0 f20 0 io_l74n_0/gclk7p l21 0 io_l74p_0/gclk6s m21 0 io_l75n_0/gclk5p d20 0 io_l75p_0/gclk4s e20 1 io_l75n_1/gclk3p k20 1 io_l75p_1/gclk2s j20 1 io_l74n_1/gclk1p n20 1 io_l74p_1/gclk0s m20 1 io_l73n_1 e19 1 io_l73p_1 d19 1 io_l69n_1/vref_1 g19 1 io_l69p_1 f19 1 io_l68n_1 l19 1 io_l68p_1 k19 1 io_l67n_1 j19 1 io_l67p_1 h19 1 io_l66n_1/vref_1 c19 1 io_l66p_1 c18 1 io_l65n_1 n19 1 io_l65p_1 m19 ta bl e 1 2 : ff1517 ? xc2vp50 and xc2vp70 bank pin description pin number no connects xc2vp50 xc2vp70 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 165 product not recommended for new designs 1 io_l64n_1 e18 1 io_l64p_1 d18 1 io_l60n_1 g18 1 io_l60p_1 f18 1 io_l59n_1 l18 1 io_l59p_1 k18 1 io_l58n_1 j18 1 io_l58p_1 h18 1 io_l57n_1/vref_1 d17 1 io_l57p_1 c17 1 io_l56n_1 n18 1 io_l56p_1 m18 1 io_l55n_1 e17 1 io_l55p_1 e16 1 io_l54n_1 g17 1 io_l54p_1 f16 1 io_l53_1/no_pair j17 1 io_l50_1/no_pair h17 1 io_l49n_1 j16 1 io_l49p_1 h16 1 io_l48n_1 d15 1 io_l48p_1 c15 1 io_l47n_1 l17 1 io_l47p_1 k16 1 io_l46n_1 f15 1 io_l46p_1 e15 1 io_l45n_1/vref_1 h15 1 io_l45p_1 g15 1 io_l44n_1 n17 1 io_l44p_1 m17 1 io_l43n_1 d14 1 io_l43p_1 c14 1 io_l39n_1 f14 1 io_l39p_1 e14 1 io_l38n_1 m16 1 io_l38p_1 m15 1 io_l37n_1 h14 1 io_l37p_1 g14 ta bl e 1 2 : ff1517 ? xc2vp50 and xc2vp70 bank pin description pin number no connects xc2vp50 xc2vp70 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 166 product not recommended for new designs 1 io_l36n_1/vref_1 e13 nc 1 io_l36p_1 d13 nc 1 io_l35n_1 k15 nc 1 io_l35p_1 j15 nc 1 io_l34n_1 g13 nc 1 io_l34p_1 f12 nc 1 io_l30n_1 j13 nc 1 io_l30p_1 h13 nc 1 io_l29n_1 l15 nc 1 io_l29p_1 l14 nc 1 io_l28n_1 e12 nc 1 io_l28p_1 d12 nc 1 io_l27n_1/vref_1 j12 1 io_l27p_1 h12 1 io_l26n_1 k14 1 io_l26p_1 j14 1 io_l25n_1 d11 1 io_l25p_1 c11 1 io_l21n_1 f11 1 io_l21p_1 e11 1 io_l20n_1 m14 1 io_l20p_1 m13 1 io_l19n_1 h11 1 io_l19p_1 g11 1 io_l09n_1/vref_1 j11 1 io_l09p_1 j10 1 io_l08n_1 l13 1 io_l08p_1 l12 1 io_l07n_1 d10 1 io_l07p_1 c10 1 io_l06n_1 f10 1 io_l06p_1 e10 1 io_l05_1/no_pair k10 1 io_l03n_1/vref_1 h10 1 io_l03p_1 g10 1 io_l02n_1 k12 1 io_l02p_1 k11 1 io_l01n_1/vrp_1 e9 ta bl e 1 2 : ff1517 ? xc2vp50 and xc2vp70 bank pin description pin number no connects xc2vp50 xc2vp70 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 167 product not recommended for new designs 1 io_l01p_1/vrn_1 d9 2 io_l01n_2/vrp_2 c7 2 io_l01p_2/vrn_2 d7 2 io_l02n_2 g9 2 io_l02p_2 h9 2 io_l03n_2 c5 2 io_l03p_2 d5 2 io_l04n_2/vref_2 d6 2 io_l04p_2 e6 2 io_l05n_2 h8 2 io_l05p_2 j9 2 io_l06n_2 e7 2 io_l06p_2 f7 2 io_l73n_2 d1 nc 2 io_l73p_2 d2 nc 2 io_l75n_2 e2 nc 2 io_l75p_2 e3 nc 2 io_l76n_2/vref_2 f5 nc 2 io_l76p_2 g5 nc 2 io_l78n_2 f3 nc 2 io_l78p_2 f4 nc 2 io_l79n_2 f1 nc 2 io_l79p_2 f2 nc 2 io_l81n_2 g6 nc 2 io_l81p_2 g7 nc 2 io_l82n_2/vref_2 g3 nc 2 io_l82p_2 g4 nc 2 io_l84n_2 g1 nc 2 io_l84p_2 g2 nc 2 io_l07n_2 h6 2 io_l07p_2 h7 2 io_l08n_2 k8 2 io_l08p_2 k9 2 io_l09n_2 h2 2 io_l09p_2 h3 2 io_l10n_2/vref_2 j6 2 io_l10p_2 j7 ta bl e 1 2 : ff1517 ? xc2vp50 and xc2vp70 bank pin description pin number no connects xc2vp50 xc2vp70 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 168 product not recommended for new designs 2 io_l11n_2 l9 2 io_l11p_2 m10 2 io_l12n_2 h4 2 io_l12p_2 j5 2 io_l13n_2 j1 2 io_l13p_2 j2 2 io_l14n_2 m8 2 io_l14p_2 n9 2 io_l15n_2 k6 2 io_l15p_2 k7 2 io_l16n_2/vref_2 k4 2 io_l16p_2 k5 2 io_l17n_2 p10 2 io_l17p_2 n10 2 io_l18n_2 k3 2 io_l18p_2 j3 2 io_l19n_2 k1 2 io_l19p_2 k2 2 io_l20n_2 m11 2 io_l20p_2 n11 2 io_l21n_2 l7 2 io_l21p_2 l8 2 io_l22n_2/vref_2 l5 2 io_l22p_2 l6 2 io_l23n_2 p8 2 io_l23p_2 p9 2 io_l24n_2 l3 2 io_l24p_2 l4 2 io_l25n_2 l1 2 io_l25p_2 l2 2 io_l26n_2 p11 2 io_l26p_2 p12 2 io_l27n_2 m6 2 io_l27p_2 m7 2 io_l28n_2/vref_2 m2 2 io_l28p_2 m3 2 io_l29n_2 r9 2 io_l29p_2 r10 ta bl e 1 2 : ff1517 ? xc2vp50 and xc2vp70 bank pin description pin number no connects xc2vp50 xc2vp70 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 169 product not recommended for new designs 2 io_l30n_2 n6 2 io_l30p_2 n7 2 io_l31n_2 m4 2 io_l31p_2 n5 2 io_l32n_2 r11 2 io_l32p_2 r12 2 io_l33n_2 n1 2 io_l33p_2 n2 2 io_l34n_2/vref_2 p6 2 io_l34p_2 p7 2 io_l35n_2 r13 2 io_l35p_2 t13 2 io_l36n_2 p4 2 io_l36p_2 p5 2 io_l37n_2 p3 2 io_l37p_2 n3 2 io_l38n_2 t10 2 io_l38p_2 t11 2 io_l39n_2 p1 2 io_l39p_2 p2 2 io_l40n_2/vref_2 r7 2 io_l40p_2 r8 2 io_l41n_2 t12 2 io_l41p_2 u12 2 io_l42n_2 r5 2 io_l42p_2 r6 2 io_l43n_2 r3 2 io_l43p_2 r4 2 io_l44n_2 u8 2 io_l44p_2 t8 2 io_l45n_2 r1 2 io_l45p_2 r2 2 io_l46n_2/vref_2 t6 2 io_l46p_2 t7 2 io_l47n_2 u9 2 io_l47p_2 u10 2 io_l48n_2 t2 2 io_l48p_2 t3 ta bl e 1 2 : ff1517 ? xc2vp50 and xc2vp70 bank pin description pin number no connects xc2vp50 xc2vp70 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 170 product not recommended for new designs 2 io_l49n_2 u5 2 io_l49p_2 u6 2 io_l50n_2 u13 2 io_l50p_2 v13 2 io_l51n_2 u4 2 io_l51p_2 t4 2 io_l52n_2/vref_2 u1 2 io_l52p_2 u2 2 io_l53n_2 v9 2 io_l53p_2 v10 2 io_l54n_2 v7 2 io_l54p_2 v8 2 io_l55n_2 v5 2 io_l55p_2 v6 2 io_l56n_2 v11 2 io_l56p_2 v12 2 io_l57n_2 v3 2 io_l57p_2 v4 2 io_l58n_2/vref_2 v1 2 io_l58p_2 v2 2 io_l59n_2 w10 2 io_l59p_2 w11 2 io_l60n_2 w7 2 io_l60p_2 w8 2 io_l85n_2 w5 2 io_l85p_2 w6 2 io_l86n_2 w12 2 io_l86p_2 w13 2 io_l87n_2 w3 2 io_l87p_2 w4 2 io_l88n_2/vref_2 y7 2 io_l88p_2 y8 2 io_l89n_2 w9 2 io_l89p_2 y9 2 io_l90n_2 y3 2 io_l90p_2 y4 3 io_l90n_3 aa7 ta bl e 1 2 : ff1517 ? xc2vp50 and xc2vp70 bank pin description pin number no connects xc2vp50 xc2vp70 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 171 product not recommended for new designs 3 io_l90p_3 aa8 3 io_l89n_3 y11 3 io_l89p_3 y12 3 io_l88n_3 aa5 3 io_l88p_3 aa6 3 io_l87n_3/vref_3 aa3 3 io_l87p_3 aa4 3 io_l86n_3 y13 3 io_l86p_3 aa13 3 io_l85n_3 ab7 3 io_l85p_3 ab8 3 io_l60n_3 ab5 3 io_l60p_3 ab6 3 io_l59n_3 aa9 3 io_l59p_3 aa10 3 io_l58n_3 ab3 3 io_l58p_3 ab4 3 io_l57n_3/vref_3 ab1 3 io_l57p_3 ab2 3 io_l56n_3 aa11 3 io_l56p_3 aa12 3 io_l55n_3 ac5 3 io_l55p_3 ac6 3 io_l54n_3 ac1 3 io_l54p_3 ac2 3 io_l53n_3 ab9 3 io_l53p_3 ab10 3 io_l52n_3 ac8 3 io_l52p_3 ad8 3 io_l51n_3/vref_3 ac4 3 io_l51p_3 ad4 3 io_l50n_3 ab11 3 io_l50p_3 ab12 3 io_l49n_3 ad6 3 io_l49p_3 ad7 3 io_l48n_3 ad2 3 io_l48p_3 ad3 3 io_l47n_3 ac9 ta bl e 1 2 : ff1517 ? xc2vp50 and xc2vp70 bank pin description pin number no connects xc2vp50 xc2vp70 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 172 product not recommended for new designs 3 io_l47p_3 ac10 3 io_l46n_3 ae7 3 io_l46p_3 ae8 3 io_l45n_3/vref_3 ae5 3 io_l45p_3 ae6 3 io_l44n_3 ab13 3 io_l44p_3 ac13 3 io_l43n_3 ae3 3 io_l43p_3 ae4 3 io_l42n_3 ae1 3 io_l42p_3 ae2 3 io_l41n_3 ad10 3 io_l41p_3 ad11 3 io_l40n_3 af6 3 io_l40p_3 af7 3 io_l39n_3/vref_3 af4 3 io_l39p_3 af5 3 io_l38n_3 ac12 3 io_l38p_3 ad12 3 io_l37n_3 af1 3 io_l37p_3 af2 3 io_l36n_3 ag6 3 io_l36p_3 ag7 3 io_l35n_3 ae9 3 io_l35p_3 ae10 3 io_l34n_3 af3 3 io_l34p_3 ag3 3 io_l33n_3/vref_3 ag1 3 io_l33p_3 ag2 3 io_l32n_3 ae11 3 io_l32p_3 ae12 3 io_l31n_3 ah6 3 io_l31p_3 ah7 3 io_l30n_3 ag5 3 io_l30p_3 ah4 3 io_l29n_3 ad13 3 io_l29p_3 ae13 3 io_l28n_3 ah2 ta bl e 1 2 : ff1517 ? xc2vp50 and xc2vp70 bank pin description pin number no connects xc2vp50 xc2vp70 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 173 product not recommended for new designs 3 io_l28p_3 ah3 3 io_l27n_3/vref_3 aj7 3 io_l27p_3 aj8 3 io_l26n_3 af8 3 io_l26p_3 af9 3 io_l25n_3 aj5 3 io_l25p_3 aj6 3 io_l24n_3 aj3 3 io_l24p_3 aj4 3 io_l23n_3 af10 3 io_l23p_3 ag10 3 io_l22n_3 aj1 3 io_l22p_3 aj2 3 io_l21n_3/vref_3 ak6 3 io_l21p_3 ak7 3 io_l20n_3 af11 3 io_l20p_3 af12 3 io_l19n_3 ak4 3 io_l19p_3 ak5 3 io_l18n_3 ak1 3 io_l18p_3 ak2 3 io_l17n_3 ag9 3 io_l17p_3 ah8 3 io_l16n_3 al6 3 io_l16p_3 al7 3 io_l15n_3/vref_3 ak3 3 io_l15p_3 al3 3 io_l14n_3 ag11 3 io_l14p_3 ah11 3 io_l13n_3 al1 3 io_l13p_3 al2 3 io_l12n_3 am6 3 io_l12p_3 am7 3 io_l11n_3 ah10 3 io_l11p_3 aj9 3 io_l10n_3 al5 3 io_l10p_3 am4 3 io_l09n_3/vref_3 am2 ta bl e 1 2 : ff1517 ? xc2vp50 and xc2vp70 bank pin description pin number no connects xc2vp50 xc2vp70 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 174 product not recommended for new designs 3 io_l09p_3 am3 3 io_l08n_3 ak8 3 io_l08p_3 ak9 3 io_l07n_3 an6 3 io_l07p_3 an7 3 io_l84n_3 an3 nc 3 io_l84p_3 an4 nc 3 io_l82n_3 an1 nc 3 io_l82p_3 an2 nc 3 io_l81n_3/vref_3 an5 nc 3 io_l81p_3 ap5 nc 3 io_l79n_3 ap3 nc 3 io_l79p_3 ap4 nc 3 io_l78n_3 ap1 nc 3 io_l78p_3 ap2 nc 3 io_l76n_3 ar2 nc 3 io_l76p_3 ar3 nc 3 io_l75n_3/vref_3 at1 nc 3 io_l75p_3 at2 nc 3 io_l73n_3 at5 nc 3 io_l73p_3 au5 nc 3 io_l06n_3 ar6 3 io_l06p_3 at6 3 io_l05n_3 al9 3 io_l05p_3 am8 3 io_l04n_3 ap7 3 io_l04p_3 ar7 3 io_l03n_3/vref_3 am9 3 io_l03p_3 an9 3 io_l02n_3 ar8 3 io_l02p_3 at8 3 io_l01n_3/vrp_3 at7 3 io_l01p_3/vrn_3 au7 4 io_l01n_4/busy/dout (1) at 9 4 io_l01p_4/init_b ar9 4 io_l02n_4/d0/din (1) ak11 4 io_l02p_4/d1 ak12 ta bl e 1 2 : ff1517 ? xc2vp50 and xc2vp70 bank pin description pin number no connects xc2vp50 xc2vp70 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 175 product not recommended for new designs 4 io_l03n_4/d2 an10 4 io_l03p_4/d3 am10 4 io_l05_4/no_pair ak10 4 io_l06n_4/vrp_4 ar10 4 io_l06p_4/vrn_4 ap10 4 io_l07n_4 au10 4 io_l07p_4/vref_4 at10 4 io_l08n_4 aj12 4 io_l08p_4 aj13 4 io_l09n_4 al10 4 io_l09p_4/vref_4 al11 4 io_l19n_4 an11 4 io_l19p_4 am11 4 io_l20n_4 ah13 4 io_l20p_4 ah14 4 io_l21n_4 ar11 4 io_l21p_4 ap11 4 io_l25n_4 au11 4 io_l25p_4 at11 4 io_l26n_4 al14 4 io_l26p_4 ak14 4 io_l27n_4 am12 4 io_l27p_4/vref_4 al12 4 io_l28n_4 at12 nc 4 io_l28p_4 ar12 nc 4 io_l29n_4 aj14 nc 4 io_l29p_4 aj15 nc 4 io_l30n_4 am13 nc 4 io_l30p_4 al13 nc 4 io_l34n_4 ap12 nc 4 io_l34p_4 an13 nc 4 io_l35n_4 al15 nc 4 io_l35p_4 ak15 nc 4 io_l36n_4 at13 nc 4 io_l36p_4/vref_4 ar13 nc 4 io_l37n_4 an14 4 io_l37p_4 am14 4 io_l38n_4 ah15 ta bl e 1 2 : ff1517 ? xc2vp50 and xc2vp70 bank pin description pin number no connects xc2vp50 xc2vp70 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 176 product not recommended for new designs 4 io_l38p_4 ah16 4 io_l39n_4 ar14 4 io_l39p_4 ap14 4 io_l43n_4 au14 4 io_l43p_4 at14 4 io_l44n_4 ah17 4 io_l44p_4 ag17 4 io_l45n_4 an15 4 io_l45p_4/vref_4 am15 4 io_l46n_4 ar15 4 io_l46p_4 ap15 4 io_l47n_4 ak16 4 io_l47p_4 aj17 4 io_l48n_4 au15 4 io_l48p_4 at15 4 io_l49n_4 am16 4 io_l49p_4 al16 4 io_l50_4/no_pair am17 4 io_l53_4/no_pair al17 4 io_l54n_4 ap16 4 io_l54p_4 an17 4 io_l55n_4 ar16 4 io_l55p_4 ar17 4 io_l56n_4 ah18 4 io_l56p_4 ag18 4 io_l57n_4 au17 4 io_l57p_4/vref_4 at17 4 io_l58n_4 am18 4 io_l58p_4 al18 4 io_l59n_4 ak18 4 io_l59p_4 aj18 4 io_l60n_4 ap18 4 io_l60p_4 an18 4 io_l64n_4 at18 4 io_l64p_4 ar18 4 io_l65n_4 ah19 4 io_l65p_4 ag19 4 io_l66n_4 au18 ta bl e 1 2 : ff1517 ? xc2vp50 and xc2vp70 bank pin description pin number no connects xc2vp50 xc2vp70 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 177 product not recommended for new designs 4 io_l66p_4/vref_4 au19 4 io_l67n_4 am19 4 io_l67p_4 al19 4 io_l68n_4 ak19 4 io_l68p_4 aj19 4 io_l69n_4 ap19 4 io_l69p_4/vref_4 an19 4 io_l73n_4 at19 4 io_l73p_4 ar19 4 io_l74n_4/gclk3s ah20 4 io_l74p_4/gclk2p ag20 4 io_l75n_4/gclk1s al20 4 io_l75p_4/gclk0p ak20 5 io_l75n_5/gclk7s ar20 5 io_l75p_5/gclk6p at20 5 io_l74n_5/gclk5s ah21 5 io_l74p_5/gclk4p aj21 5 io_l73n_5 ap20 5 io_l73p_5 ap21 5 io_l69n_5/vref_5 au21 5 io_l69p_5 au22 5 io_l68n_5 ak21 5 io_l68p_5 al21 5 io_l67n_5 ar21 5 io_l67p_5 at21 5 io_l66n_5/vref_5 an21 5 io_l66p_5 an22 5 io_l65n_5 am20 5 io_l65p_5 am21 5 io_l64n_5 ar22 5 io_l64p_5 at22 5 io_l60n_5 ap22 5 io_l60p_5 ar23 5 io_l59n_5 ag21 5 io_l59p_5 ag22 5 io_l58n_5 al22 5 io_l58p_5 am22 ta bl e 1 2 : ff1517 ? xc2vp50 and xc2vp70 bank pin description pin number no connects xc2vp50 xc2vp70 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 178 product not recommended for new designs 5 io_l57n_5/vref_5 at23 5 io_l57p_5 au23 5 io_l56n_5 aj22 5 io_l56p_5 ak22 5 io_l55n_5 an23 5 io_l55p_5 ap24 5 io_l54n_5 al23 5 io_l54p_5 am23 5 io_l53_5/no_pair ah23 5 io_l50_5/no_pair ag23 5 io_l49n_5 ar24 5 io_l49p_5 ar25 5 io_l48n_5 al24 5 io_l48p_5 am24 5 io_l47n_5 ah22 5 io_l47p_5 aj23 5 io_l46n_5 at25 5 io_l46p_5 au25 5 io_l45n_5/vref_5 an25 5 io_l45p_5 ap25 5 io_l44n_5 ah24 5 io_l44p_5 ah25 5 io_l43n_5 al25 5 io_l43p_5 am25 5 io_l39n_5 at26 5 io_l39p_5 au26 5 io_l38n_5 ak24 5 io_l38p_5 ak25 5 io_l37n_5 ap26 5 io_l37p_5 ar26 5 io_l36n_5/vref_5 am26 nc 5 io_l36p_5 an26 nc 5 io_l35n_5 aj25 nc 5 io_l35p_5 aj26 nc 5 io_l34n_5 ar27 nc 5 io_l34p_5 at27 nc 5 io_l30n_5 an27 nc 5 io_l30p_5 ap28 nc ta bl e 1 2 : ff1517 ? xc2vp50 and xc2vp70 bank pin description pin number no connects xc2vp50 xc2vp70 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 179 product not recommended for new designs 5 io_l29n_5 ak26 nc 5 io_l29p_5 al26 nc 5 io_l28n_5 al27 nc 5 io_l28p_5 am27 nc 5 io_l27n_5/vref_5 ar28 5 io_l27p_5 at28 5 io_l26n_5 ah26 5 io_l26p_5 ah27 5 io_l25n_5 al28 5 io_l25p_5 am28 5 io_l21n_5 at29 5 io_l21p_5 au29 5 io_l20n_5 aj27 5 io_l20p_5 aj28 5 io_l19n_5 ap29 5 io_l19p_5 ar29 5 io_l09n_5/vref_5 am29 5 io_l09p_5 an29 5 io_l08n_5 ak29 5 io_l08p_5 al29 5 io_l07n_5/vref_5 at30 5 io_l07p_5 au30 5 io_l06n_5/vrp_5 ap30 5 io_l06p_5/vrn_5 ar30 5 io_l05_5/no_pair ak28 5 io_l03n_5/d4 am30 5 io_l03p_5/d5 an30 5 io_l02n_5/d6 al30 5 io_l02p_5/d7 ak30 5 io_l01n_5/rdwr_b ar31 5 io_l01p_5/cs_b at31 6 io_l01p_6/vrn_6 au33 6 io_l01n_6/vrp_6 at33 6 io_l02p_6 at32 6 io_l02n_6 ar32 6 io_l03p_6 an31 6 io_l03n_6/vref_6 am31 ta bl e 1 2 : ff1517 ? xc2vp50 and xc2vp70 bank pin description pin number no connects xc2vp50 xc2vp70 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 180 product not recommended for new designs 6 io_l04p_6 ar33 6 io_l04n_6 ap33 6 io_l05p_6 am32 6 io_l05n_6 al31 6 io_l06p_6 at34 6 io_l06n_6 ar34 6 io_l73p_6 au35 nc 6 io_l73n_6 at35 nc 6 io_l75p_6 at38 nc 6 io_l75n_6/vref_6 at39 nc 6 io_l76p_6 ar37 nc 6 io_l76n_6 ar38 nc 6 io_l78p_6 ap38 nc 6 io_l78n_6 ap39 nc 6 io_l79p_6 ap36 nc 6 io_l79n_6 ap37 nc 6 io_l81p_6 ap35 nc 6 io_l81n_6/vref_6 an35 nc 6 io_l82p_6 an38 nc 6 io_l82n_6 an39 nc 6 io_l84p_6 an36 nc 6 io_l84n_6 an37 nc 6 io_l07p_6 an33 6 io_l07n_6 an34 6 io_l08p_6 ak31 6 io_l08n_6 ak32 6 io_l09p_6 am37 6 io_l09n_6/vref_6 am38 6 io_l10p_6 am36 6 io_l10n_6 al35 6 io_l11p_6 aj31 6 io_l11n_6 ah30 6 io_l12p_6 am33 6 io_l12n_6 am34 6 io_l13p_6 al38 6 io_l13n_6 al39 6 io_l14p_6 ah29 6 io_l14n_6 ag29 ta bl e 1 2 : ff1517 ? xc2vp50 and xc2vp70 bank pin description pin number no connects xc2vp50 xc2vp70 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 181 product not recommended for new designs 6 io_l15p_6 al37 6 io_l15n_6/vref_6 ak37 6 io_l16p_6 al33 6 io_l16n_6 al34 6 io_l17p_6 ah32 6 io_l17n_6 ag31 6 io_l18p_6 ak38 6 io_l18n_6 ak39 6 io_l19p_6 ak35 6 io_l19n_6 ak36 6 io_l20p_6 af28 6 io_l20n_6 af29 6 io_l21p_6 ak33 6 io_l21n_6/vref_6 ak34 6 io_l22p_6 aj38 6 io_l22n_6 aj39 6 io_l23p_6 ag30 6 io_l23n_6 af30 6 io_l24p_6 aj36 6 io_l24n_6 aj37 6 io_l25p_6 aj34 6 io_l25n_6 aj35 6 io_l26p_6 af31 6 io_l26n_6 af32 6 io_l27p_6 aj32 6 io_l27n_6/vref_6 aj33 6 io_l28p_6 ah37 6 io_l28n_6 ah38 6 io_l29p_6 ae27 6 io_l29n_6 ad27 6 io_l30p_6 ah36 6 io_l30n_6 ag35 6 io_l31p_6 ah33 6 io_l31n_6 ah34 6 io_l32p_6 ae28 6 io_l32n_6 ae29 6 io_l33p_6 ag38 6 io_l33n_6/vref_6 ag39 ta bl e 1 2 : ff1517 ? xc2vp50 and xc2vp70 bank pin description pin number no connects xc2vp50 xc2vp70 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 182 product not recommended for new designs 6 io_l34p_6 ag37 6 io_l34n_6 af37 6 io_l35p_6 ae30 6 io_l35n_6 ae31 6 io_l36p_6 ag33 6 io_l36n_6 ag34 6 io_l37p_6 af38 6 io_l37n_6 af39 6 io_l38p_6 ad28 6 io_l38n_6 ac28 6 io_l39p_6 af35 6 io_l39n_6/vref_6 af36 6 io_l40p_6 af33 6 io_l40n_6 af34 6 io_l41p_6 ad29 6 io_l41n_6 ad30 6 io_l42p_6 ae38 6 io_l42n_6 ae39 6 io_l43p_6 ae36 6 io_l43n_6 ae37 6 io_l44p_6 ac27 6 io_l44n_6 ab27 6 io_l45p_6 ae34 6 io_l45n_6/vref_6 ae35 6 io_l46p_6 ae32 6 io_l46n_6 ae33 6 io_l47p_6 ac30 6 io_l47n_6 ac31 6 io_l48p_6 ad37 6 io_l48n_6 ad38 6 io_l49p_6 ad33 6 io_l49n_6 ad34 6 io_l50p_6 ab28 6 io_l50n_6 ab29 6 io_l51p_6 ad36 6 io_l51n_6/vref_6 ac36 6 io_l52p_6 ad32 6 io_l52n_6 ac32 ta bl e 1 2 : ff1517 ? xc2vp50 and xc2vp70 bank pin description pin number no connects xc2vp50 xc2vp70 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 183 product not recommended for new designs 6 io_l53p_6 ab30 6 io_l53n_6 ab31 6 io_l54p_6 ac38 6 io_l54n_6 ac39 6 io_l55p_6 ac34 6 io_l55n_6 ac35 6 io_l56p_6 aa28 6 io_l56n_6 aa29 6 io_l57p_6 ab38 6 io_l57n_6/vref_6 ab39 6 io_l58p_6 ab36 6 io_l58n_6 ab37 6 io_l59p_6 aa30 6 io_l59n_6 aa31 6 io_l60p_6 ab34 6 io_l60n_6 ab35 6 io_l85p_6 ab32 6 io_l85n_6 ab33 6 io_l86p_6 aa27 6 io_l86n_6 y27 6 io_l87p_6 aa36 6 io_l87n_6/vref_6 aa37 6 io_l88p_6 aa34 6 io_l88n_6 aa35 6 io_l89p_6 y28 6 io_l89n_6 y29 6 io_l90p_6 aa32 6 io_l90n_6 aa33 7 io_l90p_7 y36 7 io_l90n_7 y37 7 io_l89p_7 y31 7 io_l89n_7 w31 7 io_l88p_7 y32 7 io_l88n_7/vref_7 y33 7 io_l87p_7 w36 7 io_l87n_7 w37 7 io_l86p_7 w27 ta bl e 1 2 : ff1517 ? xc2vp50 and xc2vp70 bank pin description pin number no connects xc2vp50 xc2vp70 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 184 product not recommended for new designs 7 io_l86n_7 w28 7 io_l85p_7 w34 7 io_l85n_7 w35 7 io_l60p_7 w32 7 io_l60n_7 w33 7 io_l59p_7 w29 7 io_l59n_7 w30 7 io_l58p_7 v38 7 io_l58n_7/vref_7 v39 7 io_l57p_7 v36 7 io_l57n_7 v37 7 io_l56p_7 v28 7 io_l56n_7 v29 7 io_l55p_7 v34 7 io_l55n_7 v35 7 io_l54p_7 v32 7 io_l54n_7 v33 7 io_l53p_7 v30 7 io_l53n_7 v31 7 io_l52p_7 u38 7 io_l52n_7/vref_7 u39 7 io_l51p_7 t36 7 io_l51n_7 u36 7 io_l50p_7 v27 7 io_l50n_7 u27 7 io_l49p_7 u34 7 io_l49n_7 u35 7 io_l48p_7 t37 7 io_l48n_7 t38 7 io_l47p_7 u30 7 io_l47n_7 u31 7 io_l46p_7 t33 7 io_l46n_7/vref_7 t34 7 io_l45p_7 r38 7 io_l45n_7 r39 7 io_l44p_7 t32 7 io_l44n_7 u32 7 io_l43p_7 r36 ta bl e 1 2 : ff1517 ? xc2vp50 and xc2vp70 bank pin description pin number no connects xc2vp50 xc2vp70 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 185 product not recommended for new designs 7 io_l43n_7 r37 7 io_l42p_7 r34 7 io_l42n_7 r35 7 io_l41p_7 u28 7 io_l41n_7 t28 7 io_l40p_7 r32 7 io_l40n_7/vref_7 r33 7 io_l39p_7 p38 7 io_l39n_7 p39 7 io_l38p_7 t29 7 io_l38n_7 t30 7 io_l37p_7 n37 7 io_l37n_7 p37 7 io_l36p_7 p35 7 io_l36n_7 p36 7 io_l35p_7 t27 7 io_l35n_7 r27 7 io_l34p_7 p33 7 io_l34n_7/vref_7 p34 7 io_l33p_7 n38 7 io_l33n_7 n39 7 io_l32p_7 r28 7 io_l32n_7 r29 7 io_l31p_7 n35 7 io_l31n_7 m36 7 io_l30p_7 n33 7 io_l30n_7 n34 7 io_l29p_7 r30 7 io_l29n_7 r31 7 io_l28p_7 m37 7 io_l28n_7/vref_7 m38 7 io_l27p_7 m33 7 io_l27n_7 m34 7 io_l26p_7 p28 7 io_l26n_7 p29 7 io_l25p_7 l38 7 io_l25n_7 l39 7 io_l24p_7 l36 ta bl e 1 2 : ff1517 ? xc2vp50 and xc2vp70 bank pin description pin number no connects xc2vp50 xc2vp70 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 186 product not recommended for new designs 7 io_l24n_7 l37 7 io_l23p_7 p31 7 io_l23n_7 p32 7 io_l22p_7 l34 7 io_l22n_7/vref_7 l35 7 io_l21p_7 l32 7 io_l21n_7 l33 7 io_l20p_7 n29 7 io_l20n_7 m29 7 io_l19p_7 k38 7 io_l19n_7 k39 7 io_l18p_7 j37 7 io_l18n_7 k37 7 io_l17p_7 n30 7 io_l17n_7 p30 7 io_l16p_7 k35 7 io_l16n_7/vref_7 k36 7 io_l15p_7 k34 7 io_l15n_7 k33 7 io_l14p_7 n31 7 io_l14n_7 m32 7 io_l13p_7 j38 7 io_l13n_7 j39 7 io_l12p_7 j35 7 io_l12n_7 h36 7 io_l11p_7 m30 7 io_l11n_7 l31 7 io_l10p_7 j33 7 io_l10n_7/vref_7 j34 7 io_l09p_7 h37 7 io_l09n_7 h38 7 io_l08p_7 k31 7 io_l08n_7 k32 7 io_l07p_7 h33 7 io_l07n_7 h34 7 io_l84p_7 g38 nc 7 io_l84n_7 g39 nc 7 io_l82p_7 g36 nc ta bl e 1 2 : ff1517 ? xc2vp50 and xc2vp70 bank pin description pin number no connects xc2vp50 xc2vp70 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 187 product not recommended for new designs 7 io_l82n_7/vref_7 g37 nc 7 io_l81p_7 g33 nc 7 io_l81n_7 g34 nc 7 io_l79p_7 f38 nc 7 io_l79n_7 f39 nc 7 io_l78p_7 f36 nc 7 io_l78n_7 f37 nc 7 io_l76p_7 g35 nc 7 io_l76n_7/vref_7 f35 nc 7 io_l75p_7 e37 nc 7 io_l75n_7 e38 nc 7 io_l73p_7 d38 nc 7 io_l73n_7 d39 nc 7 io_l06p_7 f33 7 io_l06n_7 e33 7 io_l05p_7 j31 7 io_l05n_7 h32 7 io_l04p_7 e34 7 io_l04n_7/vref_7 d34 7 io_l03p_7 d35 7 io_l03n_7 c35 7 io_l02p_7 h31 7 io_l02n_7 g31 7 io_l01p_7/vrn_7 d33 7 io_l01n_7/vrp_7 c33 7 vcco_7 e39 7 vcco_7 u37 7 vcco_7 n36 7 vcco_7 j36 7 vcco_7 e36 7 vcco_7 y35 7 vcco_7 u33 7 vcco_7 n32 7 vcco_7 j32 7 vcco_7 f32 7 vcco_7 u29 7 vcco_7 n28 ta bl e 1 2 : ff1517 ? xc2vp50 and xc2vp70 bank pin description pin number no connects xc2vp50 xc2vp70 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 188 product not recommended for new designs 7 vcco_7 p27 7 vcco_7 w26 7 vcco_7 v26 7 vcco_7 u26 7 vcco_7 t26 7 vcco_7 r26 6 vcco_6 ar39 6 vcco_6 ac37 6 vcco_6 ar36 6 vcco_6 al36 6 vcco_6 ag36 6 vcco_6 ac33 6 vcco_6 ap32 6 vcco_6 al32 6 vcco_6 ag32 6 vcco_6 ac29 6 vcco_6 ag28 6 vcco_6 af27 6 vcco_6 ae26 6 vcco_6 ad26 6 vcco_6 ac26 6 vcco_6 ab26 6 vcco_6 aa26 6 vcco_6 y26 5 vcco_5 ap27 5 vcco_5 ak27 5 vcco_5 ag26 5 vcco_5 ag25 5 vcco_5 af25 5 vcco_5 ag24 5 vcco_5 af24 5 vcco_5 ap23 5 vcco_5 ak23 5 vcco_5 af23 5 vcco_5 af22 5 vcco_5 af21 4 vcco_4 af19 4 vcco_4 af18 ta bl e 1 2 : ff1517 ? xc2vp50 and xc2vp70 bank pin description pin number no connects xc2vp50 xc2vp70 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 189 product not recommended for new designs 4 vcco_4 ap17 4 vcco_4 ak17 4 vcco_4 af17 4 vcco_4 ag16 4 vcco_4 af16 4 vcco_4 ag15 4 vcco_4 af15 4 vcco_4 ag14 4 vcco_4 ap13 4 vcco_4 ak13 3 vcco_3 ae14 3 vcco_3 ad14 3 vcco_3 ac14 3 vcco_3 ab14 3 vcco_3 aa14 3 vcco_3 y14 3 vcco_3 af13 3 vcco_3 ag12 3 vcco_3 ac11 3 vcco_3 ap8 3 vcco_3 al8 3 vcco_3 ag8 3 vcco_3 ac7 3 vcco_3 ar4 3 vcco_3 al4 3 vcco_3 ag4 3 vcco_3 ac3 3 vcco_3 ar1 2 vcco_2 w14 2 vcco_2 v14 2 vcco_2 u14 2 vcco_2 t14 2 vcco_2 r14 2 vcco_2 p13 2 vcco_2 n12 2 vcco_2 u11 2 vcco_2 n8 2 vcco_2 j8 ta bl e 1 2 : ff1517 ? xc2vp50 and xc2vp70 bank pin description pin number no connects xc2vp50 xc2vp70 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 190 product not recommended for new designs 2 vcco_2 f8 2 vcco_2 u7 2 vcco_2 y5 2 vcco_2 n4 2 vcco_2 j4 2 vcco_2 e4 2 vcco_2 u3 2 vcco_2 e1 1 vcco_1 n14 1 vcco_1 k13 1 vcco_1 f13 1 vcco_1 p19 1 vcco_1 p18 1 vcco_1 p17 1 vcco_1 k17 1 vcco_1 f17 1 vcco_1 p16 1 vcco_1 n16 1 vcco_1 p15 1 vcco_1 n15 0 vcco_0 k27 0 vcco_0 f27 0 vcco_0 n26 0 vcco_0 p25 0 vcco_0 n25 0 vcco_0 p24 0 vcco_0 n24 0 vcco_0 p23 0 vcco_0 k23 0 vcco_0 f23 0 vcco_0 p22 0 vcco_0 p21 n/a cclk aj10 n/a prog_b d32 n/a done aj11 n/a m0 ap31 n/a m1 aj30 ta bl e 1 2 : ff1517 ? xc2vp50 and xc2vp70 bank pin description pin number no connects xc2vp50 xc2vp70 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 191 product not recommended for new designs n/a m2 aj29 n/a tck e8 n/a tdi l30 n/a tdo l10 n/a tms f9 n/a pwrdwn_b ap9 n/a hswap_en e32 n/a rsvd d8 n/a vbatt l11 n/a dxp l29 n/a dxn f31 n/a avccauxtx2 b35 n/a vttxpad2 b36 n/a txnpad2 a36 n/a txppad2 a35 n/a gnda2 c34 n/a rxppad2 a34 n/a rxnpad2 a33 n/a vtrxpad2 b34 n/a avccauxrx2 b33 n/a avccauxtx4 b31 n/a vttxpad4 b32 n/a txnpad4 a32 n/a txppad4 a31 n/a gnda4 c31 n/a rxppad4 a30 n/a rxnpad4 a29 n/a vtrxpad4 b30 n/a avccauxrx4 b29 n/a avccauxtx5 b27 n/a vttxpad5 b28 n/a txnpad5 a28 n/a txppad5 a27 n/a gnda5 c27 n/a rxppad5 a26 n/a rxnpad5 a25 n/a vtrxpad5 b26 n/a avccauxrx5 b25 ta bl e 1 2 : ff1517 ? xc2vp50 and xc2vp70 bank pin description pin number no connects xc2vp50 xc2vp70 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 192 product not recommended for new designs n/a avccauxtx6 b23 n/a vttxpad6 b24 n/a txnpad6 a24 n/a txppad6 a23 n/a gnda6 c24 n/a rxppad6 a22 n/a rxnpad6 a21 n/a vtrxpad6 b22 n/a avccauxrx6 b21 n/a avccauxtx7 b18 n/a vttxpad7 b19 n/a txnpad7 a19 n/a txppad7 a18 n/a gnda7 c16 n/a rxppad7 a17 n/a rxnpad7 a16 n/a vtrxpad7 b17 n/a avccauxrx7 b16 n/a avccauxtx8 b14 n/a vttxpad8 b15 n/a txnpad8 a15 n/a txppad8 a14 n/a gnda8 c13 n/a rxppad8 a13 n/a rxnpad8 a12 n/a vtrxpad8 b13 n/a avccauxrx8 b12 n/a avccauxtx9 b10 n/a vttxpad9 b11 n/a txnpad9 a11 n/a txppad9 a10 n/a gnda9 c9 n/a rxppad9 a9 n/a rxnpad9 a8 n/a vtrxpad9 b9 n/a avccauxrx9 b8 n/a avccauxtx11 b6 n/a vttxpad11 b7 ta bl e 1 2 : ff1517 ? xc2vp50 and xc2vp70 bank pin description pin number no connects xc2vp50 xc2vp70 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 193 product not recommended for new designs n/a txnpad11 a7 n/a txppad11 a6 n/a gnda11 c6 n/a rxppad11 a5 n/a rxnpad11 a4 n/a vtrxpad11 b5 n/a avccauxrx11 b4 n/a avccauxrx14 av4 n/a vtrxpad14 av5 n/a rxnpad14 aw4 n/a rxppad14 aw5 n/a gnda14 au6 n/a txppad14 aw6 n/a txnpad14 aw7 n/a vttxpad14 av7 n/a avccauxtx14 av6 n/a avccauxrx16 av8 n/a vtrxpad16 av9 n/a rxnpad16 aw8 n/a rxppad16 aw9 n/a gnda16 au9 n/a txppad16 aw10 n/a txnpad16 aw11 n/a vttxpad16 av11 n/a avccauxtx16 av10 n/a avccauxrx17 av12 n/a vtrxpad17 av13 n/a rxnpad17 aw12 n/a rxppad17 aw13 n/a gnda17 au13 n/a txppad17 aw14 n/a txnpad17 aw15 n/a vttxpad17 av15 n/a avccauxtx17 av14 n/a avccauxrx18 av16 n/a vtrxpad18 av17 n/a rxnpad18 aw16 n/a rxppad18 aw17 ta bl e 1 2 : ff1517 ? xc2vp50 and xc2vp70 bank pin description pin number no connects xc2vp50 xc2vp70 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 194 product not recommended for new designs n/a gnda18 au16 n/a txppad18 aw18 n/a txnpad18 aw19 n/a vttxpad18 av19 n/a avccauxtx18 av18 n/a avccauxrx19 av21 n/a vtrxpad19 av22 n/a rxnpad19 aw21 n/a rxppad19 aw22 n/a gnda19 au24 n/a txppad19 aw23 n/a txnpad19 aw24 n/a vttxpad19 av24 n/a avccauxtx19 av23 n/a avccauxrx20 av25 n/a vtrxpad20 av26 n/a rxnpad20 aw25 n/a rxppad20 aw26 n/a gnda20 au27 n/a txppad20 aw27 n/a txnpad20 aw28 n/a vttxpad20 av28 n/a avccauxtx20 av27 n/a avccauxrx21 av29 n/a vtrxpad21 av30 n/a rxnpad21 aw29 n/a rxppad21 aw30 n/a gnda21 au31 n/a txppad21 aw31 n/a txnpad21 aw32 n/a vttxpad21 av32 n/a avccauxtx21 av31 n/a avccauxrx23 av33 n/a vtrxpad23 av34 n/a rxnpad23 aw33 n/a rxppad23 aw34 n/a gnda23 au34 n/a txppad23 aw35 ta bl e 1 2 : ff1517 ? xc2vp50 and xc2vp70 bank pin description pin number no connects xc2vp50 xc2vp70 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 195 product not recommended for new designs n/a txnpad23 aw36 n/a vttxpad23 av36 n/a avccauxtx23 av35 n/a vccint ah28 n/a vccint m28 n/a vccint ag27 n/a vccint n27 n/a vccint af26 n/a vccint p26 n/a vccint ae25 n/a vccint ad25 n/a vccint ac25 n/a vccint ab25 n/a vccint aa25 n/a vccint y25 n/a vccint w25 n/a vccint v25 n/a vccint u25 n/a vccint t25 n/a vccint r25 n/a vccint ae24 n/a vccint ad24 n/a vccint t24 n/a vccint r24 n/a vccint ae23 n/a vccint r23 n/a vccint ae22 n/a vccint r22 n/a vccint ae21 n/a vccint r21 n/a vccint ae20 n/a vccint r20 n/a vccint ae19 n/a vccint r19 n/a vccint ae18 n/a vccint r18 n/a vccint ae17 ta bl e 1 2 : ff1517 ? xc2vp50 and xc2vp70 bank pin description pin number no connects xc2vp50 xc2vp70 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 196 product not recommended for new designs n/a vccint r17 n/a vccint ae16 n/a vccint ad16 n/a vccint t16 n/a vccint r16 n/a vccint ae15 n/a vccint ad15 n/a vccint ac15 n/a vccint ab15 n/a vccint aa15 n/a vccint y15 n/a vccint w15 n/a vccint v15 n/a vccint u15 n/a vccint t15 n/a vccint r15 n/a vccint af14 n/a vccint p14 n/a vccint ag13 n/a vccint n13 n/a vccint ah12 n/a vccint m12 n/a vccaux av39 n/a vccaux aa39 n/a vccaux y39 n/a vccaux w39 n/a vccaux b39 n/a vccaux aw38 n/a vccaux y38 n/a vccaux a38 n/a vccaux ar35 n/a vccaux e35 n/a vccaux ap34 n/a vccaux f34 n/a vccaux aw20 n/a vccaux av20 n/a vccaux b20 n/a vccaux a20 ta bl e 1 2 : ff1517 ? xc2vp50 and xc2vp70 bank pin description pin number no connects xc2vp50 xc2vp70 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 197 product not recommended for new designs n/a vccaux ap6 n/a vccaux f6 n/a vccaux ar5 n/a vccaux e5 n/a vccaux aw2 n/a vccaux y2 n/a vccaux a2 n/a vccaux av1 n/a vccaux aa1 n/a vccaux y1 n/a vccaux w1 n/a vccaux b1 n/a gnd a3 n/a gnd av2 n/a gnd au2 n/a gnd aa2 n/a gnd w2 n/a gnd c2 n/a gnd b2 n/a gnd au1 n/a gnd am1 n/a gnd ah1 n/a gnd ad1 n/a gnd t1 n/a gnd m1 n/a gnd h1 n/a gnd c1 n/a gnd ad5 n/a gnd t5 n/a gnd m5 n/a gnd h5 n/a gnd au4 n/a gnd at4 n/a gnd d4 n/a gnd c4 n/a gnd aw3 n/a gnd av3 ta bl e 1 2 : ff1517 ? xc2vp50 and xc2vp70 bank pin description pin number no connects xc2vp50 xc2vp70 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 198 product not recommended for new designs n/a gnd au3 n/a gnd at3 n/a gnd d3 n/a gnd c3 n/a gnd b3 n/a gnd an12 n/a gnd g12 n/a gnd c12 n/a gnd y10 n/a gnd ah9 n/a gnd ad9 n/a gnd t9 n/a gnd m9 n/a gnd au8 n/a gnd an8 n/a gnd g8 n/a gnd c8 n/a gnd y6 n/a gnd am5 n/a gnd ah5 n/a gnd t17 n/a gnd at16 n/a gnd an16 n/a gnd aj16 n/a gnd ac16 n/a gnd ab16 n/a gnd aa16 n/a gnd y16 n/a gnd w16 n/a gnd v16 n/a gnd u16 n/a gnd l16 n/a gnd g16 n/a gnd d16 n/a gnd au12 n/a gnd ab18 n/a gnd aa18 n/a gnd y18 ta bl e 1 2 : ff1517 ? xc2vp50 and xc2vp70 bank pin description pin number no connects xc2vp50 xc2vp70 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 199 product not recommended for new designs n/a gnd w18 n/a gnd v18 n/a gnd u18 n/a gnd t18 n/a gnd ad17 n/a gnd ac17 n/a gnd ab17 n/a gnd aa17 n/a gnd y17 n/a gnd w17 n/a gnd v17 n/a gnd u17 n/a gnd p20 n/a gnd l20 n/a gnd g20 n/a gnd c20 n/a gnd ad19 n/a gnd ac19 n/a gnd ab19 n/a gnd aa19 n/a gnd y19 n/a gnd w19 n/a gnd v19 n/a gnd u19 n/a gnd t19 n/a gnd ad18 n/a gnd ac18 n/a gnd u21 n/a gnd t21 n/a gnd au20 n/a gnd an20 n/a gnd aj20 n/a gnd af20 n/a gnd ad20 n/a gnd ac20 n/a gnd ab20 n/a gnd aa20 n/a gnd y20 ta bl e 1 2 : ff1517 ? xc2vp50 and xc2vp70 bank pin description pin number no connects xc2vp50 xc2vp70 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 200 product not recommended for new designs n/a gnd w20 n/a gnd v20 n/a gnd u20 n/a gnd t20 n/a gnd ac22 n/a gnd ab22 n/a gnd aa22 n/a gnd y22 n/a gnd w22 n/a gnd v22 n/a gnd u22 n/a gnd t22 n/a gnd ad21 n/a gnd ac21 n/a gnd ab21 n/a gnd aa21 n/a gnd y21 n/a gnd w21 n/a gnd v21 n/a gnd b38 n/a gnd aw37 n/a gnd av37 n/a gnd au37 n/a gnd at37 n/a gnd d37 n/a gnd c37 n/a gnd b37 n/a gnd a37 n/a gnd au36 n/a gnd at36 n/a gnd d36 n/a gnd c36 n/a gnd am35 n/a gnd ah35 n/a gnd ad35 n/a gnd t35 n/a gnd m35 n/a gnd h35 ta bl e 1 2 : ff1517 ? xc2vp50 and xc2vp70 bank pin description pin number no connects xc2vp50 xc2vp70 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 201 product not recommended for new designs n/a gnd y34 n/a gnd au32 n/a gnd an32 n/a gnd g32 n/a gnd c32 n/a gnd ah31 n/a gnd ad31 n/a gnd t31 n/a gnd m31 n/a gnd y30 n/a gnd au28 n/a gnd an28 n/a gnd g28 n/a gnd c28 n/a gnd at24 n/a gnd an24 n/a gnd aj24 n/a gnd ac24 n/a gnd ab24 n/a gnd aa24 n/a gnd y24 n/a gnd w24 n/a gnd v24 n/a gnd u24 n/a gnd l24 n/a gnd g24 n/a gnd d24 n/a gnd ad23 n/a gnd ac23 n/a gnd ab23 n/a gnd aa23 n/a gnd y23 n/a gnd w23 n/a gnd v23 n/a gnd u23 n/a gnd t23 n/a gnd ad22 n/a gnd au39 ta bl e 1 2 : ff1517 ? xc2vp50 and xc2vp70 bank pin description pin number no connects xc2vp50 xc2vp70 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 202 product not recommended for new designs n/a gnd am39 n/a gnd ah39 n/a gnd ad39 n/a gnd t39 n/a gnd m39 n/a gnd h39 n/a gnd c39 n/a gnd av38 n/a gnd au38 n/a gnd aa38 n/a gnd w38 n/a gnd c38 notes: 1. see ta b l e 4 for an explanation of the signals available on this pin. ta bl e 1 2 : ff1517 ? xc2vp50 and xc2vp70 bank pin description pin number no connects xc2vp50 xc2vp70 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 203 product not recommended for new designs ff1517 flip-chip fine-pitc h bga package specificat ions (1.00mm pitch) figure 8: ff1517 flip-chip fine-pitch bga package specifications virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 204 product not recommended for new designs ff1704 flip-chip fine-pitch bga package as shown in ta b l e 1 3 , xc2vp70 and xc2vp100 virtex-ii pro devices are available in the ff1704 flip-chip fine-pitch bga package. following this table are the ff1704 flip-chip fine-pitch bga package specifications (1.00mm pitch) . ta bl e 1 3 : ff1704 ? xc2vp70, xc2vpx70, and xc2vp100 bank pin description pin number no connects virtex-ii pro devices xc2vpx70 (if different) xc2vp70, xc2vpx70 xc2vp100 0 io_l01n_0/vrp_0 g34 0 io_l01p_0/vrn_0 h34 0 io_l02n_0 f34 0 io_l02p_0 e34 0 io_l03n_0 c34 0 io_l03p_0/vref_0 d34 0 io_l05_0/no_pair k32 0 io_l06n_0 h33 0 io_l06p_0 j33 0 io_l07n_0 f33 0 io_l07p_0 g33 0 io_l08n_0 e33 0 io_l08p_0 d33 0 io_l09n_0 h32 0 io_l09p_0/vref_0 j32 0 io_l19n_0 e32 0 io_l19p_0 f32 0 io_l20n_0 c33 0 io_l20p_0 c32 0 io_l21n_0 k31 0 io_l21p_0 l31 0 io_l25n_0 h31 0 io_l25p_0 j31 0 io_l26n_0 g31 0 io_l26p_0 f31 0 io_l27n_0 d31 0 io_l27p_0/vref_0 e31 0 io_l28n_0 l30 0 io_l28p_0 m30 0 io_l29n_0 j30 0 io_l29p_0 k30 0 io_l30n_0 g30 0 io_l30p_0 h30 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 205 product not recommended for new designs 0 io_l34n_0 e30 0 io_l34p_0 f30 0 io_l35n_0 d30 0 io_l35p_0 c30 0 io_l36n_0 m28 0 io_l36p_0/vref_0 m29 0 io_l78n_0 k29 nc 0 io_l78p_0 l29 nc 0 io_l83_0/no_pair h29 nc 0 io_l84n_0 f29 nc 0 io_l84p_0 g29 nc 0 io_l85n_0 d29 nc 0 io_l85p_0 e29 nc 0 io_l86n_0 l28 nc 0 io_l86p_0 k28 nc 0 io_l87n_0 h28 nc 0 io_l87p_0/vref_0 j28 nc 0 io_l37n_0 e28 0 io_l37p_0 f28 0 io_l38n_0 c29 0 io_l38p_0 c28 0 io_l39n_0 l27 0 io_l39p_0 m27 0 io_l43n_0 j27 0 io_l43p_0 k27 0 io_l44n_0 h27 0 io_l44p_0 g27 0 io_l45n_0 e27 0 io_l45p_0/vref_0 f27 0 io_l46n_0 m25 0 io_l46p_0 m26 0 io_l47n_0 l26 0 io_l47p_0 k26 0 io_l48n_0 h26 0 io_l48p_0 j26 0 io_l49n_0 f26 ta bl e 1 3 : ff1704 ? xc2vp70, xc2vpx70, and xc2vp100 bank pin description pin number no connects virtex-ii pro devices xc2vpx70 (if different) xc2vp70, xc2vpx70 xc2vp100 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 206 product not recommended for new designs 0 io_l49p_0 g26 0 io_l50_0/no_pair d27 0 io_l53_0/no_pair d26 0 io_l54n_0 k25 0 io_l54p_0 l25 0 io_l55n_0 g25 0 io_l55p_0 h25 0 io_l56n_0 e26 0 io_l56p_0 e25 0 io_l57n_0 c25 0 io_l57p_0/vref_0 c26 0 io_l58n_0 l24 0 io_l58p_0 m24 0 io_l59n_0 j24 0 io_l59p_0 k24 0 io_l60n_0 g24 0 io_l60p_0 h24 0 io_l64n_0 e24 0 io_l64p_0 f24 0 io_l65n_0 d24 0 io_l65p_0 c24 0 io_l66n_0 m22 0 io_l66p_0/vref_0 m23 0 io_l67n_0 k23 0 io_l67p_0 l23 0 io_l68n_0 j23 0 io_l68p_0 h23 0 io_l69n_0 e23 0 io_l69p_0/vref_0 f23 0 io_l73n_0 c23 0 io_l73p_0 d23 0 io_l74n_0/gclk7p k22 0 io_l74p_0/gclk6s j22 0 io_l75n_0/gclk5p brefclkn f22 0 io_l75p_0/gclk4s brefclkp g22 ta bl e 1 3 : ff1704 ? xc2vp70, xc2vpx70, and xc2vp100 bank pin description pin number no connects virtex-ii pro devices xc2vpx70 (if different) xc2vp70, xc2vpx70 xc2vp100 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 207 product not recommended for new designs 1 io_l75n_1/gclk3p g21 1 io_l75p_1/gclk2s f21 1 io_l74n_1/gclk1p j21 1 io_l74p_1/gclk0s k21 1 io_l73n_1 d20 1 io_l73p_1 c20 1 io_l69n_1/vref_1 f20 1 io_l69p_1 e20 1 io_l68n_1 h20 1 io_l68p_1 j20 1 io_l67n_1 l20 1 io_l67p_1 k20 1 io_l66n_1/vref_1 m20 1 io_l66p_1 m21 1 io_l65n_1 c19 1 io_l65p_1 d19 1 io_l64n_1 f19 1 io_l64p_1 e19 1 io_l60n_1 h19 1 io_l60p_1 g19 1 io_l59n_1 k19 1 io_l59p_1 j19 1 io_l58n_1 m19 1 io_l58p_1 l19 1 io_l57n_1/vref_1 c17 1 io_l57p_1 c18 1 io_l56n_1 e18 1 io_l56p_1 e17 1 io_l55n_1 h18 1 io_l55p_1 g18 1 io_l54n_1 l18 1 io_l54p_1 k18 1 io_l53_1/no_pair d17 1 io_l50_1/no_pair d16 1 io_l49n_1 g17 1 io_l49p_1 f17 ta bl e 1 3 : ff1704 ? xc2vp70, xc2vpx70, and xc2vp100 bank pin description pin number no connects virtex-ii pro devices xc2vpx70 (if different) xc2vp70, xc2vpx70 xc2vp100 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 208 product not recommended for new designs 1 io_l48n_1 j17 1 io_l48p_1 h17 1 io_l47n_1 k17 1 io_l47p_1 l17 1 io_l46n_1 m17 1 io_l46p_1 m18 1 io_l45n_1/vref_1 f16 1 io_l45p_1 e16 1 io_l44n_1 g16 1 io_l44p_1 h16 1 io_l43n_1 k16 1 io_l43p_1 j16 1 io_l39n_1 m16 1 io_l39p_1 l16 1 io_l38n_1 c15 1 io_l38p_1 c14 1 io_l37n_1 f15 1 io_l37p_1 e15 1 io_l87n_1/vref_1 j15 nc 1 io_l87p_1 h15 nc 1 io_l86n_1 k15 nc 1 io_l86p_1 l15 nc 1 io_l85n_1 e14 nc 1 io_l85p_1 d14 nc 1 io_l84n_1 g14 nc 1 io_l84p_1 f14 nc 1 io_l83_1/no_pair h14 nc 1 io_l78n_1 l14 nc 1 io_l78p_1 k14 nc 1 io_l36n_1/vref_1 m14 1 io_l36p_1 m15 1 io_l35n_1 c13 1 io_l35p_1 d13 1 io_l34n_1 f13 1 io_l34p_1 e13 1 io_l30n_1 h13 ta bl e 1 3 : ff1704 ? xc2vp70, xc2vpx70, and xc2vp100 bank pin description pin number no connects virtex-ii pro devices xc2vpx70 (if different) xc2vp70, xc2vpx70 xc2vp100 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 209 product not recommended for new designs 1 io_l30p_1 g13 1 io_l29n_1 k13 1 io_l29p_1 j13 1 io_l28n_1 m13 1 io_l28p_1 l13 1 io_l27n_1/vref_1 e12 1 io_l27p_1 d12 1 io_l26n_1 f12 1 io_l26p_1 g12 1 io_l25n_1 j12 1 io_l25p_1 h12 1 io_l21n_1 l12 1 io_l21p_1 k12 1 io_l20n_1 c11 1 io_l20p_1 c10 1 io_l19n_1 f11 1 io_l19p_1 e11 1 io_l09n_1/vref_1 j11 1 io_l09p_1 h11 1 io_l08n_1 d10 1 io_l08p_1 e10 1 io_l07n_1 g10 1 io_l07p_1 f10 1 io_l06n_1 j10 1 io_l06p_1 h10 1 io_l05_1/no_pair k11 1 io_l03n_1/vref_1 d9 1 io_l03p_1 c9 1 io_l02n_1 e9 1 io_l02p_1 f9 1 io_l01n_1/vrp_1 h9 1 io_l01p_1/vrn_1 g9 2 io_l01n_2/vrp_2 c5 2 io_l01p_2/vrn_2 c6 2 io_l02n_2 e7 ta bl e 1 3 : ff1704 ? xc2vp70, xc2vpx70, and xc2vp100 bank pin description pin number no connects virtex-ii pro devices xc2vpx70 (if different) xc2vp70, xc2vpx70 xc2vp100 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 210 product not recommended for new designs 2 io_l02p_2 d7 2 io_l03n_2 e6 2 io_l03p_2 d6 2 io_l04n_2/vref_2 g6 2 io_l04p_2 f7 2 io_l05n_2 d3 2 io_l05p_2 e3 2 io_l06n_2 d1 2 io_l06p_2 d2 2 io_l73n_2 e1 2 io_l73p_2 e2 2 io_l74n_2 f4 2 io_l74p_2 f3 2 io_l75n_2 f1 2 io_l75p_2 f2 2 io_l76n_2/vref_2 g3 2 io_l76p_2 g4 2 io_l77n_2 g2 2 io_l77p_2 g1 2 io_l78n_2 g5 2 io_l78p_2 h6 2 io_l79n_2 h4 2 io_l79p_2 h5 2 io_l80n_2 h3 2 io_l80p_2 h2 2 io_l81n_2 h7 2 io_l81p_2 j8 2 io_l82n_2/vref_2 j6 2 io_l82p_2 j7 2 io_l83n_2 j5 2 io_l83p_2 j4 2 io_l84n_2 j1 2 io_l84p_2 j2 2 io_l07n_2 k9 2 io_l07p_2 l10 2 io_l08n_2 k6 ta bl e 1 3 : ff1704 ? xc2vp70, xc2vpx70, and xc2vp100 bank pin description pin number no connects virtex-ii pro devices xc2vpx70 (if different) xc2vp70, xc2vpx70 xc2vp100 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 211 product not recommended for new designs 2 io_l08p_2 k5 2 io_l09n_2 k8 2 io_l09p_2 k7 2 io_l10n_2/vref_2 k2 2 io_l10p_2 k1 2 io_l11n_2 l8 2 io_l11p_2 l9 2 io_l12n_2 l6 2 io_l12p_2 l7 2 io_l13n_2 k3 2 io_l13p_2 l3 2 io_l14n_2 l5 2 io_l14p_2 l4 2 io_l15n_2 l1 2 io_l15p_2 l2 2 io_l16n_2/vref_2 m7 2 io_l16p_2 m8 2 io_l17n_2 m11 2 io_l17p_2 m12 2 io_l18n_2 m9 2 io_l18p_2 m10 2 io_l19n_2 m2 2 io_l19p_2 m3 2 io_l20n_2 m4 2 io_l20p_2 m5 2 io_l21n_2 n7 2 io_l21p_2 n8 2 io_l22n_2/vref_2 n5 2 io_l22p_2 n6 2 io_l23n_2 n9 2 io_l23p_2 n10 2 io_l24n_2 n3 2 io_l24p_2 n4 2 io_l25n_2 n1 2 io_l25p_2 n2 2 io_l26n_2 n11 ta bl e 1 3 : ff1704 ? xc2vp70, xc2vpx70, and xc2vp100 bank pin description pin number no connects virtex-ii pro devices xc2vpx70 (if different) xc2vp70, xc2vpx70 xc2vp100 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 212 product not recommended for new designs 2 io_l26p_2 n12 2 io_l27n_2 p9 2 io_l27p_2 p10 2 io_l28n_2/vref_2 p7 2 io_l28p_2 p8 2 io_l29n_2 p11 2 io_l29p_2 p12 2 io_l30n_2 p5 2 io_l30p_2 p6 2 io_l31n_2 p1 2 io_l31p_2 p2 2 io_l32n_2 r9 2 io_l32p_2 r10 2 io_l33n_2 r5 2 io_l33p_2 r6 2 io_l34n_2/vref_2 p3 2 io_l34p_2 r3 2 io_l35n_2 r1 2 io_l35p_2 r2 2 io_l36n_2 r11 2 io_l36p_2 r12 2 io_l37n_2 t6 2 io_l37p_2 t7 2 io_l38n_2 t8 2 io_l38p_2 r8 2 io_l39n_2 t4 2 io_l39p_2 t5 2 io_l40n_2/vref_2 t2 2 io_l40p_2 t3 2 io_l41n_2 t10 2 io_l41p_2 t11 2 io_l42n_2 u7 2 io_l42p_2 u8 2 io_l43n_2 u5 2 io_l43p_2 u6 2 io_l44n_2 u9 ta bl e 1 3 : ff1704 ? xc2vp70, xc2vpx70, and xc2vp100 bank pin description pin number no connects virtex-ii pro devices xc2vpx70 (if different) xc2vp70, xc2vpx70 xc2vp100 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 213 product not recommended for new designs 2 io_l44p_2 u10 2 io_l45n_2 u3 2 io_l45p_2 u4 2 io_l46n_2/vref_2 u1 2 io_l46p_2 u2 2 io_l47n_2 t12 2 io_l47p_2 u12 2 io_l48n_2 v10 2 io_l48p_2 v11 2 io_l49n_2 v7 2 io_l49p_2 v8 2 io_l50n_2 u11 2 io_l50p_2 v12 2 io_l51n_2 v4 2 io_l51p_2 v5 2 io_l52n_2/vref_2 v1 2 io_l52p_2 v2 2 io_l53n_2 w9 2 io_l53p_2 w10 2 io_l54n_2 w7 2 io_l54p_2 w8 2 io_l55n_2 w5 2 io_l55p_2 w6 2 io_l56n_2 w11 2 io_l56p_2 w12 2 io_l57n_2 w3 2 io_l57p_2 w4 2 io_l58n_2/vref_2 w1 2 io_l58p_2 w2 2 io_l59n_2 y9 2 io_l59p_2 y10 2 io_l60n_2 y6 2 io_l60p_2 y7 2 io_l85n_2 y3 2 io_l85p_2 y4 2 io_l86n_2 y11 ta bl e 1 3 : ff1704 ? xc2vp70, xc2vpx70, and xc2vp100 bank pin description pin number no connects virtex-ii pro devices xc2vpx70 (if different) xc2vp70, xc2vpx70 xc2vp100 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 214 product not recommended for new designs 2 io_l86p_2 y12 2 io_l87n_2 aa9 2 io_l87p_2 aa10 2 io_l88n_2/vref_2 aa6 2 io_l88p_2 aa7 2 io_l89n_2 aa12 2 io_l89p_2 ab12 2 io_l90n_2 aa3 2 io_l90p_2 aa4 3 io_l90n_3 ab3 3 io_l90p_3 ab4 3 io_l89n_3 ab6 3 io_l89p_3 ab7 3 io_l88n_3 ab9 3 io_l88p_3 ab10 3 io_l87n_3/vref_3 ac3 3 io_l87p_3 ac4 3 io_l86n_3 ac11 3 io_l86p_3 ac12 3 io_l85n_3 ac6 3 io_l85p_3 ac7 3 io_l60n_3 ac9 3 io_l60p_3 ac10 3 io_l59n_3 ad9 3 io_l59p_3 ad10 3 io_l58n_3 ad1 3 io_l58p_3 ad2 3 io_l57n_3/vref_3 ad3 3 io_l57p_3 ad4 3 io_l56n_3 ad11 3 io_l56p_3 ad12 3 io_l55n_3 ad5 3 io_l55p_3 ad6 3 io_l54n_3 ad7 3 io_l54p_3 ad8 ta bl e 1 3 : ff1704 ? xc2vp70, xc2vpx70, and xc2vp100 bank pin description pin number no connects virtex-ii pro devices xc2vpx70 (if different) xc2vp70, xc2vpx70 xc2vp100 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 215 product not recommended for new designs 3 io_l53n_3 ae10 3 io_l53p_3 ae11 3 io_l52n_3 ae1 3 io_l52p_3 ae2 3 io_l51n_3/vref_3 ae4 3 io_l51p_3 ae5 3 io_l50n_3 af11 3 io_l50p_3 ae12 3 io_l49n_3 ae7 3 io_l49p_3 ae8 3 io_l48n_3 af1 3 io_l48p_3 af2 3 io_l47n_3 ag12 3 io_l47p_3 af12 3 io_l46n_3 af3 3 io_l46p_3 af4 3 io_l45n_3/vref_3 af5 3 io_l45p_3 af6 3 io_l44n_3 af7 3 io_l44p_3 af8 3 io_l43n_3 af9 3 io_l43p_3 af10 3 io_l42n_3 ag2 3 io_l42p_3 ag3 3 io_l41n_3 ag10 3 io_l41p_3 ag11 3 io_l40n_3 ag4 3 io_l40p_3 ag5 3 io_l39n_3/vref_3 ag6 3 io_l39p_3 ag7 3 io_l38n_3 ag8 3 io_l38p_3 ah8 3 io_l37n_3 ah1 3 io_l37p_3 ah2 3 io_l36n_3 ah3 3 io_l36p_3 aj3 ta bl e 1 3 : ff1704 ? xc2vp70, xc2vpx70, and xc2vp100 bank pin description pin number no connects virtex-ii pro devices xc2vpx70 (if different) xc2vp70, xc2vpx70 xc2vp100 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 216 product not recommended for new designs 3 io_l35n_3 ah11 3 io_l35p_3 ah12 3 io_l34n_3 ah5 3 io_l34p_3 ah6 3 io_l33n_3/vref_3 ah9 3 io_l33p_3 ah10 3 io_l32n_3 aj11 3 io_l32p_3 aj12 3 io_l31n_3 aj1 3 io_l31p_3 aj2 3 io_l30n_3 aj5 3 io_l30p_3 aj6 3 io_l29n_3 aj9 3 io_l29p_3 aj10 3 io_l28n_3 aj7 3 io_l28p_3 aj8 3 io_l27n_3/vref_3 ak1 3 io_l27p_3 ak2 3 io_l26n_3 ak11 3 io_l26p_3 ak12 3 io_l25n_3 ak3 3 io_l25p_3 ak4 3 io_l24n_3 ak5 3 io_l24p_3 ak6 3 io_l23n_3 ak9 3 io_l23p_3 ak10 3 io_l22n_3 ak7 3 io_l22p_3 ak8 3 io_l21n_3/vref_3 al2 3 io_l21p_3 al3 3 io_l20n_3 al11 3 io_l20p_3 al12 3 io_l19n_3 al4 3 io_l19p_3 al5 3 io_l18n_3 al7 3 io_l18p_3 al8 ta bl e 1 3 : ff1704 ? xc2vp70, xc2vpx70, and xc2vp100 bank pin description pin number no connects virtex-ii pro devices xc2vpx70 (if different) xc2vp70, xc2vpx70 xc2vp100 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 217 product not recommended for new designs 3 io_l17n_3 al9 3 io_l17p_3 al10 3 io_l16n_3 am1 3 io_l16p_3 am2 3 io_l15n_3/vref_3 am3 3 io_l15p_3 an3 3 io_l14n_3 am8 3 io_l14p_3 am9 3 io_l13n_3 am4 3 io_l13p_3 am5 3 io_l12n_3 am6 3 io_l12p_3 am7 3 io_l11n_3 an9 3 io_l11p_3 am10 3 io_l10n_3 an1 3 io_l10p_3 an2 3 io_l09n_3/vref_3 an5 3 io_l09p_3 an6 3 io_l08n_3 an7 3 io_l08p_3 an8 3 io_l07n_3 ap1 3 io_l07p_3 ap2 3 io_l84n_3 ap4 3 io_l84p_3 ap5 3 io_l83n_3 ar7 3 io_l83p_3 ap8 3 io_l82n_3 ap6 3 io_l82p_3 ap7 3 io_l81n_3/vref_3 ar2 3 io_l81p_3 ar3 3 io_l80n_3 at5 3 io_l80p_3 ar6 3 io_l79n_3 ar4 3 io_l79p_3 ar5 3 io_l78n_3 at1 3 io_l78p_3 at2 ta bl e 1 3 : ff1704 ? xc2vp70, xc2vpx70, and xc2vp100 bank pin description pin number no connects virtex-ii pro devices xc2vpx70 (if different) xc2vp70, xc2vpx70 xc2vp100 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 218 product not recommended for new designs 3 io_l77n_3 at3 3 io_l77p_3 at4 3 io_l76n_3 au1 3 io_l76p_3 au2 3 io_l75n_3/vref_3 au3 3 io_l75p_3 au4 3 io_l74n_3 av3 3 io_l74p_3 aw3 3 io_l73n_3 av1 3 io_l73p_3 av2 3 io_l06n_3 aw1 3 io_l06p_3 aw2 3 io_l05n_3 at8 3 io_l05p_3 au8 3 io_l04n_3 at6 3 io_l04p_3 au7 3 io_l03n_3/vref_3 ay5 3 io_l03p_3 ay6 3 io_l02n_3 av7 3 io_l02p_3 aw7 3 io_l01n_3/vrp_3 av6 3 io_l01p_3/vrn_3 aw6 4 io_l01n_4/busy/dout (1) at 9 4 io_l01p_4/init_b ar9 4 io_l02n_4/d0/din (1) au9 4 io_l02p_4/d1 av9 4 io_l03n_4/d2 ay9 4 io_l03p_4/d3 aw9 4 io_l05_4/no_pair an11 4 io_l06n_4/vrp_4 ar10 4 io_l06p_4/vrn_4 ap10 4 io_l07n_4 au10 4 io_l07p_4/vref_4 at10 4 io_l08n_4 av10 4 io_l08p_4 aw10 ta bl e 1 3 : ff1704 ? xc2vp70, xc2vpx70, and xc2vp100 bank pin description pin number no connects virtex-ii pro devices xc2vpx70 (if different) xc2vp70, xc2vpx70 xc2vp100 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 219 product not recommended for new designs 4 io_l09n_4 ar11 4 io_l09p_4/vref_4 ap11 4 io_l19n_4 av11 4 io_l19p_4 au11 4 io_l20n_4 ay10 4 io_l20p_4 ay11 4 io_l21n_4 an12 4 io_l21p_4 am12 4 io_l25n_4 ar12 4 io_l25p_4 ap12 4 io_l26n_4 at12 4 io_l26p_4 au12 4 io_l27n_4 aw12 4 io_l27p_4/vref_4 av12 4 io_l28n_4 am13 4 io_l28p_4 al13 4 io_l29n_4 ap13 4 io_l29p_4 an13 4 io_l30n_4 at13 4 io_l30p_4 ar13 4 io_l34n_4 av13 4 io_l34p_4 au13 4 io_l35n_4 aw13 4 io_l35p_4 ay13 4 io_l36n_4 al15 4 io_l36p_4/vref_4 al14 4 io_l78n_4 an14 nc 4 io_l78p_4 am14 nc 4 io_l83_4/no_pair ar14 nc 4 io_l84n_4 au14 nc 4 io_l84p_4 at14 nc 4 io_l85n_4 aw14 nc 4 io_l85p_4 av14 nc 4 io_l86n_4 am15 nc 4 io_l86p_4 an15 nc 4 io_l87n_4 ar15 nc ta bl e 1 3 : ff1704 ? xc2vp70, xc2vpx70, and xc2vp100 bank pin description pin number no connects virtex-ii pro devices xc2vpx70 (if different) xc2vp70, xc2vpx70 xc2vp100 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 220 product not recommended for new designs 4 io_l87p_4/vref_4 ap15 nc 4 io_l37n_4 av15 4 io_l37p_4 au15 4 io_l38n_4 ay14 4 io_l38p_4 ay15 4 io_l39n_4 am16 4 io_l39p_4 al16 4 io_l43n_4 ap16 4 io_l43p_4 an16 4 io_l44n_4 ar16 4 io_l44p_4 at16 4 io_l45n_4 av16 4 io_l45p_4/vref_4 au16 4 io_l46n_4 al18 4 io_l46p_4 al17 4 io_l47n_4 am17 4 io_l47p_4 an17 4 io_l48n_4 ar17 4 io_l48p_4 ap17 4 io_l49n_4 au17 4 io_l49p_4 at17 4 io_l50_4/no_pair aw16 4 io_l53_4/no_pair aw17 4 io_l54n_4 an18 4 io_l54p_4 am18 4 io_l55n_4 at18 4 io_l55p_4 ar18 4 io_l56n_4 av17 4 io_l56p_4 av18 4 io_l57n_4 ay18 4 io_l57p_4/vref_4 ay17 4 io_l58n_4 am19 4 io_l58p_4 al19 4 io_l59n_4 ap19 4 io_l59p_4 an19 4 io_l60n_4 at19 ta bl e 1 3 : ff1704 ? xc2vp70, xc2vpx70, and xc2vp100 bank pin description pin number no connects virtex-ii pro devices xc2vpx70 (if different) xc2vp70, xc2vpx70 xc2vp100 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 221 product not recommended for new designs 4 io_l60p_4 ar19 4 io_l64n_4 av19 4 io_l64p_4 au19 4 io_l65n_4 aw19 4 io_l65p_4 ay19 4 io_l66n_4 al21 4 io_l66p_4/vref_4 al20 4 io_l67n_4 an20 4 io_l67p_4 am20 4 io_l68n_4 ap20 4 io_l68p_4 ar20 4 io_l69n_4 av20 4 io_l69p_4/vref_4 au20 4 io_l73n_4 ay20 4 io_l73p_4 aw20 4 io_l74n_4/gclk3s an21 4 io_l74p_4/gclk2p ap21 4 io_l75n_4/gclk1s au21 4 io_l75p_4/gclk0p at21 5 io_l75n_5/gclk7s brefclkn at22 5 io_l75p_5/gclk6p brefclkp au22 5 io_l74n_5/gclk5s ap22 5 io_l74p_5/gclk4p an22 5 io_l73n_5 aw23 5 io_l73p_5 ay23 5 io_l69n_5/vref_5 au23 5 io_l69p_5 av23 5 io_l68n_5 ar23 5 io_l68p_5 ap23 5 io_l67n_5 am23 5 io_l67p_5 an23 5 io_l66n_5/vref_5 al23 5 io_l66p_5 al22 5 io_l65n_5 ay24 5 io_l65p_5 aw24 ta bl e 1 3 : ff1704 ? xc2vp70, xc2vpx70, and xc2vp100 bank pin description pin number no connects virtex-ii pro devices xc2vpx70 (if different) xc2vp70, xc2vpx70 xc2vp100 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 222 product not recommended for new designs 5 io_l64n_5 au24 5 io_l64p_5 av24 5 io_l60n_5 ar24 5 io_l60p_5 at24 5 io_l59n_5 an24 5 io_l59p_5 ap24 5 io_l58n_5 al24 5 io_l58p_5 am24 5 io_l57n_5/vref_5 ay26 5 io_l57p_5 ay25 5 io_l56n_5 av25 5 io_l56p_5 av26 5 io_l55n_5 ar25 5 io_l55p_5 at25 5 io_l54n_5 am25 5 io_l54p_5 an25 5 io_l53_5/no_pair aw26 5 io_l50_5/no_pair aw27 5 io_l49n_5 at26 5 io_l49p_5 au26 5 io_l48n_5 ap26 5 io_l48p_5 ar26 5 io_l47n_5 an26 5 io_l47p_5 am26 5 io_l46n_5 al26 5 io_l46p_5 al25 5 io_l45n_5/vref_5 au27 5 io_l45p_5 av27 5 io_l44n_5 at27 5 io_l44p_5 ar27 5 io_l43n_5 an27 5 io_l43p_5 ap27 5 io_l39n_5 al27 5 io_l39p_5 am27 5 io_l38n_5 ay28 5 io_l38p_5 ay29 ta bl e 1 3 : ff1704 ? xc2vp70, xc2vpx70, and xc2vp100 bank pin description pin number no connects virtex-ii pro devices xc2vpx70 (if different) xc2vp70, xc2vpx70 xc2vp100 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 223 product not recommended for new designs 5 io_l37n_5 au28 5 io_l37p_5 av28 5 io_l87n_5/vref_5 ap28 nc 5 io_l87p_5 ar28 nc 5 io_l86n_5 an28 nc 5 io_l86p_5 am28 nc 5 io_l85n_5 av29 nc 5 io_l85p_5 aw29 nc 5 io_l84n_5 at29 nc 5 io_l84p_5 au29 nc 5 io_l83_5/no_pair ar29 nc 5 io_l78n_5 am29 nc 5 io_l78p_5 an29 nc 5 io_l36n_5/vref_5 al29 5 io_l36p_5 al28 5 io_l35n_5 ay30 5 io_l35p_5 aw30 5 io_l34n_5 au30 5 io_l34p_5 av30 5 io_l30n_5 ar30 5 io_l30p_5 at30 5 io_l29n_5 an30 5 io_l29p_5 ap30 5 io_l28n_5 al30 5 io_l28p_5 am30 5 io_l27n_5/vref_5 av31 5 io_l27p_5 aw31 5 io_l26n_5 au31 5 io_l26p_5 at31 5 io_l25n_5 ap31 5 io_l25p_5 ar31 5 io_l21n_5 am31 5 io_l21p_5 an31 5 io_l20n_5 ay32 5 io_l20p_5 ay33 5 io_l19n_5 au32 ta bl e 1 3 : ff1704 ? xc2vp70, xc2vpx70, and xc2vp100 bank pin description pin number no connects virtex-ii pro devices xc2vpx70 (if different) xc2vp70, xc2vpx70 xc2vp100 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 224 product not recommended for new designs 5 io_l19p_5 av32 5 io_l09n_5/vref_5 ap32 5 io_l09p_5 ar32 5 io_l08n_5 aw33 5 io_l08p_5 av33 5 io_l07n_5/vref_5 at33 5 io_l07p_5 au33 5 io_l06n_5/vrp_5 ap33 5 io_l06p_5/vrn_5 ar33 5 io_l05_5/no_pair an32 5 io_l03n_5/d4 aw34 5 io_l03p_5/d5 ay34 5 io_l02n_5/d6 av34 5 io_l02p_5/d7 au34 5 io_l01n_5/rdwr_b ar34 5 io_l01p_5/cs_b at34 6 io_l01p_6/vrn_6 aw37 6 io_l01n_6/vrp_6 av37 6 io_l02p_6 aw36 6 io_l02n_6 av36 6 io_l03p_6 ay37 6 io_l03n_6/vref_6 ay38 6 io_l04p_6 au36 6 io_l04n_6 at37 6 io_l05p_6 au35 6 io_l05n_6 at35 6 io_l06p_6 aw41 6 io_l06n_6 aw42 6 io_l73p_6 av41 6 io_l73n_6 av42 6 io_l74p_6 aw40 6 io_l74n_6 av40 6 io_l75p_6 au39 6 io_l75n_6/vref_6 au40 6 io_l76p_6 au41 ta bl e 1 3 : ff1704 ? xc2vp70, xc2vpx70, and xc2vp100 bank pin description pin number no connects virtex-ii pro devices xc2vpx70 (if different) xc2vp70, xc2vpx70 xc2vp100 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 225 product not recommended for new designs 6 io_l76n_6 au42 6 io_l77p_6 at39 6 io_l77n_6 at40 6 io_l78p_6 at41 6 io_l78n_6 at42 6 io_l79p_6 ar38 6 io_l79n_6 ar39 6 io_l80p_6 ar37 6 io_l80n_6 at38 6 io_l81p_6 ar40 6 io_l81n_6/vref_6 ar41 6 io_l82p_6 ap36 6 io_l82n_6 ap37 6 io_l83p_6 ap35 6 io_l83n_6 ar36 6 io_l84p_6 ap38 6 io_l84n_6 ap39 6 io_l07p_6 ap41 6 io_l07n_6 ap42 6 io_l08p_6 an35 6 io_l08n_6 an36 6 io_l09p_6 an37 6 io_l09n_6/vref_6 an38 6 io_l10p_6 an41 6 io_l10n_6 an42 6 io_l11p_6 am33 6 io_l11n_6 an34 6 io_l12p_6 am36 6 io_l12n_6 am37 6 io_l13p_6 am38 6 io_l13n_6 am39 6 io_l14p_6 am34 6 io_l14n_6 am35 6 io_l15p_6 an40 6 io_l15n_6/vref_6 am40 6 io_l16p_6 am41 ta bl e 1 3 : ff1704 ? xc2vp70, xc2vpx70, and xc2vp100 bank pin description pin number no connects virtex-ii pro devices xc2vpx70 (if different) xc2vp70, xc2vpx70 xc2vp100 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 226 product not recommended for new designs 6 io_l16n_6 am42 6 io_l17p_6 al33 6 io_l17n_6 al34 6 io_l18p_6 al35 6 io_l18n_6 al36 6 io_l19p_6 al38 6 io_l19n_6 al39 6 io_l20p_6 al31 6 io_l20n_6 al32 6 io_l21p_6 al40 6 io_l21n_6/vref_6 al41 6 io_l22p_6 ak35 6 io_l22n_6 ak36 6 io_l23p_6 ak33 6 io_l23n_6 ak34 6 io_l24p_6 ak37 6 io_l24n_6 ak38 6 io_l25p_6 ak39 6 io_l25n_6 ak40 6 io_l26p_6 ak31 6 io_l26n_6 ak32 6 io_l27p_6 ak41 6 io_l27n_6/vref_6 ak42 6 io_l28p_6 aj35 6 io_l28n_6 aj36 6 io_l29p_6 aj33 6 io_l29n_6 aj34 6 io_l30p_6 aj37 6 io_l30n_6 aj38 6 io_l31p_6 aj41 6 io_l31n_6 aj42 6 io_l32p_6 aj31 6 io_l32n_6 aj32 6 io_l33p_6 ah33 6 io_l33n_6/vref_6 ah34 6 io_l34p_6 ah37 ta bl e 1 3 : ff1704 ? xc2vp70, xc2vpx70, and xc2vp100 bank pin description pin number no connects virtex-ii pro devices xc2vpx70 (if different) xc2vp70, xc2vpx70 xc2vp100 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 227 product not recommended for new designs 6 io_l34n_6 ah38 6 io_l35p_6 ah31 6 io_l35n_6 ah32 6 io_l36p_6 aj40 6 io_l36n_6 ah40 6 io_l37p_6 ah41 6 io_l37n_6 ah42 6 io_l38p_6 ah35 6 io_l38n_6 ag35 6 io_l39p_6 ag36 6 io_l39n_6/vref_6 ag37 6 io_l40p_6 ag38 6 io_l40n_6 ag39 6 io_l41p_6 ag32 6 io_l41n_6 ag33 6 io_l42p_6 ag40 6 io_l42n_6 ag41 6 io_l43p_6 af33 6 io_l43n_6 af34 6 io_l44p_6 af35 6 io_l44n_6 af36 6 io_l45p_6 af37 6 io_l45n_6/vref_6 af38 6 io_l46p_6 af39 6 io_l46n_6 af40 6 io_l47p_6 af31 6 io_l47n_6 ag31 6 io_l48p_6 af41 6 io_l48n_6 af42 6 io_l49p_6 ae35 6 io_l49n_6 ae36 6 io_l50p_6 ae31 6 io_l50n_6 af32 6 io_l51p_6 ae38 6 io_l51n_6/vref_6 ae39 6 io_l52p_6 ae41 ta bl e 1 3 : ff1704 ? xc2vp70, xc2vpx70, and xc2vp100 bank pin description pin number no connects virtex-ii pro devices xc2vpx70 (if different) xc2vp70, xc2vpx70 xc2vp100 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 228 product not recommended for new designs 6 io_l52n_6 ae42 6 io_l53p_6 ae32 6 io_l53n_6 ae33 6 io_l54p_6 ad35 6 io_l54n_6 ad36 6 io_l55p_6 ad37 6 io_l55n_6 ad38 6 io_l56p_6 ad31 6 io_l56n_6 ad32 6 io_l57p_6 ad39 6 io_l57n_6/vref_6 ad40 6 io_l58p_6 ad41 6 io_l58n_6 ad42 6 io_l59p_6 ad33 6 io_l59n_6 ad34 6 io_l60p_6 ac33 6 io_l60n_6 ac34 6 io_l85p_6 ac36 6 io_l85n_6 ac37 6 io_l86p_6 ac31 6 io_l86n_6 ac32 6 io_l87p_6 ac39 6 io_l87n_6/vref_6 ac40 6 io_l88p_6 ab33 6 io_l88n_6 ab34 6 io_l89p_6 ab36 6 io_l89n_6 ab37 6 io_l90p_6 ab39 6 io_l90n_6 ab40 7 io_l90p_7 aa39 7 io_l90n_7 aa40 7 io_l89p_7 ab31 7 io_l89n_7 aa31 7 io_l88p_7 aa36 7 io_l88n_7/vref_7 aa37 ta bl e 1 3 : ff1704 ? xc2vp70, xc2vpx70, and xc2vp100 bank pin description pin number no connects virtex-ii pro devices xc2vpx70 (if different) xc2vp70, xc2vpx70 xc2vp100 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 229 product not recommended for new designs 7 io_l87p_7 aa33 7 io_l87n_7 aa34 7 io_l86p_7 y31 7 io_l86n_7 y32 7 io_l85p_7 y39 7 io_l85n_7 y40 7 io_l60p_7 y36 7 io_l60n_7 y37 7 io_l59p_7 y33 7 io_l59n_7 y34 7 io_l58p_7 w41 7 io_l58n_7/vref_7 w42 7 io_l57p_7 w39 7 io_l57n_7 w40 7 io_l56p_7 w31 7 io_l56n_7 w32 7 io_l55p_7 w37 7 io_l55n_7 w38 7 io_l54p_7 w35 7 io_l54n_7 w36 7 io_l53p_7 w33 7 io_l53n_7 w34 7 io_l52p_7 v41 7 io_l52n_7/vref_7 v42 7 io_l51p_7 v38 7 io_l51n_7 v39 7 io_l50p_7 v31 7 io_l50n_7 u32 7 io_l49p_7 v35 7 io_l49n_7 v36 7 io_l48p_7 v32 7 io_l48n_7 v33 7 io_l47p_7 u31 7 io_l47n_7 t31 7 io_l46p_7 u41 7 io_l46n_7/vref_7 u42 ta bl e 1 3 : ff1704 ? xc2vp70, xc2vpx70, and xc2vp100 bank pin description pin number no connects virtex-ii pro devices xc2vpx70 (if different) xc2vp70, xc2vpx70 xc2vp100 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 230 product not recommended for new designs 7 io_l45p_7 u39 7 io_l45n_7 u40 7 io_l44p_7 u33 7 io_l44n_7 u34 7 io_l43p_7 u37 7 io_l43n_7 u38 7 io_l42p_7 u35 7 io_l42n_7 u36 7 io_l41p_7 t32 7 io_l41n_7 t33 7 io_l40p_7 t40 7 io_l40n_7/vref_7 t41 7 io_l39p_7 t38 7 io_l39n_7 t39 7 io_l38p_7 r35 7 io_l38n_7 t35 7 io_l37p_7 t36 7 io_l37n_7 t37 7 io_l36p_7 r31 7 io_l36n_7 r32 7 io_l35p_7 r41 7 io_l35n_7 r42 7 io_l34p_7 r40 7 io_l34n_7/vref_7 p40 7 io_l33p_7 r37 7 io_l33n_7 r38 7 io_l32p_7 r33 7 io_l32n_7 r34 7 io_l31p_7 p41 7 io_l31n_7 p42 7 io_l30p_7 p37 7 io_l30n_7 p38 7 io_l29p_7 p31 7 io_l29n_7 p32 7 io_l28p_7 p35 7 io_l28n_7/vref_7 p36 ta bl e 1 3 : ff1704 ? xc2vp70, xc2vpx70, and xc2vp100 bank pin description pin number no connects virtex-ii pro devices xc2vpx70 (if different) xc2vp70, xc2vpx70 xc2vp100 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 231 product not recommended for new designs 7 io_l27p_7 p33 7 io_l27n_7 p34 7 io_l26p_7 n31 7 io_l26n_7 n32 7 io_l25p_7 n41 7 io_l25n_7 n42 7 io_l24p_7 n39 7 io_l24n_7 n40 7 io_l23p_7 n33 7 io_l23n_7 n34 7 io_l22p_7 n37 7 io_l22n_7/vref_7 n38 7 io_l21p_7 n35 7 io_l21n_7 n36 7 io_l20p_7 m38 7 io_l20n_7 m39 7 io_l19p_7 m40 7 io_l19n_7 m41 7 io_l18p_7 m33 7 io_l18n_7 m34 7 io_l17p_7 m31 7 io_l17n_7 m32 7 io_l16p_7 m35 7 io_l16n_7/vref_7 m36 7 io_l15p_7 l41 7 io_l15n_7 l42 7 io_l14p_7 l39 7 io_l14n_7 l38 7 io_l13p_7 l40 7 io_l13n_7 k40 7 io_l12p_7 l36 7 io_l12n_7 l37 7 io_l11p_7 l34 7 io_l11n_7 l35 7 io_l10p_7 k42 7 io_l10n_7/vref_7 k41 ta bl e 1 3 : ff1704 ? xc2vp70, xc2vpx70, and xc2vp100 bank pin description pin number no connects virtex-ii pro devices xc2vpx70 (if different) xc2vp70, xc2vpx70 xc2vp100 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 232 product not recommended for new designs 7 io_l09p_7 k36 7 io_l09n_7 k35 7 io_l08p_7 k38 7 io_l08n_7 k37 7 io_l07p_7 l33 7 io_l07n_7 k34 7 io_l84p_7 j41 7 io_l84n_7 j42 7 io_l83p_7 j39 7 io_l83n_7 j38 7 io_l82p_7 j36 7 io_l82n_7/vref_7 j37 7 io_l81p_7 j35 7 io_l81n_7 h36 7 io_l80p_7 h41 7 io_l80n_7 h40 7 io_l79p_7 h38 7 io_l79n_7 h39 7 io_l78p_7 h37 7 io_l78n_7 g38 7 io_l77p_7 g42 7 io_l77n_7 g41 7 io_l76p_7 g39 7 io_l76n_7/vref_7 g40 7 io_l75p_7 f41 7 io_l75n_7 f42 7 io_l74p_7 f40 7 io_l74n_7 f39 7 io_l73p_7 e41 7 io_l73n_7 e42 7 io_l06p_7 d41 7 io_l06n_7 d42 7 io_l05p_7 e40 7 io_l05n_7 d40 7 io_l04p_7 f36 7 io_l04n_7/vref_7 g37 ta bl e 1 3 : ff1704 ? xc2vp70, xc2vpx70, and xc2vp100 bank pin description pin number no connects virtex-ii pro devices xc2vpx70 (if different) xc2vp70, xc2vpx70 xc2vp100 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 233 product not recommended for new designs 7 io_l03p_7 d37 7 io_l03n_7 e37 7 io_l02p_7 d36 7 io_l02n_7 e36 7 io_l01p_7/vrn_7 c37 7 io_l01n_7/vrp_7 c38 0 vcco_0 d25 0 vcco_0 g23 0 vcco_0 g28 0 vcco_0 g32 0 vcco_0 j25 0 vcco_0 j29 0 vcco_0 p22 0 vcco_0 p23 0 vcco_0 p24 0 vcco_0 p25 0 vcco_0 p26 0 vcco_0 r22 0 vcco_0 r23 0 vcco_0 r24 0 vcco_0 r25 1 vcco_1 r21 1 vcco_1 r20 1 vcco_1 r19 1 vcco_1 r18 1 vcco_1 p21 1 vcco_1 p20 1 vcco_1 p19 1 vcco_1 p18 1 vcco_1 p17 1 vcco_1 j18 1 vcco_1 j14 1 vcco_1 g20 1 vcco_1 g15 1 vcco_1 g11 ta bl e 1 3 : ff1704 ? xc2vp70, xc2vpx70, and xc2vp100 bank pin description pin number no connects virtex-ii pro devices xc2vpx70 (if different) xc2vp70, xc2vpx70 xc2vp100 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 234 product not recommended for new designs 1 vcco_1 d18 2 vcco_2 aa15 2 vcco_2 aa14 2 vcco_2 y15 2 vcco_2 y14 2 vcco_2 y8 2 vcco_2 y5 2 vcco_2 w15 2 vcco_2 w14 2 vcco_2 v15 2 vcco_2 v14 2 vcco_2 v3 2 vcco_2 u15 2 vcco_2 u14 2 vcco_2 t15 2 vcco_2 t14 2 vcco_2 r14 2 vcco_2 t9 2 vcco_2 p4 2 vcco_2 m6 2 vcco_2 j3 2 vcco_2 f5 3 vcco_3 au5 3 vcco_3 ap3 3 vcco_3 al6 3 vcco_3 aj4 3 vcco_3 ah14 3 vcco_3 ag15 3 vcco_3 ag14 3 vcco_3 ag9 3 vcco_3 af15 3 vcco_3 af14 3 vcco_3 ae15 3 vcco_3 ae14 3 vcco_3 ae3 3 vcco_3 ad15 ta bl e 1 3 : ff1704 ? xc2vp70, xc2vpx70, and xc2vp100 bank pin description pin number no connects virtex-ii pro devices xc2vpx70 (if different) xc2vp70, xc2vpx70 xc2vp100 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 235 product not recommended for new designs 3 vcco_3 ad14 3 vcco_3 ac15 3 vcco_3 ac14 3 vcco_3 ac8 3 vcco_3 ac5 3 vcco_3 ab15 3 vcco_3 ab14 4 vcco_4 aw18 4 vcco_4 at20 4 vcco_4 at15 4 vcco_4 at11 4 vcco_4 ap18 4 vcco_4 ap14 4 vcco_4 aj21 4 vcco_4 aj20 4 vcco_4 aj19 4 vcco_4 aj18 4 vcco_4 aj17 4 vcco_4 ah21 4 vcco_4 ah20 4 vcco_4 ah19 4 vcco_4 ah18 5 vcco_5 aw25 5 vcco_5 at32 5 vcco_5 at28 5 vcco_5 at23 5 vcco_5 ap29 5 vcco_5 ap25 5 vcco_5 aj26 5 vcco_5 aj25 5 vcco_5 aj24 5 vcco_5 aj23 5 vcco_5 aj22 5 vcco_5 ah25 5 vcco_5 ah24 5 vcco_5 ah23 ta bl e 1 3 : ff1704 ? xc2vp70, xc2vpx70, and xc2vp100 bank pin description pin number no connects virtex-ii pro devices xc2vpx70 (if different) xc2vp70, xc2vpx70 xc2vp100 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 236 product not recommended for new designs 5 vcco_5 ah22 6 vcco_6 au38 6 vcco_6 ap40 6 vcco_6 al37 6 vcco_6 aj39 6 vcco_6 ah29 6 vcco_6 ag34 6 vcco_6 ag29 6 vcco_6 ag28 6 vcco_6 af29 6 vcco_6 af28 6 vcco_6 ae40 6 vcco_6 ae29 6 vcco_6 ae28 6 vcco_6 ad29 6 vcco_6 ad28 6 vcco_6 ac38 6 vcco_6 ac35 6 vcco_6 ac29 6 vcco_6 ac28 6 vcco_6 ab29 6 vcco_6 ab28 7 vcco_7 aa29 7 vcco_7 aa28 7 vcco_7 y38 7 vcco_7 y35 7 vcco_7 y29 7 vcco_7 y28 7 vcco_7 w29 7 vcco_7 w28 7 vcco_7 v40 7 vcco_7 v29 7 vcco_7 v28 7 vcco_7 u29 7 vcco_7 u28 7 vcco_7 t34 ta bl e 1 3 : ff1704 ? xc2vp70, xc2vpx70, and xc2vp100 bank pin description pin number no connects virtex-ii pro devices xc2vpx70 (if different) xc2vp70, xc2vpx70 xc2vp100 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 237 product not recommended for new designs 7 vcco_7 t29 7 vcco_7 t28 7 vcco_7 r29 7 vcco_7 p39 7 vcco_7 m37 7 vcco_7 j40 7 vcco_7 f38 n/a cclk ay7 n/a prog_b g35 n/a done aw8 n/a m0 av35 n/a m1 ay36 n/a m2 aw35 n/a tck g8 n/a tdi c36 n/a tdo c7 n/a tms f8 n/a pwrdwn_b av8 n/a hswap_en f35 n/a rsvd d8 n/a vbatt e8 n/a dxp e35 n/a dxn d35 n/a avccauxtx2 b40 n/a vttxpad2 b41 n/a txnpad2 a41 n/a txppad2 a40 n/a gnda2 c39 n/a rxppad2 a39 n/a rxnpad2 a38 n/a vtrxpad2 b39 n/a avccauxrx2 b38 n/a avccauxtx3 b36 n/a vttxpad3 b37 n/a txnpad3 a37 ta bl e 1 3 : ff1704 ? xc2vp70, xc2vpx70, and xc2vp100 bank pin description pin number no connects virtex-ii pro devices xc2vpx70 (if different) xc2vp70, xc2vpx70 xc2vp100 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 238 product not recommended for new designs n/a txppad3 a36 n/a gnda3 c35 n/a rxppad3 a35 n/a rxnpad3 a34 n/a vtrxpad3 b35 n/a avccauxrx3 b34 n/a avccauxtx4 b32 n/a vttxpad4 b33 n/a txnpad4 a33 n/a txppad4 a32 n/a gnda4 c31 n/a rxppad4 a31 n/a rxnpad4 a30 n/a vtrxpad4 b31 n/a avccauxrx4 b30 n/a avccauxtx5 b28 n/a vttxpad5 b29 n/a txnpad5 a29 n/a txppad5 a28 n/a gnda5 c27 n/a rxppad5 a27 n/a rxnpad5 a26 n/a vtrxpad5 b27 n/a avccauxrx5 b26 n/a avccauxtx6 b24 n/a vttxpad6 b25 n/a txnpad6 a25 n/a txppad6 a24 n/a gnda6 c22 n/a rxppad6 a23 n/a rxnpad6 a22 n/a vtrxpad6 b23 n/a avccauxrx6 b22 n/a avccauxtx7 b20 n/a vttxpad7 b21 n/a txnpad7 a21 ta bl e 1 3 : ff1704 ? xc2vp70, xc2vpx70, and xc2vp100 bank pin description pin number no connects virtex-ii pro devices xc2vpx70 (if different) xc2vp70, xc2vpx70 xc2vp100 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 239 product not recommended for new designs n/a txppad7 a20 n/a gnda7 c21 n/a rxppad7 a19 n/a rxnpad7 a18 n/a vtrxpad7 b19 n/a avccauxrx7 b18 n/a avccauxtx8 b16 n/a vttxpad8 b17 n/a txnpad8 a17 n/a txppad8 a16 n/a gnda8 c16 n/a rxppad8 a15 n/a rxnpad8 a14 n/a vtrxpad8 b15 n/a avccauxrx8 b14 n/a avccauxtx9 b12 n/a vttxpad9 b13 n/a txnpad9 a13 n/a txppad9 a12 n/a gnda9 c12 n/a rxppad9 a11 n/a rxnpad9 a10 n/a vtrxpad9 b11 n/a avccauxrx9 b10 n/a avccauxtx10 b8 n/a vttxpad10 b9 n/a txnpad10 a9 n/a txppad10 a8 n/a gnda10 c8 n/a rxppad10 a7 n/a rxnpad10 a6 n/a vtrxpad10 b7 n/a avccauxrx10 b6 n/a avccauxtx11 b4 n/a vttxpad11 b5 n/a txnpad11 a5 ta bl e 1 3 : ff1704 ? xc2vp70, xc2vpx70, and xc2vp100 bank pin description pin number no connects virtex-ii pro devices xc2vpx70 (if different) xc2vp70, xc2vpx70 xc2vp100 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 240 product not recommended for new designs n/a txppad11 a4 n/a gnda11 c4 n/a rxppad11 a3 n/a rxnpad11 a2 n/a vtrxpad11 b3 n/a avccauxrx11 b2 n/a avccauxrx14 ba2 n/a vtrxpad14 ba3 n/a rxnpad14 bb2 n/a rxppad14 bb3 n/a gnda14 ay4 n/a txppad14 bb4 n/a txnpad14 bb5 n/a vttxpad14 ba5 n/a avccauxtx14 ba4 n/a avccauxrx15 ba6 n/a vtrxpad15 ba7 n/a rxnpad15 bb6 n/a rxppad15 bb7 n/a gnda15 ay8 n/a txppad15 bb8 n/a txnpad15 bb9 n/a vttxpad15 ba9 n/a avccauxtx15 ba8 n/a avccauxrx16 ba10 n/a vtrxpad16 ba11 n/a rxnpad16 bb10 n/a rxppad16 bb11 n/a gnda16 ay12 n/a txppad16 bb12 n/a txnpad16 bb13 n/a vttxpad16 ba13 n/a avccauxtx16 ba12 n/a avccauxrx17 ba14 n/a vtrxpad17 ba15 n/a rxnpad17 bb14 ta bl e 1 3 : ff1704 ? xc2vp70, xc2vpx70, and xc2vp100 bank pin description pin number no connects virtex-ii pro devices xc2vpx70 (if different) xc2vp70, xc2vpx70 xc2vp100 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 241 product not recommended for new designs n/a rxppad17 bb15 n/a gnda17 ay16 n/a txppad17 bb16 n/a txnpad17 bb17 n/a vttxpad17 ba17 n/a avccauxtx17 ba16 n/a avccauxrx18 ba18 n/a vtrxpad18 ba19 n/a rxnpad18 bb18 n/a rxppad18 bb19 n/a gnda18 ay21 n/a txppad18 bb20 n/a txnpad18 bb21 n/a vttxpad18 ba21 n/a avccauxtx18 ba20 n/a avccauxrx19 ba22 n/a vtrxpad19 ba23 n/a rxnpad19 bb22 n/a rxppad19 bb23 n/a gnda19 ay22 n/a txppad19 bb24 n/a txnpad19 bb25 n/a vttxpad19 ba25 n/a avccauxtx19 ba24 n/a avccauxrx20 ba26 n/a vtrxpad20 ba27 n/a rxnpad20 bb26 n/a rxppad20 bb27 n/a gnda20 ay27 n/a txppad20 bb28 n/a txnpad20 bb29 n/a vttxpad20 ba29 n/a avccauxtx20 ba28 n/a avccauxrx21 ba30 n/a vtrxpad21 ba31 n/a rxnpad21 bb30 ta bl e 1 3 : ff1704 ? xc2vp70, xc2vpx70, and xc2vp100 bank pin description pin number no connects virtex-ii pro devices xc2vpx70 (if different) xc2vp70, xc2vpx70 xc2vp100 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 242 product not recommended for new designs n/a rxppad21 bb31 n/a gnda21 ay31 n/a txppad21 bb32 n/a txnpad21 bb33 n/a vttxpad21 ba33 n/a avccauxtx21 ba32 n/a avccauxrx22 ba34 n/a vtrxpad22 ba35 n/a rxnpad22 bb34 n/a rxppad22 bb35 n/a gnda22 ay35 n/a txppad22 bb36 n/a txnpad22 bb37 n/a vttxpad22 ba37 n/a avccauxtx22 ba36 n/a avccauxrx23 ba38 n/a vtrxpad23 ba39 n/a rxnpad23 bb38 n/a rxppad23 bb39 n/a gnda23 ay39 n/a txppad23 bb40 n/a txnpad23 bb41 n/a vttxpad23 ba41 n/a avccauxtx23 ba40 n/a vccint ab27 n/a vccint ab16 n/a vccint ac27 n/a vccint ac16 n/a vccint ad27 n/a vccint ad16 n/a vccint ae27 n/a vccint ae16 n/a vccint af27 n/a vccint af26 n/a vccint af17 ta bl e 1 3 : ff1704 ? xc2vp70, xc2vpx70, and xc2vp100 bank pin description pin number no connects virtex-ii pro devices xc2vpx70 (if different) xc2vp70, xc2vpx70 xc2vp100 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 243 product not recommended for new designs n/a vccint af16 n/a vccint ag27 n/a vccint ag26 n/a vccint ag25 n/a vccint ag24 n/a vccint ag23 n/a vccint ag22 n/a vccint ag21 n/a vccint ag20 n/a vccint ag19 n/a vccint ag18 n/a vccint ag17 n/a vccint ag16 n/a vccint ah28 n/a vccint ah27 n/a vccint ah26 n/a vccint ah17 n/a vccint ah16 n/a vccint ah15 n/a vccint aj29 n/a vccint aj28 n/a vccint aj27 n/a vccint aj16 n/a vccint aj15 n/a vccint aj14 n/a vccint ak30 n/a vccint ak13 n/a vccint aa27 n/a vccint aa16 n/a vccint y27 n/a vccint y16 n/a vccint w27 n/a vccint w16 n/a vccint v27 n/a vccint v16 n/a vccint u27 ta bl e 1 3 : ff1704 ? xc2vp70, xc2vpx70, and xc2vp100 bank pin description pin number no connects virtex-ii pro devices xc2vpx70 (if different) xc2vp70, xc2vpx70 xc2vp100 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 244 product not recommended for new designs n/a vccint u26 n/a vccint u17 n/a vccint u16 n/a vccint t27 n/a vccint t26 n/a vccint t25 n/a vccint t24 n/a vccint t23 n/a vccint t22 n/a vccint t21 n/a vccint t20 n/a vccint t19 n/a vccint t18 n/a vccint t17 n/a vccint t16 n/a vccint r28 n/a vccint r27 n/a vccint r26 n/a vccint r17 n/a vccint r16 n/a vccint r15 n/a vccint p29 n/a vccint p28 n/a vccint p27 n/a vccint p16 n/a vccint p15 n/a vccint p14 n/a vccint n30 n/a vccint n13 n/a vccaux ab42 n/a vccaux ab41 n/a vccaux ab2 n/a vccaux ab1 n/a vccaux ac42 n/a vccaux ac1 n/a vccaux am32 ta bl e 1 3 : ff1704 ? xc2vp70, xc2vpx70, and xc2vp100 bank pin description pin number no connects virtex-ii pro devices xc2vpx70 (if different) xc2vp70, xc2vpx70 xc2vp100 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 245 product not recommended for new designs n/a vccaux am11 n/a vccaux an33 n/a vccaux an10 n/a vccaux av39 n/a vccaux av4 n/a vccaux aw38 n/a vccaux aw22 n/a vccaux aw21 n/a vccaux aw5 n/a vccaux aa42 n/a vccaux aa41 n/a vccaux aa2 n/a vccaux aa1 n/a vccaux y42 n/a vccaux y1 n/a vccaux l32 n/a vccaux l11 n/a vccaux k33 n/a vccaux k10 n/a vccaux e39 n/a vccaux e4 n/a vccaux d38 n/a vccaux d22 n/a vccaux d21 n/a vccaux d5 n/a gnd ab38 n/a gnd ab35 n/a gnd ab32 n/a gnd ab26 n/a gnd ab25 n/a gnd ab24 n/a gnd ab23 n/a gnd ab22 n/a gnd ab21 n/a gnd ab20 n/a gnd ab19 ta bl e 1 3 : ff1704 ? xc2vp70, xc2vpx70, and xc2vp100 bank pin description pin number no connects virtex-ii pro devices xc2vpx70 (if different) xc2vp70, xc2vpx70 xc2vp100 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 246 product not recommended for new designs n/a gnd ab18 n/a gnd ab17 n/a gnd ab11 n/a gnd ab8 n/a gnd ab5 n/a gnd ac41 n/a gnd ac26 n/a gnd ac25 n/a gnd ac24 n/a gnd ac23 n/a gnd ac22 n/a gnd ac21 n/a gnd ac20 n/a gnd ac19 n/a gnd ac18 n/a gnd ac17 n/a gnd ac2 n/a gnd ad26 n/a gnd ad25 n/a gnd ad24 n/a gnd ad23 n/a gnd ad22 n/a gnd ad21 n/a gnd ad20 n/a gnd ad19 n/a gnd ad18 n/a gnd ad17 n/a gnd ae37 n/a gnd ae34 n/a gnd ae26 n/a gnd ae25 n/a gnd ae24 n/a gnd ae23 n/a gnd ae22 n/a gnd ae21 n/a gnd ae20 ta bl e 1 3 : ff1704 ? xc2vp70, xc2vpx70, and xc2vp100 bank pin description pin number no connects virtex-ii pro devices xc2vpx70 (if different) xc2vp70, xc2vpx70 xc2vp100 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 247 product not recommended for new designs n/a gnd ae19 n/a gnd ae18 n/a gnd ae17 n/a gnd ae9 n/a gnd ae6 n/a gnd af25 n/a gnd af24 n/a gnd af23 n/a gnd af22 n/a gnd af21 n/a gnd af20 n/a gnd af19 n/a gnd af18 n/a gnd ag42 n/a gnd ag1 n/a gnd ah39 n/a gnd ah36 n/a gnd ah7 n/a gnd ah4 n/a gnd al42 n/a gnd al1 n/a gnd am22 n/a gnd am21 n/a gnd an39 n/a gnd an4 n/a gnd ap34 n/a gnd ap9 n/a gnd ar42 n/a gnd ar35 n/a gnd ar22 n/a gnd ar21 n/a gnd ar8 n/a gnd ar1 n/a gnd at36 n/a gnd at7 n/a gnd au37 ta bl e 1 3 : ff1704 ? xc2vp70, xc2vpx70, and xc2vp100 bank pin description pin number no connects virtex-ii pro devices xc2vpx70 (if different) xc2vp70, xc2vpx70 xc2vp100 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 248 product not recommended for new designs n/a gnd au25 n/a gnd au18 n/a gnd au6 n/a gnd av38 n/a gnd av22 n/a gnd av21 n/a gnd av5 n/a gnd aw39 n/a gnd aw32 n/a gnd aw28 n/a gnd aw15 n/a gnd aw11 n/a gnd aw4 n/a gnd ay42 n/a gnd ay41 n/a gnd ay40 n/a gnd ay3 n/a gnd ay2 n/a gnd ay1 n/a gnd ba42 n/a gnd ba1 n/a gnd aa38 n/a gnd aa35 n/a gnd aa32 n/a gnd aa26 n/a gnd aa25 n/a gnd aa24 n/a gnd aa23 n/a gnd aa22 n/a gnd aa21 n/a gnd aa20 n/a gnd aa19 n/a gnd aa18 n/a gnd aa17 n/a gnd aa11 n/a gnd aa8 ta bl e 1 3 : ff1704 ? xc2vp70, xc2vpx70, and xc2vp100 bank pin description pin number no connects virtex-ii pro devices xc2vpx70 (if different) xc2vp70, xc2vpx70 xc2vp100 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 249 product not recommended for new designs n/a gnd aa5 n/a gnd y41 n/a gnd y26 n/a gnd y25 n/a gnd y24 n/a gnd y23 n/a gnd y22 n/a gnd y21 n/a gnd y20 n/a gnd y19 n/a gnd y18 n/a gnd y17 n/a gnd y2 n/a gnd w26 n/a gnd w25 n/a gnd w24 n/a gnd w23 n/a gnd w22 n/a gnd w21 n/a gnd w20 n/a gnd w19 n/a gnd w18 n/a gnd w17 n/a gnd v37 n/a gnd v34 n/a gnd v26 n/a gnd v25 n/a gnd v24 n/a gnd v23 n/a gnd v22 n/a gnd v21 n/a gnd v20 n/a gnd v19 n/a gnd v18 n/a gnd v17 n/a gnd v9 ta bl e 1 3 : ff1704 ? xc2vp70, xc2vpx70, and xc2vp100 bank pin description pin number no connects virtex-ii pro devices xc2vpx70 (if different) xc2vp70, xc2vpx70 xc2vp100 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 250 product not recommended for new designs n/a gnd v6 n/a gnd u25 n/a gnd u24 n/a gnd u23 n/a gnd u22 n/a gnd u21 n/a gnd u20 n/a gnd u19 n/a gnd u18 n/a gnd t42 n/a gnd t1 n/a gnd r39 n/a gnd r36 n/a gnd r7 n/a gnd r4 n/a gnd m42 n/a gnd m1 n/a gnd l22 n/a gnd l21 n/a gnd k39 n/a gnd k4 n/a gnd j34 n/a gnd j9 n/a gnd h42 n/a gnd h35 n/a gnd h22 n/a gnd h21 n/a gnd h8 n/a gnd h1 n/a gnd g36 n/a gnd g7 n/a gnd f37 n/a gnd f25 n/a gnd f18 n/a gnd f6 n/a gnd e38 ta bl e 1 3 : ff1704 ? xc2vp70, xc2vpx70, and xc2vp100 bank pin description pin number no connects virtex-ii pro devices xc2vpx70 (if different) xc2vp70, xc2vpx70 xc2vp100 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 251 product not recommended for new designs n/a gnd e22 n/a gnd e21 n/a gnd e5 n/a gnd d39 n/a gnd d32 n/a gnd d28 n/a gnd d15 n/a gnd d11 n/a gnd d4 n/a gnd c42 n/a gnd c41 n/a gnd c40 n/a gnd c3 n/a gnd c2 n/a gnd c1 n/a gnd b42 n/a gnd b1 n/a gnd n14 n/a gnd n29 n/a gnd ak14 n/a gnd ak29 n/a gnd p13 n/a gnd p30 n/a gnd aj13 n/a gnd aj30 notes: 1. see ta b l e 4 for an explanation of the signals available on this pin. ta bl e 1 3 : ff1704 ? xc2vp70, xc2vpx70, and xc2vp100 bank pin description pin number no connects virtex-ii pro devices xc2vpx70 (if different) xc2vp70, xc2vpx70 xc2vp100 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 252 product not recommended for new designs ff1704 flip-chip fine-pitc h bga package specificat ions (1.00mm pitch) figure 9: ff1704 flip-chip fine-pitch bga package specifications virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 253 product not recommended for new designs ff1696 flip-chip fine-pitch bga package as shown in ta bl e 1 4 , xc2vp100 virtex-ii pro devices are available in the ff1696 flip-chip fine-pitch bga package. following this table are the ff1696 flip-chip fine-pitch bga pack age specifications (1.00mm pitch) . ta bl e 1 4 : ff1696 ? xc2vp100 bank pin description pin number no connects xc2vp100 0 io_l01n_0/vrp_0 e33 0 io_l01p_0/vrn_0 f33 0 io_l02n_0 k32 0 io_l02p_0 l32 0 io_l03n_0 c32 0 io_l03p_0/vref_0 c33 0 io_l05_0/no_pair g33 0 io_l06n_0 a33 0 io_l06p_0 b33 0 io_l07n_0 f32 0 io_l07p_0 g32 0 io_l08n_0 h32 0 io_l08p_0 j32 0 io_l09n_0 d32 0 io_l09p_0/vref_0 e32 0 io_l19n_0 a32 0 io_l19p_0 b32 0 io_l20n_0 k31 0 io_l20p_0 l31 0 io_l21n_0 h30 0 io_l21p_0 g31 0 io_l25n_0 e31 0 io_l25p_0 f31 0 io_l26n_0 h31 0 io_l26p_0 j31 0 io_l27n_0 d30 0 io_l27p_0/vref_0 d31 0 io_l28n_0 b31 0 io_l28p_0 c31 0 io_l29n_0 k30 0 io_l29p_0 l30 0 io_l30n_0 f30 0 io_l30p_0 g30 0 io_l34n_0 b30 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 254 product not recommended for new designs 0 io_l34p_0 c30 0 io_l35n_0 l29 0 io_l35p_0 m29 0 io_l36n_0 h28 0 io_l36p_0/vref_0 g29 0 io_l76n_0 e29 0 io_l76p_0 f29 0 io_l77n_0 j29 0 io_l77p_0 k29 0 io_l78n_0 d28 0 io_l78p_0 c29 0 io_l79n_0 a29 0 io_l79p_0 b29 0 io_l80_0/no_pair l28 0 io_l83_0/no_pair m28 0 io_l84n_0 g27 0 io_l84p_0 g28 0 io_l85n_0 e28 0 io_l85p_0 f28 0 io_l86n_0 j28 0 io_l86p_0 k28 0 io_l87n_0 c27 0 io_l87p_0/vref_0 c28 0 io_l37n_0 a28 0 io_l37p_0 b28 0 io_l38n_0 l27 0 io_l38p_0 m27 0 io_l39n_0 h26 0 io_l39p_0 h27 0 io_l43n_0 e27 0 io_l43p_0 f27 0 io_l44n_0 j27 0 io_l44p_0 k27 0 io_l45n_0 d26 0 io_l45p_0/vref_0 d27 0 io_l10n_0 a27 nc 0 io_l10p_0 b27 nc ta bl e 1 4 : ff1696 ? xc2vp100 bank pin description pin number no connects xc2vp100 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 255 product not recommended for new designs 0 io_l11n_0 m25 nc 0 io_l11p_0 m26 nc 0 io_l12n_0 f26 nc 0 io_l12p_0 g26 nc 0 io_l18n_0 b26 nc 0 io_l18p_0/vref_0 c26 nc 0 io_l46n_0 g24 0 io_l46p_0 g25 0 io_l47n_0 k26 0 io_l47p_0 l26 0 io_l48n_0 e25 0 io_l48p_0 f25 0 io_l49n_0 c24 0 io_l49p_0 c25 0 io_l50_0/no_pair l24 0 io_l53_0/no_pair l25 0 io_l54n_0 a25 0 io_l54p_0 b25 0 io_l55n_0 h23 0 io_l55p_0 h24 0 io_l56n_0 j25 0 io_l56p_0 k25 0 io_l57n_0 e24 0 io_l57p_0/vref_0 f24 0 io_l58n_0 d23 0 io_l58p_0 d24 0 io_l59n_0 j24 0 io_l59p_0 k24 0 io_l60n_0 a24 0 io_l60p_0 b24 0 io_l64n_0 f23 0 io_l64p_0 g23 0 io_l65n_0 m22 0 io_l65p_0 m23 0 io_l66n_0 b23 0 io_l66p_0/vref_0 c23 0 io_l67n_0 h22 ta bl e 1 4 : ff1696 ? xc2vp100 bank pin description pin number no connects xc2vp100 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 256 product not recommended for new designs 0 io_l67p_0 j22 0 io_l68n_0 k23 0 io_l68p_0 l23 0 io_l69n_0 f22 0 io_l69p_0/vref_0 g22 0 io_l73n_0 d22 0 io_l73p_0 e22 0 io_l74n_0/gclk7p k22 0 io_l74p_0/gclk6s l22 0 io_l75n_0/gclk5p b22 0 io_l75p_0/gclk4s c22 1 io_l75n_1/gclk3p c21 1 io_l75p_1/gclk2s b21 1 io_l74n_1/gclk1p l21 1 io_l74p_1/gclk0s k21 1 io_l73n_1 e21 1 io_l73p_1 d21 1 io_l69n_1/vref_1 g21 1 io_l69p_1 f21 1 io_l68n_1 l20 1 io_l68p_1 k20 1 io_l67n_1 j21 1 io_l67p_1 h21 1 io_l66n_1/vref_1 c20 1 io_l66p_1 b20 1 io_l65n_1 m20 1 io_l65p_1 m21 1 io_l64n_1 g20 1 io_l64p_1 f20 1 io_l60n_1 b19 1 io_l60p_1 a19 1 io_l59n_1 k19 1 io_l59p_1 j19 1 io_l58n_1 d19 1 io_l58p_1 d20 1 io_l57n_1/vref_1 f19 ta bl e 1 4 : ff1696 ? xc2vp100 bank pin description pin number no connects xc2vp100 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 257 product not recommended for new designs 1 io_l57p_1 e19 1 io_l56n_1 k18 1 io_l56p_1 j18 1 io_l55n_1 h19 1 io_l55p_1 h20 1 io_l54n_1 b18 1 io_l54p_1 a18 1 io_l53_1/no_pair l18 1 io_l50_1/no_pair l19 1 io_l49n_1 c18 1 io_l49p_1 c19 1 io_l48n_1 f18 1 io_l48p_1 e18 1 io_l47n_1 l17 1 io_l47p_1 k17 1 io_l46n_1 g18 1 io_l46p_1 g19 1 io_l18n_1/vref_1 c17 nc 1 io_l18p_1 b17 nc 1 io_l12n_1 g17 nc 1 io_l12p_1 f17 nc 1 io_l11n_1 m17 nc 1 io_l11p_1 m18 nc 1 io_l10n_1 b16 nc 1 io_l10p_1 a16 nc 1 io_l45n_1/vref_1 d16 1 io_l45p_1 d17 1 io_l44n_1 k16 1 io_l44p_1 j16 1 io_l43n_1 f16 1 io_l43p_1 e16 1 io_l39n_1 h16 1 io_l39p_1 h17 1 io_l38n_1 m16 1 io_l38p_1 l16 1 io_l37n_1 b15 1 io_l37p_1 a15 ta bl e 1 4 : ff1696 ? xc2vp100 bank pin description pin number no connects xc2vp100 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 258 product not recommended for new designs 1 io_l87n_1/vref_1 c15 1 io_l87p_1 c16 1 io_l86n_1 k15 1 io_l86p_1 j15 1 io_l85n_1 f15 1 io_l85p_1 e15 1 io_l84n_1 g15 1 io_l84p_1 g16 1 io_l83_1/no_pair m15 1 io_l80_1/no_pair l15 1 io_l79n_1 b14 1 io_l79p_1 a14 1 io_l78n_1 c14 1 io_l78p_1 d15 1 io_l77n_1 k14 1 io_l77p_1 j14 1 io_l76n_1 f14 1 io_l76p_1 e14 1 io_l36n_1/vref_1 g14 1 io_l36p_1 h15 1 io_l35n_1 m14 1 io_l35p_1 l14 1 io_l34n_1 c13 1 io_l34p_1 b13 1 io_l30n_1 g13 1 io_l30p_1 f13 1 io_l29n_1 l13 1 io_l29p_1 k13 1 io_l28n_1 c12 1 io_l28p_1 b12 1 io_l27n_1/vref_1 d12 1 io_l27p_1 d13 1 io_l26n_1 j12 1 io_l26p_1 h12 1 io_l25n_1 f12 1 io_l25p_1 e12 1 io_l21n_1 g12 ta bl e 1 4 : ff1696 ? xc2vp100 bank pin description pin number no connects xc2vp100 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 259 product not recommended for new designs 1 io_l21p_1 h13 1 io_l20n_1 l12 1 io_l20p_1 k12 1 io_l19n_1 b11 1 io_l19p_1 a11 1 io_l09n_1/vref_1 e11 1 io_l09p_1 d11 1 io_l08n_1 j11 1 io_l08p_1 h11 1 io_l07n_1 g11 1 io_l07p_1 f11 1 io_l06n_1 b10 1 io_l06p_1 a10 1 io_l05_1/no_pair g10 1 io_l03n_1/vref_1 c10 1 io_l03p_1 c11 1 io_l02n_1 l11 1 io_l02p_1 k11 1 io_l01n_1/vrp_1 f10 1 io_l01p_1/vrn_1 e10 2 io_l01n_2/vrp_2 b8 2 io_l01p_2/vrn_2 a8 2 io_l02n_2 c9 2 io_l02p_2 b9 2 io_l03n_2 b7 2 io_l03p_2 a7 2 io_l04n_2/vref_2 b6 2 io_l04p_2 a6 2 io_l05n_2 d8 2 io_l05p_2 d9 2 io_l06n_2 b4 2 io_l06p_2 a4 2 io_l73n_2 c7 2 io_l73p_2 c8 2 io_l74n_2 g9 2 io_l74p_2 f9 ta bl e 1 4 : ff1696 ? xc2vp100 bank pin description pin number no connects xc2vp100 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 260 product not recommended for new designs 2 io_l75n_2 c5 2 io_l75p_2 b5 2 io_l76n_2/vref_2 d7 2 io_l76p_2 c6 2 io_l77n_2 h8 2 io_l77p_2 h9 2 io_l78n_2 c3 2 io_l78p_2 c4 2 io_l79n_2 d1 2 io_l79p_2 d2 2 io_l80n_2 j8 2 io_l80p_2 k9 2 io_l81n_2 e6 2 io_l81p_2 d5 2 io_l82n_2/vref_2 e4 2 io_l82p_2 d4 2 io_l83n_2 l8 2 io_l83p_2 l9 2 io_l84n_2 e3 2 io_l84p_2 d3 2 io_l61n_2 f8 2 io_l61p_2 e8 2 io_l62n_2 m8 2 io_l62p_2 m9 2 io_l63n_2 f7 2 io_l63p_2 e7 2 io_l64n_2/vref_2 f3 2 io_l64p_2 e2 2 io_l65n_2 n12 2 io_l65p_2 p12 2 io_l66n_2 f1 2 io_l66p_2 f2 2 io_l67n_2 g7 2 io_l67p_2 g8 2 io_l68n_2 n10 2 io_l68p_2 n11 2 io_l69n_2 g6 ta bl e 1 4 : ff1696 ? xc2vp100 bank pin description pin number no connects xc2vp100 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 261 product not recommended for new designs 2 io_l69p_2 f6 2 io_l70n_2/vref_2 g5 2 io_l70p_2 f5 2 io_l71n_2 p10 2 io_l71p_2 p11 2 io_l72n_2 g3 2 io_l72p_2 g4 2 io_l07n_2 g1 2 io_l07p_2 g2 2 io_l08n_2 n8 2 io_l08p_2 p9 2 io_l09n_2 h6 2 io_l09p_2 h7 2 io_l10n_2/vref_2 h4 2 io_l10p_2 h5 2 io_l11n_2 r12 2 io_l11p_2 t12 2 io_l12n_2 h2 2 io_l12p_2 h3 2 io_l13n_2 j6 2 io_l13p_2 j7 2 io_l14n_2 r10 2 io_l14p_2 r11 2 io_l15n_2 j3 2 io_l15p_2 j4 2 io_l16n_2/vref_2 j2 2 io_l16p_2 h1 2 io_l17n_2 r8 2 io_l17p_2 r9 2 io_l18n_2 k5 2 io_l18p_2 k6 2 io_l19n_2 k1 2 io_l19p_2 k2 2 io_l20n_2 t10 2 io_l20p_2 t11 2 io_l21n_2 l7 2 io_l21p_2 k7 ta bl e 1 4 : ff1696 ? xc2vp100 bank pin description pin number no connects xc2vp100 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 262 product not recommended for new designs 2 io_l22n_2/vref_2 l4 2 io_l22p_2 l5 2 io_l23n_2 t8 2 io_l23p_2 t9 2 io_l24n_2 l3 2 io_l24p_2 k3 2 io_l25n_2 l1 2 io_l25p_2 l2 2 io_l26n_2 u12 2 io_l26p_2 v12 2 io_l27n_2 m7 2 io_l27p_2 l6 2 io_l28n_2/vref_2 m5 2 io_l28p_2 m6 2 io_l29n_2 u10 2 io_l29p_2 u11 2 io_l30n_2 m3 2 io_l30p_2 m4 2 io_l31n_2 n6 2 io_l31p_2 n7 2 io_l32n_2 u7 2 io_l32p_2 u8 2 io_l33n_2 n3 2 io_l33p_2 n4 2 io_l34n_2/vref_2 n2 2 io_l34p_2 m2 2 io_l35n_2 v10 2 io_l35p_2 v11 2 io_l36n_2 p6 2 io_l36p_2 p7 2 io_l37n_2 p1 2 io_l37p_2 p2 2 io_l38n_2 v8 2 io_l38p_2 v9 2 io_l39n_2 r6 2 io_l39p_2 p5 2 io_l40n_2/vref_2 r4 ta bl e 1 4 : ff1696 ? xc2vp100 bank pin description pin number no connects xc2vp100 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 263 product not recommended for new designs 2 io_l40p_2 r5 2 io_l41n_2 v6 2 io_l41p_2 v7 2 io_l42n_2 r3 2 io_l42p_2 p3 2 io_l43n_2 r1 2 io_l43p_2 r2 2 io_l44n_2 w10 2 io_l44p_2 w11 2 io_l45n_2 t7 2 io_l45p_2 r7 2 io_l46n_2/vref_2 t4 2 io_l46p_2 t5 2 io_l47n_2 w9 2 io_l47p_2 y10 2 io_l48n_2 t1 2 io_l48p_2 t2 2 io_l49n_2 u6 2 io_l49p_2 t6 2 io_l50n_2 w7 2 io_l50p_2 y8 2 io_l51n_2 u4 2 io_l51p_2 t3 2 io_l52n_2/vref_2 u2 2 io_l52p_2 u3 2 io_l53n_2 y11 2 io_l53p_2 y12 2 io_l54n_2 v4 2 io_l54p_2 v5 2 io_l55n_2 v1 2 io_l55p_2 v2 2 io_l56n_2 y6 2 io_l56p_2 y7 2 io_l57n_2 w5 2 io_l57p_2 w6 2 io_l58n_2/vref_2 w3 2 io_l58p_2 v3 ta bl e 1 4 : ff1696 ? xc2vp100 bank pin description pin number no connects xc2vp100 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 264 product not recommended for new designs 2 io_l59n_2 aa11 2 io_l59p_2 aa12 2 io_l60n_2 w1 2 io_l60p_2 w2 2 io_l85n_2 y2 2 io_l85p_2 y3 2 io_l86n_2 aa9 2 io_l86p_2 aa10 2 io_l87n_2 aa5 2 io_l87p_2 aa6 2 io_l88n_2/vref_2 aa4 2 io_l88p_2 y4 2 io_l89n_2 aa7 2 io_l89p_2 aa8 2 io_l90n_2 aa2 2 io_l90p_2 aa3 3 io_l90n_3 ab5 3 io_l90p_3 ab6 3 io_l89n_3 ab11 3 io_l89p_3 ab12 3 io_l88n_3 ab2 3 io_l88p_3 ab3 3 io_l87n_3/vref_3 ab4 3 io_l87p_3 ac4 3 io_l86n_3 ab9 3 io_l86p_3 ab10 3 io_l85n_3 ac2 3 io_l85p_3 ac3 3 io_l60n_3 ad5 3 io_l60p_3 ad6 3 io_l59n_3 ab7 3 io_l59p_3 ab8 3 io_l58n_3 ad1 3 io_l58p_3 ad2 3 io_l57n_3/vref_3 ae4 3 io_l57p_3 ae5 ta bl e 1 4 : ff1696 ? xc2vp100 bank pin description pin number no connects xc2vp100 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 265 product not recommended for new designs 3 io_l56n_3 ac11 3 io_l56p_3 ac12 3 io_l55n_3 ad3 3 io_l55p_3 ae3 3 io_l54n_3 ae1 3 io_l54p_3 ae2 3 io_l53n_3 ac6 3 io_l53p_3 ac7 3 io_l52n_3 af2 3 io_l52p_3 af3 3 io_l51n_3/vref_3 af6 3 io_l51p_3 ag6 3 io_l50n_3 ad10 3 io_l50p_3 ad11 3 io_l49n_3 ag4 3 io_l49p_3 ag5 3 io_l48n_3 af4 3 io_l48p_3 ag3 3 io_l47n_3 ac10 3 io_l47p_3 ad9 3 io_l46n_3 ag1 3 io_l46p_3 ag2 3 io_l45n_3/vref_3 ag7 3 io_l45p_3 ah7 3 io_l44n_3 ac8 3 io_l44p_3 ad7 3 io_l43n_3 ah4 3 io_l43p_3 ah5 3 io_l42n_3 ah1 3 io_l42p_3 ah2 3 io_l41n_3 ae10 3 io_l41p_3 ae11 3 io_l40n_3 aj6 3 io_l40p_3 aj7 3 io_l39n_3/vref_3 ah6 3 io_l39p_3 aj5 3 io_l38n_3 ae8 ta bl e 1 4 : ff1696 ? xc2vp100 bank pin description pin number no connects xc2vp100 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 266 product not recommended for new designs 3 io_l38p_3 ae9 3 io_l37n_3 ah3 3 io_l37p_3 aj3 3 io_l36n_3 aj1 3 io_l36p_3 aj2 3 io_l35n_3 ae6 3 io_l35p_3 ae7 3 io_l34n_3 ak6 3 io_l34p_3 ak7 3 io_l33n_3/vref_3 ak3 3 io_l33p_3 ak4 3 io_l32n_3 ae12 3 io_l32p_3 af12 3 io_l31n_3 al5 3 io_l31p_3 al6 3 io_l30n_3 al3 3 io_l30p_3 al4 3 io_l29n_3 af10 3 io_l29p_3 af11 3 io_l28n_3 ak2 3 io_l28p_3 al2 3 io_l27n_3/vref_3 al7 3 io_l27p_3 am6 3 io_l26n_3 af7 3 io_l26p_3 af8 3 io_l25n_3 am4 3 io_l25p_3 am5 3 io_l24n_3 am1 3 io_l24p_3 am2 3 io_l23n_3 ag10 3 io_l23p_3 ag11 3 io_l22n_3 am7 3 io_l22p_3 an7 3 io_l21n_3/vref_3 an5 3 io_l21p_3 an6 3 io_l20n_3 ag8 3 io_l20p_3 ag9 ta bl e 1 4 : ff1696 ? xc2vp100 bank pin description pin number no connects xc2vp100 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 267 product not recommended for new designs 3 io_l19n_3 am3 3 io_l19p_3 an3 3 io_l18n_3 an1 3 io_l18p_3 an2 3 io_l17n_3 ag12 3 io_l17p_3 ah12 3 io_l16n_3 ap6 3 io_l16p_3 ap7 3 io_l15n_3/vref_3 ap3 3 io_l15p_3 ap4 3 io_l14n_3 ah10 3 io_l14p_3 ah11 3 io_l13n_3 ar6 3 io_l13p_3 ar7 3 io_l12n_3 ar4 3 io_l12p_3 ar5 3 io_l11n_3 ah8 3 io_l11p_3 ah9 3 io_l10n_3 ar2 3 io_l10p_3 ar3 3 io_l09n_3/vref_3 ap2 3 io_l09p_3 ar1 3 io_l08n_3 aj10 3 io_l08p_3 aj11 3 io_l07n_3 at7 3 io_l07p_3 at8 3 io_l72n_3 at3 3 io_l72p_3 at4 3 io_l71n_3 aj12 3 io_l71p_3 ak12 3 io_l70n_3 at1 3 io_l70p_3 at2 3 io_l69n_3/vref_3 at6 3 io_l69p_3 au6 3 io_l68n_3 ak10 3 io_l68p_3 ak11 3 io_l67n_3 at5 ta bl e 1 4 : ff1696 ? xc2vp100 bank pin description pin number no connects xc2vp100 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 268 product not recommended for new designs 3 io_l67p_3 au5 3 io_l66n_3 au1 3 io_l66p_3 au2 3 io_l65n_3 aj9 3 io_l65p_3 ak8 3 io_l64n_3 au8 3 io_l64p_3 av8 3 io_l63n_3/vref_3 au7 3 io_l63p_3 av7 3 io_l62n_3 al8 3 io_l62p_3 al9 3 io_l61n_3 au3 3 io_l61p_3 av2 3 io_l84n_3 av6 3 io_l84p_3 aw5 3 io_l83n_3 am8 3 io_l83p_3 am9 3 io_l82n_3 av4 3 io_l82p_3 aw4 3 io_l81n_3/vref_3 av3 3 io_l81p_3 aw3 3 io_l80n_3 an9 3 io_l80p_3 ap8 3 io_l79n_3 aw1 3 io_l79p_3 aw2 3 io_l78n_3 ay7 3 io_l78p_3 ay8 3 io_l77n_3 ar8 3 io_l77p_3 ar9 3 io_l76n_3 aw7 3 io_l76p_3 ay6 3 io_l75n_3/vref_3 ay3 3 io_l75p_3 ay4 3 io_l74n_3 at9 3 io_l74p_3 au9 3 io_l73n_3 ay5 3 io_l73p_3 ba5 ta bl e 1 4 : ff1696 ? xc2vp100 bank pin description pin number no connects xc2vp100 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 269 product not recommended for new designs 3 io_l06n_3 ba8 3 io_l06p_3 bb8 3 io_l05n_3 aw8 3 io_l05p_3 aw9 3 io_l04n_3 ba7 3 io_l04p_3 bb7 3 io_l03n_3/vref_3 ba6 3 io_l03p_3 bb6 3 io_l02n_3 ay9 3 io_l02p_3 ba9 3 io_l01n_3/vrp_3 ba4 3 io_l01p_3/vrn_3 bb4 4 io_l01n_4/busy/dout (1) al11 4 io_l01p_4/init_b al12 4 io_l02n_4/d0/din (1) av10 4 io_l02p_4/d1 au10 4 io_l03n_4/d2 an11 4 io_l03p_4/d3 am11 4 io_l05_4/no_pair at10 4 io_l06n_4/vrp_4 ay11 4 io_l06p_4/vrn_4 ay10 4 io_l07n_4 bb10 4 io_l07p_4/vref_4 ba10 4 io_l08n_4 au11 4 io_l08p_4 at11 4 io_l09n_4 ar11 4 io_l09p_4/vref_4 ap11 4 io_l19n_4 aw11 4 io_l19p_4 av11 4 io_l20n_4 bb11 4 io_l20p_4 ba11 4 io_l21n_4 an12 4 io_l21p_4 am12 4 io_l25n_4 ar13 4 io_l25p_4 at12 4 io_l26n_4 av12 ta bl e 1 4 : ff1696 ? xc2vp100 bank pin description pin number no connects xc2vp100 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 270 product not recommended for new designs 4 io_l26p_4 au12 4 io_l27n_4 ar12 4 io_l27p_4/vref_4 ap12 4 io_l28n_4 aw13 4 io_l28p_4 aw12 4 io_l29n_4 ba12 4 io_l29p_4 ay12 4 io_l30n_4 an13 4 io_l30p_4 am13 4 io_l34n_4 au13 4 io_l34p_4 at13 4 io_l35n_4 ba13 4 io_l35p_4 ay13 4 io_l36n_4 am14 4 io_l36p_4/vref_4 al14 4 io_l76n_4 ar15 4 io_l76p_4 at14 4 io_l77n_4 av14 4 io_l77p_4 au14 4 io_l78n_4 ap14 4 io_l78p_4 an14 4 io_l79n_4 aw15 4 io_l79p_4 ay14 4 io_l80_4/no_pair bb14 4 io_l83_4/no_pair ba14 4 io_l84n_4 am15 4 io_l84p_4 al15 4 io_l85n_4 at16 4 io_l85p_4 at15 4 io_l86n_4 av15 4 io_l86p_4 au15 4 io_l87n_4 ap15 4 io_l87p_4/vref_4 an15 4 io_l37n_4 ay16 4 io_l37p_4 ay15 4 io_l38n_4 bb15 4 io_l38p_4 ba15 ta bl e 1 4 : ff1696 ? xc2vp100 bank pin description pin number no connects xc2vp100 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 271 product not recommended for new designs 4 io_l39n_4 am16 4 io_l39p_4 al16 4 io_l43n_4 ar17 4 io_l43p_4 ar16 4 io_l44n_4 av16 4 io_l44p_4 au16 4 io_l45n_4 ap16 4 io_l45p_4/vref_4 an16 4 io_l10n_4 aw17 nc 4 io_l10p_4 aw16 nc 4 io_l11n_4 bb16 nc 4 io_l11p_4 ba16 nc 4 io_l12n_4 al18 nc 4 io_l12p_4 al17 nc 4 io_l16n_4 au17 nc 4 io_l16p_4 at17 nc 4 io_l18n_4 ba17 nc 4 io_l18p_4/vref_4 ay17 nc 4 io_l46n_4 at19 4 io_l46p_4 at18 4 io_l47n_4 an17 4 io_l47p_4 am17 4 io_l48n_4 av18 4 io_l48p_4 au18 4 io_l49n_4 ay19 4 io_l49p_4 ay18 4 io_l50_4/no_pair am19 4 io_l53_4/no_pair am18 4 io_l54n_4 bb18 4 io_l54p_4 ba18 4 io_l55n_4 ar20 4 io_l55p_4 ar19 4 io_l56n_4 ap18 4 io_l56p_4 an18 4 io_l57n_4 av19 4 io_l57p_4/vref_4 au19 4 io_l58n_4 aw20 ta bl e 1 4 : ff1696 ? xc2vp100 bank pin description pin number no connects xc2vp100 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 272 product not recommended for new designs 4 io_l58p_4 aw19 4 io_l59n_4 ap19 4 io_l59p_4 an19 4 io_l60n_4 bb19 4 io_l60p_4 ba19 4 io_l64n_4 au20 4 io_l64p_4 at20 4 io_l65n_4 al21 4 io_l65p_4 al20 4 io_l66n_4 ba20 4 io_l66p_4/vref_4 ay20 4 io_l67n_4 ar21 4 io_l67p_4 ap21 4 io_l68n_4 an20 4 io_l68p_4 am20 4 io_l69n_4 au21 4 io_l69p_4/vref_4 at21 4 io_l73n_4 aw21 4 io_l73p_4 av21 4 io_l74n_4/gclk3s an21 4 io_l74p_4/gclk2p am21 4 io_l75n_4/gclk1s ba21 4 io_l75p_4/gclk0p ay21 5 io_l75n_5/gclk7s ay22 5 io_l75p_5/gclk6p ba22 5 io_l74n_5/gclk5s am22 5 io_l74p_5/gclk4p an22 5 io_l73n_5 av22 5 io_l73p_5 aw22 5 io_l69n_5/vref_5 at22 5 io_l69p_5 au22 5 io_l68n_5 am23 5 io_l68p_5 an23 5 io_l67n_5 ap22 5 io_l67p_5 ar22 5 io_l66n_5/vref_5 ay23 ta bl e 1 4 : ff1696 ? xc2vp100 bank pin description pin number no connects xc2vp100 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 273 product not recommended for new designs 5 io_l66p_5 ba23 5 io_l65n_5 al23 5 io_l65p_5 al22 5 io_l64n_5 at23 5 io_l64p_5 au23 5 io_l60n_5 ba24 5 io_l60p_5 bb24 5 io_l59n_5 an24 5 io_l59p_5 ap24 5 io_l58n_5 aw24 5 io_l58p_5 aw23 5 io_l57n_5/vref_5 au24 5 io_l57p_5 av24 5 io_l56n_5 an25 5 io_l56p_5 ap25 5 io_l55n_5 ar24 5 io_l55p_5 ar23 5 io_l54n_5 ba25 5 io_l54p_5 bb25 5 io_l53_5/no_pair am25 5 io_l50_5/no_pair am24 5 io_l49n_5 ay25 5 io_l49p_5 ay24 5 io_l48n_5 au25 5 io_l48p_5 av25 5 io_l47n_5 am26 5 io_l47p_5 an26 5 io_l46n_5 at25 5 io_l46p_5 at24 5 io_l18n_5/vref_5 ay26 nc 5 io_l18p_5 ba26 nc 5 io_l16n_5 at26 nc 5 io_l16p_5 au26 nc 5 io_l12n_5 al26 nc 5 io_l12p_5 al25 nc 5 io_l11n_5 ba27 nc 5 io_l11p_5 bb27 nc ta bl e 1 4 : ff1696 ? xc2vp100 bank pin description pin number no connects xc2vp100 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 274 product not recommended for new designs 5 io_l10n_5 aw27 nc 5 io_l10p_5 aw26 nc 5 io_l45n_5/vref_5 an27 5 io_l45p_5 ap27 5 io_l44n_5 au27 5 io_l44p_5 av27 5 io_l43n_5 ar27 5 io_l43p_5 ar26 5 io_l39n_5 al27 5 io_l39p_5 am27 5 io_l38n_5 ba28 5 io_l38p_5 bb28 5 io_l37n_5 ay28 5 io_l37p_5 ay27 5 io_l87n_5/vref_5 an28 5 io_l87p_5 ap28 5 io_l86n_5 au28 5 io_l86p_5 av28 5 io_l85n_5 at28 5 io_l85p_5 at27 5 io_l84n_5 al28 5 io_l84p_5 am28 5 io_l83_5/no_pair ba29 5 io_l80_5/no_pair bb29 5 io_l79n_5 ay29 5 io_l79p_5 aw28 5 io_l78n_5 an29 5 io_l78p_5 ap29 5 io_l77n_5 au29 5 io_l77p_5 av29 5 io_l76n_5 at29 5 io_l76p_5 ar28 5 io_l36n_5/vref_5 al29 5 io_l36p_5 am29 5 io_l35n_5 ay30 5 io_l35p_5 ba30 5 io_l34n_5 at30 ta bl e 1 4 : ff1696 ? xc2vp100 bank pin description pin number no connects xc2vp100 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 275 product not recommended for new designs 5 io_l34p_5 au30 5 io_l30n_5 am30 5 io_l30p_5 an30 5 io_l29n_5 ay31 5 io_l29p_5 ba31 5 io_l28n_5 aw31 5 io_l28p_5 aw30 5 io_l27n_5/vref_5 ap31 5 io_l27p_5 ar31 5 io_l26n_5 au31 5 io_l26p_5 av31 5 io_l25n_5 at31 5 io_l25p_5 ar30 5 io_l21n_5 am31 5 io_l21p_5 an31 5 io_l20n_5 ba32 5 io_l20p_5 bb32 5 io_l19n_5 av32 5 io_l19p_5 aw32 5 io_l09n_5/vref_5 ap32 5 io_l09p_5 ar32 5 io_l08n_5 at32 5 io_l08p_5 au32 5 io_l07n_5/vref_5 ba33 5 io_l07p_5 bb33 5 io_l06n_5/vrp_5 ay33 5 io_l06p_5/vrn_5 ay32 5 io_l05_5/no_pair at33 5 io_l03n_5/d4 am32 5 io_l03p_5/d5 an32 5 io_l02n_5/d6 au33 5 io_l02p_5/d7 av33 5 io_l01n_5/rdwr_b al31 5 io_l01p_5/cs_b al32 6 io_l01p_6/vrn_6 bb39 6 io_l01n_6/vrp_6 ba39 ta bl e 1 4 : ff1696 ? xc2vp100 bank pin description pin number no connects xc2vp100 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 276 product not recommended for new designs 6 io_l02p_6 ba34 6 io_l02n_6 ay34 6 io_l03p_6 bb37 6 io_l03n_6/vref_6 ba37 6 io_l04p_6 bb36 6 io_l04n_6 ba36 6 io_l05p_6 aw34 6 io_l05n_6 aw35 6 io_l06p_6 bb35 6 io_l06n_6 ba35 6 io_l73p_6 ba38 6 io_l73n_6 ay38 6 io_l74p_6 au34 6 io_l74n_6 at34 6 io_l75p_6 ay39 6 io_l75n_6/vref_6 ay40 6 io_l76p_6 ay37 6 io_l76n_6 aw36 6 io_l77p_6 ar34 6 io_l77n_6 ar35 6 io_l78p_6 ay35 6 io_l78n_6 ay36 6 io_l79p_6 aw41 6 io_l79n_6 aw42 6 io_l80p_6 ap35 6 io_l80n_6 an34 6 io_l81p_6 aw40 6 io_l81n_6/vref_6 av40 6 io_l82p_6 aw39 6 io_l82n_6 av39 6 io_l83p_6 am34 6 io_l83n_6 am35 6 io_l84p_6 aw38 6 io_l84n_6 av37 6 io_l61p_6 av41 6 io_l61n_6 au40 6 io_l62p_6 al34 ta bl e 1 4 : ff1696 ? xc2vp100 bank pin description pin number no connects xc2vp100 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 277 product not recommended for new designs 6 io_l62n_6 al35 6 io_l63p_6 av36 6 io_l63n_6/vref_6 au36 6 io_l64p_6 av35 6 io_l64n_6 au35 6 io_l65p_6 ak35 6 io_l65n_6 aj34 6 io_l66p_6 au41 6 io_l66n_6 au42 6 io_l67p_6 au38 6 io_l67n_6 at38 6 io_l68p_6 ak32 6 io_l68n_6 ak33 6 io_l69p_6 au37 6 io_l69n_6/vref_6 at37 6 io_l70p_6 at41 6 io_l70n_6 at42 6 io_l71p_6 ak31 6 io_l71n_6 aj31 6 io_l72p_6 at39 6 io_l72n_6 at40 6 io_l07p_6 at35 6 io_l07n_6 at36 6 io_l08p_6 aj32 6 io_l08n_6 aj33 6 io_l09p_6 ar42 6 io_l09n_6/vref_6 ap41 6 io_l10p_6 ar40 6 io_l10n_6 ar41 6 io_l11p_6 ah34 6 io_l11n_6 ah35 6 io_l12p_6 ar38 6 io_l12n_6 ar39 6 io_l13p_6 ar36 6 io_l13n_6 ar37 6 io_l14p_6 ah32 6 io_l14n_6 ah33 ta bl e 1 4 : ff1696 ? xc2vp100 bank pin description pin number no connects xc2vp100 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 278 product not recommended for new designs 6 io_l15p_6 ap39 6 io_l15n_6/vref_6 ap40 6 io_l16p_6 ap36 6 io_l16n_6 ap37 6 io_l17p_6 ah31 6 io_l17n_6 ag31 6 io_l18p_6 an41 6 io_l18n_6 an42 6 io_l19p_6 an40 6 io_l19n_6 am40 6 io_l20p_6 ag34 6 io_l20n_6 ag35 6 io_l21p_6 an37 6 io_l21n_6/vref_6 an38 6 io_l22p_6 an36 6 io_l22n_6 am36 6 io_l23p_6 ag32 6 io_l23n_6 ag33 6 io_l24p_6 am41 6 io_l24n_6 am42 6 io_l25p_6 am38 6 io_l25n_6 am39 6 io_l26p_6 af35 6 io_l26n_6 af36 6 io_l27p_6 am37 6 io_l27n_6/vref_6 al36 6 io_l28p_6 al41 6 io_l28n_6 ak41 6 io_l29p_6 af32 6 io_l29n_6 af33 6 io_l30p_6 al39 6 io_l30n_6 al40 6 io_l31p_6 al37 6 io_l31n_6 al38 6 io_l32p_6 af31 6 io_l32n_6 ae31 6 io_l33p_6 ak39 ta bl e 1 4 : ff1696 ? xc2vp100 bank pin description pin number no connects xc2vp100 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 279 product not recommended for new designs 6 io_l33n_6/vref_6 ak40 6 io_l34p_6 ak36 6 io_l34n_6 ak37 6 io_l35p_6 ae36 6 io_l35n_6 ae37 6 io_l36p_6 aj41 6 io_l36n_6 aj42 6 io_l37p_6 aj40 6 io_l37n_6 ah40 6 io_l38p_6 ae34 6 io_l38n_6 ae35 6 io_l39p_6 aj38 6 io_l39n_6/vref_6 ah37 6 io_l40p_6 aj36 6 io_l40n_6 aj37 6 io_l41p_6 ae32 6 io_l41n_6 ae33 6 io_l42p_6 ah41 6 io_l42n_6 ah42 6 io_l43p_6 ah38 6 io_l43n_6 ah39 6 io_l44p_6 ad36 6 io_l44n_6 ac35 6 io_l45p_6 ah36 6 io_l45n_6/vref_6 ag36 6 io_l46p_6 ag41 6 io_l46n_6 ag42 6 io_l47p_6 ad34 6 io_l47n_6 ac33 6 io_l48p_6 ag40 6 io_l48n_6 af39 6 io_l49p_6 ag38 6 io_l49n_6 ag39 6 io_l50p_6 ad32 6 io_l50n_6 ad33 6 io_l51p_6 ag37 6 io_l51n_6/vref_6 af37 ta bl e 1 4 : ff1696 ? xc2vp100 bank pin description pin number no connects xc2vp100 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 280 product not recommended for new designs 6 io_l52p_6 af40 6 io_l52n_6 af41 6 io_l53p_6 ac36 6 io_l53n_6 ac37 6 io_l54p_6 ae41 6 io_l54n_6 ae42 6 io_l55p_6 ae40 6 io_l55n_6 ad40 6 io_l56p_6 ac31 6 io_l56n_6 ac32 6 io_l57p_6 ae38 6 io_l57n_6/vref_6 ae39 6 io_l58p_6 ad41 6 io_l58n_6 ad42 6 io_l59p_6 ab35 6 io_l59n_6 ab36 6 io_l60p_6 ad37 6 io_l60n_6 ad38 6 io_l85p_6 ac40 6 io_l85n_6 ac41 6 io_l86p_6 ab33 6 io_l86n_6 ab34 6 io_l87p_6 ac39 6 io_l87n_6/vref_6 ab39 6 io_l88p_6 ab40 6 io_l88n_6 ab41 6 io_l89p_6 ab31 6 io_l89n_6 ab32 6 io_l90p_6 ab37 6 io_l90n_6 ab38 7 io_l90p_7 aa40 7 io_l90n_7 aa41 7 io_l89p_7 aa35 7 io_l89n_7 aa36 7 io_l88p_7 y39 7 io_l88n_7/vref_7 aa39 ta bl e 1 4 : ff1696 ? xc2vp100 bank pin description pin number no connects xc2vp100 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 281 product not recommended for new designs 7 io_l87p_7 aa37 7 io_l87n_7 aa38 7 io_l86p_7 aa33 7 io_l86n_7 aa34 7 io_l85p_7 y40 7 io_l85n_7 y41 7 io_l60p_7 w41 7 io_l60n_7 w42 7 io_l59p_7 aa31 7 io_l59n_7 aa32 7 io_l58p_7 v40 7 io_l58n_7/vref_7 w40 7 io_l57p_7 w37 7 io_l57n_7 w38 7 io_l56p_7 y36 7 io_l56n_7 y37 7 io_l55p_7 v41 7 io_l55n_7 v42 7 io_l54p_7 v38 7 io_l54n_7 v39 7 io_l53p_7 y31 7 io_l53n_7 y32 7 io_l52p_7 u40 7 io_l52n_7/vref_7 u41 7 io_l51p_7 t40 7 io_l51n_7 u39 7 io_l50p_7 y35 7 io_l50n_7 w36 7 io_l49p_7 t37 7 io_l49n_7 u37 7 io_l48p_7 t41 7 io_l48n_7 t42 7 io_l47p_7 y33 7 io_l47n_7 w34 7 io_l46p_7 t38 7 io_l46n_7/vref_7 t39 7 io_l45p_7 r36 ta bl e 1 4 : ff1696 ? xc2vp100 bank pin description pin number no connects xc2vp100 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 282 product not recommended for new designs 7 io_l45n_7 t36 7 io_l44p_7 w32 7 io_l44n_7 w33 7 io_l43p_7 r41 7 io_l43n_7 r42 7 io_l42p_7 p40 7 io_l42n_7 r40 7 io_l41p_7 v36 7 io_l41n_7 v37 7 io_l40p_7 r38 7 io_l40n_7/vref_7 r39 7 io_l39p_7 p38 7 io_l39n_7 r37 7 io_l38p_7 v34 7 io_l38n_7 v35 7 io_l37p_7 p41 7 io_l37n_7 p42 7 io_l36p_7 p36 7 io_l36n_7 p37 7 io_l35p_7 v32 7 io_l35n_7 v33 7 io_l34p_7 m41 7 io_l34n_7/vref_7 n41 7 io_l33p_7 n39 7 io_l33n_7 n40 7 io_l32p_7 u35 7 io_l32n_7 u36 7 io_l31p_7 n36 7 io_l31n_7 n37 7 io_l30p_7 m39 7 io_l30n_7 m40 7 io_l29p_7 u32 7 io_l29n_7 u33 7 io_l28p_7 m37 7 io_l28n_7/vref_7 m38 7 io_l27p_7 l37 7 io_l27n_7 m36 ta bl e 1 4 : ff1696 ? xc2vp100 bank pin description pin number no connects xc2vp100 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 283 product not recommended for new designs 7 io_l26p_7 v31 7 io_l26n_7 u31 7 io_l25p_7 l41 7 io_l25n_7 l42 7 io_l24p_7 k40 7 io_l24n_7 l40 7 io_l23p_7 t34 7 io_l23n_7 t35 7 io_l22p_7 l38 7 io_l22n_7/vref_7 l39 7 io_l21p_7 k36 7 io_l21n_7 l36 7 io_l20p_7 t32 7 io_l20n_7 t33 7 io_l19p_7 k41 7 io_l19n_7 k42 7 io_l18p_7 k37 7 io_l18n_7 k38 7 io_l17p_7 r34 7 io_l17n_7 r35 7 io_l16p_7 h42 7 io_l16n_7/vref_7 j41 7 io_l15p_7 j39 7 io_l15n_7 j40 7 io_l14p_7 r32 7 io_l14n_7 r33 7 io_l13p_7 j36 7 io_l13n_7 j37 7 io_l12p_7 h40 7 io_l12n_7 h41 7 io_l11p_7 t31 7 io_l11n_7 r31 7 io_l10p_7 h38 7 io_l10n_7/vref_7 h39 7 io_l09p_7 h36 7 io_l09n_7 h37 7 io_l08p_7 p34 ta bl e 1 4 : ff1696 ? xc2vp100 bank pin description pin number no connects xc2vp100 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 284 product not recommended for new designs 7 io_l08n_7 n35 7 io_l07p_7 g41 7 io_l07n_7 g42 7 io_l72p_7 g39 7 io_l72n_7 g40 7 io_l71p_7 p32 7 io_l71n_7 p33 7 io_l70p_7 f38 7 io_l70n_7/vref_7 g38 7 io_l69p_7 f37 7 io_l69n_7 g37 7 io_l68p_7 n32 7 io_l68n_7 n33 7 io_l67p_7 g35 7 io_l67n_7 g36 7 io_l66p_7 f41 7 io_l66n_7 f42 7 io_l65p_7 p31 7 io_l65n_7 n31 7 io_l64p_7 e41 7 io_l64n_7/vref_7 f40 7 io_l63p_7 e36 7 io_l63n_7 f36 7 io_l62p_7 m34 7 io_l62n_7 m35 7 io_l61p_7 e35 7 io_l61n_7 f35 7 io_l84p_7 d40 7 io_l84n_7 e40 7 io_l83p_7 l34 7 io_l83n_7 l35 7 io_l82p_7 d39 7 io_l82n_7/vref_7 e39 7 io_l81p_7 d38 7 io_l81n_7 e37 7 io_l80p_7 k34 7 io_l80n_7 j35 ta bl e 1 4 : ff1696 ? xc2vp100 bank pin description pin number no connects xc2vp100 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 285 product not recommended for new designs 7 io_l79p_7 d41 7 io_l79n_7 d42 7 io_l78p_7 c39 7 io_l78n_7 c40 7 io_l77p_7 h34 7 io_l77n_7 h35 7 io_l76p_7 c37 7 io_l76n_7/vref_7 d36 7 io_l75p_7 b38 7 io_l75n_7 c38 7 io_l74p_7 f34 7 io_l74n_7 g34 7 io_l73p_7 c35 7 io_l73n_7 c36 7 io_l06p_7 a39 7 io_l06n_7 b39 7 io_l05p_7 d34 7 io_l05n_7 d35 7 io_l04p_7 a37 7 io_l04n_7/vref_7 b37 7 io_l03p_7 a36 7 io_l03n_7 b36 7 io_l02p_7 b34 7 io_l02n_7 c34 7 io_l01p_7/vrn_7 a35 7 io_l01n_7/vrp_7 b35 7 vcco_7 w39 7 vcco_7 p39 7 vcco_7 k39 7 vcco_7 f39 7 vcco_7 d37 7 vcco_7 w35 7 vcco_7 p35 7 vcco_7 k35 7 vcco_7 m33 7 vcco_7 h33 ta bl e 1 4 : ff1696 ? xc2vp100 bank pin description pin number no connects xc2vp100 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 286 product not recommended for new designs 7 vcco_7 aa29 7 vcco_7 y29 7 vcco_7 w29 7 vcco_7 v29 7 vcco_7 u29 7 vcco_7 t29 7 vcco_7 r29 7 vcco_7 aa28 7 vcco_7 y28 7 vcco_7 w28 7 vcco_7 v28 7 vcco_7 u28 7 vcco_7 t28 6 vcco_6 au39 6 vcco_6 an39 6 vcco_6 aj39 6 vcco_6 ad39 6 vcco_6 aw37 6 vcco_6 an35 6 vcco_6 aj35 6 vcco_6 ad35 6 vcco_6 ar33 6 vcco_6 al33 6 vcco_6 ah29 6 vcco_6 ag29 6 vcco_6 af29 6 vcco_6 ae29 6 vcco_6 ad29 6 vcco_6 ac29 6 vcco_6 ab29 6 vcco_6 ag28 6 vcco_6 af28 6 vcco_6 ae28 6 vcco_6 ad28 6 vcco_6 ac28 6 vcco_6 ab28 5 vcco_5 aw33 ta bl e 1 4 : ff1696 ? xc2vp100 bank pin description pin number no connects xc2vp100 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 287 product not recommended for new designs 5 vcco_5 al30 5 vcco_5 aw29 5 vcco_5 ar29 5 vcco_5 aj26 5 vcco_5 aw25 5 vcco_5 ar25 5 vcco_5 aj25 5 vcco_5 ah25 5 vcco_5 aj24 5 vcco_5 ah24 5 vcco_5 aj23 5 vcco_5 ah23 5 vcco_5 aj22 5 vcco_5 ah22 4 vcco_4 aj21 4 vcco_4 ah21 4 vcco_4 aj20 4 vcco_4 ah20 4 vcco_4 aj19 4 vcco_4 ah19 4 vcco_4 aw18 4 vcco_4 ar18 4 vcco_4 aj18 4 vcco_4 ah18 4 vcco_4 aj17 4 vcco_4 aw14 4 vcco_4 ar14 4 vcco_4 al13 4 vcco_4 aw10 3 vcco_3 ag15 3 vcco_3 af15 3 vcco_3 ae15 3 vcco_3 ad15 3 vcco_3 ac15 3 vcco_3 ab15 3 vcco_3 ah14 3 vcco_3 ag14 ta bl e 1 4 : ff1696 ? xc2vp100 bank pin description pin number no connects xc2vp100 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 288 product not recommended for new designs 3 vcco_3 af14 3 vcco_3 ae14 3 vcco_3 ad14 3 vcco_3 ac14 3 vcco_3 ab14 3 vcco_3 ar10 3 vcco_3 al10 3 vcco_3 an8 3 vcco_3 aj8 3 vcco_3 ad8 3 vcco_3 aw6 3 vcco_3 au4 3 vcco_3 an4 3 vcco_3 aj4 3 vcco_3 ad4 2 vcco_2 aa15 2 vcco_2 y15 2 vcco_2 w15 2 vcco_2 v15 2 vcco_2 u15 2 vcco_2 t15 2 vcco_2 aa14 2 vcco_2 y14 2 vcco_2 w14 2 vcco_2 v14 2 vcco_2 u14 2 vcco_2 t14 2 vcco_2 r14 2 vcco_2 m10 2 vcco_2 h10 2 vcco_2 w8 2 vcco_2 p8 2 vcco_2 k8 2 vcco_2 d6 2 vcco_2 w4 2 vcco_2 p4 2 vcco_2 k4 ta bl e 1 4 : ff1696 ? xc2vp100 bank pin description pin number no connects xc2vp100 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 289 product not recommended for new designs 2 vcco_2 f4 1 vcco_1 r21 1 vcco_1 p21 1 vcco_1 r20 1 vcco_1 p20 1 vcco_1 r19 1 vcco_1 p19 1 vcco_1 r18 1 vcco_1 p18 1 vcco_1 h18 1 vcco_1 d18 1 vcco_1 p17 1 vcco_1 h14 1 vcco_1 d14 1 vcco_1 m13 1 vcco_1 d10 0 vcco_0 d33 0 vcco_0 m30 0 vcco_0 h29 0 vcco_0 d29 0 vcco_0 p26 0 vcco_0 r25 0 vcco_0 p25 0 vcco_0 h25 0 vcco_0 d25 0 vcco_0 r24 0 vcco_0 p24 0 vcco_0 r23 0 vcco_0 p23 0 vcco_0 r22 0 vcco_0 p22 n/a cclk am10 n/a prog_b j33 n/a done an10 n/a m0 ap33 n/a m1 an33 ta bl e 1 4 : ff1696 ? xc2vp100 bank pin description pin number no connects xc2vp100 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 290 product not recommended for new designs n/a m2 am33 n/a tck k10 n/a tdi m32 n/a tdo m11 n/a tms l10 n/a pwrdwn_b ap10 n/a hswap_en k33 n/a rsvd j10 n/a vbatt m12 n/a dxp m31 n/a dxn l33 n/a vccint ak30 n/a vccint n30 n/a vccint aj29 n/a vccint p29 n/a vccint aj28 n/a vccint ah28 n/a vccint r28 n/a vccint p28 n/a vccint aj27 n/a vccint ah27 n/a vccint ag27 n/a vccint af27 n/a vccint ae27 n/a vccint ad27 n/a vccint ac27 n/a vccint ab27 n/a vccint aa27 n/a vccint y27 n/a vccint w27 n/a vccint v27 n/a vccint u27 n/a vccint t27 n/a vccint r27 n/a vccint p27 n/a vccint ah26 ta bl e 1 4 : ff1696 ? xc2vp100 bank pin description pin number no connects xc2vp100 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 291 product not recommended for new designs n/a vccint ag26 n/a vccint af26 n/a vccint u26 n/a vccint t26 n/a vccint r26 n/a vccint ag25 n/a vccint t25 n/a vccint ag24 n/a vccint t24 n/a vccint ag23 n/a vccint t23 n/a vccint ag22 n/a vccint t22 n/a vccint ag21 n/a vccint t21 n/a vccint ag20 n/a vccint t20 n/a vccint ag19 n/a vccint t19 n/a vccint ag18 n/a vccint t18 n/a vccint ah17 n/a vccint ag17 n/a vccint af17 n/a vccint u17 n/a vccint t17 n/a vccint r17 n/a vccint aj16 n/a vccint ah16 n/a vccint ag16 n/a vccint af16 n/a vccint ae16 n/a vccint ad16 n/a vccint ac16 n/a vccint ab16 n/a vccint aa16 n/a vccint y16 ta bl e 1 4 : ff1696 ? xc2vp100 bank pin description pin number no connects xc2vp100 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 292 product not recommended for new designs n/a vccint w16 n/a vccint v16 n/a vccint u16 n/a vccint t16 n/a vccint r16 n/a vccint p16 n/a vccint aj15 n/a vccint ah15 n/a vccint r15 n/a vccint p15 n/a vccint aj14 n/a vccint p14 n/a vccint ak13 n/a vccint n13 n/a vccaux ba42 n/a vccaux ay42 n/a vccaux al42 n/a vccaux ab42 n/a vccaux aa42 n/a vccaux m42 n/a vccaux c42 n/a vccaux b42 n/a vccaux bb41 n/a vccaux a41 n/a vccaux bb40 n/a vccaux a40 n/a vccaux bb31 n/a vccaux a31 n/a vccaux bb22 n/a vccaux a22 n/a vccaux bb21 n/a vccaux a21 n/a vccaux bb12 n/a vccaux a12 n/a vccaux bb3 n/a vccaux a3 n/a vccaux bb2 ta bl e 1 4 : ff1696 ? xc2vp100 bank pin description pin number no connects xc2vp100 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 293 product not recommended for new designs n/a vccaux a2 n/a vccaux ba1 n/a vccaux ay1 n/a vccaux al1 n/a vccaux ab1 n/a vccaux aa1 n/a vccaux m1 n/a vccaux c1 n/a vccaux b1 n/a gnd av42 n/a gnd ap42 n/a gnd ak42 n/a gnd af42 n/a gnd ac42 n/a gnd y42 n/a gnd u42 n/a gnd n42 n/a gnd j42 n/a gnd e42 n/a gnd ba41 n/a gnd ay41 n/a gnd c41 n/a gnd b41 n/a gnd ba40 n/a gnd b40 n/a gnd bb38 n/a gnd av38 n/a gnd ap38 n/a gnd ak38 n/a gnd af38 n/a gnd ac38 n/a gnd y38 n/a gnd u38 n/a gnd n38 n/a gnd j38 n/a gnd e38 n/a gnd a38 ta bl e 1 4 : ff1696 ? xc2vp100 bank pin description pin number no connects xc2vp100 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 294 product not recommended for new designs n/a gnd bb34 n/a gnd av34 n/a gnd ap34 n/a gnd ak34 n/a gnd af34 n/a gnd ac34 n/a gnd y34 n/a gnd u34 n/a gnd n34 n/a gnd j34 n/a gnd e34 n/a gnd a34 n/a gnd ad31 n/a gnd w31 n/a gnd bb30 n/a gnd av30 n/a gnd ap30 n/a gnd j30 n/a gnd e30 n/a gnd a30 n/a gnd bb26 n/a gnd av26 n/a gnd ap26 n/a gnd ae26 n/a gnd ad26 n/a gnd ac26 n/a gnd ab26 n/a gnd aa26 n/a gnd y26 n/a gnd w26 n/a gnd v26 n/a gnd j26 n/a gnd e26 n/a gnd a26 n/a gnd af25 n/a gnd ae25 n/a gnd ad25 ta bl e 1 4 : ff1696 ? xc2vp100 bank pin description pin number no connects xc2vp100 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 295 product not recommended for new designs n/a gnd ac25 n/a gnd ab25 n/a gnd aa25 n/a gnd y25 n/a gnd w25 n/a gnd v25 n/a gnd u25 n/a gnd al24 n/a gnd af24 n/a gnd ae24 n/a gnd ad24 n/a gnd ac24 n/a gnd ab24 n/a gnd aa24 n/a gnd y24 n/a gnd w24 n/a gnd v24 n/a gnd u24 n/a gnd m24 n/a gnd bb23 n/a gnd av23 n/a gnd ap23 n/a gnd af23 n/a gnd ae23 n/a gnd ad23 n/a gnd ac23 n/a gnd ab23 n/a gnd aa23 n/a gnd y23 n/a gnd w23 n/a gnd v23 n/a gnd u23 n/a gnd j23 n/a gnd e23 n/a gnd a23 n/a gnd af22 n/a gnd ae22 ta bl e 1 4 : ff1696 ? xc2vp100 bank pin description pin number no connects xc2vp100 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 296 product not recommended for new designs n/a gnd ad22 n/a gnd ac22 n/a gnd ab22 n/a gnd aa22 n/a gnd y22 n/a gnd w22 n/a gnd v22 n/a gnd u22 n/a gnd af21 n/a gnd ae21 n/a gnd ad21 n/a gnd ac21 n/a gnd ab21 n/a gnd aa21 n/a gnd y21 n/a gnd w21 n/a gnd v21 n/a gnd u21 n/a gnd bb20 n/a gnd av20 n/a gnd ap20 n/a gnd af20 n/a gnd ae20 n/a gnd ad20 n/a gnd ac20 n/a gnd ab20 n/a gnd aa20 n/a gnd y20 n/a gnd w20 n/a gnd v20 n/a gnd u20 n/a gnd j20 n/a gnd e20 n/a gnd a20 n/a gnd al19 n/a gnd af19 n/a gnd ae19 ta bl e 1 4 : ff1696 ? xc2vp100 bank pin description pin number no connects xc2vp100 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 297 product not recommended for new designs n/a gnd ad19 n/a gnd ac19 n/a gnd ab19 n/a gnd aa19 n/a gnd y19 n/a gnd w19 n/a gnd v19 n/a gnd u19 n/a gnd m19 n/a gnd af18 n/a gnd ae18 n/a gnd ad18 n/a gnd ac18 n/a gnd ab18 n/a gnd aa18 n/a gnd y18 n/a gnd w18 n/a gnd v18 n/a gnd u18 n/a gnd bb17 n/a gnd av17 n/a gnd ap17 n/a gnd ae17 n/a gnd ad17 n/a gnd ac17 n/a gnd ab17 n/a gnd aa17 n/a gnd y17 n/a gnd w17 n/a gnd v17 n/a gnd j17 n/a gnd e17 n/a gnd a17 n/a gnd bb13 n/a gnd av13 n/a gnd ap13 n/a gnd j13 ta bl e 1 4 : ff1696 ? xc2vp100 bank pin description pin number no connects xc2vp100 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 298 product not recommended for new designs n/a gnd e13 n/a gnd a13 n/a gnd ad12 n/a gnd w12 n/a gnd bb9 n/a gnd av9 n/a gnd ap9 n/a gnd ak9 n/a gnd af9 n/a gnd ac9 n/a gnd y9 n/a gnd u9 n/a gnd n9 n/a gnd j9 n/a gnd e9 n/a gnd a9 n/a gnd bb5 n/a gnd av5 n/a gnd ap5 n/a gnd ak5 n/a gnd af5 n/a gnd ac5 n/a gnd y5 n/a gnd u5 n/a gnd n5 n/a gnd j5 n/a gnd e5 n/a gnd a5 n/a gnd ba3 n/a gnd b3 n/a gnd ba2 n/a gnd ay2 n/a gnd c2 n/a gnd b2 n/a gnd av1 n/a gnd ap1 n/a gnd ak1 ta bl e 1 4 : ff1696 ? xc2vp100 bank pin description pin number no connects xc2vp100 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 299 product not recommended for new designs n/a gnd af1 n/a gnd ac1 n/a gnd y1 n/a gnd u1 n/a gnd n1 n/a gnd j1 n/a gnd e1 notes: 1. see ta b l e 4 for an explanation of the signals available on this pin. ta bl e 1 4 : ff1696 ? xc2vp100 bank pin description pin number no connects xc2vp100 virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 300 product not recommended for new designs ff1696 flip-chip fine-pitc h bga package specificat ions (1.00mm pitch) figure 10: ff1696 flip-chip fine-pitch bga package specifications virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 301 product not recommended for new designs revision history this section records the change history for this module of the data sheet. date version revision 01/31/02 1.0 initial xilinx release. 08/14/02 2.0 added package and pinout information for new devices. 08/27/02 2.1 ? updated selectio-ultra information in ta b l e 4 . (table deleted in v2.3.) ? corrected direction for rxnpad and txppad in ta bl e 4 (formerly table 5). 09/27/02 2.2 corrected ta b l e 2 and ta bl e 3 entries for xc2vp30, ff1152 package, maximum i/os from 692 to 644. 11/20/02 2.3 added number of differential pairs data to ta b l e 3 . removed former table 4. 12/03/02 2.4 corrections in ta bl e 4 : ? reclassified gclkx (s/p) pins as input/ou tput, since these pins can be used as normal i/os if not used as clocks. ? added cautionary note to pwrdwn_b pin, indicating that this function is not supported. 01/20/03 2.5 added and removed package/pinout information for existing devices: ?in ta bl e 1 , added fg676 package information. ?in ta bl e 3 , added fg676 package option for xc2vp20, xc2vp30, and xc2vp40. ?in ta bl e 1 2 , removed ff1517 package option for xc2vp40. ? added fg676 package pinouts ( ta b l e 7 ) for xc2vp20, xc2vp30, and xc2vp40. ? added package diagram ( figure 3 ) for fg676 package. 05/19/03 2.5.1 ? added section brefclk pin definitions , page 5 . ? added clarification to ta b l e 4 and all device pinout tables regarding the dual-use nature of pins d0/din and busy/dout during configuration. 06/19/03 2.5.3 ? added notation of "open-drain" to tdo pin in ta b l e 4 . ? the final gnd pin in each of six pinout tables was inadvertently deleted in v2.5.1. this revision restores the deleted gnd pins as follows: - pin a1, table 6, page 16 (fg456) - pin af26, table 7, page 30 (fg676) - pin an34, table 10, page 98 (ff1152) - pin e1, table 11, page 130 (ff1148) - pin c38, table 12, page 162 (ff1517) - pin e1, table 14, page 253 (ff1696) 08/25/03 2.5.5 ? ta b l e 4 : deleted note 2, obsolete. there is only one gnda pin per mgt. ? ta b l e 4 : deleted pins alt_vrp and alt_vrn. not used in virtex-ii pro fpgas. 12/10/03 3.0 ? xc2vp2 through xc2vp70 speed grades -5, -6, and -7, and xc2vp100 speed grades -5 and -6, are released to production status . 02/19/04 3.1 ? ta b l e 4 , signal descriptions column: - for signals tdi, tms, and tck, added: pins are 3.3v-compatible. - for signals m2, m1, m0, added: tie to 3.3v only with 100 ? series resistor. no toggling during or after configuration. - for signal tdo, added: no internal pull-up. external pull-up to 3.3v ok with resistor greater than 200 ? . 03/09/04 3.1.1 ? recompiled for back ward compatibility with acrobat 4 and above. no content changes. 06/30/04 4.0 merged in ds110-4 (module 4 of virtex-ii pro x data sheet). added data on available pb-free packages and updated package diagrams for affected devices. virtex-ii pro and virtex-ii pro x platform fpgas: pinout information r ds083 (v5.0) june 21, 2011 www.xilinx.com module 4 of 4 product specification 302 product not recommended for new designs notice of disclaimer the xilinx hardware fpga and cpld devices referred to herein (?products?) are subject to the terms and conditions of the xilinx limite d warranty which can be viewed at http://www.xilinx.com/warranty.htm . this limited warranty does not extend to any use of products in an application or environment that is not within the specifications stated in the xilinx data sheet. all specifications are subject to change without notice. products are not designed or intended to be fail-safe or for use in any application requiring fail-safe performance, such as life-support or safety devic es or systems, or any other application that invokes the potential risks of death, personal injury, or property or environmental damage (?critical applications?). use of products in critical applications is at the sole risk of customer, subject to applicable laws and regulations. virtex-ii pro data sheet the virtex-ii pro data sheet contains the following modules: ? virtex-ii pro and virtex-ii pro x platform fpgas: introduction and overview (module 1) ? virtex-ii pro and virtex-ii pro x platform fpgas: functional description (module 2) ? virtex-ii pro and virtex-ii pro x platform fpgas: dc and switching characteristics (module 3) ? virtex-ii pro and virtex-ii pro x platform fpgas: pinout information (module 4) 11/17/04 4.1 ? ta b l e 4 : added requirement to v batt to connect pin to v ccaux or gnd if battery is not used. 03/01/05 4.2 ? ta b l e 3 : corrected number of differential i/o pairs for xc2vp30-ff1152 from 340 to 316. ? ta b l e 4 : changed direction for user i/o pins (io_lxxy_#) from ?input/output? to ?input/output/bidirectional?. 06/20/05 4.3 no changes in module 4 for this revision. 09/15/05 4.4 no changes in module 4 for this revision. 10/10/05 4.5 no changes in module 4 for this revision. 03/05/07 4.6 ? figure 2, page 29 : corrected note 3. ? figure 7, page 161 : updated with drawing showing correct heat sink profile and detail. 11/05/07 4.7 updated copyright notice and legal disclaimer. 06/21/11 5.0 added product not recommended for new designs banner. updated figure 3, page 50 , with the newest fg676/fgg676 mechanical drawing. date version revision |
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