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| rev. 4226as?aero?06/03 note: this is a summary document. a complete document is not available at this time. contact atmel for a complete document. f eatures sparc v8 high-performance low-power 32-bit architecture ? 8 register windows integrated 32/64-bit floating point unit advanced architecture ? on-chip amba bus ? 5-stage pipeline ? 16-kbyte multi-sets data cache ? 32-kbyte multi-sets instruction cache on-chip peripherals ? memory interface chip select generator waitstate generator sdram controller ? timers two 24-bit timers watchdog timer ? two 8-bit uarts ? interrupt controller with 4 external programmable inputs ? 32 parallel i/o interface ? 33 mhz pci interface compliant with 2.2 pci specification fault tolerance by design ? full triple modular redundancy (tmr) ? edac protection ? parity protection debug and test facilities ? debug support unit (dsu) for trace and debug ? ieee 1149.1 jtag interface ? four hardware watchpoints speed optimized code ram interface 8 or 40-bit boot-prom (flash) interface possibilities clock: 100 mhz (target) core consumption: to be defined performance: to be defined voltage operating range: 3.3v i/o - 1.8v core temperature operating range: -55 c to 125 c total dose radiation capability (parametric & functional) ? 100 krads (si) (target) latch-up immunity better than 70 mev.cm 2 /mg (target) package: mcga 349 (multi-layer column grid array) o verview the AT697E is a highly-integrated, high-performance 32-bit risc embedded proces- sor implementing the sparc architecture v8 specification. the implementation is based on the european space agency (esa) leon2 fault tolerant model. the processor is manufactured using the atmel standard 0.18 m cmos commercial process. it operates at a low voltage. it has been especially designed for space, as it has on-chip concurrent transient and permanent error detection. the AT697E includes an on-chip integer unit (iu), a floating point unit (fpu), sepa- rate instruction and data caches, hardware multiplier and divider, interrupt controller, debug support unit with trace buffer, two 24-bit timers, parallel and serial interfaces, idle mode function, watchdog, a pci interface and a flexible memory controller. the design is highly testable with the support of a debug system unit (dsu) and a boundary scan through jtag interface. rad-hard 32-bit sparc embedded processor AT697E advance information summary
2 AT697E 4226as ? aero ? 06/03 block diagram figure 1. AT697E block diagram pin description interrupt controller uart a uart b timer 1 timer 2 general purpose interface debug support unit fpu integer unit (sparc v8) i-cache ahb/apb bridge ahb controller amba apb amba ahb watchdog pci waitstate memory controller controller edac rxd txd rxd txd gpi bits pci bus ready busy add. ... jtag tap tds tdi tdo ... prom sram sdram i/o d-cache pci/amba bridge signal type active description a[27:0] output high memory address d[31:0] bidir high memory data cb[7:0] bidir high check bits bexc input low bux exception brdy input low bus ready strobe ios output low local i/o select oe output low output enable ramoe [4:0] output low sram output enable rams [4:0] output low sram chip-select read output high read strobe roms [1:0] output low prom chip select rwe [3:0] output low sram write enable sdcas output low sdram column address strobe sdclk output ? sdram clock 3 AT697E 4226as ? aero ? 06/03 sdcs [1:0] output low sdram chip select sddqm [3:0] output low sdram data mask sdras output low sdram row address strobe sdwe output low sdram write enable write output low write strobe clk input high system clock error low system error pio[15..0] bidir parallel i/o interface rst input low system reset wdog output low watchdog output dsuact output high dsu active dsubre input high dsu break dsuen input high dsu enable dsurx input high dsu uart input dsutx output high dsu uart output tck input test (jtag) clock trst input low test (jtag) reset tms input test (jtag) mode select tdi input test (jtag) data input tdo output test (jtag) data output pa[31:0] in/out high pci address c/be[3:0] in/out low pci byte enable par in/out pci parity frame in/out low pci cycle frame trdy in/out low pci target ready irdy in/out low pci initiator ready stop in/out low pci stop devsel in/out low pci device select idsel input high pci initialization device select perr in/out low pci parity error serr in/out low pci system error req output low pci bus request gnt input low pci bus granted pclk input pci clock (continued) signal type active description 4 AT697E 4226as ? aero ? 06/03 prst input low pci lock in/out low pci host input low host/satellite mode selection agnt [3:0] output low pci bus granted areq [3:0] input low pci bus request bypass input high enable/disable pll clkdiv4 output pll divider clock output plock output high pll lock flt analog passive filter vcc18 dedicated power supply 1.8v vcc33 dedicated power supply 3.3v vss dedicated power supply 0v test test mode (continued) signal type active description 5 AT697E 4226as ? aero ? 06/03 product description integer unit the AT697E integer unit (iu) implements sparc integer instructions as defined in sparc architecture manual version 8. the iu is designed for highly dependable space and military applications, and includes support for error detection. the risc architecture makes possible the creation of a processor that can execute instructions at a rate approaching one instruction per processor clock. floating point unit (fpu) the fpu is designed to provide execution of single and double-precision floating point instructions. the processor is stopped during the execution of floating point instructions. instruction set AT697E instruction set describes six functional categories: load/store, arithmetic/logi- cal/shift, control transfer, read/write control register, floating-point, and miscellaneous. please refer to sparc v8 architecture manual that presents implemented instructions. cache sub-system separate instruction and data caches are provided. the instruction cache uses stream- ing during line-refill to minimize refill latency. the data cache uses writethrough policy and implements a double-word write-buffer. the data cache also performs bus-snoop- ing on the ahb bus. memory interface the AT697E is designed to allow easy interfacing to internal/external memory resources. the flexible memory interface provides a direct interface for prom, memory mapped i/o devices, static ram (sram) and synchronous dynamic ram (sdram). the memory areas can be programmed to either 8-, 16- or 32-bit data width. fault tolerance the AT697E includes fault tolerance features to prevent the processor from arbitrary single-event upset errors. this feature is implemented to withstand these errors without data loss. AT697E device is based on a full triple modular redundancy design. the main features that make AT697E radiation tolerant are the following: three internal clock trees register file protection data protection cache protection address range size mapping 0x00000000 - 0x1fffffff 512 mb prom 0x20000000 - 0x3fffffff 512 mb i/o 0x40000000 - 0x7fffffff 1 gb sram/sdram 6 AT697E 4226as ? aero ? 06/03 traps the AT697E supports two types of traps: synchronous traps asynchronous traps also called interrupts synchronous traps are caused by hardware responding to a particular instruction: they occur during the instruction that caused them. asynchronous traps occur when an exter- nal event interrupts the processor. they are not related to any particular instruction and occur between the execution of instructions. timers general purpose timers two 24-bit timers are provided on-chip. the timers can work in periodic or one-shot mode. both timers are clocked by a common 10-bit prescaler. watchdog timer a 24-bit watchdog is provided on-chip. the watchdog is clocked by the timer prescaler. when the watchdog reaches zero, an output signal (wdog) is asserted. this signal can be used to generate system reset. communication interfaces serial interfaces ? uarts two full duplex asynchronous receiver transmitters (uart) are included. the data for- mat of the uart ? s is eight data bits with one stop bit. it is possible to choose between no parity, even and odd parity. uart ? s provide double buffering, i.e. each uart con- sists of a transmitter holding register, a receiver holding register, a transmitter shift register, and a receiver shift register. each of these registers are 8-bit wide. for each uart a data register is provided. the baud rate of both the uart ? s is individually programmable. parallel interface a 32-bit parallel i/o port is provided. 16 bits are always available and can be individually programmed by software to be an input or an output. the additional 16 bits are only available when the memory bus is configured for 8- or 16-bit operation. some of the bits have alternate usage, such as uart inputs/outputs and external inter- rupts inputs. pci interface the pci implementation standing on the AT697E is pci 2.2 compliant. it is a high per- formance 32-bit bus with multiplexed address and data lines. it is intended for use as an interconnect mechanism between processor/memory systems and peripheral controller components. 7 AT697E 4226as ? aero ? 06/03 test and diagnostics the design is highly testable with the support of a debug system unit (dsu), an internal and boundary scan through jtag interface. test access port (tap) a tap is provided through a jtag interface. dsu the on-chip debug support unit (dsu) allows non-intrusive debugging on target hard- ware. the dsu allows to insert instruction and data watchpoints, and access to all on- chip registers from a remote debugger. a trace buffer is provided to trace the executed instruction flow and/or ahb bus traffic. communication to an outside debugger (e.g. gdb) is done using a dedicated uart (rs232). watchpoint registers to aid software debugging, up to four watchpoint registers are provided. each register can cause a debug-trap on an arbitrary instruction or data address range. if the debug support unit is enabled, the watchpoints can be used to enter debug mode. 9 AT697E 4226as ? aero ? 06/03 signals description all signals are clocked on the rising edge of clk. iu and fpu signals a[27:0] ? address bus (output) these active high outputs carry the address during accesses on the memory bus. when no access is performed, the address of the last access is driven (also internal cycles). d[31:0] ? data bus (bi-directional) d[31:0] carries the data during transfers on the memory bus. the processor only drives thebus during write cycles. during accesses to 8-bit areas, only d[31:24] are used. cb[7:0] ? check bits (bi-directional) cb[6:0] carries the edac checkbits. cb[7] (1) takes the value of tcb[7] in the error control register. processor only drives cb[7:0] during write cycles to areas programmed to be edac protected. note: 1. cb[7] is implemented to enable programming of flash memories. when only 7 bits are useful for edac protection, 8 are needed for programming. that is why there is an addition 8th bit in the check bits. memory interface signals globals oe* ? output enable (output) this active low output is asserted during read cycles on the memory bus. brdy* ? bus ready (input) this active low input indicates that the access to a memory mapped i/o area can be ter- minated on the next rising clock edge. read ? read cycle this active high output is asserted during read cycles on the memory bus. write* ? write enable (output) this active low output provides a write strobe during write cycles on the memory bus. 10 AT697E 4226as ? aero ? 06/03 prom roms*[1:0] ? prom chip-select (output) these active low outputs provide the chip-select signal for the prom area. romsn[0] is asserted when the lower half of the prom area is accessed (0 - 0x10000000), while romsn[1] is asserted for the upper half. sram ramoe*[4:0] ? ram output enable (output) these active low signals provide an individual output enable for each ram bank. rams*[4:0] ? ram chip-select (output) these active low outputs provide the chip-select signals for each ram bank. rwen [3:0] ? ram write enable (output) these active low outputs provide individual write strobes for each byte lane. rwen[0] controls d[31:24], rwen[1] controls d[23:16], etc. i/o ios* ? i/o select (output) this active low output is the chip-select signal for the memory mapped i/o area. sdram interface sdclk ? sdram clock sdram clock, can be configured to be identical or inverted in relation to the system clock. sdcasn ? sdram column address strobe this active low signal provides a common cas for all sdram devices. sdcsn[1:0] ? sdram chip select these active low outputs provide the chip select signals for the two sdram banks. sddqm[3:0] ? sdram data mask these active low outputs provide the dqm signals for both sdram banks. sdras* ? sdram row address strobe this active low signal provides a common ras for all sdram devices. sdwen ? sdram write strobe this active low signal provides a common write strobe for all sdram devices. 11 AT697E 4226as ? aero ? 06/03 system signals clk ? processor clock (input) this active high input provides the main processor clock. reset* ? processor reset (input) when asserted, this active low input will reset the processor and all on-chip peripherals. wdog* ? watchdog time-out (open-drain output) this active low output is asserted when the watchdog times-out. bexc* ? bus exception (input) this active low input is sampled simultaneously with the data during accesses on the memory bus. if asserted, a memory error will be generated. error* ? processor error (open-drain output) this active low output is asserted when the processor has entered error state and is halted. this happens when traps are disabled and an synchronous (un-maskable) trap occurs. test ? test mode input when asserted, this active high input will make processor enter test mode. pio[15:0] ? parallel i/o port (bi-directional) these bi-directional signals can be used as inputs or outputs to control external devices. bypass ? pll bypass when asserted, this active high input set the pll in bypass mode. the device is directly clocked by the external clock. when not asserted, the device is clocked through the pll. pdiv4 ? pll divider output this output provides the main clock delivered by the pll inner divider. skew[1:0] ? clock tree skew this input signals configurate the programmable skew on the redundant clock trees. 12 AT697E 4226as ? aero ? 06/03 plock ? pll lock this active high output is asserted when the pll is locked in the functioning frequency corresponding to the input command plft ? pll passive low pass filter this input is used to connect the pll passive low pass filter. skew[0:1] ? skew on internal clocks those inputs are used to program the skew on internal clock trees dsu signals dsuact ? dsu active (output) this active high output is asserted when the processor is in debug mode and controlled by the dsu. dsubre ? dsu break enable a low-to-high transition on this active high input will generate break condition and put the processor in debug mode. dsuen ? dsu enable (input) the active high input enables the dsu unit. if de-asserted, the dsu trace buffer will continue to operate but the processor will not enter debug mode. dsurx ? dsu receiver (input) this active high input provides the data to the dsu communication link receiver dsutx ? dsu transmitter (output) this active high input provides the output from the dsu communication link transmitter. jtag signals tck ? test clock (input) used to clock serial data into scan latches and control sequence of the test state machine. tck can be asynchronous with clk. tms ? test mode select (input) primary control signal for the state machine. synchronous with tck. a sequence of val- ues on tms adjusts the current state of the tap. tdi ? test data input (input) serial input data to the scan latches. synchronous with tck 13 AT697E 4226as ? aero ? 06/03 tdo ? test data output (output) serial output data from the scan latches. synchronous with tck trst ? test reset (input) resets the test state machine. can be asynchronous with tck pci arbiter areq*[3:0] ? pci bus request (input) when asserted, this active low input indicates that a pci agent is requesting the bus. agnt*[3:0] ? pci bus grant (output) when asserted, this active low output indicates that pci agent is granted the pci bus. pci interface signals pa[31:0] ? pci address data address and data are multiplexed on the same pci pins. during the address phase, ad[31::00] contain a physical address (32 bits). for i/o, this is a byte address; for configuration and memory, it is a dword address. during data phases, ad[07::00] contain the least significant byte and ad[31::24] contain the most significant byte. c/be[3:0]* ? pci bus command and byte enables during the address phase of a transaction, c/be[3::0]# define the bus command. during the data phase, c/be[3::0]# are used as byte enables. the byte enables are valid for the entire data phase. par ? parity the number of "1"s on ad[31::00], c/be[3::0]#, and par equals an even number frame* ? cycle frame it is driven by the current master to indicate the beginning and duration of an access. frame* is asserted to indicate a bus transaction is beginning. while frame* is asserted, data transfers continue. when frame* is deasserted, the transaction is in the final data phase or has completed. 14 AT697E 4226as ? aero ? 06/03 irdy* ? initiator ready irdy* indicates the initiating agent ? s ability to complete the current data phase of the transaction. irdy# is used in conjunction with trdy#. during a write, irdy# indicates that valid data is present on ad[31::00]. during a read, it indicates the master is pre- pared to accept data. trdy* ? target ready trdy* indicates the target agent ? s (selected device ? s) ability to complete the current data phase of the transaction. trdy# is used in conjunction with irdy#. during a read, trdy# indicates that valid data is present on ad[31::00]. during a write, it indicates the target is prepared to accept data. stop* ? stop stop* indicates the current target is requesting the master to stop the current transaction. lock* ? lock lock* indicates an atomic operation to a bridge that may require multiple transactions to complete. idsel ? initialization device select initialization device select is used as a chip select during configuration read and write transactions. devsel* ? device select when actively driven, indicates the driving device has decoded its address as the target of the current access. as an input, devsel* indicates whether any device on the bus has been selected. req* ? pci bus request req* indicates to the arbiter that this agent desires use of the bus. this is a point-to- point signal. every master has its own req* which must be tri-stated while rst* is asserted. gnt* ? pci bus grant gnt* indicates to the agent that access to the bus has been granted. this is a point-to- point signal. every master has its own gnt# which must be ignored while rst# is asserted. 15 AT697E 4226as ? aero ? 06/03 pclk ? pci clock clock provides timing for all transactions on pci and is an input to every pci device. all other pci signals, except rst*, are sampled on the rising edge of clk and all other tim- ing parameters are defined with respect to this edge. rst* ? pci reset reset is used to bring pci-specific registers, sequencers, and signals to a consistent state. perr* ? parity error parity error is only for the reporting of data parity errors during all pci transactions except a special cycle. the perr# pin is sustained tri-state and must be driven active by the agent receiving data two clocks following the data when a data parity error is detected. the minimum duration of perr# is one clock for each data phase that a data parity error is detected. serr* ? system error system error is for reporting address parity errors, data parity errors on the special cycle command, or any other system error where the result will be catastrophic. if an agent does not want a non-maskable interrupt (nmi) to be generated, a different reporting mechanism is required. host ? pci host to be defined. 16 AT697E 4226as ? aero ? 06/03 package description mcga 349 package a a2 a1 e min max min max d/e 24,8 25,2 0,976 0,992 d1/e1 a1 1,4 1,85 0,055 0,073 a2 2,4 3,45 0,094 0,136 a 4,3 5,9 0,169 0,232 b 0,79 0,99 0,031 0,04 e 0,9 0,05 inch 22,86 1,27 mm printed on recycled paper. disclaimer: atmel corporation makes no warranty for the use of its products, other than those expressly contained in the company ? s standard warranty which is detailed in atmel ? s terms and conditions located on the company ? s web site. the company assumes no responsibility for any errors which may appear in this document, reserves the right to change devices or specifications detailed herein at any time wi thout notice, and does not make any commitment to update the information contained herein. no licenses to patents or other intellectual property of atmel are granted by the company in connection with the sale of atmel products, expressly or by implication. atmel ? s products are not authorized for use as critical components in life support devices or systems. atmel corporation atmel operations 2325 orchard parkway san jose, ca 95131 tel: 1(408) 441-0311 fax: 1(408) 487-2600 regional headquarters europe atmel sarl route des arsenaux 41 case postale 80 ch-1705 fribourg switzerland tel: (41) 26-426-5555 fax: (41) 26-426-5500 asia room 1219 chinachem golden plaza 77 mody road tsimshatsui east kowloon hong kong tel: (852) 2721-9778 fax: (852) 2722-1369 japan 9f, tonetsu shinkawa bldg. 1-24-8 shinkawa chuo-ku, tokyo 104-0033 japan tel: (81) 3-3523-3551 fax: (81) 3-3523-7581 memory 2325 orchard parkway san jose, ca 95131 tel: 1(408) 441-0311 fax: 1(408) 436-4314 microcontrollers 2325 orchard parkway san jose, ca 95131 tel: 1(408) 441-0311 fax: 1(408) 436-4314 la chantrerie bp 70602 44306 nantes cedex 3, france tel: (33) 2-40-18-18-18 fax: (33) 2-40-18-19-60 asic/assp/smart cards zone industrielle 13106 rousset cedex, france tel: (33) 4-42-53-60-00 fax: (33) 4-42-53-60-01 1150 east cheyenne mtn. blvd. colorado springs, co 80906 tel: 1(719) 576-3300 fax: 1(719) 540-1759 scottish enterprise technology park maxwell building east kilbride g75 0qr, scotland tel: (44) 1355-803-000 fax: (44) 1355-242-743 rf/automotive theresienstrasse 2 postfach 3535 74025 heilbronn, germany tel: (49) 71-31-67-0 fax: (49) 71-31-67-2340 1150 east cheyenne mtn. blvd. colorado springs, co 80906 tel: 1(719) 576-3300 fax: 1(719) 540-1759 biometrics/imaging/hi-rel mpu/ high speed converters/rf datacom avenue de rochepleine bp 123 38521 saint-egreve cedex, france tel: (33) 4-76-58-30-00 fax: (33) 4-76-58-34-80 e-mail literature@atmel.com web site http://www.atmel.com 4226as ? aero ? 06/03 /xm ? atmel corporation 2003 . all rights reserved. atmel ? and combinations thereof are the registered trademarks of atmel corporation or its subsidiaries. other terms and product names may be the trademarks of others. |
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