preliminary rev. 0.31 8/01 copyright ? 2001 by silicon laboratories si5540-ds031 this information applies to a product under development. its characteristics and specifications are subject to change without n otice. si5540 siphy ? oc-192/stm-64 t ransmitter features complete sonet/sdh transmitter for oc-192/stm-64 data rates with integrated 16:1 multiplexer and dspll ? based clock multiplier unit: applications description the si5540 is a fully integrated low-power transmitter for high-speed serial communication systems. it combines high speed clock generation with a 16:1 multiplexer to serialize data for oc-192/stm-64 applications. the si5540 is based on silicon laboratories? dspll ? technology which eliminates the external loop filter components required by traditional clock multiplier units. in addition, selectable loop filter bandwidths are provided to ensure superior jitter performance while relaxing the jitter requirements on external clock distribution subsystems. support for data streams up to 10.7 gbps is also provided for applications that employ forward error correction (fec). the si5540 represents a new standard in low jitter, low power and small size for 10 gbps serial transmitters. it operates from a single 1.8 v supply over the industrial temperature range (?40 c to 85 c). functional block diagram � data rates supported: oc-192/stm-64, 10gbe, and 10.7 gbps fec � low power operation 0.6 w (typ) � small footprint: 99-pin bga package (11 x 11 mm) � dspll? based clock multiplier unit w/ selectable loop filter bandwidths � oif sfi-4 compliant interface � output clock powerdown � operates with 155 or 622 mhz reference sources � optional 3.3 v supply pin for lvttl compatible outputs � single 1.8 v supply operation � sonet/sdh/atm routers � add/drop multiplexers � digital cross connects � optical transceiver modules � sonet/sdh test equipment txdout txdin[15:0] txclk16out fiforst fifoerr 16:1 mux fifo txclk16in txmsbsel txclkout txsqlch 2 2 2 refclk txlol dspll tm cmu txclkdsbl 2 txclk16in refsel bwsel 2 32 16 refrate bias reset control rext reset ordering information: see page 17. si5364 bottom view p reliminary d ata s heet
si5540 2 preliminary rev. 0.31
si5540 preliminary rev. 0.31 3 t able of c ontents section page electrical specifications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4 functional description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9 dspll? clock multiplier unit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9 reference clock . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9 serialization . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9 reset . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10 clock disable . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10 bias generation circuitry . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10 differential output circuitry . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11 si5540 pinout: 99-pin bga . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12 pin descriptions: si5540 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14 ordering guide . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17 package outline . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 18 contact information . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2 0
si5540 4 preliminary rev. 0.31 electrical specifications figure 1. differential voltage measurement (txdin, txdout, txclk16in, txclk16out) figure 2. data to clock delay figure 3. rise/fall time measurement table 1. recommended operating conditions parameter symbol test condition min* typ max* unit ambient temperature t a ?40 25 85 c lvttl output supply voltage v dd33 1.71 ? 3.47 v si5540 supply voltage v dd 1.71 1.8 1.89 v *note: all minimum and maximum specifications are guaranteed and apply across the recommended operating conditions. typical values apply at nominal supply voltages and an operating temperature of 25 c unless otherwise stated. v is v id ,v od (v id = 2v is ) differential i/os differential voltage swing single ended voltage differential peak-to-peak voltage signal + signal ? (signal +) ? (signal ?) v icm , v ocm v t txdout, txdin txclkout, txclk16in t cp t hd t su t ch all differential ios t f t r 80% 20%
si5540 preliminary rev. 0.31 5 table 2. dc characteristics, v dd = 1.8 v (v dd = 1.8 v 5%, t a = ?40c to 85c) parameter symbol test condition min typ max unit supply current i dd ? 333 tbd ma power dissipation p d ?0.6tbdw common mode output voltage (txdout,txclkout) v ocm .8 0.9 1.0 v differential output voltage swing (txdout,txclkout), differential pk-pk v od see figure 1 800 1000 1200 mv (pk-pk) lvpecl input voltage high (refclk) v ih 1.975 2.3 2.59 v lvpecl input voltage low (refclk) v il 1.32 1.6 1.99 v lvpecl input voltage swing (refclk), differential pk-pk v id 250 ? 2600 mv (pk-pk) lvpecl input common mode (refclk) v icm 1.65 1.95 2.30 v input impedance (refclk, txdin, txclk16in) r in each input to common mode 42 50 58 ? lvds input high voltage (txdin, txclk16in) v ih ??2.4v lvds input low voltage (txdin, txclk16in) v il 0.0 ? ? v lvds input voltage, single ended pk-pk (txdin, txclk16in) v ise 100 ? 600 mv (pk-pk) lvds input common mode voltage (txdin, txclk16in) v icm .8 2.0 2.4 v lvds output high voltage (txclk16out) v oh 100 ? load line-to-line tbd ? 1.475 v lvds output low voltage (txclk16out) v ol 100 ? load line-to-line 0.925 ? tbd v lvds output voltage, single ended pk-pk (txclk16out) v ose 100 ? load line-to-line, see figure 1 250 400 550 mv (pk-pk) lvds output common mode voltage (txclk16out) v ocm 1.125 1.20 1.275 v output short to gnd (txclk16out, txdout, txclkout) i sc? ?25tbdma output short to v dd (txclk16out, txdout, txclkout) i sc+ tbd ?100 ? a lvttl input voltage low (txclkdsbl, fiforst, txsqlch , bwsel, refrate, refsel, txmsbsel, reset ) v il2 ??0.8v
si5540 6 preliminary rev. 0.31 input voltage high (txclkdsbl, fiforst, txsqlch , bwsel, refrate, refsel, txmsbsel, reset ) v ih2 2.0 ? ? v input low current (txclkdsbl, fiforst, txsqlch , bwsel, refrate, refsel, txmsbsel, reset ) i il ??10 a input high current (txclkdsbl, fiforst, txsqlch , bwsel, refrate, refsel, txmsbsel, reset ) i ih ??10 a input impedance (txclkdsbl, fiforst, txsqlch , bwsel, refrate, refsel, txmsbsel, reset ) r in 10 ? ? k ? lvttl output voltage low (fifoerr, txlol ) v ol2 vdd33 = 1.8 v ? ? 0.4 v vdd33 = 3.3 v ? ? 0.4 lvttl output voltage high (fifoerr, txlol ) v oh2 vdd33 = 1.8 v 1.4 ? ? v vdd33 = 3.3 v 2.4 ? ? table 2. dc characteristics, v dd = 1.8 v (continued) (v dd = 1.8 v 5%, t a = ?40c to 85c) parameter symbol test condition min typ max unit
si5540 preliminary rev. 0.31 7 table 3. ac characteristics (txclk16out, txclk16in, txclkout, txdin, txdout) (v dd = 1.8 v 5%, t a = ?40c to 85c) parameter symbol test condition min typ max unit txclkout frequency f clkout ? 9.95 10.7 ghz txclkout duty cycle tch/tcp, figure 2 45 ? 55 % output rise time (txclkout, txdout) t r figure 3 ? 25 ? ps output fall time (txclkout, txdout) t f figure 3 ? 25 ? ps txclkout setup to txdout t su figure 2 25 ? ? ps txclkout hold from txdout t hd figure 2 25 ? ? ps output return loss 400 khz?10 ghz 10 ghz?16 ghz tbd tbd ? ? ? ? db db txclk16out frequency f clkin figure 2 ? 622 667 mhz txclk16out duty cycle tch/tcp, figure 2 40 ? 60 % txclk16out rise & fall times t r , t f 100 ? 300 ps txdin setup to txclk16in t dsin ? ? 300 ps txdin hold from txclk16in t dhin ? ? 300 ps txclk16in frequency f clkin ? 622 667 mhz txclk16in duty cycle tch/tcp, figure 2 40 ? 60 % txclk16in rise & fall times t r , t f 100 ? 300 ps table 4. ac characteristics (clock multiplier characteristics) (v dd = 1.8 v 5%, t a = ?40c to 85c) parameter symbol test condition min typ max unit jitter generation?deterministic j det(pp) prbs-23 ? 0.020 tbd ui pp jitter generation?random j gen(rms) ?0.005tbdui rms jitter transfer bandwidth j bw bwsel = 0 ? ? 12 khz bwsel = 1 ? ? 50 khz jitter transfer peaking ? 0.05 0.1 db acquisition time t aq valid refclk ? 15 20 ms input reference clock frequency rc freq refrate = 1 ? 622 667 mhz refrate = 0 ? 155 167 mhz input reference clock duty cycle rc duty 40 ? 60 % input reference clock frequency tolerance rc tol ?100 ? 100 ppm note: bellcore specifications: gr-1377-core, issue 5, december 1998.
si5540 8 preliminary rev. 0.31 table 5. absolute maximum ratings parameter symbol value unit dc supply voltage v dd ?0.5 to 3.0 v lvttl input voltage v dd33 ?0.5 to 3.6 v differential input voltages v dif ?0.3 to (v dd + 0.3) v maximum current any output pin 50 ma operating junction temperature t jct ?55 to 150 c storage temperature range t stg ?55 to 150 c package temperature (soldering 10 seconds) 275 c esd hbm tolerance (100 pf, 1.5 k ? )tbdv note: permanent device damage may occur if the above absolute maximum ratings are exceeded. functional operation should be restricted to the conditions as specified in the operational sections of this data sheet. exposure to absolute maximum rating conditions for extended periods may affect device reliab ility. table 6. thermal characteristics parameter symbol test condition value unit thermal resistance junction to ambient ? ja still air 35 c/w
si5540 preliminary rev. 0.31 9 functional description the si5540 is a fully integrated, low power, sonet/ sdh transmitter for oc-192/stm-64 applications. it combines a high performance clock multiplier unit (cmu) with a 16:1 serializer that has a low-speed interface compliant with the optical interface forum (oif) sfi-4 standard. the cmu uses a phase-locked loop (pll) architecture based on silicon laboratories? proprietary dspll ? technology. this technology is used to generate ultra- low jitter clock and data outputs that provide significant margin to the sonet/sdh specifications. the dspll architecture also utilizes a digitally implemented loop filter that eliminates the need for external loop filter components. as a result, sensitive noise coupling nodes that typically cause degraded jitter performance in crowded pcb environments are removed. the dspll also reduces the complexity and performance requirements of reference clock distribution strategies for oc-192/stm-64 optical port cards. this is possible because the dspll provides selectable wideband and narrowband loop filter settings that allow the user to set the jitter attenuation characteristics of the cmu to accommodate reference clock sources that have a high jitter content. unlike traditional analog pll implementations, the loop filter bandwidth is controlled by a digital filter inside the dspll and can be changed without any modification to external components. dspll ? clock multiplier unit the si5540?s clock multiplier unit (cmu) uses silicon laboratories? proprietary dspll technology to generate a low jitter, high frequency clock source capable of producing a high speed serial clock and data output with significant margin to the sonet/sdh specifications. this is achieved by using a digital signal processing (dsp) algorithm to replace the loop filter commonly found in analog pll designs. this algorithm processes the phase detector error term and generates a digital control value to adjust the frequency of the voltage controlled oscillator (vco). because external loop filter components are not required, sensitive noise entry points are eliminated, thus making the dspll less susceptible to board-level noise sources. therefore, sonet/sdh jitter compliance is easier to attain in the application. programmable loop filter bandwidth the digital loop filter in the si5530 provides two bandwidth settings that support either wideband or narrowband jitter transfer characteristics. the filter bandwidth is selected via the bwsel control input. in traditional pll implementations, changing the loop filter bandwidth would require changing the values of external loop filter components. in narrowband mode, a loop filter cutoff of 12 khz is provided. this setting makes the si5540 more tolerant of jitter on the reference clock source. as a result, the complexity of the clock distribution circuitry used to generate the physical layer reference clocks can be simplified without compromising jitter margin to the sonet/sdh specification. in wideband mode, the loop filter provides a cutoff of 50 khz. this setting is desirable in applications where the reference clock is provided by a low jitter source like the si5364 clock synchronization ic or si5320 precision clock multiplier/jitter attenuator ic. this allows the dspll to more closely track the precision reference source resulting in the best possible jitter performance. reference clock the cmu within the si5530 is designed to operate with reference clock sources that are either 1/16th or 1/64th the desired output data rate. the cmu will support operation with data rates between 9.9 gbps and 10.7 gbps and the reference clock should be scaled accordingly. for example, to support 10.66 gbps operation the reference clock source would be approximately 167 mhz or 666 mhz. the refrate input pin is used to configure the device for operation with one of the two supported reference clock submultiples of the data rate. the si5540 supports operation with two selectable reference clock sources. the first configuration uses an externally provided reference clock that is input via refclk. the second configuration uses the parallel data clock, txclk16in, as the reference clock source. when using txclk16in as the reference source, the narrowband loop filter setting may be preferable to remove jitter that may be present on the data clock. the selection of reference clock configuration is controlled via the refsel input. the si5540 will drive the txlol output high to indicate the dspll has locked to the selected reference source. serialization the si5540 includes serialization circuitry that combines a fifo with a parallel to serial shift register. low speed data on the parallel input bus, txdin[15:0], is latched into the fifo on the rising edge of txclk16in. the data in the fifo is clocked into the
si5540 10 preliminary rev. 0.31 shift register by an output clock, txclk16out, that is produced by dividing down the high speed transmit clock, txclkout, by a factor of 16. the txclk16out clock output is provided to support 16 bit word transfers between the si5540 and upstream devices using a counter clocking scheme. the high-speed serial data stream is clocked out of the shift register using txclkout. input fifo the si5540 integrates a fifo to decouple data transferred into the fifo via txclk16in from data transferred into the shift register via txclk16out. the fifo is eight parallel words deep and accommodates any static phase delay that may be introduced between txclk16out and txclk16in in counter clocking schemes. further, the fifo will accommodate a phase drift or wander between txclk16in and txclk16out of up to three parallel data words. the fifo circuitry indicates an overflow or underflow condition by asserting fifoerr high. this output can be used to recenter the fifo read/write pointers by tieing it directly to the fiforst input. the si5540 will also recenter the read/write pointers after the device?s power on reset, external reset via reset , and each time the dspll transitions from an out of lock state to a locked state (txlol transitions from low to high). parallel input to serial output relationship the si5540 provides the capability to select the order in which data on the parallel input bus is transmitted seri- ally. data on this bus can be transmitted msb first or lsb first depending on the setting of txmsbsel. if txmsbsel is tied low, txdin0 is transmitted first fol- lowed in order by txdin1 through txdin15. if txmsb- sel is tied high, txdin15 is transmitted first followed in order by txdin14 through txdin0. this feature simpli- fies board routing when ics are mounted on both sides of the pcb. transmit data squelch to prevent the transmission of corrupted data into the network, the si5540 provides a control pin that can be used to force the high speed data output, txdout, to 0. by driving txsqlch low txdout will be forced to 0. reset a device reset can be forced by holding the reset pin low for at least 1 s. when reset is asserted low, the input fifo pointers reset and the digital control circuitry initializes. when reset transitions high to start normal operation, the dspll will be calibrated. clock disable the si5540 provides a clock disable pin, txclkdsbl, that is used to disable the high-speed serial data clock output, txclkout. when the txclkdsbl pin is asserted, the positive and negative terminals of clk- out are tied to 1.5 v through 50 ? on-chip resistors. this feature is used to reduce power consumption in applications that do not use the high speed transmit data clock. bias generation circuitry the si5540 makes use of an external resistor to set internal bias currents. the external resistor allows pre- cise generation of bias currents which significantly reduces power consumption versus traditional imple- mentations that use an internal resistor. the bias gener- ation circuitry requires a 3.09 k ? (1%) resistor connected between rext and gnd.
si5540 preliminary rev. 0.31 11 differential output circuitry the si5540 utilizes a current-mode logic (cml) architecture to drive the high speed serial output clock and data on txclkout and txdout. an example of output termination with ac coupling is shown in figure 4. in applications where direct dc coupling is possible, the 250 nf capacitors may be omitted. the differential peak-to-peak voltage swing of the cml architecture is listed in table 2 on page 5. figure 4. cml output driver termination (txclkout, txdout) 1.5 v 50 ? 50 ? 24 ma zo = 50 ? zo = 50 ? 50 ? 50 ? vdd vdd 250 nf 250 nf
si5540 12 preliminary rev. 0.31 si5540 pinout: 99 bga figure 5. si5540 pin configuration (bottom view) bottom view txdin[12]? txdin[12]+ txdin[14]? txdin[14]+ refclk? refclk+ txsqlch rsvd_ vdd33 refrate txdin[10]+ txdin[11]+ txdin[13]? txdin[13]+ txdin[15]? txdin[15]+ txclkdsbl refsel rsvd_ vdd33 gnd txdin[10]? txdin[11]? gnd gnd gnd gnd reset vdd33 gnd txclkout+ txdin[8]+ txdin[9]+ gnd vdd vdd vdd vdd rsvd_ gnd gnd txclkout? txdin[8]? txdin[9]? gnd vdd vdd vdd vdd rsvd_ gnd gnd gnd txdin[6]+ txdin[7]+ gnd vdd vdd vdd vdd rsvd_ gnd gnd txdout+ txdin[6]? txdin[7]? gnd vdd vdd vdd vdd rsvd_ gnd gnd txdout? txdin[4]+ txdin[5]+ gnd gnd gnd gnd gnd bwsel nc gnd txdin[4]? txdin[5]? txdin[3]+ txdin[3]? txdin[1]+ txdin[1]? txmsbsel rsvd_ gnd txlol rext txdin[2]? txdin[0]+ txdin[0]? txclk16 in+ txclk16 in? txclk16 out+ txclk16 out? fiforst fifoerr txdin[2]+ 10 1 2 3 4 5 6 7 8 9 a k j g h f e d c b
si5540 preliminary rev. 0.31 13 figure 6. si5540 pin configuration (transparent top view) top view txdin[12]? txdin[12]+ txdin[14]? txdin[14]+ refclk- refclk+ txsqlch rsvd_ vdd33 refrate txdin[10]? txdin[8]+ txdin[9]+ txdin[8]? txdin[9]? gnd txdin[6]+ txdin[7]+ gnd vdd txdin[6]? txdin[7]? gnd vdd txdin[4]+ txdin[5]+ gnd gnd txdin[4]? txdin[5]? txdin[3]+ txdin[3]? txdin[1]+ txdin[1]? txdin[2]? txdin[0]+ txdin[0]? txclk16 in+ txclk16 in? txclk16 out+ txclk16 out? fiforst fifoerr txdin[2]+ 10 123456789 a k gnd gnd vdd txmsbsel rsvd_ gnd txlol rext j gnd bwsel nc gnd h vdd vdd rsvd_ gnd gnd txdout? g vdd vdd vdd rsvd_ gnd gnd txdout+ f vdd vdd vdd rsvd_ gnd gnd gnd e vdd gnd vdd vdd vdd vdd rsvd_ gnd gnd txclkout? d gnd gnd gnd gnd reset vdd33 gnd txclkout+ c txdin[11]? txdin[10]+ txdin[11]+ txdin[13]? txdin[13]+ txdin[15]? txdin[15]+ txclkdsbl refsel rsvd_ vdd33 gnd b
si5540 14 preliminary rev. 0.31 pin descriptions: si5540 pin number(s) pin name i/o signal level description h3 bwsel i lvttl bandwidth select dspll. this input selects loop bandwidth of the dspll. bwsel = 0: loop bandwidth set to 12 khz bwsel = 1: loop bandwidth set to 50 khz. k1 fifoerr o lvttl fifo error. this output is driven high when a fifo over- flow/underflow has occurred. this output will stick high until reset by asserting fiforst. k2 fiforst i lvttl fifo reset. this input, when asserted high, resets the read/ write fifo pointers to their initial state. b1, c5?8, c2, d8, d2, e8, e1?2, f8, f2, g8, g2, h4? 8, h1 gnd gnd gnd. h2 nc ? no connect. reserved for device testing; leave electrically unconnected. a5?6 refclk+, refclk? i lvpecl differential reference clock. the reference clock sets the operating fre- quency of the pll used to generate the output clock frequency. the si5540 will operate with reference clock frequencies that are either 1/ 16th or 1/64th the output clock rate. a2 refrate i lvttl reference frequency select. this input configures the cmu to operate with one of two possible reference clock frequen- cies. when refrate = 1, the cmu will oper- ate with a reference that is 1/16th the output clock rate. when refrate = 0, the cmu will operate with a reference that is 1/64th the out- put clock rate. b3 refsel i lvttl reference clock selection. this inputs selects the reference clock source used by the cmu. when refsel = 0, the low speed data input clock, txclk16in, is used as the cmu reference. when refsel = 1, the ref- erence clock provided on refclk is used. c4 reset ilvttl device reset. forcing this input low for at least 1 s will cause a device reset. for normal operation, this pin should be held high.
si5540 preliminary rev. 0.31 15 j1 rext external bias resistor. this resistor is used by onboard circuitry to establish bias currents within the device. this pin must be connected to gnd through a 3.09 k ? ( 1 %) resistor. d3, e3, f3, g3, j3 rsvd_gnd ? reserved tie to ground. must tie directly to gnd for proper operation. a3, b2 rsvd_vdd33 ? reserved tie to vdd33. must tie directly to vdd33 for proper operation. k5?6 txclk16in?, txclk16in+ ilvds differential data clock input. the rising edge of this in put clocks data present on txdin into the device. k3?4 txclk16out+, txclk16out? olvds divided down output clock. this clock output is generated by dividing down the high speed output clock, txclkout, by a factor of 16. it is intended for use in counter clocking schemes that transfer data between the system asic and the si5540. b4 txclkdsbl i lvttl high speed clock disable. when this input is high, the output driver for txclkout is disabled. in applications that do not require the output data clock, the output clock driver should be disabled to save power. c1, d1 txclkout+, txclkout? ocml high speed clock output. the high speed output clock, txclkout, is generated by the pll in the clock multiplier unit. it?s frequency is nominally 16 or 64 times the selected reference source. a7?10, b5?10, c9?10, d9?10, e9?10, f9?10, g9?10, h9?10, j5?10, k7?10 txdin[15:0]?, txdin[15:0]+ ilvds differential parallel data input. the 16-bit data word present on these pins is multiplexed into a high speed serial stream and output on txdout. the data on these inputs is clocked into the device by the rising edge of txclkin. f1, g1 txdout+, txdout? ocml differential high speed data output. the 16-bit word input on txdin[15:0] is multi- plexed into a high speed serial stream that is output on these pins. this output is updated by the rising edge of txclkout. j2 txlol olvttl cmu loss-of-lock. the output is asserted low when the cmu is not phase locked to the selected reference source. pin number(s) pin name i/o signal level description
si5540 16 preliminary rev. 0.31 j4 txmsbsel i lvttl data bus transmit order. for txmsbsel = 0, data on txdin[0] is trans- mitted first followed by txdin[1] through txdin[15]. for txmsbsel = 1, txdin[15] is transmitted first followed by txdin[14] through txdin[0]. a4 txsqlch ilvttl transmit data squelch. if txsqlch is asserted low, the output data stream on txdout will be forced to 0. if txsqlch = 1, tx squelching is turned off. d4?7, e4?7, f4?7, g4?7, vdd vdd 1.8 v supply voltage. nominally 1.8 v. c3 vdd33 vdd33 1.8 v or 3.3 v digital output supply. must be tied to either 1.8 v or 3.3 v. when tied to 3.3 v, lvttl compatible output voltage swings on txlol and fifoerr are sup- ported. pin number(s) pin name i/o signal level description
si5540 preliminary rev. 0.31 17 ordering guide table 7. ordering guide part number package temperature si5540-bc 99 bga ?40c to 85c
si5540 18 preliminary rev. 0.31 package outline figure 7 illustrates the package details for the si5540. table 8 lists the values for the dimensions shown in the illustration. figure 7. 99-ball grid array (bga) table 8. package diagram dimensions symbol millimeters min nom max a 1.30 1.40 1.50 a1 0.31 0.36 0.41 a2 0.65 0.70 0.75 b ? 0.46 ? d?11.00? e?11.00? e ? 1.00 ? d e 10987654321 a b c d e f g h j k a1 ball pad corner a1 ball pad corner seating plane a a1 a2 e bottom view top view side view 1.00 ref 1.00 ref b e
si5540 preliminary rev. 0.31 19 n otes :
si5540 20 preliminary rev. 0.31 contact information silicon laboratories inc. 4635 boston lane austin, tx 78735 tel: 1+(512) 416-8500 fax: 1+(512) 416-9669 toll free: 1+(877) 444-3032 email: productinfo@silabs.com internet: www.silabs.com silicon laboratories, silicon labs, siphy, and dspll are trademarks of silicon laboratories inc. other products or brandnames mentioned herein are trademarks or registered trademarks of their respective holders. the information in this document is believed to be accurate in all respects at the time of publication but is subject to change without notice. silicon laboratories assumes no responsibility for errors and omissions, and disclaims responsibility for any consequences resu lting from the use of information included herein. additionally, silicon laboratories assumes no responsibility for the functioning of und escribed features or parameters. silicon laboratories reserves the right to make changes without further notice. silicon laboratories makes no wa rranty, rep- resentation or guarantee regarding the suitability of its products for any particular purpose, nor does silicon laboratories as sume any liability arising out of the application or use of any product or circuit, and specifically disclaims any and all liability, including wi thout limitation conse- quential or incidental damages. silicon laboratories products are not designed, intended, or authorized for use in applications intended to support or sustain life, or for any other application in which the failure of the silicon laboratories product could create a s ituation where per- sonal injury or death may occur. should buyer purchase or use silicon laboratories products for any such unintended or unauthor ized ap- plication, buyer shall indemnify and hold silicon laboratories harmless against all claims and damages.
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