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1 november 2003 IDT72V3654 idt72v3664 idt72v3674 3.3 volt cmos syncbififo tm with bus-matching 2,048 x 36 x 2 4,096 x 36 x 2 8,192 x 36 x 2 idt and the idt logo are registered trademarks of integrated device technology, inc. the syncfifo is a trademark of integrated device technology, inc. commercial temperature range ? 2003 integrated device technology, inc. all rights reserved. product specifications subject to change without notice. dsc-4664/4 functional block diagram features ? ? ? ? ? memory storage capacity: IDT72V3654 ? 2,048 x 36 x 2 idt72v3664 ? 4,096 x 36 x 2 idt72v3674 ? 8,192 x 36 x 2 ? ? ? ? ? clock frequencies up to 100 mhz (6.5ns access time) ? ? ? ? ? two independent clocked fifos buffering data in opposite directions ? ? ? ? ? select idt standard timing (using efa , efb , ffa , and ffb flags functions) or first word fall through timing (using ora, orb, ira, and irb flag functions) ? ? ? ? ? programmable almost-empty and almost-full flags; each has five default offsets (8, 16, 64, 256 and 1,024 ) ? ? ? ? ? serial or parallel programming of partial flags ? ? ? ? ? port b bus sizing of 36 bits (long word), 18 bits (word) and 9 bits (byte) ? ? ? ? ? big- or little-endian format for word and byte bus sizes ? ? ? ? ? retransmit capability ? ? ? ? ? master reset clears data and configures fifo, partial reset clears data but retains configuration settings ? ? ? ? ? mailbox bypass registers for each fifo ? ? ? ? ? free-running clka and clkb may be asynchronous or coincident (simultaneous reading and writing of data on a single clock edge is permitted) ? ? ? ? ? auto power down minimizes power dissipation ? ? ? ? ? available in space saving 128-pin thin quad flatpack (tqfp) ? ? ? ? ? pin and functionally compatible version of the 5v operating idt723654/723664/723674 ? ? ? ? ? pin compatible to the lower density parts, idt72v3624/72v3634/ 72v3644 ? ? ? ? ? industrial temperature range (?40 c to +85 c) is available mail 1 register programmable flag offset registers input register ram array 2,048 x 36 4,096 x 36 8,192 x 36 write pointer read pointer status flag logic input register output register ram array 2,048 x 36 4,096 x 36 8,192 x 36 write pointer read pointer status flag logic clka csa w/ r a ena mba port-a control logic fifo1, mail1 reset logic mrs1 mail 2 register mbf2 clkb csb w /rb enb mbb be bm size port-b control logic fifo2, mail2 reset logic mrs2 mbf1 fifo1 fifo2 13 efb /orb aeb 36 36 ffb /irb afb b 0 -b 35 ffa /ira afa fs2 fs0/sd fs1/ sen a 0 -a 35 efa /ora aea 4664 drw01 36 36 output bus- matching output register prs2 prs1 timing mode fwft 36 36 36 36 input bus- matching fifo1 and fifo2 retransmit logic rt1 rt2 rtm
2 commercial temperature range IDT72V3654/72v3664/72v3674 3.3v cmos syncbififo tm with bus-matching 2,048 x 36 x 2, 4,096 x 36 x 2 and 8,192 x 36 x 2 pin configuration tqfp (pk128-1, order code: pf) top view w/ r a clkb 4664 drw 02 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 ena clka gnd a35 a34 a33 a32 vcc a31 a30 gnd a29 a28 a27 a26 a25 a24 a23 be/ fwft gnd a22 vcc a21 a20 a19 a18 gnd a17 a16 a15 a14 a13 vcc a12 gnd a11 a10 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 64 65 66 67 68 69 70 71 72 73 74 75 76 77 78 79 80 81 82 83 84 85 86 87 88 89 90 91 92 93 94 95 96 97 98 99 100 102 101 128 127 126 125 124 123 122 121 120 119 118 117 116 115 114 113 112 111 110 109 108 107 106 105 prs2 / rt2 vcc b35 b34 b33 b32 rtm gnd b31 b30 b29 b28 b27 b26 vcc b25 b24 bm gnd b23 b22 b21 b20 b19 b18 gnd b17 b16 vcc b15 b14 b13 b12 gnd b11 b10 csa ffa /ira efa /ora prs1 / rt1 vcc afa aea mbf2 mba mrs1 fs0/sd gnd gnd fs1/ sen mrs2 mbb mbf1 vcc aeb afb efb /orb ffb /irb gnd csb w /rb enb a9 a8 a7 a6 gnd a5 a4 a3 vcc a2 a1 a0 gnd b0 b1 b2 b3 b4 b5 gnd b6 vcc b7 b8 b9 104 103 index size fs2 description the IDT72V3654/72v3664/72v3674 are pin and functionally compat- ible versions of the idt723654/723664/723674, designed to run off a 3.3v supply for exceptionally low-power consumption. these devices are mono- lithic, high-speed, low-power, cmos bidirectional synchronous (clocked) fifo memory which supports clock frequencies up to 100 mhz and has read access times as fast as 6.5ns. two independent 2,048/4,096/8,192 x 36 dual- port sram fifos on board each chip buffer data in opposite directions. fifo data on port b can be input and output in 36-bit, 18-bit, or 9-bit formats with a choice of big- or little-endian configurations. these devices are a synchronous (clocked) fifo, meaning each port employs a synchronous interface. all data transfers through a port are gated to the low-to-high transition of a port clock by enable signals. the clocks for each port are independent of one another and can be asynchronous or 3 commercial temperature range IDT72V3654/72v3664/72v3674 3.3v cmos syncbififo tm with bus-matching 2,048 x 36 x 2, 4,096 x 36 x 2 and 8,192 x 36 x 2 coincident. the enables for each port are arranged to provide a simple bidirectional interface between microprocessors and/or buses with synchro- nous control. communication between each port may bypass the fifos via two mailbox registers. the mailbox registers? width matches the selected port b bus width. each mailbox register has a flag ( mbf1 and mbf2 ) to signal when new mail has been stored. two kinds of reset are available on these fifos: master reset and partial reset. master reset initializes the read and write pointers to the first location of the memory array, configures the fifo for big- or little-endian byte arrangement and selects serial flag programming, parallel flag programming, or one of five possible default flag offset settings, 8, 16, 64, 256 or 1,024. there are two master reset pins, mrs1 and mrs2 . partial reset also sets the read and write pointers to the first location of the memory. unlike master reset, any settings existing prior to partial reset (i.e., programming method and partial flag default offsets) are retained. partial reset is useful since it permits flushing of the fifo memory without changing any configuration settings. each fifo has its own, independent partial reset pin, prs1 and prs2 . both fifo's have retramsmit capability, when a retransmit is performed on a respective fifo only the read pointer is reset to the first memory location. a retransmit is performed by using the retransmit mode, rtm pin in conjunction with the retransmit pins rt1 or rt2, for each respective fifo. note that the two retransmit pins rt1 and rt2 are muxed with the partial reset pins. these devices have two modes of operation: in the idt standard mode , the first word written to an empty fifo is deposited into the memory array. a read operation is required to access that word (along with all other words residing in memory). in the first word fall through mode (fwft), the first word written to an empty fifo appears automatically on the outputs, no read operation required (nevertheless, accessing subsequent words does neces- sitate a formal read request). the state of the be/ fwft pin during master reset determines the mode in use. these devices have two modes of operation: in the idt standard mode , the first word written to an empty fifo is deposited into the memory array. a read operation is required to access that word (along with all other words residing in memory). in the first word fall through mode (fwft), the first long- word (36-bit wide) written to an empty fifo appears automatically on the outputs, no read operation is required (nevertheless, accessing subsequent words does necessitate a formal read request). the state of the be/ fwft pin during fifo operation determines the mode in use. each fifo has a combined empty/output ready flag ( efa /ora and efb /orb) and a combined full/input ready flag ( ffa /ira and ffb / irb). the ef and ff functions are selected in the idt standard mode. ef indicates whether or not the fifo memory is empty. ff shows whether the memory is full or not. the ir and or functions are selected in the first word fall through mode. ir indicates whether or not the fifo has available memory locations. or shows whether the fifo has data available for reading or not. it marks the presence of valid data on the outputs. each fifo has a programmable almost-empty flag ( aea and aeb ) and a programmable almost-full flag ( afa and afb ). aea and aeb indicate when a selected number of words remain in the fifo memory. afa and afb indicate when the fifo contains more than a selected number of words. ffa /ira, ffb /irb, afa and afb are two-stage synchronized to the port clock that writes data into its array. efa /ora, efb /orb, aea and aeb are two-stage synchronized to the port clock that reads data from its array. programmable offsets for aea , aeb , afa and afb are loaded in parallel using port a or in serial via the sd input. five default offset settings are also provided. the aea and aeb threshold can be set at 8, 16, 64, 256 or 1,024 locations from the empty boundary and the afa and afb threshold can be set at 8, 16, 64, 256 or 1,024 locations from the full boundary. all these choices are made using the fs0, fs1 and fs2 inputs during master reset. interspersed parity can also be selected during a master reset of the fifo. if interspersed parity is selected then during parallel programming of the flag offset values, the device will ignore data line a8. if non-interspersed parity is selected then data line a8 will become a valid bit. two or more devices may be used in parallel to create wider data paths. if, at any time, the fifo is not actively performing a function, the chip will automatically power down. during the power down state, supply current consumption (i cc ) is at a minimum. initiating any operation (by activating control inputs) will immediately take the device out of the power down state. the IDT72V3654/72v3664/72v3674 are characterized for operation from 0 c to 70 c. industrial temperature range (-40 c to +85 c) is available. they are fabricated using idt?s high speed, submicron cmos technology. 4 commercial temperature range IDT72V3654/72v3664/72v3674 3.3v cmos syncbififo tm with bus-matching 2,048 x 36 x 2, 4,096 x 36 x 2 and 8,192 x 36 x 2 pin descriptions symbol name i/o description a0-a35 port a data i/o 36-bit bidirectional data port for side a. aea port a almost- o programmable almost-empty flag synchronized to clka. it is low when the number of words in empty flag fifo2 is less than or equal to the value in the almost-empty a offset register, x2. aeb port b almost- o programmable almost-empty flag synchronized to clkb. it is low when the number of words in empty flag fifo1 is less than or equal to the value in the almost-empty b offset register, x1. afa port a almost- o programmable almost-full flag synchronized to clka. it is low when the number of empty full flag locations in fifo1 is less than or equal to the value in the almost-full a offset register, y1. afb port b almost- o programmable almost-full flag synchronized to clkb. it is low when the number of empty full flag locations in fifo2 is less than or equal to the value in the almost-full b offset register, y2. b0-b35 port a data i/o 36-bit bidirectional data port for side b. be/ fwft big-endian/ i this is a dual purpose pin. during master reset, a high on be will select big endian operation. first word in this case, depending on the bus size, the most significant byte or word on port a is read from fall through port b first (a-to-b data flow) or written to port b first (b-to-a data flow). a low on be will select select little-endian operation. in this case, the least significant byte or word on port a is read from port b first (for a-to-b data flow) or written to port b first (b-to-a data flow). after master reset, this pin selects the timing mode. a high on fwft selects idt standard mode, a low selects first word fall through mode. once the timing mode has been selected, the level on fwft must be static throughout device operation. bm (1) bus-match select i a high on this pin enables either byte or word bus width on port b, depending on the state of (port b) size. a low selects long word operation. bm works with size and be to select the bus size and endian arrangement for port b. the level of bm must be static throughout device operation. clka port a clock i clka is a continuous clock that synchronizes all data transfers through port a and can be asynchronous or coincident to clkb. ffa /ira, efa /ora, afa , and aea are all synchronized to the low-to-high transition of clka. clkb port b clock i clkb is a continuous clock that synchronizes all data transfers through port b and can be asynchronous or coincident to clka. ffb /irb, efb /orb, afb , and aeb are synchronized to the low-to-high transition of clkb. csa port a chip select i csa must be low to enable to low-to-high transition of clka to read or write on port a. the a0-a35 outputs are in the high-impedance state when csa is high. csb port b chip select i csb must be low to enable a low-to-high transition of clkb to read or write data on port b. the b0-b35 outputs are in the high-impedance state when csb is high. efa /ora port a empty/ o this is a dual function pin. in the idt standard mode, the efa function is selected. efa output ready flag indicates whether or not the fifo2 memory is empty. in the fwft mode, the ora function is selected. ora indicates the presence of valid data on a0-a35 outputs, available for reading. efa /ora is synchronized to the low-to-high transition of clka. efb /orb port b empty/ o this is a dual function pin. in the idt standard mode, the efb function is selected. efb indicates output ready flag whether or not the fifo1 memory is empty. in the fwft mode, the orb function is selected. orb indicates the presence of valid data on the b0-b35 outputs, available for reading. efb /orb is synchronized to the low-to-high transition of clkb. ena port a enable i ena must be high to enable a low-to-high transition of clka to read or write data on port a. enb port b enable i enb must be high to enable a low-to-high transition of clkb to read or write data on port b. ffa /ira port a full/ o this is a dual function pin. in the idt standard mode, the ffa function is selected. ffa indicates input ready flag whether or not the fifo1 memory is full. in the fwft mode, the ira function is selected. ira indicates whether or not there is space available for writing to the fifo1 memory. ffa /ira is synchronized to the low-to-high transition of clka. ffb /irb port b full/ o this is a dual function pin. in the idt standard mode, the ffb function is selected. ffb indicates input ready flag whether or not the fifo2 memory is full. in the fwft mode, the irb function is selected. irb indicates whether or not there is space available for writing to the fifo2 memory. ffb /irb is synchronized to the low-to-high transition of clkb. 5 commercial temperature range IDT72V3654/72v3664/72v3674 3.3v cmos syncbififo tm with bus-matching 2,048 x 36 x 2, 4,096 x 36 x 2 and 8,192 x 36 x 2 symbol name i/o description fs0/sd flag offset select 0/ i fs1/ sen and fs0/sd are dual-purpose inputs used for flag offset register programming. during serial data master reset, fs1/ sen and fs0/sd, together with fs2, select the flag offset programming method three offset register programming methods are available: automatically load one of five preset values (8, 16, 64, 256 or 1,024), parallel load from port a, and serial load. fs1/ sen flag offset select 1/ i serial enable, when serial load is selected for flag offset register programming, fs1/ sen is used as an enable synchronous to the low-to-high transition of clka. when fs1/ sen is low, a rising edge on clka fs2 (1) flag offset select 2 i load the bit present on fs0/sd into the x and y registers. the number of bit writes required to program the offset registers is 44 for the IDT72V3654, 48 for the idt72v3664, and 52 for the idt72v3674. the first bit write stores the y-register (y1) msb and the last bit write stores the x-register (x2) lsb. mba port a mailbox i a high level on mba chooses a mailbox register for a port a read or write operation. when select the a0-a35 outputs are active, a high level on mba selects data from the mail2 register for output and a low level selects fifo2 output register data for output. mbb port b mailbox i a high level on mbb chooses a mailbox register for a port b read or write operation. when the select b0-b35 outputs are active, a high level on mbb selects data from the mail1 register for output and a low level selects fifo1 output register data for output. mbf1 mail1 register o mbf1 is set low by a low-to-high transition of clka that writes data to the mail1 register. flag writes to the mail1 register are inhibited while mbf1 is low. mbf1 is set high by a low-to-high transition of clkb when a port b read is selected and mbb is high. mbf1 is set high following either a master or partial reset of fifo1. mbf2 mail2 register o mbf2 is set low by a low-to-high transition of clkb that writes data to the mail2 register. writes flag to the mail2 register are inhibited while mbf2 is low. mbf2 is set high by a low-to-high transition of clka when a port a read is selected and mba is high. mbf2 is set high following either a master or partial reset of fifo2. mrs1 fifo1 master i a low on this pin initializes the fifo1 read and write pointers to the first location of memory and sets the reset port b output register to all zeroes. a low-to-high transition on mrs1 selects the programming method (serial or parallel) and one of five programmable flag default offsets for fifo1 and fifo2. it also configures port b for bus size and endian arrangement. four low-to-high transitions of clka and four low-to-high transitions of clkb must occur while mrs1 is low. mrs2 fifo2 master i a low on this pin initializes the fifo2 read and write pointers to the first location of memory and sets reset the port a output register to all zeroes. a low-to-high transition on mrs2 , toggled simultaneously with mrs1 , selects the programming method (serial or parallel) and one of the programmable flag default offsets for fifo2. four low-to-high transitions of clka and four low-to-high transitions of clkb must occur while mrs2 is low. prs1 / partial reset/ i this pin is muxed for both partial reset and retransmit operations, it is used in conjunction with the rtm rt1 retransmit fifo1 pin. if rtm is in a low condition, a low on this pin performs a partial reset on fifo1 and initializes the fifo1 read and write pointers to the first location of memory and sets the port b output register to all zeroes. during partial reset, the currently selected bus size, endian arrangement, programming method (serial or parallel), and programmable flag settings are all retained. if rtm is high, a low on this pin performs a retransmit and initializes the fifo1 read pointer only to the first memory location. prs2 / partial reset/ i this pin is muxed for both partial reset and retransmit operations, it is used in conjunction with the rtm rt2 retransmit fifo2 pin. if rtm is in a low condition, a low on this pin performs a partial reset on fifo2 and initializes the fifo2 read and write selected bus size, endian arrangement, programming method (serial or parallel), and programmable flag settings are all retained. if rtm is high, a low on this pin performs a retransmit and initializes the fifo2 read pointer only to the first memory location. rtm retransmit mode i this pin is used in conjunction with the rt1 and rt2 pins. when rtm is high a retransmit is performed on fifo1 or fifo2 respectively. size (1) bus size select i a high on this pin when bm is high selects byte bus (9-bit) size on port b. a low on this pin when bm is high selects word (18-bit) bus size. size works with bm and be to select the bus size and endian arrangement for port b. the level of size must be static throughout device operation pin descriptions (continued) note: 1. fs2, bm and size inputs are not ttl compatible. these inputs should be tied to gnd or v cc . 6 commercial temperature range IDT72V3654/72v3664/72v3674 3.3v cmos syncbififo tm with bus-matching 2,048 x 36 x 2, 4,096 x 36 x 2 and 8,192 x 36 x 2 symbol name i/o description w/ r a port-a write/ i a high selects a write operation and a low selects a read operation on port a for a low-to-high read select transition of clka. the a0-a35 outputs are in the high impedance state when w/ r a is high. w /rb port-b write/ i a low selects a write operation and a high selects a read operation on port b for a low-to-high read select transition of clkb. the b0-b35 outputs are in the high impedance state when w /rb is low. pin descriptions (continued) 7 commercial temperature range IDT72V3654/72v3664/72v3674 3.3v cmos syncbififo tm with bus-matching 2,048 x 36 x 2, 4,096 x 36 x 2 and 8,192 x 36 x 2 electrical characteristics over recommended operating free- air temperature range (unless otherwise noted) symbol rating commercial unit v cc supply voltage range ?0.5 to +4.6 v v i (2) input voltage range ?0.5 to v cc +0.5 v v o (2) output voltage range ?0.5 to v cc +0.5 v i ik input clamp current (v i < 0 or v i > v cc ) 20 ma i ok output clamp current (v o = < 0 or v o > v cc ) 50 ma i out continuous output current (v o = 0 to v cc ) 50 ma i cc continuous current through v cc or gnd 400 ma t stg storage temperature range ?65 to 150 c notes: 1. stresses beyond those listed under "absolute maximum ratings" may cause permanent damage to the device. these are stress rat ings only and functional operation of the device at these or any other conditions beyond those indicated under "recommended operating conditions" is not implied. exposure to absolute-m aximum-rated conditions for extended periods may affect device reliability. 2. the input and output voltage ratings may be exceeded provided the input and output current ratings are observed. absolute maximum ratings over operating free-air temperature range (unless otherwise noted) (1) recommended operating conditions note: 1. for 10ns speed grade: vcc = 3.3v 0.15v, jedec jesd8-a compliant symbol parameter min. typ. max. unit v cc (1) supply voltage for 10ns 3.15 3.3 3.45 v v cc supply voltage for 15ns 3.0 3.3 3.6 v v ih high-level input voltage 2 ? v cc +0.5 v v il low-level input voltage ? ? 0.8 v i oh high-level output current ? ? ?4 ma i ol low-level output current ? ? 8 ma t a operating temperature 0 ? 70 c notes: 1. all typical values are at v cc = 3.3v, t a = 25 c. 2. commercial-10ns speed grade only: vcc = 3.3v 0.15v, t a = 0 to +70 ; jedec jesd8-a compliant. 3. for additional i cc information, see figure 1, typical characteristics: supply current (i cc ) vs. clock frequency (f s ) . 4. characterized values, not currently tested. IDT72V3654 idt72v3664 idt72v3674 commercial t clk = 10, 15 ns (2) symbol parameter test condit ions min. typ. (1) max. unit v oh output logic "1" voltage v cc = 3.0v, i oh = ?4 ma 2.4 ? ? v v ol output logic "0" voltage v cc = 3.0v, i ol = 8 ma ? ? 0.5 v i li input leakage current (any input) v cc = 3.6v, v i = v cc or 0 ? ? 10 a i lo output leakage current v cc = 3.6v, v o = v cc or 0 ? ? 10 a i cc2 (3) standby current (with clka & clkb running) v cc = 3.6v, v i = v cc ?0.2v or 0v ? ? 5 ma i cc3 (3) standby current (no clocks running) v cc = 3.6v, v i = v cc ?0.2v or 0v ? ? 1 ma c in (4) input capacitance v i = 0, f = 1 mhz ? 4 ? pf c out (4) output capacitance v o = 0, f = 1 mhz ? 8 ? pf 8 commercial temperature range IDT72V3654/72v3664/72v3674 3.3v cmos syncbififo tm with bus-matching 2,048 x 36 x 2, 4,096 x 36 x 2 and 8,192 x 36 x 2 determining active current consumption and power dissipation the i cc(f) current for the graph in figure 1 was taken while simultaneously reading and writing a fifo on the IDT72V3654/72v3664/72v3674 with clka and clkb set to f s . all data inputs and data outputs change state during each clock cycle to consume the highest supply current. data outputs w ere disconnected to normalize the graph to a zero capacitance load. once the capacitance load per data-output channel and the number of these d evice's inputs driven by ttl high levels are known, the power dissipation can be calculated with the equation below. calculating power dissipation with i cc(f) taken from figure 1, the maximum power dissipation (pt) of these fifos may be calculated by: p t = v cc x i cc (f) + (c l x v cc 2 x fo) n where: n = number of used outputs (36-bit (long word), 18-bit (word) or 9-bit (byte) bus size) c l = output capacitance load f o = switching frequency of an output figure 1. typical characteristics: supply current (i cc ) vs. clock frequency (f s ) 010203040506070 0 10 20 30 40 50 60 f s ? clock frequency ? mhz i cc(f) supply current ma f data = 1/2 f s t a = 25 c c l = 0 pf 4664 drw03 70 90 80 100 80 90 100 v cc = 3.3v v cc = 3.6v v cc = 3.0v 9 commercial temperature range IDT72V3654/72v3664/72v3674 3.3v cmos syncbififo tm with bus-matching 2,048 x 36 x 2, 4,096 x 36 x 2 and 8,192 x 36 x 2 timing requirements over recommended ranges of supply voltage and operating free-air temperature IDT72V3654l10 (1) IDT72V3654l15 idt72v3664l10 (1) idt72v3664l15 idt72v3674l10 (1) idt72v3674l15 symbol parameter min. max. min. max. unit f s clock frequency, clka or clkb ? 100 ? 66.7 mhz t clk clock cycle time, clka or clkb 10 ? 15 ? ns t clkh pulse duration, clka or clkb high 4.5 ? 6 ? ns t clkl pulse duration, clka and clkb low 4.5 ? 6 ? ns t ds setup time, a0-a35 before clka and b0-b35 before clkb 3?4?ns t ens1 setup time, csa and w/ r a before clka ; csb and 4 ? 4.5 ? ns w /rb before clkb t ens2 setup time, ena, and mba before clka ; enb, and 3 ? 4.5 ? ns mbb before clkb t rsts setup time, mrs1 , mrs2 , prs1 , or prs2 low before 5 ? 5 ? ns clka or clkb (2) t fss setup time, fs0, fs1, fs2 before mrs1 and mrs2 high 7.5 ? 7.5 ? ns t bes setup time, be/ fwft before mrs1 and mrs2 high 7.5 ? 7.5 ? ns t sds setup time, fs0/sd before clka 3?4?ns t sens setup time, fs1/ sen before clka 3?4?ns t fws setup time, be/ fwft before clka 0?0?ns t rtms setup time, rtm before rt1 ; rtm before rt2 5?5?ns t dh hold time, a0-a35 after clka and b0-b35 after clkb 0.5 ? 1 ? ns t enh hold time, csa , w/ r a, ena, and mba after clka ; csb , 0.5 ? 1 ? ns w /rb, enb, and mbb after clkb t rsth hold time, mrs1 , mrs2 , prs1 or prs2 low after clka 4?4?ns or clkb (2) t fsh hold time, fs0, fs1, fs2 after mrs1 and mrs2 high 2 ? 2 ? ns t beh hold time, be/ fwft after mrs1 and mrs2 high 2 ? 2 ? ns t sdh hold time, fs0/sd after clka 0.5 ? 1 ? ns t senh hold time, fs1/ sen high after clka 0.5 ? 1 ? ns t sph hold time, fs1/ sen high after mrs1 and mrs2 high 2 ? 2 ? ns t rtmh hold time, rtm after rt1 ; rtm after rt2 5?5?ns t skew1 (3) skew time between clka and clkb for efa /ora, 5 ? 7.5 ? ns efb /orb, ffa /ira, and ffb /irb t skew2 (3,4) skew time between clka and clkb for aea , aeb , afa ,12?12?ns and afb notes: 1. for 10ns speed grade: vcc = 3.3v 0.15v; t a = 0 to +70 . 2. requirement to count the clock edge as one of at least four needed to reset a fifo. 3. skew time is not a timing constraint for proper device operation and is only included to illustrate the timing relationship b etween clka cycle and clkb cycle. 4. design simulated, not tested. (for 10ns speed grade only: vcc = 3.3v 0.15v ; t a = 0 c to +70 c; jedec jesd8-a compliant) 10 commercial temperature range IDT72V3654/72v3664/72v3674 3.3v cmos syncbififo tm with bus-matching 2,048 x 36 x 2, 4,096 x 36 x 2 and 8,192 x 36 x 2 switching characteristics over recommended ranges of supply voltage and operating free-air temperature, c l = 30pf IDT72V3654l10 (1) IDT72V3654l15 idt72v3664l10 (1) idt72v3664l15 idt72v3674l10 (1) idt72v3674l15 symbol parameter min. max. min. max. unit t a access time, clka to a0-a35 and clkb to b0-b35 2 6.5 2 10 ns t wff propagation delay time, clka to ffa /ira and clkb 2 6.5 2 8 ns to ffb /irb t ref propagation delay time, clka to efa /ora and clkb 1 6.5 1 8 ns to efb /orb t pae propagation delay time, clka to aea and clkb to 1 6.5 1 8 ns aeb t paf propagation delay time, clka to afa and clkb to 1 6.5 1 8 ns afb t pmf propagation delay time, clka to mbf1 low or mbf2 0 6.5 0 8 ns high and clkb to mbf2 low or mbf1 high t pmr propagation delay time, clka to b0-b35 (2) and clkb 38210ns to a0-a35 (3) t mdv propagation delay time, mba to a0-a35 valid and mbb to 3 6.5 2 10 ns b0-b35 valid t rsf propagation delay time, mrs1 or prs1 low to aeb 110115ns low, afa high, and mbf1 high and mrs2 or prs2 low to aea low, afb high, and mbf2 high t en enable time, csa or w/ r a low to a0-a35 active and 2 6 2 10 ns csb low and w /rb high to b0-b35 active t dis disable time, csa or w/ r a high to a0-a35 at high 1 6 1 8 ns impedance and csb high or w /rb low to b0-b35 at high impedance notes: 1. for 10ns speed grade: vcc = 3.3v 0.15v; t a = 0 to +70 . 2. writing data to the mail1 register when the b0-b35 outputs are active and mbb is high. 3. writing data to the mail2 register when the a0-a35 outputs are active and mba is high. (for 10ns speed grade only: vcc = 3.3v 0.15v ; t a = 0 c to +70 c; jedec jesd8-a compliant) 11 commercial temperature range IDT72V3654/72v3664/72v3674 3.3v cmos syncbififo tm with bus-matching 2,048 x 36 x 2, 4,096 x 36 x 2 and 8,192 x 36 x 2 signal description master reset ( mrs1 , mrs2 ) after power up, a master reset operation must be performed by providing a low pulse to mrs1 and mrs2 simultaneously. afterwards, each of the two fifo memories of the IDT72V3654/72v3664/72v3674 undergoes a complete reset by taking its associated master reset ( mrs1 , mrs2 ) input low for at least four port a clock (clka) and four port b clock (clkb) low- to-high transitions. the master reset inputs can switch asynchronously to the clocks. a master reset initializes the associated write and read pointers to the first location of the memory and forces the full/input ready flag ( ffa /ira, ffb /irb) low, the empty/output ready flag ( efa /ora, efb /orb) low, the almost-empty flag ( aea , aeb ) low and forces the almost-full flag ( afa , afb ) high. a master reset also forces the associated mailbox flag ( mbf1 , mfb2 ) of the parallel mailbox register high. after a master reset, the fifo's full/input ready flag is set high after two write clock cycles. then the fifo is ready to be written to. a low-to-high transition on the fifo1 master reset ( mrs1 ) input latches the values of the big-endian (be) input for determining the order by which bytes are transferred through port b. it also latches the values of the flag select (fs0, fs1 and fs2) inputs for choosing the almost-full and almost- empty offset programming method. a low-to-high transition on the fifo2 master reset ( mrs2 ) clears the flag offset registers of fifo2 (x2, y2). a low-to-high transition on the fifo2 master reset ( mrs2 ) together with the fifo1 master reset ( mrs1 ) input latches the value of the big-endian (be) input for port b and also latches the values of the flag select (fs0, fs1 and fs2) inputs for choosing the almost- full and almost-empty offset programming method. (for details see table 1, flag programming , and the programming the almost-empty and almost-full flags section). the relevant fifo master reset timing diagram can be found in figure 3. partial reset ( prs1 , prs2 ) each of the two fifo memories of these devices undergoes a limited reset by taking its associated partial reset ( prs1 , prs2 ) input low for at least four port a clock (clka) and four port b clock (clkb) low-to-high transitions. the partial reset inputs can switch asynchronously to the clocks. a partial reset initializes the internal read and write pointers and forces the full/input ready flag ( ffa /ira, ffb /irb) low, the empty/output ready flag ( efa /ora, efb /orb) low, the almost-empty flag ( aea , aeb ) low, and the almost-full flag ( afa , afb ) high. a partial reset also forces the mailbox flag ( mbf1 , mbf2 ) of the parallel mailbox register high. after a partial reset, the fifo?s full/input ready flag is set high after two write clock cycles. then the fifo is ready to be written to. whatever flag offsets, programming method (parallel or serial), and timing mode (fwft or idt standard mode) are currently selected at the time a partial reset is initiated, those settings will be remain unchanged upon completion of the reset operation. a partial reset may be useful in the case where reprogramming a fifo following a master reset would be inconvenient. see figure 4 for the partial reset timing diagram. retransmit ( rt1 , rt2 ) the fifo1 memory of these devices undergoes a retransmit by taking its associated retransmit ( rt1 ) input low for at least four port a clock (clka) and four port b clock (clkb) low-to-high transitions. the retransmit initializes the read pointer of fifo1 to the first memory location. the fifo2 memory undergoes a retransmit by taking its associated retransmit ( rt2 ) input low for at least four port a clock (clka) and four port c clock (clkc) low-to-high transitions. the retransmit initializes the read pointer of fifo2 to the first memory location. the rtm pin must be high during the time of retranmit. note that the rt1 input is muxed with the prs1 input, the state of the rtm pin determining whether this pin performs a retransmit or partial reset. also, the rt2 input is muxed with the prs2 input, the state of the rtm pin determining whether this pin performs a retransmit or partial reset. big-endian/first word fall through (be/ fwft ) ? endian selection this is a dual purpose pin. at the time of master reset, the be select function is active, permitting a choice of big or little-endian byte arrangement for data written to or read from port b. this selection determines the order by which bytes (or words) of data are transferred through this port. for the following illustrations, assume that a byte (or word) bus size has been selected for port b. (note that when port b is configured for a long word size, the big-endian function has no application and the be input is a ?don?t care? 1 .) a high on the be/ fwft input when the master reset ( mrs1 , mrs2 ) inputs go from low to high will select a big-endian arrangement. when data is moving in the direction from port a to port b, the most significant byte (word) of the long word written to port a will be read from port b first; the least significant byte (word) of the long word written to port a will be read from port b last. when data is moving in the direction from port b to port a, the byte (word) written to port b first will be read from port a as the most significant byte (word) of the long word; the byte (word) written to port b last will be read from port a as the least significant byte (word) of the long word. a low on the be/ fwft input when the master reset ( mrs1 , mrs2 ) inputs go from low to high will select a little-endian arrangement. when data is moving in the direction from port a to port b, the least significant byte (word) of the long word written to port a will be read from port b first; the most significant byte (word) of the long word written to port a will be read from port b last. when data is moving in the direction from port b to port a, the byte (word) written to port b first will be read from port a as the least significant byte (word) of the long word; the byte (word) written to port b last will be read from port a as the most significant byte (word) of the long word. refer to figure 2 for an illustration of the be function. see figure 3 (master reset) for the endian select timing diagram. ? timing mode selection after master reset, the fwft select function is active, permitting a choice between two possible timing modes: idt standard mode or first word fall through (fwft) mode. once the master reset ( mrs1 , mrs2 ) input is high, a high on the be/ fwft input during the next low-to-high transition of clka (for fifo1) and clkb (for fifo2) will select idt standard mode. this mode uses the empty flag function ( efa , efb ) to indicate whether or not there are any words present in the fifo memory. it uses the full flag function ( ffa , ffb ) to indicate whether or not the fifo memory has any free space for writing. in idt standard mode, every word read from the fifo, including the first, must be requested using a formal read operation. note: 1. either a high or low can be applied to a "don't care" input with no change to the logical operation of the fifo. nevertheles s, inputs that are temporarily "don't care" (along with unused inputs) must not be left open, rather they must be either high or low. 12 commercial temperature range IDT72V3654/72v3664/72v3674 3.3v cmos syncbififo tm with bus-matching 2,048 x 36 x 2, 4,096 x 36 x 2 and 8,192 x 36 x 2 once the master reset ( mrs1 , mrs2 ) input is high, a low on the be/ fwft input during the next low-to-high transition of clka (for fifo1) and clkb (for fifo2) will select fwft mode. this mode uses the output ready function (ora, orb) to indicate whether or not there is valid data at the data outputs (a0-a35 or b0-b35). it also uses the input ready function (ira, irb) to indicate whether or not the fifo memory has any free space for writing. in the fwft mode, the first word written to an empty fifo goes directly to data outputs, no read request necessary. subsequent words must be accessed by performing a formal read operation. following master reset, the level applied to the be/ fwft input to choose the desired timing mode must remain static throughout fifo operation. refer to figure 3 (master reset) for a first word fall through select timing diagram. programming the almost-empty and almost-full flags four registers in the IDT72V3654/72v3664/72v3674 are used to hold the offset values for the almost-empty and almost-full flags. the port b almost- empty flag ( aeb ) offset register is labeled x1 and the port a almost-empty flag ( aea ) offset register is labeled x2. the port a almost-full flag ( afa ) offset register is labeled y1 and the port b almost-full flag ( afb ) offset register is labeled y2. the index of each register name corresponds to its fifo number. the offset registers can be loaded with preset values during the reset of a fifo, programmed in parallel using the fifo?s port a data inputs, or programmed in serial using the serial data (sd) input (see table 1). fs0/sd, fs1/ sen and fs2 function the same way in both idt standard and fwft modes. ? preset values to load a fifo?s almost-empty flag and almost-full flag offset registers with one of the five preset values listed in table 1, the flag select inputs must be high or low during a master reset. for example, to load the preset value of 64 into x1 and y1, fs0, fs1 and fs2 must be high when flfo1 reset ( mrs1 ) returns high. flag-offset registers associated with fifo2 are loaded with one of the preset values in the same way with fifo2 master reset ( mrs2 ), toggled simultaneously with fifo1 master reset ( mrs1 ). for relevant preset value loading timing diagram, see figure 3. parallel load from port a to program the x1, x2, y1, and y2 registers from port a, perform a master reset on both flfos simultaneously with fs2 high or low, fs0 and fs1 low during the low-to-high transition of mrs1 and mrs2. the state of fs2 at this point of reset will determine whether the parallel programming method has interspersed parity or non-interspersed parity. refer to table 1 for flag programming flag offset setup . it is important to note that once parallel programming has been selected during a master reset by holding both fs0 & fs1 low, these inputs must remain low during all subsequent fifo operation. they can only be toggled high when future master resets are performed and other programming methods are desired. after this reset is complete, the first four writes to fifo1 do not store data in ram but load the offset registers in the order y1, x1, y2, x2. for non- interspersed parity mode the port a data inputs used by the offset registers are (a10-a0), (a11-a0), or (a12-a0) for the IDT72V3654, idt72v3664, or idt72v3674, respectively. for interspersed parity mode the port a data inputs used by the offset registers are (a11-a9, a7-a0), (a12-a9, a7-a0), or (a13- a9, a7-a0) for the IDT72V3654, idt72v3664, or idt72v3674, respectively. the highest numbered input is used as the most significant bit of the binary number in each case. valid programming values for the registers range from 1 to 2,044 for the IDT72V3654; 1 to 4,092 for the idt72v3664; and 1 to 8,188 for the idt72v3674. after all the offset registers are programmed from port a, notes: 1. x1 register holds the offset for aeb ; y1 register holds the offset for afa . 2. x2 register holds the offset for aea ; y2 register holds the offset for afb . 3. when this method of parallel programming is selected, port a will assume non-interspersed parity. 4. when ip mode is selected, only parallel programming of the offset values via port a, can be performed and port a will assume interspersed parity. 5. if parallel programming is selected during a master reset, then fs0 & fs1 must remain low during fifo operation. fs2 fs1/ sen fs0/sd mrs1 mrs2 x1 and y1 reglsters (1) x2 and y2 reglsters (2) hhh x64 x hhhx x64 hhl x16 x hhlx x16 hlh x8 x hlhx x8 lhh x 256 x lhhx x 256 llh x 1,024 x llhx x 1,024 lhl serial programming via sd serial programming via sd hll parallel programming via port a (3, 5) parallel programming via port a (3, 5) lll ip mode (4, 5) ip mode (4, 5) table 1 flag programming 13 commercial temperature range IDT72V3654/72v3664/72v3674 3.3v cmos syncbififo tm with bus-matching 2,048 x 36 x 2, 4,096 x 36 x 2 and 8,192 x 36 x 2 offset values, the device will ignore data line a8. if non-interspersed parity is selected then data line a8 will become a valid bit. if interspersed parity is selected serial programming of the offset values is not permitted, only parallel program- ming can be done. ? serial load to program the x1, x2, y1, and y2 registers serially, initiate a master reset with fs2 low, fs0/sd low and fs1/ sen high during the low-to-high transition of mrs1 and mrs2 . after this reset is complete, the x and y register values are loaded bit-wise through the fs0/sd input on each low-to-high transition of clka that the fs1/ sen input is low. there are 44-, 48-, or 52- bit writes needed to complete the programming for the IDT72V3654, idt72v3664, or idt72v3674, respectively. the four registers are written in the order y1, table 3 port b enable function table the port b full/input ready flag ( ffb /irb) is set high, and both fifos begin normal operation. refer to figure 5 for a timing diagram illustration of parallel programming of the flag offset values. interspersed parity interspersed parity is selected during a master reset of the fifo. refer to table 1 for the set-up configuration of interspersed parity. the interspersed parity function allows the user to select the location of the parity bits in the word loaded into the parallel port (a0-an) during programming of the flag offset values. if interspersed parity is selected then during parallel programming of the flag csa w/ r a ena mba clka data a (a0-a35) i/o port function h x x x x high-impedance none l h l x x input none lhh l input fifo1 write lhh h input mail1 write l l l l x output none llh l output fifo2 read l l l h x output none llh h output mail2 read (set mbf2 high) table 2 port a enable function table csb w /rb enb mbb clkb data b (b0-b35) i/o port function h x x x x high-impedance none l l l x x input none llh l input fifo2 write llh h input mail2 write l h l l x output none lhh l output fifo1 read l h l h x output none lhh h output mail1 read (set mbf1 high) x1, y2, and finally, x2. the first-bit write stores the most significant bit of the y1 register and the last-bit write stores the least significant bit of the x2 register. each register value can be programmed from 1 to 2,044 (IDT72V3654), 1 to 4,092 (idt72v3664), or 1 to 8,188 (idt72v3674). when the option to program the offset registers serially is chosen, the port a full/input ready ( ffa /ira) flag remains low until all register bits are written. ffa /ira is set high by the low-to-high transition of clka after the last bit is loaded to allow normal fifo1 operation. the port b full/input ready ( ffb / irb) flag also remains low throughout the serial programming process, until all register bits are written. ffb /irb is set high by the low-to-high transition of clkb after the last bit is loaded to allow normal fifo2 operation. see figure 6 for serial programming of the almost-full flag and almost-empty flag offset values (idt standard and fwft modes) timing diagram. fifo write/read operation the state of the port a data (a0-a35) lines is controlled by port a chip select ( csa ) and port a write/read select (w/ r a). the a0-a35 lines are in the high- impedance state when either csa or w/ r a is high. the a0-a35 lines are active outputs when both csa and w/ r a are low. data is loaded into fifo1 from the a0-a35 inputs on a low-to-high transition of clka when csa is low, w/ r a is high, ena is high, mba is low, and ffa /ira is high. data is read from fifo2 to the a0-a35 outputs by a low-to-high transition of clka when csa is low, w/ r a is low, 14 commercial temperature range IDT72V3654/72v3664/72v3674 3.3v cmos syncbififo tm with bus-matching 2,048 x 36 x 2, 4,096 x 36 x 2 and 8,192 x 36 x 2 synchronized synchronized number of words in fifo memory (1,2) to clka to clkb IDT72V3654 (3) idt72v3664 (3) idt72v3674 (3) efa /ora aea afb ffb /irb 000llhh 1 to x2 1 to x2 1 to x2 h l h h (x2+1) to [2,048-(y2+1)] (x2+1) to [4,096-(y2+1)] (x2+1) to [8,192-(y2+1)] h h h h (2,048-y2) to 2,047 (4,096-y2) to 4,095 (8,192-y2) to 8,191 h h l h 2,048 4,096 8,192 h h l l table 4 fifo1 flag operation (idt standard and fwft modes) table 5 fifo2 flag operation (idt standard and fwft modes) synchronized synchronized number of words in fifo memory (1,2) to clkb to clka IDT72V3654 (3) idt72v3664 (3) idt72v3674 (3) efb /orb aeb afa ffa /ira 000llhh 1 to x1 1 to x1 1 to x1 h l h h (x1+1) to [2,048-(y1+1)] (x1+1) to [4,096-(y1+1)] (x1+1) to [8,192-(y1+1)] h h h h (2,048-y1) to 2,047 (4,096-y1) to 4,095 (8,192-y1) to 8,191 h h l h 2,048 4,096 8,192 h h l l ena is high, mba is low, and efa /ora is high (see table 2). fifo reads and writes on port a are independent of any concurrent port b operation. the port b control signals are identical to those of port a with the exception that the port b write/read select ( w /rb) is the inverse of the port a write/read select (w/ r a). the state of the port b data (b0-b35) lines is controlled by the port b chip select ( csb ) and port b write/read select ( w /rb). the b0-b35 lines are in the high-impedance state when either csb is high or w /rb is low. the b0-b35 lines are active outputs when csb is low and w /rb is high. data is loaded into fifo2 from the b0-b35 inputs on a low-to-high transition of clkb when csb is low, w /rb is low, enb is high, mbb is low, and ffb /irb is high. data is read from fifo1 to the b0-b35 outputs by a low-to-high transition of clkb when csb is low, w /rb is high, enb is high, mbb is low, and efb /orb is high (see table 3). fifo reads and writes on port b are independent of any concurrent port a operation. the setup and hold time constraints to the port clocks for the port chip selects and write/read selects are only for enabling write and read operations notes: 1. when a word loaded to an empty fifo is shifted to the output register, its previous fifo memory location is free. 2. data in the output register does not count as a "word in fifo memory". since in fwft mode, the first word written to an empty fifo goes unrequested to the output register (no read operation necessary), it is not included in the fifo memory count. 3. x1 is the almost-empty offset for fifo1 used by aeb . y1 is the almost-full offset for fifo1 used by afa . both x1 and y1 are selected during a fifo1 reset or port a programming. 4. the orb and ira functions are active during fwft mode; the efb and ffa functions are active in idt standard mode. notes: 1. when a word loaded to an empty fifo is shifted to the output register, its previous fifo memory location is free. 2. data in the output register does not count as a "word in fifo memory". since in fwft mode, the first word written to an empty fifo goes unrequested to the output register (no read operation necessary), it is not included in the fifo memory count. 3. x2 is the almost-empty offset for fifo2 used by aea . y2 is the almost-full offset for fifo2 used by afb . both x2 and y2 are selected during a fifo2 reset or port a programming. 4. the ora and irb functions are active during fwft mode; the efa and ffb functions are active in idt standard mode. and are not related to high-impedance control of the data outputs. if a port enable is low during a clock cycle, the port?s chip select and write/read select may change states during the setup and hold time window of the cycle. when operating the fifo in fwft mode and the output ready flag is low, the next word written is automatically sent to the fifo?s output register by the low-to-high transition of the port clock that sets the output ready flag high. when the output ready flag is high, subsequent data is clocked to the output registers only when a read is selected using the port?s chip select, write/read select, enable, and mailbox select. when operating the fifo in idt standard mode, the first word will cause the empty flag to change state on the second low-to-high transition of the read clock. the data word will not be automatically sent to the output register. instead, data residing in the fifo's memory array is clocked to the output register only when a read is selected using the port?s chip select, write/read select, enable, and mailbox select. write and read timing diagrams for port a can be found in figure 7 and 14. relevant port b write and read cycle timing diagrams together with bus-matching and endian select operations can be found in figures 8 through 13. 15 commercial temperature range IDT72V3654/72v3664/72v3674 3.3v cmos syncbififo tm with bus-matching 2,048 x 36 x 2, 4,096 x 36 x 2 and 8,192 x 36 x 2 synchronized fifo flags each fifo is synchronized to its port clock through at least two flip-flop stages. this is done to improve flag-signal reliability by reducing the probability of metastable events when clka and clkb operate asynchronously to one another. efa /ora, aea , ffa /ira, and afa are synchronized to clka. efb /orb, aeb , ffb /irb, and afb are synchronized to clkb. tables 4 and 5 show the relationship of each port flag to fifo1 and fifo2. empty/output ready flags ( efa /ora, efb /orb) these are dual purpose flags. in the fwft mode, the output ready (ora, orb) function is selected. when the output-ready flag is high, new data is present in the fifo output register. when the output ready flag is low, the previous data word is present in the fifo output register and attempted fifo reads are ignored. in the idt standard mode, the empty flag ( efa , efb ) function is selected. when the empty flag is high, data is available in the fifo?s ram memory for reading to the output register. when the empty flag is low, the previous data word is present in the fifo output register and attempted fifo reads are ignored. the empty/output ready flag of a fifo is synchronized to the port clock that reads data from its array. for both the fwft and idt standard modes, the fifo read pointer is incremented each time a new word is clocked to its output register. the state machine that controls an output ready flag monitors a write pointer and read pointer comparator that indicates when the fifo memory status is empty, empty+1, or empty+2. in fwft mode, from the time a word is written to a fifo, it can be shifted to the fifo output register in a minimum of three cycles of the output ready flag synchronizing clock. therefore, an output ready flag is low if a word in memory is the next data to be sent to the flfo output register and three cycles of the port clock that reads data from the fifo have not elapsed since the time the word was written. the output ready flag of the fifo remains low until the third low-to-high transition of the synchronizing clock occurs, simulta- neously forcing the output ready flag high and shifting the word to the fifo output register. in idt standard mode, from the time a word is written to a fifo, the empty flag will indicate the presence of data available for reading in a minimum of two cycles of the empty flag synchronizing clock. therefore, an empty flag is low if a word in memory is the next data to be sent to the flfo output register and two cycles of the port clock that reads data from the fifo have not elapsed since the time the word was written. the empty flag of the fifo remains low until the second low-to-high transition of the synchronizing clock occurs, forcing the empty flag high; only then can data be read. a low-to-high transition on an empty/output ready flag synchronizing clock begins the first synchronization cycle of a write if the clock transition occurs at time t skew1 or greater after the write. otherwise, the subsequent clock cycle can be the first synchronization cycle (see figures 15, 16, 17, and 18). full/input ready flags ( ffa /ira, ffb /irb) this is a dual purpose flag. in fwft mode, the input ready (ira and irb) function is selected. in idt standard mode, the full flag ( ffa and ffb ) function is selected. for both timing modes, when the full/input ready flag is high, a memory location is free in the fifo to receive new data. no memory locations are free when the full/input ready flag is low and attempted writes to the fifo are ignored. the full/input ready flag of a flfo is synchronized to the port clock that writes data to its array. for both fwft and idt standard modes, each time a word is written to a fifo, its write pointer is incremented. the state machine that controls a full/input ready flag monitors a write pointer and read pointer comparator that indicates when the flfo memory status is full, full-1, or full- 2. from the time a word is read from a fifo, its previous memory location is ready to be written to in a minimum of two cycles of the full/input ready flag synchronizing clock. therefore, an full/input ready flag is low if less than two cycles of the full/input ready flag synchronizing clock have elapsed since the next memory write location has been read. the second low-to-high transition on the full/input ready flag synchronizing clock after the read sets the full/input ready flag high. a low-to-high transition on a full/input ready flag synchronizing clock begins the first synchronization cycle of a read if the clock transition occurs at time t skew1 or greater after the read. otherwise, the subsequent clock cycle can be the first synchronization cycle (see figures 19, 20, 21, and 22). almost-empty flags ( aea , aeb ) the almost-empty flag of a fifo is synchronized to the port clock that reads data from its array. the state machine that controls an almost-empty flag monitors a write pointer and read pointer comparator that indicates when the fifo memory status is almost-empty, almost-empty+1, or almost-empty+2. the almost-empty state is defined by the contents of register x1 for aeb and register x2 for aea . these registers are loaded with preset values during a fifo reset, programmed from port a, or programmed serially (see almost- empty flag and almost-full flag offset programming section). an almost- empty flag is low when its fifo contains x or less words and is high when its fifo contains (x+1) or more words. a data word present in the fifo output register has been read from memory. two low-to-high transitions of the almost-empty flag synchronizing clock are required after a fifo write for its almost-empty flag to reflect the new level of fill. therefore, the almost-full flag of a fifo containing (x+1) or more words remains low if two cycles of its synchronizing clock have not elapsed since the write that filled the memory to the (x+1) level. an almost-empty flag is set high by the second low-to-high transition of its synchronizing clock after the fifo write that fills memory to the (x+1) level. a low-to-high transition of an almost-empty flag synchronizing clock begins the first synchro- nization cycle if it occurs at time t skew2 or greater after the write that fills the fifo to (x+1) words. otherwise, the subsequent synchronizing clock cycle may be the first synchronization cycle. (see figure 23 and 24). almost-full flags ( afa , afb ) the almost-full flag of a fifo is synchronized to the port clock that writes data to its array. the state machine that controls an almost-full flag monitors a write pointer and read pointer comparator that indicates when the fifo memory status is almost-full, almost-full-1, or almost-full-2. the almost-full state is defined by the contents of register y1 for afa and register y2 for afb . these registers are loaded with preset values during a flfo reset, programmed from port a, or programmed serially (see almost-empty flag and almost-full flag offset programming section). an almost-full flag is low when the number of words in its fifo is greater than or equal to (2,048-y), (4,096-y), or (8,192-y) for the IDT72V3654, idt72v3664, or idt72v3674 respectively. an almost- full flag is high when the number of words in its fifo is less than or equal to [2,048-(y+1)], [4,096-(y+1)], or [8,192-(y+1)] for the IDT72V3654, idt72v3664, or idt72v3674 respectively. note that a data word present in the fifo output register has been read from memory. two low-to-high transitions of the almost-full flag synchronizing clock are required after a fifo read for its almost-full flag to reflect the new level of fill. therefore, the almost-full flag of a fifo containing [2,048/4,096/8,192- (y+1)] or less words remains low if two cycles of its synchronizing clock have not elapsed since the read that reduced the number of words in memory to [2,048/4,096/8,192-(y+1)]. an almost-full flag is set high by the second 16 commercial temperature range IDT72V3654/72v3664/72v3674 3.3v cmos syncbififo tm with bus-matching 2,048 x 36 x 2, 4,096 x 36 x 2 and 8,192 x 36 x 2 low-to-high transition of its synchronizing clock after the fifo read that reduces the number of words in memory to [2,048/4,096/8,192-(y+1)]. a low-to-high transition of an almost-full flag synchronizing clock begins the first synchronization cycle if it occurs at time t skew2 or greater after the read that reduces the number of words in memory to [2,048/4,096/8,192-(y+1)]. otherwise, the subsequent synchronizing clock cycle may be the first synchro- nization cycle (see figure 25 and 26). mailbox registers each fifo has a 36-bit bypass register to pass command and control information between port a and port b without putting it in queue. the mailbox select (mba, mbb) inputs choose between a mail register and a fifo for a port data transfer operation. the usable width of both the mail1 and mail2 registers matches the selected bus size for port b. a low-to-high transition on clka writes data to the mail 1 register when a port a write is selected by csa , w/ r a, and ena with mba high. if the selected port b bus size is also 36 bits, then the usable width of the mail1 register employs data lines a0-a35. if the selected port b bus size is 18 bits, then the usable width of the mail1 register employs data lines a0-a17. (in this case, a18-a35 are don?t care inputs.) if the selected port b bus size is 9 bits, then the usable width of the mail1 register employs data lines a0-a8. (in this case, a9-a35 are don?t care inputs.) a low-to-high transition on clkb writes b0-b35 data to the mail2 register when a port b write is selected by csb , w /rb, and enb with mbb high. if the selected port b bus size is also 36 bits, then the usable width of the mail2 employs data lines b0-b35. if the selected port b bus size is 18 bits, then the usable width of the mail2 register employs data lines b0-b17. (in this case, b18-b35 are don?t care inputs.) if the selected port b bus size is 9 bits, then the usable width of the mail2 register employs data lines b0-b8. (in this case, b9-b35 are don?t care inputs.) writing data to a mail register sets its corresponding flag ( mbf1 or mbf2 ) low. attempted writes to a mail register are ignored while the mail flag is low. when data outputs of a port are active, the data on the bus comes from the fifo output register when the port mailbox select input is low and from the mail register when the port mailbox select input is high. the mail1 register flag ( mbf1 ) is set high by a low-to-high transition on clkb when a port b read is selected by csb , w /rb, and enb with mbb high. for a 36-bit bus size, 36 bits of mailbox data are placed on b0-b35. for an 18-bit bus size, 18 bits of mailbox data are placed on b0-b17. (in this case, b18-b35 are indeterminate.) for a 9-bit bus size, 9 bits of mailbox data are placed on b0-b8. (in this case, b9-b35 are indeterminate.) the mail2 register flag ( mbf2 ) is set high by a low-to-high transition on clka when a port a read is selected by csa , w/ r a, and ena with mba high. for a 36-bit bus size, 36 bits of mailbox data are placed on a0-a35. for an 18-bit bus size, 18 bits of mailbox data are placed on a0-a17. (in this case, a18-a35 are indeterminate.) for a 9-bit bus size, 9 bits of mailbox data are placed on a0-a8. (in this case, a9-a35 are indeterminate.) the data in a mail register remains intact after it is read and changes only when new data is written to the register. the endian select feature has no effect on mailbox data. for mail register and mail register flag timing diagrams, see figure 27 and 28. bus sizing the port b bus can be configured in a 36-bit long word, 18-bit word, or 9-bit byte format for data read from fifo1 or written to fifo2. the levels applied to the port b bus size select (size) and the bus-match select (bm) determine the port b bus size. these levels should be static throughout fifo operation. both bus size selections are implemented at the completion of master reset, by the time the full/input ready flag is set high, as shown in figure 2. two different methods for sequencing data transfer are available for port b when the bus size selection is either byte- or word-size. they are referred to as big-endian (most significant byte first) and little-endian (least significant byte first). the level applied to the big-endian select (be) input during the low- to-high transition of mrs1 and mrs2 selects the endian method that will be active during fifo operation. be is a don?t care input when the bus size selected for port b is long word. the endian method is implemented at the completion of master reset, by the time the full/input ready flag is set high, as shown in figure 2. only 36-bit long word data is written to or read from the two fifo memories on the IDT72V3654/72v3664/72v3674. bus-matching operations are done after data is read from the fifo1 ram and before data is written to the fifo2 ram. these bus-matching operations are not available when transferring data via mailbox registers. furthermore, both the word- and byte-size bus selections limit the width of the data bus that can be used for mail register operations. in this case, only those byte lanes belonging to the selected word- or byte-size bus can carry mailbox data. the remaining data outputs will be indeterminate. the remaining data inputs will be don?t care inputs. for example, when a word-size bus is selected, then mailbox data can be transmitted only between a0-a17 and b0-b17. when a byte-size bus is selected, then mailbox data can be transmitted only between a0-a8 and b0- b8. (see figures 27 and 28). bus-matching fifo1 reads data is read from the fifo1 ram in 36-bit long word increments. if a long word bus size is implemented, the entire long word immediately shifts to the fifo1 output register. if byte or word size is implemented on port b, only the first one or two bytes appear on the selected portion of the fifo1 output register, with the rest of the long word stored in auxiliary registers. in this case, subsequent fifo1 reads output the rest of the long word to the fifo1 output register in the order shown by figure 2. when reading data from fifo1 in byte or word format, the unused b0-b35 outputs are indeterminate. bus-matching fifo2 writes data is written to the fifo2 ram in 36-bit long word increments. data written to fifo2 with a byte or word bus size stores the initial bytes or words in auxiliary registers. the clkb rising edge that writes the fourth byte or the second word of long word to fifo2 also stores the entire long word in the fifo2 memory. the bytes are arranged in the manner shown in figure 2. when writing data to fifo2 in byte or word format, the unused b0-b35 inputs are don't care inputs. 17 commercial temperature range IDT72V3654/72v3664/72v3674 3.3v cmos syncbififo tm with bus-matching 2,048 x 36 x 2, 4,096 x 36 x 2 and 8,192 x 36 x 2 figure 2. bus sizing a35 ? a27 a26 ? a18 a17 ? a9 a8 ? a0 b35 ? b27 b26 ? b18 b17 ? 9 b8 ? b0 a a a d a c b b b c b d c c c a d d d b b35 ? b27 b26 ? b18 b17 ? b9 b8 ? b0 (a) long word size (b) word size ? big endian (c) word size ? little-endian (d) byte size ? big-endian write to fifo1/ read from fifo2 read from fifo1/ write to fifo2 1st: read from fifo1/ write to fifo2 be bm size h h l l h l h h h x l x byte order on port a: b35 ? b27 b26 ? b18 b17 ? b9 b8 ? b0 be bm size be bm size be bm size 2nd: read from fifo1/ write to fifo2 3rd: read from fifo1/ write to fifo2 4th: read from fifo1/ write to fifo2 b35 ? b27 b26 ? b18 b17 ? b9 b8 ? b0 1st: read from fifo1/ write to fifo2 1st: read from fifo1/ write to fifo2 2nd: read from fifo1/ write to fifo2 2nd: read from fifo1/ write to fifo2 d c (e) byte size ? little-endian 1st: read from fifo1/ write to fifo2 a b be bm size l h h 2nd: read from fifo1/ write to fifo2 3rd: read from fifo1/ write to fifo2 4th: read from fifo1/ write to fifo2 b35 ? b27 b26 ? b18 b17 ? b9 b8 ? b0 4664 drw 04 byte order on port b: b35 ? b27 b26 ? b18 b17 ? b9 b8 ? b0 b35 ? b27 b26 ? b18 b17 ? b9 b8 ? b0 b35 ? b27 b26 ? b18 b17 ? b9 b8 ? b0 b35 ? b27 b26 ? b18 b17 ? b9 b8 ? b0 b35 ? b27 b26 ? b18 b17 ? b9 b8 ? b0 b35 ? b27 b26 ? b18 b17 ? b9 b8 ? b0 b35 ? b27 b26 ? b18 b17 ? b9 b8 ? b0 b35 ? b27 b26 ? b18 b17 ? b9 b8 ? b0 18 commercial temperature range IDT72V3654/72v3664/72v3674 3.3v cmos syncbififo tm with bus-matching 2,048 x 36 x 2, 4,096 x 36 x 2 and 8,192 x 36 x 2 notes: 1. partial reset is performed in the same manner for fifo2. 2. mrs1 must be high during partial reset. 3. if be/ fwft is high, then efb /orb will go low one clkb cycle earlier than in this case where be/ fwft is low. figure 3. fifo1 master reset and loading x1 and y1 with a preset value of eight (1) (idt standard and fwft modes) figure 4. fifo1 partial reset (1) (idt standard and fwft modes) notes: 1. fifo2 master reset ( mrs2 ) is performed in the same manner to load x2 and y2 with a preset value. for fifo2 master reset, mrs1 must toggle simultaneously with mrs2 . 2. prs1 must be high during master reset. 3. if be/ fwft is high, then efb /orb will go low one clkb cycle earlier than in this case where be/ fwft is low. clka mrs1 ffa /ira aeb afa mbf1 clkb efb /orb fs2, fs1,fs0 4664 drw 05 t rsts t rsth t fsh t fss t wff t wff t ref t rsf 0,1 t rsf t rsf be be/ fwft fwft t bes t beh t fws (3) rtm low clka prs1 ffa /ira aeb afa mbf1 clkb efb /orb 4664 drw 06 t rsts t rsth t wff t wff t ref (3) t rsf t rsf t rsf rtm low 19 commercial temperature range IDT72V3654/72v3664/72v3674 3.3v cmos syncbififo tm with bus-matching 2,048 x 36 x 2, 4,096 x 36 x 2 and 8,192 x 36 x 2 figure 6. serial programming of the almost-full flag and almost-empty flag offset values (idt standard and fwft modes) figure 5. parallel programming of the almost-full flag and almost-empty flag offset values after reset (idt standard and fwft modes) notes: 1. t skew1 is the minimum time between the rising clka edge and a rising clkb edge for ffb /irb to transition high in the next cycle. if the time between the rising edge of clka and rising edge of clkb is less than t skew1 , then ffb /irb may transition high one clkb cycle later than shown. 2. it is not necessary to program offset register bits on consecutive clock cycles. fifo write attempts are ignored until ffa /ira and ffb /irb is set high. 3. programmable offsets are written serially to the sd input in the order afa offset (y1), aeb offset (x1), afb offset (y2), and aea offset (x2). notes: 1. t skew1 is the minimum time between the rising clka edge and a rising clkb edge for ffb /irb to transition high in the next cycle. if the time between the rising edge of clka and rising edge of clkb is less than t skew1 , then ffb /irb may transition high one clkb cycle later than shown. 2. csa =low, w/ r a=high,mba=low. it is not necessary to program offset register on consecutive clock cycles. 4664 drw 07 clka mrs1 , mrs2 ffa /ira clkb ffb /irb a0-a35 fs1,fs0 ena t fsh t wff t enh t ens2 t skew1 t ds t dh t wff 4 0,0 afa offset (y1) aeb offset (x1) afb offset (y 2) aea offset (x 2) first word to fifo1 12 (1) t fsh t fss t fss 1 2 fs2 clka ffa /ira t sens t senh fs0/sd (3) t sph t sens t senh t fss t wff fs1/ sen aea offset (x2) lsb t sds t sdh t sds t sdh afa offset (y1) msb mrs1 , mrs2 4 4664 drw 08 t fss t fsh clkb 4 fs2 ffb /irb t wff t skew (1) 20 commercial temperature range IDT72V3654/72v3664/72v3674 3.3v cmos syncbififo tm with bus-matching 2,048 x 36 x 2, 4,096 x 36 x 2 and 8,192 x 36 x 2 note: 1. written to fifo1. figure 7. port a write cycle timing for fifo1 (idt standard and fwft modes) data size table for long-word writes to fifo2 figure 8. port b long-word write cycle timing for fifo2 (idt standard and fwft modes) size mode (1) data written to fifo2 data read from fifo2 bm size be b35-b27 b26-b18 b17-b9 b8-b0 a35-a27 a26-a18 a17-a9 a8-a0 lxxa b c d abcd note: 1. be is selected at master reset: bm and size must be static throughout device operation. note: 1. written to fifo2. 4664 drw09 clka ffa /ira ena a0 - a35 mba csa w/ r a t clkh t clkl t clk t ens1 t ens1 t ens2 t ens2 t ds t enh t enh t enh t enh t dh w1 (1) w2 (1) t ens2 t enh t enh t ens2 no operation high 4664 drw 10 clkb ffb /irb enb b0-b35 mbb csb w /rb t clk t clkh t clkl t enh t enh t enh t enh t dh w1 (1) w2 (1) t ens2 t ds t ens2 t ens2 t ens1 t ens1 t enh t enh t ens2 no operation high 21 commercial temperature range IDT72V3654/72v3664/72v3674 3.3v cmos syncbififo tm with bus-matching 2,048 x 36 x 2, 4,096 x 36 x 2 and 8,192 x 36 x 2 size mode (1) write data written data read from fifo2 no. to fifo2 bm size be b17-b9 b8-b0 a35-a27 a26-a18 a17-a9 a8-a0 hl h a b c d hl l a b c d data size table for word writes to fifo2 1a b 2c d 1c d 2a b figure 9. port b word write cycle timing for fifo2 (idt standard and fwft modes) note: 1. be is selected at master reset; bm and size must be static throughout device operation. size mode (1) write data written data read from fifo2 no. to fifo2 bm size be b8-b0 a35-a27 a26-a18 a17-a9 a8-a0 hh h a b c d hh l a b c d 1 a 2 b 3 c 4 d 1 d 2 c 3 b 4 a data size table for byte writes to fifo2 figure 10. port b byte write cycle timing for fifo2 (idt standard and fwft modes) note: 1. be is selected at master reset; bm and size must be static throughout device operation. clkb enb t enh t enh ffb /irb w /rb csb t enh high 4664 drw 11 b0-b17 t enh t enh mbb t dh t ds t ens2 t ens1 t ens1 t ens2 t ens2 t ens2 ffb /irb csb w /rb clkb t enh t ens2 enb 4664 drw 12 high b0-b8 t ens2 t enh t ens2 t enh t ds t dh t ens1 t ens1 t enh t enh mbb 22 commercial temperature range IDT72V3654/72v3664/72v3674 3.3v cmos syncbififo tm with bus-matching 2,048 x 36 x 2, 4,096 x 36 x 2 and 8,192 x 36 x 2 size mode (1) data written to fifo1 read data read from fifo1 no. bm size be a35-a27 a26-a18 a17-a9 a8-a0 b17-b9 b8-b0 hlh a b c d1 a b 2c d hll a b c d1 c d 2a b data size table for word reads from fifo1 figure 12. port-b word read cycle timing for fifo1 (idt standard and fwft modes) note: 1. be is selected at master reset; bm and size must be static throughout device operation . size mode (1) data written to fifo1 data read from fifo1 bm size be a35-a27 a26-a18 a17-a9 a8-a0 b35-b27 b26-b18 b17-b9 b8-b0 lx x a b c d a b c d note: 1. read from fifo1. data size table for fifo long-word reads from fifo1 figure 11. port b long-word read cycle timing for fifo1 (idt standard and fwft modes) note: 1. unused word b18-b35 are indeterminate for word-size reads. note: 1. be is selected at master reset; bm and size must be static throughout device operation . 4664 drw 13 clkb efb /orb enb mbb csb w /rb t clk t clkh t clkl t ens2 t a t mdv t en t a t ens2 t enh t ens2 t enh w1 w2 w3 (1) (1) t enh t dis no operation b0-b35 (fwft mode) t en w2 t dis w1 previous data b0-b35 (standard mode) t mdv t a or t a high (1) (1) (1) clkb enb efb /orb w /rb csb high 4664 drw 14 b0-b17 (standard mode) b0-b17 (fwft mode) or previous data t dis t a t a t ens2 t enh no operation read 1 t a t a read 1 read 2 read 2 read 3 t dis mbb t en t mdv t en t mdv 23 commercial temperature range IDT72V3654/72v3664/72v3674 3.3v cmos syncbififo tm with bus-matching 2,048 x 36 x 2, 4,096 x 36 x 2 and 8,192 x 36 x 2 data size table for byte reads from fifo1 size mode (1) data written to fifo1 read data read from fifo1 no. bm size be a35-a27 a26-a18 a17-a9 a8-a0 b8-b0 hh h a b c d hh l a b c d 1 a 2 b 3 c 4 d 1 d 2 c 3 b 4 a note: 1. be is selected at master reset; bm and size must be static throughout device operation. figure 13. port-b byte read cycle timing for fifo1 (idt standard and fwft modes) figure 14. port-a read cycle timing for fifo2 (idt standard and fwft modes) note: 1. unused bytes b9-b17, b18-b26, and b27-b35 are indeterminate for byte-size reads. note: 1. read from fifo2. efb /orb mbb csb w /rb enb clkb high b0-b8 b0-b8 read 5 read 2 read 3 read 4 read 3 read 4 previous data read 2 no operation t dis t dis t a t a t a t a t a t a t ens2 t enh t a t a read 1 (standard mode) (fwft mode) t en t mdv t mdv t en or read 1 4664 drw 15 4664 drw16 clka efa /ora ena mba csa w/ r a t clk t clkh t clkl t ens2 t a t mdv t en t a t ens2 t enh t ens2 t enh w1 w2 w3 (1) (1) t enh t dis no operation a0-a35 (fwft mode) t en w2 (1) (1) t dis w1 previous data a0-a35 (standard mode) t mdv t a or t a high (1) 24 commercial temperature range IDT72V3654/72v3664/72v3674 3.3v cmos syncbififo tm with bus-matching 2,048 x 36 x 2, 4,096 x 36 x 2 and 8,192 x 36 x 2 notes: 1. t skew1 is the minimum time between a rising clka edge and a rising clkb edge for orb to transition high and to clock the next word to the fifo1 output register in three clkb cycles. if the time between the rising clka edge and rising clkb edge is less than t skew1 , then the transition of orb high and load of the first word to the output register may occur one clkb cycle later than shown. 2. if port b size is word or byte, orb is set low by the last word or byte read from fifo1, respectively. figure 15. orb flag timing and first data word fall through when fifo1 is empty (fwft mode) csa w r a mba ira a0-a35 clkb orb csb w /rb mbb ena enb b0-b35 clka 4664 drw17 12 3 t clkh t clkl t clk t ens2 t ens2 t enh t enh t ds t dh t skew1 t clk t clkl t ref t ref t ens2 t enh t a old data in fifo1 output register w1 fifo1 empty low high low high low t clkh w1 high (1) 25 commercial temperature range IDT72V3654/72v3664/72v3674 3.3v cmos syncbififo tm with bus-matching 2,048 x 36 x 2, 4,096 x 36 x 2 and 8,192 x 36 x 2 notes: 1. t skew1 is the minimum time between a rising clka edge and a rising clkb edge for efb to transition high in the next clkb cycle. if the time between the rising clka edge and rising clkb edge is less than t skew1 , then the transition of efb high may occur one clkb cycle later than shown. 2. if port b size is word or byte, efb is set low by the last word or byte read from fifo1, respectively. figure 16. efb flag timing and first data read fall through when fifo1 is empty (idt standard mode) csa w r a mba ffa a0-a35 clkb efb csb w /rb mbb ena enb b0-b35 clka 12 4664 drw18 t clkh t clkl t clk t ens2 t ens2 t enh t enh t ds t dh t skew1 t clk t clkl t ens2 t enh t a w1 fifo1 empty low high low high low t clkh w1 high (1) t ref t ref 26 commercial temperature range IDT72V3654/72v3664/72v3674 3.3v cmos syncbififo tm with bus-matching 2,048 x 36 x 2, 4,096 x 36 x 2 and 8,192 x 36 x 2 notes: 1. t skew1 is the minimum time between a rising clkb edge and a rising clka edge for ora to transition high and to clock the next word to the fifo2 output register in three clka cycles. if the time between the clkb edge and the rising clka edge is less than t skew1 , then the transition of ora high and load of the first word to the output register may occur one clka cycle later than shown. 2. if port b size is word or byte, t skew1 is referenced to the rising clkb edge that writes the last word or byte of the long word, respectively. figure 17. ora flag timing and first data word fall through when fifo2 is empty (fwft mode ) csb w /rb mbb irb b0-b35 clka ora csa w/ r a mba enb ena a0-a35 clkb 4664 drw19 12 3 t clkh t clkl t clk t ens2 t ens2 t enh t enh t ds t dh t skew1 (1) t clk t clkh t ref t ref t ens2 t enh t a old data in fifo2 output register w1 fifo2 empty t clkl low low low low low high w1 27 commercial temperature range IDT72V3654/72v3664/72v3674 3.3v cmos syncbififo tm with bus-matching 2,048 x 36 x 2, 4,096 x 36 x 2 and 8,192 x 36 x 2 notes: 1. t skew1 is the minimum time between a rising clkb edge and a rising clka edge for efa to transition high in the next clka cycle. if the time between the rising clkb edge and rising clka edge is less than t skew1 , then the transition of efa high may occur one clka cycle later than shown. 2. if port b size is word or byte, t skew1 is referenced to the rising clkb edge that writes the last word or byte of the long word, respectively. figure 18. efa flag timing and first data read when fifo2 is empty (idt standard mode) csb w /rb mbb ffb b0-b35 clka efa csa w/ r a mba enb ena a0-a35 clkb 12 4664 drw20 t clkh t clkl t clk t ens2 t ens2 t enh t enh t ds t dh t skew1 (1) t clk t clkl t ens2 t enh t a w1 fifo2 empty low low low low low t clkh w1 high t ref t ref 28 commercial temperature range IDT72V3654/72v3664/72v3674 3.3v cmos syncbififo tm with bus-matching 2,048 x 36 x 2, 4,096 x 36 x 2 and 8,192 x 36 x 2 figure 20. ffa flag timing and first available write when fifo1 is full (idt standard mode) figure 19. ira flag timing and first available write when fifo1 is full (fwft mode) notes: 1. t skew1 is the minimum time between a rising clkb edge and a rising clka edge for ffa to transition high in the next clka cycle. if the time between the rising clkb edge and rising clka edge is less than t skew1 , then ffa may transition high one clka cycle later than shown. 2. if port b size is word or byte, t skew1 is referenced from the rising clkb edge that reads the last word or byte of the long word, respectively. notes: 1. t skew1 is the minimum time between a rising clkb edge and a rising clka edge for ira to transition high in the next clka cycle. if t he time between the rising clkb edge and rising clka edge is less than t skew1 , then ira may transition high one clka cycle later than shown. 2. if port b size is word or byte, t skew1 is referenced to the rising clkb edge that reads the last word or byte write of the long word, respectively. csb orb w /rb mbb enb b0-b35 clkb ira clka csa 4664 drw21 w/ r a a0-a35 mba ena 12 t clk t clkh t clkl t ens2 t enh t a t skew1 t clk t clkh t clkl t wff t ens2 t ens2 t ds t enh t enh t dh to fifo1 previous word in fifo1 output register next word from fifo1 low high low high low high (1) fifo1 full t wff write csb efb mbb enb b0-b35 clkb ffa clka csa 4664 drw22 w/ r a 12 a0-a35 mba ena t clk t clkh t clkl t ens2 t enh t a t skew1 t clk t clkh t clkl t ens2 t ens2 t ds t enh t enh t dh to fifo1 previous word in fifo1 output register next word from fifo1 low w /rb high low high low high (1) fifo1 full t wff t wff write 29 commercial temperature range IDT72V3654/72v3664/72v3674 3.3v cmos syncbififo tm with bus-matching 2,048 x 36 x 2, 4,096 x 36 x 2 and 8,192 x 36 x 2 notes: 1. t skew1 is the minimum time between a rising clka edge and a rising clkb edge for irb to transition high in the next clkb cycle. if t he time between the rising clka edge and rising clkb edge is less than t skew1 , then irb may transition high one clkb cycle later than shown. 2. if port b size is word or byte, irb is set low by the last word or byte write of the long word, respectively. figure 21. irb flag timing and first available write when fifo2 is full (fwft mode) csa ora w/ r a mba ena a0-a35 clka irb clkb csb 4664 drw23 w /rb b0-b35 mbb enb 12 t clk t clkh t clkl t ens2 t enh t a t skew1 t clk t clkh t clkl t wff t wff t ens2 t ens2 t enh t enh t ds t dh to fifo2 previous word in fifo2 output register next word from fifo2 fifo2 full low low low high low low (1) write 30 commercial temperature range IDT72V3654/72v3664/72v3674 3.3v cmos syncbififo tm with bus-matching 2,048 x 36 x 2, 4,096 x 36 x 2 and 8,192 x 36 x 2 figure 22. ffb flag timing and first available write when fifo2 is full (idt standard mode) notes: 1. t skew1 is the minimum time between a rising clka edge and a rising clkb edge for ffb to transition high in the next clkb cycle. if the time between the rising clka edge and rising clkb edge is less than t skew1 , then ffb may transition high one clkb cycle later than shown. 2. if port b size is word or byte, ffb is set low by the last word or byte write of the long word, respectively. csa efa mba ena a0-a35 clka ffb clkb csb 4664 drw24 w /rb 12 b0-b35 mbb enb t clk t clkh t clkl t ens2 t enh t a t skew1 t clk t clkh t clkl t ens2 t ens2 t ds t enh t enh t dh to fifo2 previous word in fifo2 output register next word from fifo2 low w/ r a low low high low low (1) fifo2 full t wff t wff write 31 commercial temperature range IDT72V3654/72v3664/72v3674 3.3v cmos syncbififo tm with bus-matching 2,048 x 36 x 2, 4,096 x 36 x 2 and 8,192 x 36 x 2 figure 25. timing for afa when fifo1 is almost-full (idt standard and fwft modes) figure 23. timing for aeb when fifo1 is almost-empty (idt standard and fwft modes) figure 24. timing for aea when fifo2 is almost-empty (idt standard and fwft modes) notes: 1. t skew2 is the minimum time between a rising clka edge and a rising clkb edge for aeb to transition high in the next clkb cycle. if the time between the rising clka edge and rising clkb edge is less than t skew2 , then aeb may transition high one clkb cycle later than shown. 2. fifo1 write ( csa = low, w/ r a = low, mba = low), fifo1 read ( csb = low, w /rb = high, mbb = low). data in the fifo1 output register has been read from the fifo. 3. if port b size is word or byte, aeb is set low by the last word or byte read from fifo1, respectively. notes: 1. t skew2 is the minimum time between a rising clka edge and a rising clkb edge for afa to transition high in the next clka cycle. if the time between the rising clka edge and rising clkb edge is less than t skew2 , then afa may transition high one clka cycle later than shown. 2. fifo1 write ( csa = low, w/ r a = high, mba = low), fifo1 read ( csb = low, w /rb = high, mbb = low). data in the fifo1 output register has been read from the fifo. 3. d = maximum fifo depth = 2,048 for the IDT72V3654, 4,096 for the idt72v3664, 8,192 for the idt72v3674. 4. if port b size is word or byte, t skew2 is referenced to the rising clkb edge that reads the last word or byte of the long word, respectively. aeb clka enb 4664 drw 25 ena clkb 2 1 t ens2 t enh t skew2 t pae t pae t ens2 t enh x1 words in fifo1 (x1+1) words in fifo1 (1) aea clkb ena 4664 drw 26 enb clka 2 1 t ens2 t enh t skew2 t pae t pae t ens2 t enh (x2+1) words in fifo2 x2 words in fifo2 (1) afa clka enb 4664 drw 27 ena clkb 12 t skew2 t ens2 t enh t paf t ens2 t enh t paf [d-(y1+1)] words in fifo1 (d-y1) words in fifo1 (1) notes: 1. t skew2 is the minimum time between a rising clkb edge and a rising clka edge for aea to transition high in the next clka cycle. if the time between the rising clkb edge and rising clka edge is less than t skew2 , then aea may transition high one clka cycle later than shown. 2. fifo2 write ( csb = low, w /rb = low, mbb = low), fifo2 read ( csa = low, w/ r a = low, mba = low). data in the fifo2 output register has been read from the fifo. 3. if port b size is word or byte, t skew2 is referenced to the rising clkb edge that writes the last word or byte of the long word, respectively. 32 commercial temperature range IDT72V3654/72v3664/72v3674 3.3v cmos syncbififo tm with bus-matching 2,048 x 36 x 2, 4,096 x 36 x 2 and 8,192 x 36 x 2 figure 26. timing for afb when fifo2 is almost-full (idt standard and fwft modes) figure 27. timing for mail1 register and mbf1 flag (idt standard and fwft modes) note: 1. if port b is configured for word size, data can be written to the mail1 register using a0-a17 (a18-a35 are don't care inputs) . in this first case b0-b17 will have valid data (b18-b35 will be indeterminate). if port b is configured for byte size, data can be written to the mail1 register using a0-a8 (a9-a35 a re don't care inputs). in this second case, b0-b8 will have valid data (b9-b35 will be indeterminate). notes: 1. t skew2 is the minimum time between a rising clkb edge and a rising clka edge for afb to transition high in the next clkb cycle. if the time between the rising clkb edge and rising clka edge is less than t skew2 , then afb may transition high one clkb cycle later than shown. 2. fifo2 write ( csb = low, w /rb = low, mbb = low), fifo2 read ( csa = low, w/ r a = low, mba = low). data in the fifo2 output register has been read from the fifo. 3. d = maximum fifo depth = 2,048 for the IDT72V3654, 4,096 for the idt72v3664, 8,192 for the idt72v3674. 4. if port b size is word or byte, afb is set low by the last word or byte write of the long word, respectively. afb clkb ena 4664 drw 28 enb clka 12 t skew2 t ens2 t enh t paf t ens2 t enh t paf [d-(y2+1)] words in fifo2 (d-y2) words in fifo2 (1) 4664 drw29 clka ena a0-a35 mba csa w/ r a clkb mbf1 csb mbb enb b0-b35 w /rb w1 t ens1 t enh t ds t dh t pmf t pmf t ens2 t enh t dis t en t mdv t pmr fifo1 output register w1 (remains valid in mail1 register after read) t ens1 t enh t ens2 t enh t ens2 t enh 33 commercial temperature range IDT72V3654/72v3664/72v3674 3.3v cmos syncbififo tm with bus-matching 2,048 x 36 x 2, 4,096 x 36 x 2 and 8,192 x 36 x 2 figure 28. timing for mail2 register and mbf2 flag (idt standard and fwft modes) note: 1. if port b is configured for word size, data can be written to the mail2 register using b0-b17 (b18-b35 are don?t care input s). in this first case a0-a17 will have valid data (a18-a35 will be indeterminate). if port b is configured for byte size, data can be written to the mail2 register using b0-b8 (b9-b35 are don?t care inputs). in this second case, a0-a8 will have valid data (a9-a35 will be indeterminate). 4664 drw30 clkb enb b0-b35 mbb csb w /rb clka mbf2 csa mba ena a0-a35 w/ r a w1 t ens1 t enh t dh t pmf t pmf t ens2 t enh t dis t en t mdv t pmr fifo2 output register w1 (remains valid in mail 2 register after read) t ens1 t enh t enh t enh t ens2 t ens2 t ds 34 commercial temperature range IDT72V3654/72v3664/72v3674 3.3v cmos syncbififo tm with bus-matching 2,048 x 36 x 2, 4,096 x 36 x 2 and 8,192 x 36 x 2 clka enb clkb rt1 4664 drw31 t rsts t rsth t ref (2) b0-bn rtm efb t ref (2) w1 wx t a 13 4 2 1 34 2 t rtms t rtmh t ens2 t enh notes: 1. csb = low 2. retransmit setup is complete after efb returns high, only then can a read operation begin. 3. w1 = first word written to the fifo1 after master reset on fifo1. 4. no more than d-2 may be written to the fifo1 between reset of fifo1 (master or partial) and retransmit setup. therefore, ffa will be low throughout the retransmit setup procedure. d = 2,048, 4,096 and 8,192 for the IDT72V3654, idt72v3664 and idt72v3674 respectively. figure 29. retransmit timing for fifo1 (idt standard mode) clkb ena clka rt2 4664 drw32 t rsts t rsth t ref (2) a0-an rtm efa t ref (2) w1 wx t a 13 4 2 1 34 2 t rtms t rtmh t ens2 t enh notes: 1. csa = low 2. retransmit setup is complete after efa returns high, only then can a read operation begin. 3. w1 = first word written to the fifo1 after master reset on fifo2. 4. no more than d-2 may be written to the fifo1 between reset of fifo2 (master or partial) and retransmit setup. therefore, ffb will be low throughout the retransmit setup procedure. d = 2,048, 4,096 and 8,192 for the IDT72V3654, idt72v3664 and idt72v3674 respectively. figure 30. retransmit timing for fifo2 (idt standard mode) 35 commercial temperature range IDT72V3654/72v3664/72v3674 3.3v cmos syncbififo tm with bus-matching 2,048 x 36 x 2, 4,096 x 36 x 2 and 8,192 x 36 x 2 clka enb clkb rt1 4664 drw33 t rsts t rsth t ref (2) b0-bn rtm orb t ref (2) w1 wx 13 4 2 1 34 2 t rtms t rtmh low t a notes: 1. csb = low 2. retransmit setup is complete after orb returns high, only then can a read operation begin. 3. w1 = first word written to the fifo1 after master reset on fifo1. 4. no more than d-2 may be written to the fifo1 between reset of fifo1 (master or partial) and retransmit setup. therefore, ira will be low throughout the retransmit setup procedure. d = 2,049, 4,097 and 8,193 for the IDT72V3654, idt72v3664 and idt72v3674 respectively. figure 31. retransmit timing for fifo1 (fwft mode) clkb ena clka rt2 4664 drw34 t rsts t rsth t ref (2) a0-an rtm ora t ref (2) w1 wx t a 13 4 2 1 34 2 t rtms t rtmh low notes: 1. csa = low 2. retransmit setup is complete after ora returns high, only then can a read operation begin. 3. w1 = first word written to the fifo2 after master reset on fifo2. 4. no more than d-2 may be written to the fifo2 between reset of fifo2 (master or partial) and retransmit setup. therefore, irb will be low throughout the retransmit setup procedure. d = 2,049, 4,097 and 8,193 for the IDT72V3654, idt72v3664 and idt72v3674 respectively. figure 32. retransmit timing for fifo2 (fwft mode) 36 commercial temperature range IDT72V3654/72v3664/72v3674 3.3v cmos syncbififo tm with bus-matching 2,048 x 36 x 2, 4,096 x 36 x 2 and 8,192 x 36 x 2 figure 33. output load and ac test conditions note: 1. includes probe and jig capacitance. 4664 drw 35 parameter measurement information from output under test 30 pf 330 ? 3.3v 510 ? propagation delay load circuit 3 v gnd timing input data, enable input gnd 3 v 1.5 v 1.5 v voltage waveforms setup and hold times voltage waveforms pulse durations voltage waveforms enable and disable times voltage waveforms propagation delay times 3 v gnd gnd 3 v 1.5 v 1.5 v 1.5 v 1.5 v t w output enable low-level output high-level output 3 v ol gnd 3 v 1.5 v 1.5 v 1.5 v 1.5 v oh o v gnd oh ol 1.5 v 1.5 v 1.5 v 1.5 v input in-phase output high-level input low-level input v v v v 1.5 v 3 v t s t h t plz t phz t pzl t pzh t pd t pd (1) 37 corporate headquarters for sales: for tech support: 2975 stender way 800-345-7015 or 408-727-6116 408-330-1753 santa clara, ca 95054 fax: 408-492-8674 e-mail: fifohelp@idt.com www.idt.com ordering information blank pf 10 15 l 72v3654 72v3664 72v3674 4664 drw36 commercial (0 c to +70 c) thin quad flat pack (tqfp, pk128-1) low power 2,048 x 36 x 2 ? 3.3v syncbififo with bus-matching 4,096 x 36 x 2 ? 3.3v syncbififo with bus-matching 8,192 x 36 x 2 ? 3.3v syncbififo with bus-matching xxxxxx idt device type xxx x x power speed package process/ temperature range clock cycle time (t clk ) speed in nanoseconds commercial only note: 1. industrial temperature range is available by special order. datasheet document history 06/13/2000 pgs. 1-3, 5, 6, 8-10, 12-14, 16, 19, 20, 23-33, and 37. 09/25/2000 pgs. 7, 9, 10 and 37. 12/22/2000 pgs. 4, 5 and 13. 02/08/2001 pgs. 5 and 12. 03/21/2001 pgs. 7 and 8. 11/03/2003 pg. 1. |
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