SN74ACT3641-15PCBR_技术文档

SN74ACT3641

1024 × 36

CLOCKED FIRST-IN, FIRST-OUT MEMORY

SCAS338C – JANUARY 1994 – REVISED OCTOBER 1997

Free-Running CLKA and CLKB Can Be

Asynchronous or Coincident

Output-Ready and Almost-Empty Flags

Synchronized by CLKB

Clocked FIFO Buffering Data From Port A

to Port B

Low-Power 0.8-µm Advanced CMOS

Technology

Memory Size: 1024 × 36

Supports Clock Frequencies up to 67 MHz

Fast Access Times of 11 ns

Synchronous Read-Retransmit Capability

Mailbox Register in Each Direction

Pin-to-Pin Compatible With the

SN74ACT3631 and SN74ACT3651

Programmable Almost-Full and

Almost-Empty Flags

Package Options Include 120-Pin Thin

Quad Flat (PCB) and 132-Pin Plastic Quad

Flat (PQ) Packages

Microprocessor Interface Control Logic

Input-Ready and Almost-Full Flags

Synchronized by CLKA

description

The SN74ACT3641 is a high-speed, low-power, CMOS clocked FIFO memory. It supports clock frequencies

up to 67 MHz and has read access times as fast as 12 ns. The 1024 × 36 dual-port SRAM FIFO buffers data

from port A to port B. The FIFO memory has retransmit capability, which allows previously read data to be

accessed again. The FIFO has flags to indicate empty and full conditions and two programmable flags (almost

full and almost empty) to indicate when a selected number of words is stored in memory. Communication

between each port takes place with two 36-bit mailbox registers. Each mailbox register has a flag to signal when

new mail has been stored. Two or more devices are used in parallel to create wider datapaths. Expansion is

also possible in word depth.

The SN74ACT3641 is a clocked FIFO, which means each port employs a synchronous interface. All data

transfersthroughaportaregatedtothelow-to-hightransitionofacontinuous(free-running)portclockbyenable

signals. The continuous clocks for each port are independent of one another and can be asynchronous or

coincident. The enables for each port are arranged to provide a simple interface between microprocessors

and/or buses with synchronous control.

The input-ready (IR) flag and almost-full (AF) flag of the FIFO are two-stage synchronized to CLKA. The

output-ready (OR) flag and almost-empty (AE) flag of the FIFO are two-stage synchronized to CLKB. Offset

values for the AF and AE flags of the FIFO can be programmed from port A or through a serial input.

The SN74ACT3641 is characterized for operation from 0°C to 70°C.

For more information on this device family, see the following application reports:

•

FIFO Patented Synchronous Retransmit: Programmable DSP-Interface Application for FIR Filtering

(literature number SCAA009)

FIFO Mailbox-Bypass Registers: Using Bypass Registers to Initialize DMA Control

(literature number SCAA007)

Metastability Performance of Clocked FIFOs (literature number SCZA004)

Please be aware that an important notice concerning availability, standard warranty, and use in critical applications of

Texas Instruments semiconductor products and disclaimers thereto appears at the end of this data sheet.

PRODUCTION DATA information is current as of publication date.

Products conform to specifications per the terms of Texas Instruments

standard warranty. Production processing does not necessarily include

testing of all parameters.

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SN74ACT3641

1024 × 36

CLOCKED FIRST-IN, FIRST-OUT MEMORY

SCAS338C – JANUARY 1994 – REVISED OCTOBER 1997

PCB PACKAGE

(TOP VIEW)

A35

A34

A33

A32

1

2

3

4

5

6

7

8

90

89

88

87

86

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69

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64

63

62

61

B35

B34

B33

B32

GND

B31

B30

B29

B28

B27

B26

V

A31

CC

A30

GND

A29

A28

A27

A26

A25

A24

A23

GND

A22

9

10

11

12

13

14

15

16

17

18

19

20

21

22

23

24

25

26

27

28

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30

V

CC

B25

B24

GND

B23

B22

B21

B20

B19

B18

GND

B17

B16

V

CC

A21

A20

A19

A18

GND

A17

A16

A15

A14

A13

V

CC

B15

B14

B13

B12

GND

V

A12

CC

NC – No internal connection

2

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SN74ACT3641

1024 × 36

CLOCKED FIRST-IN, FIRST-OUT MEMORY

SCAS338C – JANUARY 1994 – REVISED OCTOBER 1997

†

PQ PACKAGE

(TOP VIEW)

17 16 15 14 13 12 11 10

9

8

7

6

5

4

3

2

1 132 130 128

131

129

126 124 122 120 118

127 125 123

121 119

117

116

NC

B35

B34

B33

B32

GND

B31

B30

B29

B28

B27

B26

NC

A35

A34

A33

A32

18

19

20

21

22

23

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115

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111

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107

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105

104

103

102

101

100

99

V

CC

A31

A30

GND

A29

A28

A27

A26

A25

A24

A23

GND

A22

V

CC

B25

B24

GND

B23

B22

B21

B20

B19

B18

GND

B17

B16

98

97

V

CC

A21

A20

A19

A18

GND

A17

A16

A15

A14

A13

96

95

94

93

92

V

91

CC

B15

B14

B13

B12

GND

NC

90

89

88

87

V

86

CC

A12

NC

85

NC

84

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

NC – No internal connection

†

Uses Yamaichi socket IC51-1324-828

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SN74ACT3641

1024 × 36

CLOCKED FIRST-IN, FIRST-OUT MEMORY

SCAS338C – JANUARY 1994 – REVISED OCTOBER 1997

functional block diagram

MBF1

Mail1

Register

CLKA

CSA

W/RA

ENA

Port-A

Control

Logic

MBA

1024 × 36

SRAM

Reset

Logic

RST

RTM

RFM

36

Write

Pointer

Read

Pointer

A0–A35

B0–B35

Status-Flag

IR

AF

OR

AE

Logic

Flag-Offset

Register

FS0/SD

FS1/SEN

CLKB

CSB

W/RB

ENB

Port-B

Control

Logic

10

Mail2

Register

MBB

MBF2

4

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SN74ACT3641

1024 × 36

CLOCKED FIRST-IN, FIRST-OUT MEMORY

SCAS338C – JANUARY 1994 – REVISED OCTOBER 1997

Terminal Functions

TERMINAL

NAME

I/O

O

DESCRIPTION

A0–A35

Port-A data. The 36-bit bidirectional data port for side A.

Almost-empty flag. Programmable flag synchronized to CLKB. AE is low when the number of words in the FIFO is less

than or equal to the value in the almost-empty offset register (X).

AE

Almost-full flag. Programmable flag synchronized to CLKA. AF is low when the number of empty locations in the FIFO

is less than or equal to the value in the almost-full offset register (Y).

AF

O

I/O

I

B0–B35

CLKA

Port-B data. The 36-bit bidirectional data port for side B.

Port-A clock. CLKA is a continuous clock that synchronizes all data transfers through port A and can be asynchronous

or coincident to CLKB. IR and AF are synchronous to the low-to-high transition of CLKA.

Port-B clock. CLKB is a continuous clock that synchronizes all data transfers through port B and can be asynchronous

or coincident to CLKA. OR and AE are synchronous to the low-to-high transition of CLKB.

CLKB

CSA

CSB

I

Port-A chip select. CSA must be low to enable a low-to-high transition of CLKA to read or write data on port A. The

A0–A35 outputs are in the high-impedance state when CSA is high.

Port-B chip select. 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.

ENA

ENB

I

Port-A master enable. ENA must be high to enable a low-to-high transition of CLKA to read or write data on port A.

Port-B master enable. ENB must be high to enable a low-to-high transition of CLKB to read or write data on port B.

Flag-offset select 1/serial enable, flag-offset select 0/serial data. FS1/SEN and FS0/SD are dual-purpose inputs used

for flag-offset register programming. During a device reset, FS1/SEN and FS0/SD select the flag-offset programming

method. Three offset-register programming methods are available: automatically load one of two preset values, parallel

load from port A, and serial load.

FS1/SEN,

FS0/SD

I

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 loads the bit present on FS0/SD into the

X-and Y-offset registers. The number of bit writes required to program the offset registers is 20. The first bit write stores

the Y-register MSB and the last bit write stores the X-register LSB.

Input-ready flag. IR is synchronized to the low-to-high transition of CLKA. When IR is low, the FIFO is full and writes to

its array are disabled. When the FIFO is in retransmit mode, IR indicates when the memory has been filled to the point

of the retransmit data and prevents further writes. IR is set low during reset and is set high after reset.

IR

O

I

MBA

MBB

Port-A mailbox select. A high level on MBA chooses a mailbox register for a port-A read or write operation.

Port-B mailbox select. A high level on MBB chooses a mailbox register for a port-B read or write operation. When the

B0–B35 outputs are active, a high level on MBB selects data from the mail1 register for output and a low level selects

FIFO data for output.

I

Mail1 register flag. MBF1 is set low by the low-to-high transition of CLKA that writes data to the mail1 register. 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 by a

reset.

MBF1

MBF2

OR

O

Mail2 register flag. MBF2 is set low by the low-to-high transition of CLKB that writes data to the mail2 register. 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 by a

reset.

Output-ready flag. OR is synchronized to the low-to-high transition of CLKB. When OR is low, the FIFO is empty and

reads are disabled. Ready data is present in the output register of the FIFO when OR is high. OR is forced low during

the reset and goes high on the third low-to-high transition of CLKB after a word is loaded to empty memory.

Read from mark. When the FIFO is in retransmit mode, a high on RFM enables a low-to-high transition of CLKB to reset

the read pointer to the beginning retransmit location and output the first selected retransmit data.

RFM

RST

I

Reset. To reset the device, four low-to-high transitions of CLKA and four low-to-high transitions of CLKB must occur

while RST is low. The low-to-high transition of RST latches the status of FS0 and FS1 for AF and AE offset selection.

Retransmit mode. When RTM is high and valid data is present in the FIFO output register (OR is high), a low-to-high

transition of CLKB selects the data for the beginning of a retransmit and puts the FIFO in retransmit mode. The selected

word remains the initial retransmit point until a low-to-high transition of CLKB occurs while RTM is low, taking the FIFO

out of retransmit mode.

RTM

I

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SN74ACT3641

1024 × 36

CLOCKED FIRST-IN, FIRST-OUT MEMORY

SCAS338C – JANUARY 1994 – REVISED OCTOBER 1997

Terminal Functions (Continued)

TERMINAL

NAME

I/O

DESCRIPTION

Port-A write/read select. A high on W/RA selects a write operation and a low selects a read operation on port A for a

low-to-high transition of CLKA. The A0–A35 outputs are in the high-impedance state when W/RA is high.

W/RA

W/RB

I

Port-B write/read select. A low on W/RB selects a write operation and a high selects a read operation on port B for a

low-to-high transition of CLKB. The B0–B35 outputs are in the high-impedance state when W/RB is low.

detailed description

reset

The SN74ACT3641 is reset by taking the reset (RST) input low for at least four port-A clock (CLKA) and four

port-B clock (CLKB) low-to-high transitions. RST can switch asynchronously to the clocks. A reset initializes the

memory read and write pointers and forces the IR flag low, the OR flag low, the AE flag low, and the AF flag high.

Resetting the device also forces the mailbox flags (MBF1, MBF2) high. After a FIFO is reset, its flag is set high

after at least two clock cycles to begin normal operation. A FIFO must be reset after power up before data is

written to its memory.

almost-empty flag and almost-full flag offset programming

Two registers in the SN74ACT3641 are used to hold the offset values for the AE and AF flags. The AE flag offset

register is labeled X, and the AF flag offset register is labeled Y. The offset registers can be loaded with a value

in three ways: one of two preset values are loaded into the offset registers, parallel load from port A, or serial

load. The offset register programming mode is chosen by the flag select (FS1, FS0) inputs during a low-to-high

transition on RST (see Table 1).

Table 1. Flag Programming

†

FS1

H

FS0

H

RST

X AND Y REGISTERS

↑

Serial load

H

L

64

8

L

H

L

Parallel load from port A

†

X register holds the offset for AE; Y register holds the

offset for AF.

preset values

If a preset value of 8 or 64 is chosen by FS1 and FS0 at the time of a RST low-to-high transition according to

Table 1, the preset value is automatically loaded into the X and Y registers. No other device initialization is

necessary to begin normal operation, and the IR flag is set high after two low-to-high transitions on CLKA.

parallel load from port A

To program the X and Y registers from port A, the device is reset with FS0 and FS1 low during the low-to-high

transition of RST. After this reset is complete, IR is set high after two low-to-high transitions on CLKA. The first

two writes to the FIFO do not store data in its memory but load the offset registers in the order Y, X. Each offset

register of the SN74ACT3641 uses port-A inputs (A9–A0). Data input A9 is used as the most-significant bit of

the binary number. Each register value can be programmed from 1 to 1020. After both offset registers are

programmed from port A, subsequent FIFO writes store data in the SRAM.

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SN74ACT3641

1024 × 36

CLOCKED FIRST-IN, FIRST-OUT MEMORY

SCAS338C – JANUARY 1994 – REVISED OCTOBER 1997

serial load

To program the X and Y registers serially, the device is reset with FS0/SD and FS1/SEN high during the

low-to-high transition of RST. After this reset is complete, the X-and Y-register values are loaded bitwise through

FS0/SD on each low-to-high transition of CLKA that FS1/SEN is low. Twenty bit writes are needed to complete

the programming. The first bit write stores the most-significant bit of the Y register and the last bit write stores

the least-significant bit of the the X register. Each register value can be programmed from 1 to 1020.

When the option to program the offset registers serially is chosen, the IR remains low until all 20 bits are written.

IR is set high by the low-to-high transition of CLKA after the last bit is loaded to allow normal FIFO operation.

FIFO write/read operation

The state of the port-A data (A0–A35) outputs is controlled by the port-A chip select (CSA) and the port-A

write/read select (W/RA). The A0–A35 outputs are in the high-impedance state when either CSA or W/RA is

high. The A0–A35 outputs are active when both CSA and W/RA are low.

Data is loaded into the FIFO from the A0–A35 inputs on a low-to-high transition of CLKA when CSA and the

port-A mailbox select (MBA) are low, W/RA, the port-A enable (ENA), and the IR flag are high (see Table 2).

Writes to the FIFO are independent of any concurrent FIFO reads.

Table 2. Port-A Enable Function Table

CSA W/RA ENA

MBA CLKA

A0–A35 OUTPUTS

In high-impedance state

Active, mail2 register

PORT FUNCTION

H

L

X

H

L

X

L

X

L

X

↑

None

FIFO write

Mail1 write

None

H

L

H

L

↑

X

↑

L

H

L

None

L

H

X

↑

None

L

H

Mail2 read (set MBF2 high)

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 W/RA. The state of the port-B data (B0–B35) outputs is controlled by the port-B chip

select (CSB) and W/RB. The B0–B35 outputs are in the high-impedance state when either CSB is high or W/RB

is low. The B0–B35 outputs are active when CSB is low and W/RB is high.

Data is read from the FIFO to its output register on a low-to-high transition of CLKB when CSB and the port-B

mailbox select (MBB) are low, W/RB, the port-B enable (ENB), and the OR flag are high (see Table 3). Reads

from the FIFO are independent of any concurrent FIFO writes.

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SN74ACT3641

1024 × 36

CLOCKED FIRST-IN, FIRST-OUT MEMORY

SCAS338C – JANUARY 1994 – REVISED OCTOBER 1997

FIFO write/read operation (continued)

Table 3. Port-B Enable Function Table

CSB W/RB ENB

MBB CLKB

B0–B35 OUTPUTS

In high-impedance state

Active, FIFO output register

Active, mail1 register

PORT FUNCTION

H

L

X

L

X

L

X

L

X

↑

None

L

H

L

H

L

↑

Mail2 write

None

H

X

↑

H

L

FIFO read

H

X

↑

None

H

Active, mail1 register

Mail1 read (set MBF1 high)

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 and are not related to high-impedance control of the data outputs. If a

port enable is low during a clock cycle, the port-chip select and write/read select can change states during the

setup- and hold-time window of the cycle.

When the OR is low, the next data word is sent to the FIFO output register automatically by the CLKB low-to-high

transition that sets OR high. When OR is high, an available data word is clocked to the FIFO output register only

when a FIFO read is selected by CSB, W/RB, ENB, and MBB.

synchronized FIFO flags

Each FIFO flag is synchronized to its port clock through at least two flip-flop stages. This is done to improve the

flag’s reliability by reducing the probability of metastable events on their outputs when CLKA and CLKB operate

asynchronously to one another. OR and AE are synchronized to CLKB. IR and AF are synchronized to CLKA.

Table 4 shows the relationship of each flag to the number of words stored in memory.

Table 4. FIFO Flag Operation

SYNCHRONIZED

TO CLKB

SYNCHRONIZED

TO CLKA

NUMBER OF WORDS IN

†‡

FIFO

OR

L

AE

L

AF

H

L

IR

H

L

0

1 to X

(X + 1) to [1024 – (Y + 1)]

(1024 – Y) to 1023

1024

H

L

H

L

†

‡

X is the almost-empty offset for AE. Y is the almost-full offset for AF.

When a word is present in the FIFO output register, its previous memory

location is free.

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SN74ACT3641

1024 × 36

CLOCKED FIRST-IN, FIRST-OUT MEMORY

SCAS338C – JANUARY 1994 – REVISED OCTOBER 1997

output-ready flag (OR)

The OR flag of a FIFO is synchronized to the port clock that reads data from its array (CLKB). When the OR

flag is high, new data is present in the FIFO output register. When the OR flag is low, the previous data word

is present in the FIFO output register and attempted FIFO reads are ignored.

A FIFO read pointer is incremented each time a new word is clocked to its output register. 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 CLKB; therefore,

an OR flag is low if a word in memory is the next data to be sent to the FIFO output register and three CLKB

cycles have not elapsed since the time the word was written. The OR flag of the FIFO remains low until the third

low-to-high transition of CLKB occurs, simultaneously forcing the OR flag high and shifting the word to the FIFO

output register.

A low-to-high transition on CLKB begins the first synchronization cycle of a write if the clock transition

occurs at time t

synchronization cycle (see Figure 6).

, or greater, after the write. Otherwise, the subsequent CLKB cycle can be the first

sk(1)

input-ready flag (IR)

The IR flag of a FIFO is synchronized to the port clock that writes data to its array (CLKA). When the IR flag is

high, a memory location is free in the SRAM to write new data. No memory locations are free when the IR flag

is low and attempted writes to the FIFO are ignored.

Each time a word is written to a FIFO, its write pointer is incremented. From the time a word is read from a FIFO,

its previous memory location is ready to be written in a minimum of three cycles of CLKA; therefore, an IR flag

is low if less than two cycles of CLKA have elapsed since the next memory write location has been read. The

secondlow-to-hightransitiononCLKAafterthereadsetstheIRflaghigh, anddatacanbewritteninthefollowing

cycle.

A low-to-high transition on CLKA begins the first synchronization cycle of a read if the clock transition

occurs at time t

synchronization cycle (see Figure 7).

, or greater, after the read. Otherwise, the subsequent CLKA cycle can be the first

sk(1)

almost-empty flag (AE)

The AE flag of a FIFO is synchronized to the port clock that reads data from its array (CLKB). The almost-empty

state is defined by the contents of register X. This register is loaded with a preset value during a FIFO reset,

programmed from port A, or programmed serially (see almost-empty flag and almost-full flag offset

programming). The AE flag is low when the FIFO contains X or fewer words and is high when the 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 CLKB are required after a FIFO write for the AE flag to reflect the new level of

fill; therefore, the AE flag of a FIFO containing (X + 1) or more words remains low if two cycles of CLKB have

not elapsed since the write that filled the memory to the (X + 1) level. An AE flag is set high by the second

low-to-high transition of CLKB after the FIFO write that fills memory to the (X + 1) level.

A low-to-high transition of CLKB begins the first synchronization cycle if it occurs at time t

, or greater, after

sk(2)

the write that fills the FIFO to (X + 1) words. Otherwise, the subsequent CLKB cycle can be the first

synchronization cycle (see Figure 8).

9

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SN74ACT3641

1024 × 36

CLOCKED FIRST-IN, FIRST-OUT MEMORY

SCAS338C – JANUARY 1994 – REVISED OCTOBER 1997

almost-full flag (AF)

The AF flag of a FIFO is synchronized to the port clock that writes data to its array (CLKA). The almost-full state

is defined by the contents of register Y. This register is loaded with a preset value during a FIFO reset,

programmed from port A, or programmed serially (see almost-empty flag and almost-full flag offset

programming). The AF flag is low when the number of words in the FIFO is greater than or equal to (1024 – Y).

The AF flag is high when the number of words in the FIFO is less than or equal to [1024 – (Y + 1)]. A data word

present in the FIFO output register has been read from memory.

Two low-to-high transitions of CLKA are required after a FIFO read for its AF flag to reflect the new level of fill.

Therefore, the AF flag of a FIFO containing [1024 – (Y + 1)] or fewer words remains low if two cycles of CLKA

have not elapsed since the read that reduced the number of words in memory to [1024 – (Y + 1)]. An AF flag

is set high by the second low-to-high transition of CLKA after the FIFO read that reduces the number of words

in memory to [1024 – (Y + 1)]. A low-to-high transition of CLKA begins the first synchronization cycle if it occurs

at time t

, or greater, after the read that reduces the number of words in memory to [1024 – (Y + 1)].

sk(2)

Otherwise, the subsequent CLKA cycle can be the first synchronization cycle (see Figure 9).

synchronous retransmit

The synchronous retransmit feature of the SN74ACT3641 allows FIFO data to be read repeatedly starting at

a user-selected position. The FIFO is first put into retransmit mode to select a beginning word and prevent

ongoing FIFO write operations from destroying retransmit data. Data vectors with a minimum length of three

words can retransmit repeatedly, starting at the selected word. The FIFO can be taken out of retransmit mode

at any time and allow normal device operation.

The FIFO is put in retransmit mode by a low-to-high transition on CLKB when the retransmit mode (RTM) input

is high and OR is high. This rising CLKB edge marks the data present in the FIFO output register as the first

retransmit data. The FIFO remains in retransmit mode until a low-to-high transition occurs while RTM is low.

When two or more reads have been done past the initial retransmit word, a retransmit is initiated by alow-to-high

transition on CLKB when the read-from-mark (RFM) input is high. This rising CLKB edge shifts the first

retransmit word to the FIFO output register and subsequent reads can begin immediately. Retransmit loops can

bedoneendlesslywhiletheFIFOisinretransmitmode. RFMmustbelowduringtheCLKBrisingedgethattakes

the FIFO out of retransmit mode.

When the FIFO is put into retransmit mode, it operates with two read pointers. The current read pointer operates

normally, incrementing each time a new word is shifted to the FIFO output register and used by the OR and AE

flags. The shadow read pointer stores the SRAM location at the time the device is put into retransmit mode and

does not change until the device is taken out of retransmit mode. The shadow read pointer is used by the IR

and AF flags. Data writes can proceed while the FIFO is in retransmit mode, but AF is set low by the write that

stores (1024 – Y) words after the first retransmit word. The IR flag is set low by the 1024th write after the first

retransmit word.

When the FIFO is in retransmit mode and RFM is high, a rising CLKB edge loads the current read pointer with

theshadowread-pointervalueandtheORflagreflectsthenewleveloffillimmediately. Iftheretransmitchanges

the FIFO status out of the almost-empty range, up to two CLKB rising edges after the retransmit cycle are

needed to switch AE high (see Figure 11). The rising CLKB edge that takes the FIFO out of retransmit mode

shifts the read pointer used by the IR and AF flags from the shadow to the current read pointer. If the change

of read pointer used by IR and AF should cause one or both flags to transition high, at least two CLKA

synchronizing cycles are needed before the flags reflect the change. A rising CLKA edge after the FIFO is taken

out of retransmit mode is the first synchronizing cycle of IR if it occurs at time t

, or greater, after the rising

sk(1)

CLKB edge (see Figure 12). A rising CLKA edge after the FIFO is taken out of retransmit mode is the first

synchronizing cycle of AF if it occurs at time t , or greater, after the rising CLKB edge (see Figure 14).

sk(2)

10

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SN74ACT3641

1024 × 36

CLOCKED FIRST-IN, FIRST-OUT MEMORY

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mailbox registers

Two36-bitbypassregistersareontheSN74ACT3641topasscommandandcontrol information between portA

and port B. The mailbox-select (MBA, MBB) inputs choose between a mail register and a FIFO for a port data

transferoperation. Alow-to-hightransitiononCLKAwritesA0–A35 data to the mail1 register when a portAwrite

is selected by CSA, W/RA, and ENA with MBA high. 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. Writing data to a mail

register sets its corresponding flag (MBF1 or MBF2) low. Attempted writes to a mail register are ignored while

its mail flag is low.

When the port-B data (B0–B35) outputs are active, the data on the bus comes from the FIFO output register

when the port-B mailbox select (MBB) input is low and from the mail1 register when MBB is high. Mail2 data

is always present on the port-A data (A0–A35) outputs when they are active. 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. 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/RA, and ENA with MBA high. The data in a mail register remains intact after it is read

and changes only when new data is written to the register.

CLKA

t

h(RS)

CLKB

t

h(FS)

t

su(RS)

t

su(FS)

RST

FS1, FS0

0,1

t

pd(C-IR)

IR

OR

AE

AF

t

pd(C-OR)

t

pd(R-F)

t

pd(R-F)

t

MBF1,

MBF2

Figure 1. FIFO Reset Loading X and Y With a Preset Value of Eight

11

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CLOCKED FIRST-IN, FIRST-OUT MEMORY

SCAS338C – JANUARY 1994 – REVISED OCTOBER 1997

CLKA

RST

4

t

su(FS)

t

h(FS)

FS1, FS0

t

pd(C-IR)

IR

ENA

t

h(EN1)

t

su(EN1)

t

h(D)

t

su(D)

A0–A35

AF Offset

(Y)

AE Offset First Word Stored in FIFO

(X)

NOTE A: CSA=L, W/RA=H, MBA=L. Itisnotnecessarytoprogramoffsetregisteronconsecutiveclockcycles.

Figure 2. Programming the AF Flag and AE Flag Offset Values From Port A

CLKA

RST

4

t

pd(C-IR)

IR

FS1/SEN

FS0/SD

t

h(SP)

h(SEN)

t

su(SEN)

su(FS)

t

su(SEN)

h(SD)

t

su(FS)

t

su(SD)

h(FS)

su(SD)

AF Offset

(Y) MSB

AE Offset

(X) LSB

NOTE A: It is not necessary to program offset register bits on consecutive clock cycles. FIFO write attempts are ignored until IR is set high.

Figure 3. Programming the AF Flag and AE Flag Offset Values Serially

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CLOCKED FIRST-IN, FIRST-OUT MEMORY

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t

c

t

w(CLKL)

w(CLKH)

CLKA

IR

High

t

su(EN2)

h(EN2)

CSA

t

su(EN2)

h(EN2)

W/RA

MBA

ENA

t

su(EN2)

h(EN2)

t

h(EN1)

t

su(EN1)

h(EN1)

su(EN1)

t

su(D)

h(D)

A0–A35

No Operation

W1

W2

Figure 4. FIFO Write-Cycle Timing

t

c

t

w(CLKL)

w(CLKH)

CLKB

OR High

CSB

W/RB

MBB

t

su(EN1)

t

h(EN1)

ENB

No

Operation

t

pd(M-DV)

t

a

dis

t

a

t

en

B0–B35

W1

W2

W3

Figure 5. FIFO Read-Cycle Timing

13

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CLOCKED FIRST-IN, FIRST-OUT MEMORY

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t

c

t

w(CLKL)

w(CLKH)

CLKA

Low

CSA

W/RA

High

t

su(EN2)

t

h(EN2)

MBA

ENA

t

su(EN1)

t

h(EN1)

High

IR

t

su(D)

t

h(D)

A0–A35

W1

t

c

†

t

sk(1)

w(CLKL)

t

w(CLKH)

1

2

t

3

CLKB

OR

t

pd(C-OR)

Old Data in FIFO Output Register

CSB Low

W/RB

High

MBB Low

ENB

t

h(EN1)

su(EN1)

t

a

B0–B35

W1

Old Data in FIFO Output Register

†

t

is the minimum time between a rising CLKA edge and a rising CLKB edge for OR to transition high and to clock the next word to the

sk(1)

FIFO output register in three CLKB cycles. If the time between the rising CLKA edge and rising CLKB edge is less than t

of OR high and the first word load to the output register can occur one CLKB cycle later than shown.

, the transition

sk(1)

Figure 6. OR-Flag Timing and First Data-Word Fall-Through When the FIFO Is Empty

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t

c

t

w(CLKL)

w(CLKH)

CLKB

Low

CSB

W/RB

MBB

High

Low

t

h(EN1)

su(EN1)

ENB

OR

High

t

a

B0–B35

FIFO Output Register

Next Word From FIFO

†

t

sk(1)

t

c

t

w(CLKL)

w(CLKH)

1

2

CLKA

IR

t

pd(C-IR)

FIFO Full

CSA

W/RA

MBA

Low

High

t

h(EN2)

su(EN2)

t

su(EN1)

h(EN1)

ENA

t

su(D)

h(D)

Write

A0–A35

†

t

is the minimum time between a rising CLKB edge and a rising CLKA edge for IR to transition high in the next CLKA cycle. If the time

sk(1)

between the rising CLKB edge and rising CLKA edge is less than t

, IR can transition high one CLKA cycle later than shown.

sk(1)

Figure 7. IR-Flag Timing and First Available Write When the FIFO Is Full

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CLKA

t

h(EN1)

t

su(EN1)

ENA

†

t

sk(2)

CLKB

AE

1

2

t

pd(C-AE)

X Words in FIFO

(X + 1) Words in FIFO

t

h(EN1)

t

su(EN1)

ENB

†

t

is the minimum time between a rising CLKA edge and a rising CLKB edge for AE to transition high in the next CLKB cycle. If the time

sk(2)

between the rising CLKA edge and rising CLKB edge is less than t

, AE can transition high one CLKB cycle later than shown.

sk(2)

NOTE A: FIFO write (CSA = L, W/RA = H, MBA = L), FIFO read (CSB = L, W/RB = H, MBB = L)

Figure 8. Timing for AE When FIFO Is Almost Empty

‡

t

sk(2)

CLKA

ENA

1

2

t

h(EN1)

t

su(EN1)

t

pd(C-AF)

(1024 – Y) Words in FIFO

AF

[1024 – (Y + 1)] Words in FIFO

CLKB

ENB

t

h(EN1)

t

su(EN1)

‡

t

is the minimum time between a rising CLKA edge and a rising CLKB edge for AF to transition high in the next CLKA cycle. If the time

sk(2)

between the rising CLKB edge and rising CLKA edge is less than t

, AF can transition high one CLKA cycle later than shown.

sk(2)

NOTE A: FIFO write (CSA = L, W/RA = H, MBA = L), FIFO read (CSB = L, W/RB = H, MBB = L)

Figure 9. Timing for AF When FIFO Is Almost Full

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CLKB

ENB

t

su(EN1)

h(EN1)

t

h(RM)

t

su(RM)

h(RM)

RTM

RFM

t

h(RM)

su(RM)

OR

High

t

a

t

a

t

a

t

a

B0–B35

W0

W1

W2

W0

W1

Initiate Retransmit Mode

With W0 as First Word

Retransmit From

Selected Position

End Retransmit

Mode

NOTE A: CSB = L, W/RB = H, MBB = L. No input enables other than RTM and RFM are needed to control retransmit mode or begin a

retransmit. Other enables are shown only to relate retransmit operations to the FIFO output register.

Figure 10. Retransmit Timing Showing Minimum Retransmit Length

CLKB

RTM

1

2

High

t

h(RM)

t

su(RM)

RFM

AE

t

pd(C-AE)

X or Fewer Words From Empty

(X + 1) or More Words From Empty

NOTE A: X is the value loaded in the AE flag offset register.

Figure 11. AE Maximum Latency When Retransmit Increases the Number of Stored Words Above X

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†

t

sk(1)

CLKA

IR

1

2

t

pd(C-IR)

FIFO Filled to First Retransmit Word

One or More Write Locations Available

CLKB

t

h(RM)

su(RM)

RTM

†

t

is the minimum time between a rising CLKB edge and a rising CLKA edge for IR to transition high in the next CLKA cycle. If the time

sk(1)

between the rising CLKB edge and rising CLKA edge is less than t

, IR can transition high one CLKA cycle later than shown.

sk(1)

Figure 12. IR Timing From the End of Retransmit Mode When One or More Write Locations Are Available

‡

t

sk(2)

CLKA

AF

1

2

t

pd(C-AE)

(1024 – Y) or More Words Past First Retransmit Word

(Y + 1) or More Write Locations Available

CLKB

t

h(RM)

su(RM)

RTM

‡

t

is the minimum time between a rising CLKB edge and a rising CLKA edge for AF to transition high in the next CLKA cycle. If the time

sk(2)

between the rising CLKB edge and rising CLKA edge is less than t

, AF can transition high one CLKA cycle later than shown.

sk(2)

NOTE A: Y is the value loaded in the AF flag offset register.

Figure 13. AF Timing From the End of Retransmit Mode When (Y + 1)

or More Write Locations Are Available

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CLKA

t

h(EN2)

t

su(EN2)

CSA

W/RA

MBA

ENA

t

h(D)

t

su(D)

A0–A35

W1

CLKB

MBF1

t

pd(C-MF)

CSB

W/RB

MBB

ENB

t

h(EN1)

t

su(EN1)

t

pd(M-DV)

t

dis

t

en

t

pd(C-MR)

B0–B35

W1 (remains valid in mail1 register after read)

FIFO Output Register

Figure 14. Timing for Mail1 Register and MBF1 Flag

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CLOCKED FIRST-IN, FIRST-OUT MEMORY

SCAS338C – JANUARY 1994 – REVISED OCTOBER 1997

CLKB

t

h(EN2)

t

su(EN2)

CSB

W/RB

MBB

ENB

t

h(D)

t

su(D)

B0–B35

W1

CLKA

MBF2

t

pd(C-MF)

CSA

W/RA

MBA

ENA

t

h(EN1)

t

su(EN1)

t

en

dis

t

pd(C-MR)

A0–A35

W1 (remains valid in mail2 register after read)

Figure 15. Timing for Mail2 Register and MBF2 Flag

20

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1024 × 36

CLOCKED FIRST-IN, FIRST-OUT MEMORY

SCAS338C – JANUARY 1994 – REVISED OCTOBER 1997

†

absolute maximum ratings over operating free-air temperature range (unless otherwise noted)

Supply voltage range, V

. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . –0.5 V to 7 V

CC

Input voltage range, V (see Note 1) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . –0.5 V to V

+ 0.5 V

I

CC

Output voltage range, V (see Note 1) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . –0.5 V to V

O

Input clamp current, I (V < 0 or V > V ) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . ±20 mA

IK

I

CC

Output clamp current, I

(V < 0 or V > V ) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . ±50 mA

OK

O O CC

Continuous output current, I (V = 0 to V ) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . ±50 mA

Continuous current through V

Package thermal impedance, θ (see Note 2): PCB package . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 28°C/W

O

CC

or GND . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . ±400 mA

JA

PQ package . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 46°C/W

Storage temperature range, T

. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . –65°C to 150°C

stg

†

Stresses beyond those listed under “absolute maximum ratings” may cause permanent damage to the device. These are stress ratings only, and

functional operation of the device at these or any other conditions beyond those indicated under “recommended operating conditions” is not

implied. Exposure to absolute-maximum-rated conditions for extended periods may affect device reliability.

NOTES: 1. The input and output voltage ratings may be exceeded provided the input and output current ratings are observed.

2. The package thermal impedance is calculated in accordance with JESD 51.

recommended operating conditions

MIN

4.5

2

MAX

UNIT

V

Supply voltage

5.5

CC

High-level input voltage

Low-level input voltage

High-level output current

Low-level output current

Operating free-air temperature

V

IH

0.8

–4

8

V

IL

I

mA

°C

OH

OL

T

A

0

70

electrical characteristics over recommended operating free-air temperature range (unless

otherwise noted)

‡

PARAMETER

TEST CONDITIONS

= –4 mA

MIN TYP

MAX

UNIT

V

CC

V

CC

V

CC

V

CC

V

CC

= 4.5 V,

= 5.5 V,

I

2.4

OH

= 8 mA

0.5

±5

V

OL

I

V = V

or 0

µA

I

CC

V

= V

or 0

±5

OZ

CC

O

CC

V = V

– 0.2 V or 0

400

I

CC

CSA = V

CSB = V

CSA = V

CSB = V

A0–A35

B0–B35

A0–A35

B0–B35

0

IH

IL

V

= 5.5 V, One input at 3.4 V,

CC

§

∆I

CC

1

mA

Other inputs at V

or GND

CC

All other inputs

C

V = 0,

f = 1 MHz

4

8

pF

i

I

V

O

= 0,

o

‡

§

All typical values are at V

= 5 V, T = 25°C.

A

CC

This is the supply current when each input is at one of the specified TTL voltage levels rather than 0 V or V

.

CC

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timing requirements over recommended ranges of supply voltage and operating free-air

temperature (see Figures 1 through 16)

’ACT3641-15 ’ACT3641-20 ’ACT3641-30

UNIT

MIN

MAX

MIN

MAX

MIN

MAX

f

t

Clock frequency, CLKA or CLKB

66.7

50

33.4

MHz

ns

clock

Clock cycle time, CLKA or CLKB

15

6

20

8

30

12

7

c

Pulse duration, CLKA and CLKB high

Pulse duration, CLKA and CLKB low

ns

w(CH)

w(CL)

su(D)

su(EN1)

6

8

ns

Setup time, A0–A35 before CLKA↑ and B0–B35 before CLKB↑

Setup time, ENA to CLKA↑; ENB to CLKB↑

5

6

ns

5

6

7

ns

Setup time, CSA, W/RA, and MBA to CLKA↑;

CSB, W/RB, and MBB to CLKB↑

t

7

7.5

8

ns

su(EN2)

t

Setup time, RTM and RFM to CLKB↑

6

5

9

5

0

6.5

6

7

ns

su(RM)

su(RS)

su(FS)

†

Setup time, RST low before CLKA↑ or CLKB↑

Setup time, FS0 and FS1 before RST high

Setup time, FS0/SD before CLKA↑

10

6

11

7

‡

su(SD)

‡

Setup time, FS1/SEN before CLKA↑

6

7

su(SEN)

h(D)

Hold time, A0–A35 after CLKA↑ and B0–B35 after CLKB↑

Hold time, ENA after CLKA↑; ENB after CLKB↑

0

n(EN1)

Hold time, CSA, W/RA, and MBA after CLKA↑;

CSB, W/RB, and MBB after CLKB↑

t

0

ns

n(EN2)

t

Hold time, RTM and RFM after CLKB↑

0

5

0

6

0

7

ns

n(RM)

h(RS)

h(FS)

†

Hold time, RST low after CLKA↑ or CLKB↑

Hold time, FS0 and FS1 after RST high

Hold time, FS1/SEN high after RST high

Hold time, FS0/SD after CLKA↑

0

‡

0

h(SP)

‡

0

h(SD)

‡

Hold time, FS1/SEN after CLKA↑

0

h(SEN)

§

Skew time between CLKA↑ and CLKB↑ for OR and IR

Skew time between CLKA↑ and CLKB↑ for AE and AF

9

11

16

13

20

sk(1)

§

12

sk(2)

†

‡

§

Requirement to count the clock edge as one of at least four needed to reset a FIFO

Applies only when serial load method is used to program flag-offset registers

Skew time is not a timing constraint for proper device operation and is included only to illustrate the timing relationship between CLKA cycle and

CLKB cycle.

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SCAS338C – JANUARY 1994 – REVISED OCTOBER 1997

switching characteristics over recommended ranges of supply voltage and operating free-air

temperature, C = 30 pF (see Figures 1 through 15)

L

’ACT3641-15 ’ACT3641-20 ’ACT3641-30

PARAMETER

UNIT

MIN

MAX

MIN

50

3

MAX

MIN

MAX

f

t

66.7

33.4

MHz

ns

max

Access time, CLKB↑ to B0–B35

3

1

11

8

13

10

3

1

15

12

a

Propagation delay time, CLKA↑ to IR

Propagation delay time, CLKB↑ to OR

Propagation delay time, CLKB↑ to AE

Propagation delay time, CLKA↑ to AF

1

ns

pd(C-IR)

pd(C-OR)

pd(C-AE)

pd(C-AF)

8

1

ns

8

1

ns

8

1

ns

Propagation delay time, CLKA↑ to MBF1 low or MBF2 high and

CLKB↑ to MBF2 low or MBF1 high

t

0

3

8

0

3

10

15

0

3

12

17

ns

pd(C-MF)

pd(C-MR)

†

Propagation delay time, CLKA↑ to B0–B35 and CLKB↑ to

13.5

‡

A0–A35

t

Propagation delay time, MBB to B0–B35 valid

3

1

13

15

3

1

15

20

3

1

17

30

ns

pd(M-DV)

Propagation delay time, RST low to AE low and AF high

pd(R-F)

Enable time, CSA and W/RA low to A0–A35 active and CSB low

and W/RB high to B0–B35 active

t

2

1

12

8

2

1

13

10

2

1

14

11

ns

en

Disable time, CSA or W/RA high to A0–A35 at high impedance

and CSB high or W/RB low to B0–B35 at high impedance

t

dis

†

‡

Writing data to the mail1 register when the B0–B35 outputs are active and MBB is high

Writing data to the mail2 register when the A0–A35 outputs are active and MBA is high

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PARAMETER MEASUREMENT INFORMATION

5 V

1.1 kΩ

From Output

Under Test

30 pF

(see Note A)

680 Ω

LOAD CIRCUIT

3 V

Timing

Input

High-Level

Input

1.5 V

t

1.5 V

GND

3 V

t

h

t

su

w

Data,

Enable

Input

3 V

1.5 V

Low-Level

Input

1.5 V

GND

VOLTAGE WAVEFORMS

SETUP AND HOLD TIMES

VOLTAGE WAVEFORMS

PULSE DURATIONS

3 V

Output

Enable

1.5 V

GND

t

PLZ

t

PZL

≈ 3 V

3 V

Low-Level

Output

1.5 V

Input

V

OL

GND

t

PZH

t

pd

OH

High-Level

Output

V

OH

In-Phase

Output

1.5 V

≈ 0 V

OL

t

PHZ

VOLTAGE WAVEFORMS

PROPAGATION DELAY TIMES

VOLTAGE WAVEFORMS

ENABLE AND DISABLE TIMES

NOTES: A. Includes probe and jig capacitance

B.

C.

t

and t

are the same as t

PZL

PLZ

PZH

PHZ

en

dis

Figure 16. Load Circuit and Voltage Waveforms

24

POST OFFICE BOX 655303 • DALLAS, TEXAS 75265

SN74ACT3641

1024 × 36

CLOCKED FIRST-IN, FIRST-OUT MEMORY

SCAS338C – JANUARY 1994 – REVISED OCTOBER 1997

TYPICAL CHARACTERISTICS

SUPPLY CURRENT

vs

CLOCK FREQUENCY

250

200

150

100

50

f

T

C

= 1/2 f

clock

data

A

L

V

CC

= 5.5 V

= 25°C

= 0 pF

V

CC

= 5 V

V

CC

= 4.5 V

0

10

20

30

40

50

60

70

f

– Clock Frequency – MHz

clock

Figure 17

calculating power dissipation

The I

current in Figure 17 was taken while simultaneously reading and writing the FIFO on the

CC(f)

SN74ACT3641 with CLKA and CLKB set to f

. All data inputs and data outputs change state during each

clock

clock cycle to consume the highest supply current. Data outputs are disconnected to normalize the graph to a

zero-capacitance load. Once the capacitive load per data-output channel and the number of SN74ACT3641

inputs driven by TTL high levels are known, the power dissipation can be calculated with the equation below.

With I

by:

taken from Figure 17, the maximum power dissipation (P ) of the SN74ACT3641 can be calculated

T

CC(f)

2

P = V

× [I

+ (N × ∆I

× dc)] + ∑(C × V

× f )

T

CC

CC(f)

CC

L

CC

o

where:

N

= number of inputs driven by TTL levels

∆I

dc

= increase in power-supply current for each input at a TTL high level

= duty cycle of inputs at a TTL high level of 3.4 V

= output capacitive load

CC

C

L

f

= switching frequency of an output

o

When no reads or writes are occurring on the SN74ACT3641, the power dissipated by a single clock (CLKA

or CLKB) input running at frequency f is calculated by:

clock

P = V

× f

× 0.29 mA/MHz

T

CC

clock

25

POST OFFICE BOX 655303 • DALLAS, TEXAS 75265

PACKAGE OPTION ADDENDUM

www.ti.com

18-Dec-2006

PACKAGING INFORMATION

Orderable Device

SN74ACT3641-15PCB

SN74ACT3641-15PQ

SN74ACT3641-20PCB

SN74ACT3641-20PQ

SN74ACT3641-30PCB

SN74ACT3641-30PQ

Status ⁽¹⁾

ACTIVE

Package Package

Pins Package Eco Plan ⁽²⁾Lead/Ball Finish MSL Peak Temp ⁽³⁾

Qty

Type

Drawing

HLQFP

PCB

120

132

120

132

120

132

90 Green (RoHS & CU NIPDAU Level-3-260C-168 HR

no Sb/Br)

BQFP

HLQFP

BQFP

PQ

PCB

PQ

36 Green (RoHS & CU NIPDAU Level-4-260C-72 HR

no Sb/Br)

90 Green (RoHS & CU NIPDAU Level-3-260C-168 HR

no Sb/Br)

36 Green (RoHS & CU NIPDAU Level-4-260C-72 HR

no Sb/Br)

HLQFP

BQFP

PCB

PQ

90 Green (RoHS & CU NIPDAU Level-3-260C-168 HR

no Sb/Br)

36 Green (RoHS & CU NIPDAU Level-4-260C-72 HR

no Sb/Br)

⁽¹⁾The marketing status values are defined as follows:

ACTIVE: Product device recommended for new designs.

LIFEBUY: TI has announced that the device will be discontinued, and a lifetime-buy period is in effect.

NRND: Not recommended for new designs. Device is in production to support existing customers, but TI does not recommend using this part in

a new design.

PREVIEW: Device has been announced but is not in production. Samples may or may not be available.

OBSOLETE: TI has discontinued the production of the device.

(2)

Eco Plan - The planned eco-friendly classification: Pb-Free (RoHS), Pb-Free (RoHS Exempt), or Green (RoHS & no Sb/Br) - please check

http://www.ti.com/productcontent for the latest availability information and additional product content details.

TBD: The Pb-Free/Green conversion plan has not been defined.

Pb-Free (RoHS): TI's terms "Lead-Free" or "Pb-Free" mean semiconductor products that are compatible with the current RoHS requirements

for all 6 substances, including the requirement that lead not exceed 0.1% by weight in homogeneous materials. Where designed to be soldered

at high temperatures, TI Pb-Free products are suitable for use in specified lead-free processes.

Pb-Free (RoHS Exempt): This component has a RoHS exemption for either 1) lead-based flip-chip solder bumps used between the die and

package, or 2) lead-based die adhesive used between the die and leadframe. The component is otherwise considered Pb-Free (RoHS

compatible) as defined above.

Green (RoHS & no Sb/Br): TI defines "Green" to mean Pb-Free (RoHS compatible), and free of Bromine (Br) and Antimony (Sb) based flame

retardants (Br or Sb do not exceed 0.1% by weight in homogeneous material)

(3)

MSL, Peak Temp. -- The Moisture Sensitivity Level rating according to the JEDEC industry standard classifications, and peak solder

temperature.

Important Information and Disclaimer:The information provided on this page represents TI's knowledge and belief as of the date that it is

provided. TI bases its knowledge and belief on information provided by third parties, and makes no representation or warranty as to the

accuracy of such information. Efforts are underway to better integrate information from third parties. TI has taken and continues to take

reasonable steps to provide representative and accurate information but may not have conducted destructive testing or chemical analysis on

incoming materials and chemicals. TI and TI suppliers consider certain information to be proprietary, and thus CAS numbers and other limited

information may not be available for release.

In no event shall TI's liability arising out of such information exceed the total purchase price of the TI part(s) at issue in this document sold by TI

to Customer on an annual basis.

Addendum-Page 1

MECHANICAL DATA

MBQF001A – NOVEMBER 1995

PQ (S-PQFP-G***)

PLASTIC QUAD FLATPACK

100 LEAD SHOWN

13

1 100

89

14

88

0.012 (0,30)

0.008 (0,20)

0.006 (0,15)

M

”D3” SQ

0.025 (0,635)

0.006 (0,16) NOM

64

38

0.150 (3,81)

0.130 (3,30)

39

63

Gage Plane

”D1” SQ

”D” SQ

0.010 (0,25)

0.020 (0,51) MIN

Seating Plane

”D2” SQ

0°–8°

0.046 (1,17)

0.036 (0,91)

0.004 (0,10)

0.180 (4,57) MAX

LEADS ***

100

132

DIM

MAX

MIN

0.890 (22,61)

0.870 (22,10)

0.766 (19,46)

0.734 (18,64)

0.912 (23,16)

0.888 (22,56)

0.600 (15,24)

1.090 (27,69)

1.070 (27,18)

0.966 (24,54)

0.934 (23,72)

1.112 (28,25)

1.088 (27,64)

0.800 (20,32)

”D”

MAX

MIN

”D1”

MAX

MIN

”D2”

”D3”

NOM

4040045/C 11/95

NOTES: A. All linear dimensions are in inches (millimeters).

B. This drawing is subject to change without notice.

C. Falls within JEDEC MO-069

POST OFFICE BOX 655303 • DALLAS, TEXAS 75265

MECHANICAL DATA

MHTQ004A – JANUARY 1995 – REVISED JANUARY 1998

PCB (S-PQFP-G120)

PLASTIC QUAD FLATPACK (DIE DOWN)

0,23

0,13

M

0,07

0,40

90

61

Heat Slug

60

91

31

120

0,13 NOM

1

30

11,60 TYP

Gage Plane

14,20

SQ

13,80

0,25

16,20

SQ

0,05 MIN

0°–7°

15,80

1,45

1,35

0,75

0,45

Seating Plane

0,08

1,60 MAX

4040202/C 12/96

NOTES: A. All linear dimensions are in millimeters.

B. This drawing is subject to change without notice.

C. Thermally enhanced molded plastic package with a heat slug (HSL)

D. Falls within JEDEC MS-026

POST OFFICE BOX 655303 • DALLAS, TEXAS 75265

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TI warrants performance of its hardware products to the specifications applicable at the time of sale in

accordance with TI’s standard warranty. Testing and other quality control techniques are used to the extent TI

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Post Office Box 655303 Dallas, Texas 75265


型号：	SN74ACT3641-15PCBR
厂家：	Rochester Electronics
描述：	1KX36 OTHER FIFO, 11ns, PQFP120, GREEN, PLASTIC, HLQFP-120 先进先出芯片
文件：	总30页 (文件大小：1140K)
中文：	中文翻译
下载：	下载PDF数据表文档文件

SN74ACT3641-15PCBR [ROCHESTER]

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