CY7C43686-15AI_技术文档

CY7C43666 CY7C436461K/4K/16K x36/x18/x2 Tri Bus FIFO

CY7C43646

CY7C43666

CY7C43686

1K/4K/16K x36/x18/x2 Tri Bus FIFO

• Fully asynchronous and simultaneous read and write

operation permitted

• Mailbox bypass register for each FIFO

Features

• High-speed, low-power, first-in first-out (FIFO) memo-

ries w/ three independent ports (one bidirectional x36,

and two unidirectional x18)

• 1K x36/x18x2 (CY7C43646)

• 4K x36/x18x2 (CY7C43666)

• 16K x36/x18x2 (CY7C43686)

• Parallel and Serial Programmable Almost Full and

Almost Empty flags

• Retransmit function

• Standard or FWFT mode user-selectable

• Partial Reset

• Big or Little Endian format for word or byte bus sizes

• 128-pin TQFP packaging

• Easily expandable in width and depth

• 0.35-micron CMOS for optimum speed/power

• High speed 133-MHz operation (7.5-ns read/write

cycle times)

• Low power

— I_CC= 100 mA

— I_SB= 10 mA

Logic Block Diagram

MBF1

CLKA

Mail1

CSA

Register

Port A

Control

Logic

W/RA

ENA

MBA

RT2

1K/4K/16K

x36

Dual Ported

Memory

B

0−17

CLKB

RENB

CSB

SIZEB

MBB

RTI

Port B

Control

Logic

MRS1

PRS1

FIFO1,

Mail1

Reset

Logic

Read

Pointer

Write

Pointer

FFA/IRA

AFA

Status

Flag Logic

EFB/ORB

AEB

Common

BE

Port Logic

(B and C)

SPM

FS0/SD

FS1/SEN

Timing

Mode

Programmable

Flag Offset

Registers

BE/FWFT

A

0−35

Status

Flag Logic

FFC/IRC

AFC

EFA/ORA

AEA

FIFO2,

Mail2

Reset

Logic

MRS2

PRS2

Write

Pointer

Read

Pointer

C

0−17

256/512/1K

4K/16K x36

Dual Ported

Memory

CLKC

WENC

Port C

Control

Logic

SIZEC

MBC

Mail2

Register

MBF2

Cypress Semiconductor Corporation

•

3901 North First Street

•

San Jose, CA 95134

•

408-943-2600

Document #: 38-06023 Rev. *C

Revised September 26, 2003

CY7C43646

CY7C43666

CY7C43686

Selection Guide

CY7C43646/66/86

-7

CY7C43646/66/86

-10

CY7C43646/66/86

-15

Unit

MHz

ns

Maximum Frequency

133

6

100

8

66.7

10

Maximum Access Time

Minimum Cycle Time

Minimum Data or Enable Set-up

Minimum Data or Enable Hold

Maximum Flag Delay

7.5

3

0

10

4

0

15

5

0

8

ns

6

8

Active Power Supply

Commercial

Industrial

CY7C43646

100

CY7C43686

16K x 36

128 TQFP

mA

Current (I_CC1

)

CY7C43666

4K x 36

128 TQFP

Density

Package

1K x 36

128 TQFP

Pin Configuration

TQFP

Top View

W/RA

ENA

CLKA

GND

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

102

101

100

99

98

97

96

95

94

93

92

91

90

89

88

87

86

85

84

83

82

81

80

79

78

77

76

75

74

CLKB

PRS2

CC

V

C

17

A

35

16

A

34

C

15

A

33

32

14

GND

MBC

V

CC

A

31

C

13

12

11

A

30

GND

A

29

28

27

26

25

24

23

10

9

8

CY7C43646

CY7C43666

CY7C43686

RT1

C

7

6

SIZEB

GND

BE/FWFT

GND

C

5

A

22

C

4

3

2

V

CC

A

21

20

19

18

1

C

0

GND

B

17

A

17

16

15

14

13

B

16

SIZEC

73

V

15

72

CC

B

71

70

69

68

67

66

65

B

14

RT2

B

13

A

B

12

GND

A

B

11

A

B

10

Document #: 38-06023 Rev. *C

Page 2 of 39

CY7C43646

CY7C43666

CY7C43686

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 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 FFC/IRC). The EF and FF functions are

selected in the CY Standard Mode. EF indicates 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.^[1]

Each FIFO has a programmable Almost Empty flag (AEA and

AEB) and a programmable Almost Full flag (AFA and AFC).

AEA and AEB indicate when a selected number of words

written to FIFO memory achieve a predetermined “almost

empty state.” AFA and AFC indicate when a selected number

of words written to the memory achieve a predetermined

“almost full state.”^[2]

IRA, IRC, AFA, and AFC are synchronized to the port clock

that writes data into its array. ORA, ORB, AEA, and AEB are

synchronized to the port clock that reads data from its array.

Programmable offset for AEA, AEB, AFA, and AFC are loaded

in parallel using Port A or in serial via the SD input. Three

default offset settings are also provided. The AEA and AEB

threshold can be set at 8, 16, or 64 locations from the empty

boundary and AFA and AFC threshold can be set at 8, 16, or

64 locations from the full boundary. All these choices are made

using the FS0 and FS1 inputs during Master Reset.

Functional Description

The CY7C436X6 is a monolithic, high-speed, low-power,

CMOS Bidirectional Synchronous (clocked) FIFO memory,

which supports clock frequencies up to 133 MHz and has read

access times as fast as 6 ns. Two independent 1K/4K/16K x36

dual-port SRAM FIFOs on board each chip buffer data in

opposite directions.

The CY7C436X6 is 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

coincident. The enables for each port are arranged to provide

a simple bidirectional interface between microprocessors

and/or buses with synchronous control.

Communication between each port may bypass the FIFOs via

two mailbox registers. The mailbox registers’ width matches

the selected Port B or Port C 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 the CY7C436X6: 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 the three possible default flag offset

settings, 8, 16, or 64. Each FIFO has its own independent

Master Reset pin, 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.

The CY7C436X6 have two modes of operation. In the CY

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

Two or more devices may be used in parallel to create wider

data paths. Such a width expansion requires no additional

external components.

The CY7C436X6 are characterized for operation from 0°C to

70°C commercial, and from –40°C to 85°C industrial. Input

ESD protection is greater than 2001V, and latch-up is prevented by

the use of guard rings.

Pin Definitions

Signal Name

A_0–35

Description

Port A Data

I/O

Function

I/O 36-bit bidirectional data port for side A.

AEA

Port A Almost

Empty Flag

O

Programmable Almost Empty flag synchronized to CLKA. It is LOW when the

number of words in FIFO2 is less than or equal to the value in the Almost Empty A

offset register, X2.^[2]

Programmable Almost Empty flag synchronized to CLKB. It is LOW when the

number of words in FIFO1 is less than or equal to the value in the Almost Empty B

offset register, X1.^[2]

Programmable Almost Full flag synchronized to CLKA. It is LOW when the number

of empty locations in FIFO1 is less than or equal to the value in the Almost Full A offset

register, Y1.^[2]

Programmable Almost Full flag synchronized to CLKC. It is LOW when the number

of empty locations in FIFO2 is less than or equal to the value in the Almost Full B offset

register, Y2.^[2]

AEB

AFA

Port B Almost

Empty Flag

Port A Almost

Full Flag

AFC

B_0–17

Port C Almost

Full Flag

Port B Data

18-bit output data port for port B.

Document #: 38-06023 Rev. *C

Page 3 of 39

CY7C43646

CY7C43666

CY7C43686

Pin Definitions (continued)

Signal Name

Description

I/O

Function

BE/FWFT

Big Endian/

First-Word

Fall-Through

Select

I

This is a dual-purpose pin. During Master Reset, a HIGH on BE will select Big Endian

operation. In this case, depending on the bus size, the most significant byte or word

on Port A is transferred to Port B first for A-to-B data flow. For data flowing from Port

C to Port A, the first word/byte written to Port C will come out as the most significant

word/byte on Port A. On the other hand a LOW on BE will select Little Endian operation.

In this case, the least significant byte or word on Port A is transferred to Port B first for

A to B data flow. Similarly, the first word/byte written into Port C will come out as the

least significant word/byte on Port A for C-to-A data flow. After Master Reset, this pin

selects the timing mode. A HIGH on FWFT selects CY Standard Mode, a LOW selects

First-Word Fall-Through Mode. Once the timing mode has been selected, the level on

this pin must be static throughout device operation.

C_0–17

CLKA

Port B Data

Port A Clock

I

18-bit input data port for port C.

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

CLKC

Port B Clock

Port C Clock

I

CLKB is a continuous clock that synchronizes all data transfers through Port B

and can be asynchronous or coincident to CLKA. EFB/ORB and AEB are all synchro-

nized to the LOW-to-HIGH transition of CLKB.

CLKC is a continuous clock that synchronizes all data transfers through Port C

and can be asynchronous or coincident to CLKA. FFC/IRC, and AFC are all synchro-

nized to the LOW-to-HIGH transition of CLKC.

CSA

Port A Chip

Select

Port B Chip

Select

I

CSA must be LOW to enable a LOW-to HIGH transition of CLKA to read or write

on Port A. The A₀₋₃₅outputs are in the high-impedance state when CSA is HIGH.

CSB

CSB must be LOW to enable a LOW-to HIGH transition of CLKB to read or write

on Port B. The B_0–17outputs are in the high-impedance state when CSB is HIGH.

EFA/ORA

Port A

O

This is a dual-function pin. In the CY Standard Mode, the EFA function is selected.

EFA 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 A₀₋₃₅outputs,

available for reading. EFA/ORA is synchronized to the LOW-to-HIGH transition of

CLKA.^[1]

Empty/Output

Ready Flag

EFB/ORB

Port B

O

This is a dual-function pin. In the CY Standard Mode, the EFB function is selected.

EFB indicates 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 B_0–17outputs,

available for reading. EFB/ORB is synchronized to the LOW-to-HIGH transition of

CLKB.^[1]

Empty/Output

Ready Flag

ENA

Port A Enable

Port B Enable

I

ENA must be HIGH to enable a LOW-to-HIGH transition of CLKA to read or write

data on Port A.

ENB

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/Input

Ready Flag

O

This is a dual-function pin. In the CY Standard Mode, the FFA function is selected.

FFA indicates 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.

FFC/IRC

PortCFull/Input

Ready Flag

O

This is a dual-function pin. In the CY Standard Mode, the FFC function is selected. FFC

indicates whether or not the FIFO2 memory is full. In the FWFT mode, the IRC function

is selected. IRC indicates whether or not there is space available for writing to the

FIFO2 memory. FFC/IRC is synchronized to the LOW-to-HIGH transition of CLKB.

Notes:

1. When reading from the FIFO under FWFT, ORA/ORB signal should be included in the read logic to ensure proper operation. To read without gating the boundary

flag (e.g., in bursts), use CY standard mode.

2. When FIFO is operated at the almost empty/full boundary, there may be an uncertainty of up to three clock cycles for flag assertion and deassertion. Refer to

“Designing with CY7C436xx Synchronous FIFO” application notes for more details on flag uncertainties.

Document #: 38-06023 Rev. *C

Page 4 of 39

CY7C43646

CY7C43666

CY7C43686

Pin Definitions (continued)

Signal Name

Description

I/O

Function

FS1/SEN

Flag Offset

Select 1/Serial

Enable

Flag Offset

Select 0/Serial

Data

I

FS1/SEN and FS0/SD are dual-purpose inputs used for flag offset register

programming. During Master Reset, FS1/SEN and FS0/SD, together with SPM, select

the flag offset programming method. Three offset register programming methods are

available: automatically load one of three preset values (8, 16, or 64), parallel load from

Port A, or serial load. 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 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 32 for the CY7C43626, 36 for the CY7C43636, 40 for the CY7C43646, 48 for the

CY7C43666, and 56 for the CY7C43686. The first bit write stores the Y-register MSB

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

FS0/SD

I

MBA

MBB

Port A Mailbox

Select

I

A HIGH level on MBA chooses a mailbox register for a Port A read or write

operation. When a read operation is performed on Port A, a HIGH level on MBA selects

data from the Mail2 register for output and a LOW level selects FIFO2 output register

data for output. When a write operation is performed on Port A, a High level on MBA

will write the data into Mail 1 register, while a Low level will write the data into FIFO 1.

A HIGH level on MBB chooses a mailbox register for a Port B read operation. When

a read operation is performed on Port B, a HIGH level on MBB selects data from the

Mail1 register for output and a LOW level selects FIFO1 output register data for output.

Port B Mailbox

Select

MBC

Port C Mailbox

Select

I

When a write operation is performed on Port C, a HIGH level on MBC writes data

into Mail2 register, and a LOW level writes into FIFO2.

MBF1

Mail1 Register

Flag

O

MBF1 is set LOW by a LOW-to-HIGH transition of CLKA that writes data to the Mail1

register. 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

MRS1

Mail2 Register

Flag

O

I

MBF2 is set LOW by a LOW-to-HIGH transition of CLKB that writes data to the Mail2

register. Writes 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.

A LOW on this pin initializes the FIFO1 read and write pointers to the first location

of memory and sets the Port B output register to all zeroes. A LOW pulse on MRS1

selects the programming method (serial or parallel) and one of three programmable

flag default offsets for FIFO1. It also configures Port B for bus size and endian

arrangement. Four LOW-to-HIGH transitions of CLKA and four LOW-to-HIGH transi-

tions of CLKB must occur while MRS1 is LOW.

FIFO1 Master

Reset

MRS2

FIFO2 Master

Reset

I

A LOW on this pin initializes the FIFO2 read and write pointers to the first location

of memory and sets the Port A output register to all zeroes. A LOW pulse on MRS2

selects one of three 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

PRS2

FIFO1 Partial

Reset

I

A LOW on this pin 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.

A LOW on this pin initializes the FIFO2 read and write pointers to the first location

of memory and sets the Port A 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.

FIFO2 Partial

Reset

RENB

RT1

Port B Read

Enable

I

RENB must be HIGH to enable a LOW-to-HIGH transition of CLKB to read data on

Port B.

FIFO1

A LOW strobe on this pin will retransmit data on FIFO1. This is achieved by bringing

the read pointer back to location zero. The user will still need to perform read operations

to retransmit the data. Retransmit function applies to CY standard mode only.

Retransmit

Document #: 38-06023 Rev. *C

Page 5 of 39

CY7C43646

CY7C43666

CY7C43686

Pin Definitions (continued)

Signal Name

Description

I/O

Function

RT2

FIFO2

I

A LOW strobe on this pin will retransmit data on FIFO2. This is achieved by bringing

the read pointer back to location zero. The user will still need to perform read operations

to retransmit the data. Retransmit function applies to CY standard mode only.

Retransmit

SIZEB

SIZEC

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. SIZEB works with

BM and BE to select the bus size and endian arrangement for Port B. The level of

SIZEB must be static throughout device operation.

A HIGH on this pin when BM is HIGH selects byte bus (9-bit) size on Port C. A

LOW on this pin when BM is HIGH selects word (18-bit) bus size. SIZEC works with

BM and BE to select the bus size and endian arrangement for Port B. The level of

SIZEC must be static throughout device operation.

Bus Size Select

SPM

Serial

I

A LOW on this pin selects serial programming of partial flag offsets. A HIGH on

Programming

this pin selects parallel programming or default offsets (8, 16, or 64).

W/RA

Port A

A HIGH selects a write operation and a LOW selects a read operation on Port A for

a LOW-to-HIGH transition of CLKA. The A₀₋₃₅outputs are in the high-impedance state

when W/RA is HIGH.

Write/Read

Select

WENC

Port C Write

Enable

I

WENC must be HIGH to enable a LOW-to-HIGH transition of CLKC to write data

on Port C.

Almost Empty flag (AEA, AEB) LOW, and the Almost Full flag

(AFA, AFC) 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

Signal Description

Master Reset (MRS1, MRS2)

Each of the two FIFO memories of the CY7C436X6 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 internal read and write pointers

and forces the Full/Input Ready flag (FFA/IRA, FFC/IRC)

LOW, the Empty/Output Ready flag (EFA/ORA, EFB/ORB)

LOW, the Almost Empty flag (AEA, AEB) LOW, and the Almost

Full flag (AFA, AFC) HIGH. A Master Reset also forces the

Mailbox flag (MBF1, MBF2) of the parallel mailbox register

HIGH. After a Master Reset, the FIFO’s Full/Input Ready flag

is set HIGH after two clock cycles to begin normal operation.

A Master Reset must be performed on the FIFO after

power-up, before data is written to its memory.

A LOW-to-HIGH transition on a FIFO Master Reset (MRS1,

MRS2) input latches the value of the Big Endian (BE) input or

determines the order by which bytes are transferred through

Port B.

A LOW-to-HIGH transition on a FIFO reset (MRS1, MRS2)

input latches the values of the Flag select (FS0, FS1) and

Serial Programming Mode (SPM) inputs for choosing the

Almost Full and Almost Empty offset programming method

(see Almost Empty and Almost Full flag offset programming

below).

after two clock cycles to begin normal operation.

Whatever flag offsets, programming method (parallel or

serial), and timing mode (FWFT or CY Standard mode) are

currently selected at the time a Partial Reset is initiated, those

settings will 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.

Big Endian/First-Word Fall-Through (BE/FWFT)

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 Port C or read

from Port B. This selection determines the order by which

bytes (or words) of data are transferred through these ports.

For the following illustrations, assume that a byte (or word) bus

size has been selected for Port B and Port C.

A HIGH on the BE/FWFT input when the Master Reset (MRS1

and 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 transferred to Port B first;

the least significant byte (word) of the long-word written to Port

A will be transferred to Port B last. When data is moving in the

direction from Port C to Port A, the byte (word) written to Port

C first will be transferred to Port A as the most significant byte

(word) of the long-word; the byte (word) written to Port C last

will be transferred to Port A as the least significant byte (word)

of the long- word.

Partial Reset (PRS1, PRS2)

Each of the two FIFO memories of the CY7C436X6 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, FFC/IRC) LOW, the

Empty/Output Ready flag (EFA/ORA, EFB/ORB) LOW, the

A LOW on the BE/FWFT input when the Master Reset (MRS1

and 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 transferred to Port B first;

Document #: 38-06023 Rev. *C

Page 6 of 39

CY7C43646

CY7C43666

CY7C43686

the most significant byte (word) of the long-word written to Port

A will be transferred to Port B last. When data is moving in the

direction from Port C to Port A, the byte (word) written to Port

C first will be transferred to port A as the least significant byte

(word) of the long-word; the byte (word) written to Port C last

will be transferred to Port A as the most significant byte (word)

of the long- word.

After Master Reset, the FWFT select function is active,

permitting a choice between two possible timing modes: CY

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 CY

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, FFC) to indicate whether or not the FIFO memory has

any free space for writing. In CY Standard Mode, every word

read from the FIFO, including the first, must be requested

using a formal read operation.

Once the Master Reset (MRS1, MRS2) input is HIGH, a LOW

on the BE/FWFT input at the second LOW-to-HIGH transition

of CLKA (for FIFO1) and CLKC (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 (A_0–35or B_0–17). It also uses the Input Ready function

(IRA, IRC) 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.

first four writes to FIFO1 do not store data in RAM but load the

offset registers in the order Y1, X1, Y2, X2. The Port A data

inputs used by the offset registers are (A_0–9), (A_0–11), or

(A_0–13), for the CY7C436X6, 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 0 to 1023 for the CY7C43646; 1 to 4095

for the CY7C43666; 0to 16383 for the CY7C43686. After all

the offset registers are programmed from Port A, the Port C

Full/Input Ready (FFC/IRC) is set HIGH and both FIFOs begin

normal operation.

To program the X1, X2, Y1, and Y2 registers serially, initiate a

Master Reset with SPM 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. 40, 48, or 56 bit writes are needed to complete the

programming for the CY7C436X6, respectively. The four

registers are written in the order Y1, 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

0 to 1023 (CY7C43646), 0 to 4095 (CY7C43666), or 0 to

16383 (CY7C43686).

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 C Full/Input ready

(FFC/IRC) flag also remains LOW throughout the serial

programming process, until all register bits are written.

FFC/IRC is set HIGH by the LOW-to-HIGH transition of CLKC

after the last bit is loaded to allow normal FIFO2 operation.

Following Master Reset, the level applied to the BE/FWFT

input to choose the desired timing mode must remain static

throughout the FIFO operation.

SPM, FS0/SD, and FS1/SEN function the same way in both

Programming the Almost Empty and Almost Full Flags

CY Standard and FWFT modes.

Four registers in the CY7C436X6 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 C Almost Full flag (AFC) offset register is labeled

Y2. The index of each register name corresponds 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).

To load a FIFO’s Almost Empty flag and Almost Full flag offset

registers with one of the three preset values listed in Table 1.

The Serial Program Mode (SPM) and at least one of the

flag-select inputs must be HIGH during the LOW-to-HIGH

transition of its Master Reset input (MRS1 and MRS2). For

example, to load the preset value of 64 into X1 and Y1, SPM,

FS0, and FS1 must be HIGH when FIFO1 reset (MRS1)

returns HIGH. Flag-offset registers associated with FIFO2 are

loaded with one of the preset values in the same way with

Master Reset (MRS2). When using one of the preset values

for the flag offsets, the FIFOs can be reset simultaneously or

at different times.

FIFO Write/Read Operation

The state of the Port A data (A_0–35) lines is controlled by Port

A Chip Select (CSA) and Port A Write/Read Select (W/RA).

The A_0–35lines are in the high-impedance state when either

CSA or W/RA is HIGH. The A_0–35lines are active outputs

when both CSA and W/RA are LOW.

Data is loaded into FIFO1 from the A_0–35inputs on a

LOW-to-HIGH transition of CLKA when CSA is LOW, W/RA is

HIGH, ENA is HIGH, MBA is LOW, and FFA/IRA is HIGH. Data

is read from FIFO2 to the A_0–35outputs by a LOW-to-HIGH

transition of CLKA when CSA is LOW, W/RA is LOW, 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 state of the Port B data (B_0–17) lines is controlled by the

Port B Chip Select (CSB) and Port B Read select (RENB). The

B

_0–17lines are in the high-impedance state when either CSB

is HIGH or RENB is LOW. The B_0–17lines are active outputs

when CSB is LOW and RENB is HIGH.

Data is loaded into FIFO2 from the C_0–17inputs on a

LOW-to-HIGH transition of CLKC when WENC is LOW, MBC

is LOW, and FFC/IRC is HIGH. Data is read from FIFO1 to the

B_0–17outputs by a LOW-to-HIGH transition of CLKB when

CSB is LOW, RENB is HIGH, MBB is LOW, and EFB/ORB is

To program the X1, X2, Y1, and Y2 registers from Port A,

perform a Master Reset on both FIFOs simultaneously with

SPM HIGH and FS0 and FS1 LOW during the LOW-to-HIGH

transition of MRS1 and MRS2. After this reset is complete, the

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HIGH (see Table 3). FIFO reads on Port B and writes to Port

simultaneously forcing the Output Ready flag HIGH and

C are independent of any concurrent Port A operation.

shifting the word to the FIFO output register.

The set-up 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’s Chip Select and

Write/Read Select may change states during the set-up and

hold time window of the cycle.

When operating the FIFO in FWFT Mode with the Output

Ready flag 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, 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.

In the CY 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 FIFO output

register and two cycles 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_SKEW1or greater

after the write. Otherwise, the subsequent clock cycle can be

the first synchronization cycle.

When operating the FIFO in CY Standard Mode, regardless of

whether the Empty Flag is LOW or HIGH, 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.

Full/Input Ready Flags (FFA/IRA, FFC/IRC)

This is a dual-purpose flag. In FWFT Mode, the Input Ready

(IRA and IRC) function is selected. In CY Standard Mode, the

Full Flag (FFA and FFC) function is selected. For both timing

modes, when the Full/Input Ready flag is HIGH, a memory

location is free in the SRAM 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 FIFO is synchronized to the port

clock that writes data to its array. For both FWFT and CY

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 FIFO SRAM status

is full, or full–1. 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 synchro-

nizing 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.

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 the metastable events when CLKA,

CLKB, and CLKC operate asynchronously to one another.

EFA/ORA, AEA, FFA/IRA, and AFA are synchronized to

CLKA. EFB/ORB and AEB are synchronized to CLKB.

FFC/IRC and AFC are synchronized to CLKC. Table 5 and

Table 6 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.(See footnote #1)

In the CY 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 Empty flag is LOW, the previous data word is present in

the FIFO output register and attempted FIFO reads are

ignored.

A LOW-to-HIGH transition on a Full/Input Ready flag synchro-

nizing clock begins the first synchronization cycle of a read if

the clock transition occurs at time t_SKEW1or greater after the

read. Otherwise, the subsequent clock cycle can be the first

synchronization cycle.

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 CY 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 SRAM status is empty, or empty+1.

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 FIFO output register and three

cycles 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,

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 SRAM

status is almost empty, or almost empty+1. 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 above). 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. ^[2]

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CY7C43686

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 Empty 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 synchronization cycle if it occurs at time t_SKEW2or

greater after the write that fills the FIFO to (X+1) words.

Otherwise, the subsequent synchronizing clock cycle may be

the first synchronization cycle.

size is also 18 bits, then the usable width of the Mail2 register

employs data lines C_0-17. If the selected Port C bus size is 9

bits, then the usable width of the Mail2 register employs data

lines C_0-8. (In this case, C_9-17are “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, RENB, and ENB with MBB HIGH. For an

Almost Full Flags (AFA, AFC)

18-bit bus size, 18 bits of mailbox data are placed on B_0–17

For a 9-bit bus size, 9 bits of mailbox data are placed on B_0–8

(In this case, B_9-17are indeterminate.)

.

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 SRAM status is

almost full, almost or full–1. The Almost Full state is defined by

the contents of register Y1 for AFA and register Y2 for AFC.

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

above). An Almost Full flag is LOW when the number of words

in its FIFO is greater than or equal to (1024–Y), (4096–Y), or

(16384–Y) for the CY7C436X6 respectively. An Almost Full

flag is HIGH when the number of words in its FIFO is less than

or equal to [1024–(Y+1)], [4096–(Y+1)], or [16384–(Y+1)] for

the CY7C436X6 respectively.^[2]

Two LOW-to-HIGH transitions of the Almost Full flag synchro-

nizing 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 [1024/4096/16384–(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 [1024/4096/16384–(Y+1)]. An Almost Full

flag is set HIGH by the second LOW-to-HIGH transition of its

synchronizing clock after the FIFO read that reduces the

number of words in memory to [1024/4096/16384–(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_SKEW2or greater after the read that reduces the number of

words in memory to [1024/4096/16384–(Y+1)]. Otherwise, the

subsequent synchronizing clock cycle may be the first

synchronization cycle.

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. The

Endian Select feature has no effect on the mailbox data.

Bus Sizing

The Port B and Port C buses can be configured in a 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

(SIZEB) and the Port C Bus Size Select (SIZEC) determine the

width of the buses. The bus size can be selected indepen-

dently for Ports B and C. 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.

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 signif-

icant 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.

Only 36-bit long-word data is written to or read from the two

FIFO memories on the CY7C436X6. Bus-matching operations

are done after data is read from the FIFO1 RAM and before

data is written to 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 trans-

mitted only between A_0-17and B_0-17. When a byte-size bus is

selected, then mailbox data can be transmitted only between

Mailbox Registers

Each FIFO has a 36-bit bypass register to pass command and

control information between Port A and Port B/Port C without

putting it in queue. The Mailbox Select (MBA, MBB, MBC)

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 C.

A LOW-to-HIGH transition on CLKA writes A_0-35data to the

Mail1 Register when a Port A write is selected by CSA, W/RA,

and ENA with MBA HIGH.

When sending data from Port C to Port A via the Mail2 register,

the following is the case: A LOW-to-HIGH transition on CLKC

writes C_0-17data to the Mail2 register when a Port C write is

selected by WENC with MBC HIGH. If the selected Port C bus

A_0-8and B_0-8.

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Bus-Matching FIFO1 Reads

Retransmit (RT1, RT2)

Data is written to the FIFO1 RAM in 36-bit long-word incre-

ments. 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.

The retransmit feature is beneficial when transferring packets

of data. It enables the receipt of data to be acknowledged by

the receiver and retransmitted if necessary. Retransmit

function applies to CY standard mode only.

The number of 36-/18-/9-bit words written into the FIFO should

be less than full depth minus 2/4/8 words between the reset of

the FIFO (master or partial) and Retransmit setup. A LOW

pulse on RT1, (RT2) resets the internal read pointer to the first

physical location of the FIFO. CLKA and CLKB may be free

running but RENB and (ENA) must be disabled during and

t_RTRafter the retransmit pulse. With every valid read cycle

after retransmit, previously accessed data is read and the read

pointer is incremented until it is equal to the write pointer. Flags

are governed by the relative locations of the read and write

pointers and are updated during a retransmit cycle. Data

written to the FIFO after activation of RT1, (RT2) are trans-

mitted also.

When reading data from FIFO1 as byte, the unused B_9-17

outputs are indeterminate.

Bus-Matching FIFO2 Writes

Data is written to the FIFO2 RAM in 18-bit word increments.

Data written to FIFO2 with a byte or word bus size stores the

initial bytes or words in auxiliary registers. The CLKC rising

edge that writes the word to FIFO2 also stores the entire

long-word in FIFO2 RAM.

When reading data from FIFO2 in byte format, the unused

C_8–17outputs are LOW.

The full depth of the FIFO can be repeatedly retransmitted.

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CY7C43686

PORT B BUS SIZING

A_27–35

A

A_0–8

D

A_18–26

A_9–17

BYTE ORDER ON

PORT A:

Write to FIFO1

B

C

B_9–17

B_0–8

BE

SIZEB

1st: Read from

FIFO1

H

L

A

B_9–17

C

B

B_0–8

D

2nd: Read from

FIFO1

(A) WORD SIZE – BIG ENDIAN

B_9–17

C

B_0–8

D

BE

L

SIZEB

1st: Read from

FIFO1

L

B_9–17

A

B_0–8

B

2nd: Read from

FIFO1

(B) WORD SIZE – LITTLE ENDIAN

B_9–17

B_0–8

A

BE

H

SIZEB

H

1st: Read from

FIFO1

B_9–17

B_0–8

B

2nd: Read from

FIFO1

B_9–17

B_0–8

3rd: Read from

FIFO1

C

B_0–8

D

B_9–17

4th: Read from

FIFO1

(C) BYTE SIZE – BIG ENDIAN

B_9–17

B_0–8

D

BE

L

SIZEB

1st: Read from

FIFO1

H

B_0–8

C

2nd: Read from

FIFO1

B_0–8

B

3rd: Read from

FIFO1

B_0–8

A

4th: Read from

FIFO1

(D) BYTE SIZE – LITTLE ENDIAN

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PORT C BUS SIZING

A_27–35

A

A_0–8

D

A_18–26

B

A_9–17

C

BYTE ORDER ON

PORT A:

Read from

FIFO2

C_9–17

C_0–8

BE

SIZEC

1st: Write to

FIFO2

H

L

A

C_9–17

C

B

C_0–8

D

2nd: Write to

FIFO2

(A) WORD SIZE – BIG ENDIAN

C_9–17

C

C_0–8

D

BE

L

SIZEC

1st: Write to

FIFO2

L

C_9–17

A

C_0–8

B

2nd: Write to

FIFO2

(B) WORD SIZE – LITTLE ENDIAN

C_9–17

C_0–8

A

BE

H

SIZEC

H

1st: Write to

FIFO2

C_0–8

B

2nd: Write to

FIFO2

C_0–8

C

3rd: Write to

FIFO2

C_0–8

D

4th: Write to

FIFO2

(C) BYTE SIZE – BIG ENDIAN

C_9–17

C_0–8

BE

L

SIZEC

1st: Write to

FIFO2

H

D

C_0–8

2nd: Write to

FIFO2

C

C_0–8

B

3rd: Write to

FIFO2

C_0–8

A

4th: Write to

FIFO2

(D) BYTE SIZE – LITTLE ENDIAN

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Table 1. Flag Programming^[2]

SPM FS1/SEN FS0/SD

MRS1

MRS2

X1 and Y1 Registers^[3]

X2 and Y2 Registers^[4]

H

L

H

L

H

L

H

L

↑

X

↑

X

↑

X

↑

X

↑

X

↑

X

↑

64

X

16

X

64

X

16

L

H

L

8

X

Parallel programming via Port A

Serial programming via SD

Reserved

8

Parallel programming via Port A

Serial programming via SD

Reserved

L

H

L

Reserved

L

Table 2. Port A Enable Function Table

CSA

H

L

W/RA

ENA

X

L

H

L

H

L

H

MBA

X

L

H

L

H

CLKA

A_0–35OUTPUTS

In high-impedance state

Active, FIFO2 output register

Active, Mail2 register

PORT FUNCTION

X

H

L

X

↑

X

↑

X

↑

None

FIFO1 write

Mail1 write

None

FIFO2 read

None

Active, Mail2 register

Mail2 read (set MBF2 HIGH)

Table 3. Port B Enable Function Table

CSB

RENB

X

L

H

L

H

MBB

X

L

H

CLKB

B_0–17OUTPUTS

In high-impedance state

Active, FIFO1 output register

Active, Mail1 register

PORT FUNCTION

H

L

X

↑

X

↑

None

FIFO1 read

None

Active, Mail1 register

Mail1 read (set MBF1 HIGH)

Table 4. Port C Enable Function Table

WENC

MBC

CLKC

C_0–17INPUTS

PORT FUNCTION

FIFO2 write

Mail2 write

None

H

L

H

L

↑

X

In high-impedance state

Active, Mail1 register

L

H

None

Notes:

3. X1 register holds the offset for AEB; Y1 register holds the offset for AFA.

4. X2 register holds the offset for AEA; Y2 register holds the offset for AFC.

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Table 5. FIFO1 Flag Operation (CY Standard and FWFT Modes)^[2]

Number of Words in FIFO Memory^{[5, 6, 7, 8]}

Synchronized to CLKB

Synchronized to CLKA

CY7C43646

0

1 TO X1

CY7C43666

0

CY7C43686

0

1 TO X1

EFB/ORB

AEB

L

AFA

H

FFA/IRA

L

H

1 TO X1

(X1+1) to

(X1+1) to [16384–

(Y1+1)]

H

[1024–(Y1+1)]

[4096–(Y1+1)]

(1024–Y1) to 1023

1024

(4096–Y1) to 4095 (16384–Y1) to 16383

4096 16384

H

L

H

L

Table 6. FIFO2 FLAG OPERATION (CY Standard and FWFT Modes)^[2]

Number of Words in FIFO Memory^{[6, 7, 9, 10]}

Synchronized to CLKA

Synchronized to CLKC

CY7C43646

CY7C43666

0

CY7C43686

EFA/ORA

AEA

L

AFC

H

FFC/IRC

0

L

H

1 TO X2

(X2+1) to

H

[1024–(Y2+1)]

[4096–(Y2+1)]

[16384–(Y2+1)]

(1024–Y2) to 1023 (4096–Y2) to 4095 (16384–Y2) to 16383

1024 4096 16384

Table 7. Data Size for Word Writes to FIFO2

H

L

H

L

Size Mode^[11]

Write No. Data Written to FIFO2

Data Read From FIFO2

BM

H

SIZE

L

BE

H

C_9–17

C_0–8

B

D

B

A_27–35

A

A_18–26

B

A_9–17

C

A_0–8

D

1

2

1

2

A

C

A

H

L

A

B

C

D

Table 8. Data Size for Byte Writes to FIFO2

Data Written to

FIFO2

Size Mode^[11]

Write No.

Data Read From FIFO2

BM

H

SIZE

H

BE

H

C_0–8

A

B

C

D

C

B

A_27–35

A

A_18–26

B

A_9–17

C

A_0–8

D

1

2

3

4

1

2

3

4

H

L

A

B

C

D

A

Notes:

5. 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.

6. When a word loaded to an empty FIFO is shifted to the output register, its previous FIFO memory location is free.

7. 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.

8. The ORB and IRA functions are active during FWFT mode; the EFB and FFA functions are active in CY Standard mode.

9. X2 is the Almost Empty offset for FIFO2 used by AEA. Y2 is the Almost Full offset for FIFO2 used by AFC. Both X2 and Y2 are selected during a FIFO2 reset

or port A programming.

10. The ORA and IRC functions are active during FWFT mode; the EFA and FFC functions are active in CY Standard mode.

11. BE is selected at Master Reset. SIZEC must be static throughout device operation.

Document #: 38-06023 Rev. *C

Page 14 of 39

CY7C43646

CY7C43666

CY7C43686

Table 9. Data Size for Word Reads from FIFO1

Size Mode^[11]

Data Read From

FIFO1

Data Written to FIFO1

Read No.

BM

H

SIZE

L

BE

H

A_27–35

A

A_18–26

A_9–17

C

A_0–8

D

B_9–17

B_0–8

B

D

B

1

2

1

2

A

C

A

H

L

A

B

C

D

B

Table 10.Data Size for Byte Reads from FIFO1

Size Mode^[11]

Data Read From

FIFO1

Data Written to FIFO1

Read No.

BM

SIZE

BE

A_27–35

A_18–26

A_9–17

A_0–8

B_0–8

H

A

B

C

D

1

2

3

4

1

2

3

4

A

B

C

D

C

B

A

H

L

A

B

C

D

Document #: 38-06023 Rev. *C

Page 15 of 39

CY7C43646

CY7C43666

CY7C43686

DC Input Voltage^[13]................................. –0.5V to V_CC+0.5V

Output Current into Outputs (LOW)............................. 20 mA

Maximum Ratings^{[12, 14]}

(Above which the useful life may be impaired. For user guide-

Static Discharge Voltage...........................................> 2001V

lines, not tested.)

(per MIL-STD-883, Method 3015)

Storage Temperature .................................–65°C to +150°C

Latch-up Current.....................................................> 200 mA

Ambient Temperature with

Operating Range

Power Applied.............................................. –55°C to +125°C

Ambient

Supply Voltage to Ground Potential............... –0.5V to +7.0V

[15]

Range

Commercial

Industrial

Temperature

0°C to +70°C

V_CC

DC Voltage Applied to Outputs

5.0V±0.5V

in High-Z State^[13]....................................–0.5V to V_CC+0.5V

−40°C to +85°C

Electrical Characteristics Over the Operating Range

7C43646/66/86

Parameter

Description

Output HIGH Voltage

Output LOW Voltage

Input HIGH Voltage

Input LOW Voltage

Input Leakage Current

Output OFF, High-Z Current

Test Conditions

V_CC= 4.5V., I_OH= −4.0 mA

V_CC= 4.5V., I_OL= 8.0 mA

Min.

2.4

Max.

Unit

V

µA

V_OH

V_OL

V_IH

V_IL

0.5

V_CC

0.8

+10

2.0

–0.5

–10

I_IX

V_CC= Max.

V_SS< V_O< V_CC

I_OZL

I_OZH

[16]

I_CC1

Active Power Supply Current

Average Standby Current

Com’l

Ind

Com’l

Ind

100

10

mA

[17]

I_SB

10

Capacitance^[18]

Parameter

C_IN

Description

Input Capacitance

Output Capacitance

Test Conditions

T_A= 25°C, f = 1 MHz,

_CC= 5.0V

Max.

4

8

Unit

pF

V

C_OUT

AC Test Loads and Waveforms (-10 and -15)

R1 = 1.1 KΩ

ALL INPUT PULSES

5V

OUTPUT

3.0V

90%

10%

90%

10%

GND

C_L= 30 pF

R2 = 680Ω

≤ 3 ns

INCLUDING

JIG AND

SCOPE

V

/2

ALL INPUT PULSES

CC

3.0V

GND

90%

10%

90%

10%

50Ω

I/O

Z0 = 50Ω

≤ 3 ns

Notes:

12. 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 abso-

lute-maximum-rated conditions for extended periods may affect device reliability.

13. The input and output voltage ratings may be exceeded provided the input and output current ratings are observed.

14. The Voltage on any input or I/O pin cannot exceed the power pin during power-up.

15. Operating V Range for -7 speed is 5.0V ± 0.25V.

CC

16. Input signals switch from 0V to 3V with a rise/fall time of less than 3 ns, clocks and clock enables switch at 20 MHz, while data inputs switch at 10 MHz. Outputs

are unloaded.

17. All inputs = V – 0.2V, except RCLK and WCLK (which are at frequency = 0 MHz). All outputs are unloaded.

CC

18. Tested initially and after any design or process changes that may affect these parameters.

Document #: 38-06023 Rev. *C

Page 16 of 39

CY7C43646

CY7C43666

CY7C43686

Switching Characteristics Over the Operating Range

7C43646/

66/86

-7

7C43646/

66/86

7C43646/

66/86

-10

-15

Parameter

f_S

t_CLK

t_CLKH

t_CLKL

Description

Min. Max. Min. Max.

Min.

Max. Unit

Clock Frequency, CLKA,CLKB, or CLKC

Clock Cycle Time, CLKA,CLKB, or CLKC

Pulse Duration, CLKA,CLKB, or CLKC HIGH

Pulse Duration, CLKA,CLKB, or CLKC LOW

133

100

67

MHz

ns

7.5

3.5

3

10

4

15

6

ns

Set-up Time, A_0–35before CLKA↑ B_0–17before

CLKB↑, and C_0–17before CLKC↑

4

5

t_DS

Set-up Time, CSA, W/RA, ENA, and MBA before

CLKA↑; RENB and MBB before CLKB↑ and WENC

and MBC before CLKC↑

3

4

5

ns

t_ENS

t_RSTS

t_FSS

Set-up Time, MRS1, MRS2, PRS1, PRS2, RT1 or

2.5

6

4

7

5

ns

RT2 LOW before CLKA↑ or CLKB↑^[19]

Set-up Time, FS0 and FS1 before MRS1 and MRS2

HIGH

Set-up Time, BE/FWFT before MRS1 and MRS2

HIGH

7.5

5

t_BES

t_SPMS

t_SDS

t_SENS

t_FWS

Set-up Time, SPM before MRS1 and MRS2 HIGH

Set-up Time, FS0/SD before CLKA↑

Set-up Time, FS1/SEN before CLKA↑

Set-up Time, FWFT before CLKA↑

5

3

0

7

4

0

7.5

5

0

ns

Hold Time, A_0–35before CLKA↑ B_0–17before CLKB↑,

and C_0–17before CLKC↑

t_DH

Hold Time, CSA, W/RA, ENA, and MBA before

CLKA↑ RENB and MBB before CLKB↑ and WENC

and MBC before CLKC↑

0

ns

t_ENH

Hold Time, MRS1, MRS2, PRS1, PRS2, RT1 or RT2

1

2

1

4

2

ns

t_RSTH

LOW after CLKA↑ or CLKB↑^[19]

Hold Time, FS0 and FS1 after MRS1 and MRS2

HIGH

t_FSH

t_BEH

t_SPMH

t_SDH

Hold Time, BE/FWFT after MRS1 and MRS2 HIGH

Hold Time, SPM after MRS1 and MRS2 HIGH

Hold Time, FS0/SD after CLKA↑

Hold Time, FS1/SEN after CLKA↑

Hold Time, FS1/SEN HIGH after MRS1 and MRS2

HIGH

1

0

1

0

1

2

0

2

ns

t_SENH

t_SPH

Skew Time between CLKA↑ and CLKB↑ for

5

7

5

8

7.5

12

ns

[20]

t_SKEW1

EFA/ORA, EFB/ORB, FFA/IRA, and FFC/IRC

Skew Time between CLKA↑ and CLKB↑ for AEA,

[20]

t_SKEW2

AEB, AFA, AFC

t_A

Access Time, CLKA↑ to A_0–35and CLKB↑ to B_0–17

Propagation Delay Time, CLKA↑ to FFA/IRA and

CLKB↑ to FFC/IRC

1

6

1

8

3

2

10

8

ns

t_WFF

Notes:

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

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

Document #: 38-06023 Rev. *C

Page 17 of 39

CY7C43646

CY7C43666

CY7C43686

Switching Characteristics Over the Operating Range (continued)

7C43646/

66/86

7C43646/

66/86

-7

-10

-15

Parameter

t_REF

Description

Min. Max. Min. Max.

Min.

Max. Unit

Propagation Delay Time, CLKA↑ to EFA/ORA and

1

0

6

1

0

8

1

0

8

ns

CLKB↑ to EFB/ORB

Propagation Delay Time, CLKA↑ to AEA and CLKB↑

8

t_PAE

to AEB

Propagation Delay Time, CLKA↑ to AFA and CLKC↑

8

t_PAF

to AFC

Propagation Delay Time, CLKA↑ to MBF1 LOW or

MBF2 HIGH and CLKB↑ to MBF2 LOW or MBF1

HIGH

Propagation Delay Time, CLKA↑ to B_0–17^[21]and

12

t_PMF

t_PMR

t_MDV

1

7

6

2

1

11

9

3

1

12

11

15

ns

[22]

CLKB↑ to A_0–35

Propagation Delay Time, MBA to A_0–35Valid and

MBB to B_0–17Valid

Propagation Delay Time, MRS1 or PRS1 LOW to

AEB LOW, AFA HIGH, FFA/IRA LOW, EFB/ORB

LOW and MBF1 HIGH and MRS2 or PRS2 LOW to

AEA LOW, AFC HIGH, FFC/IRC LOW, EFA/ORA

LOW and MBF2 HIGH

Enable Time, CSA or W/RA LOW to A_0–35Active and

CSB LOW and RENB HIGH to B_0–17Active

Disable Time, CSA or W/RA HIGH to A_0–35at High

Impedance and CSB HIGH or RENB LOW to B_0–17

at High Impedance

10

t_RSF

t_EN

1

5

2

1

8

6

2

1

10

8

ns

t_DIS

t_RTR

Retransmit recovery Time

90

ns

Notes:

21. Writing data to the Mail1 register when the B

22. Writing data to the Mail2 register when the A

outputs are active and MBB is HIGH.

outputs are active and MBA is HIGH.

0–17

0–35

Document #: 38-06023 Rev. *C

Page 18 of 39

CY7C43646

CY7C43666

CY7C43686

Switching Waveforms

FIFO1 Master Reset Loading X1 and Y1 with a Preset Value of Eight ^{[23, 24]}

CLKA

CLKB

t_RSTS

t_RSTH

MRS1

t_FWS

t_BES

t_SPMS

t_FSS

t_BEH

t_SPMH

t_FSH

BE/FWFT

SPM

FS1/SEN,

FS0/SD

t_WFF

t_RSF

FFA/IRA

t_RSF

EFB/ORB

AEB

AFA

t_RSF

MBF1

Notes:

23. PRS1 and MBC must be HIGH during Master Reset until the rising edge of FFA/IRA goes HIGH.

24. If BE/FWFT is HIGH, then EFB/ORB will go LOW one CLKB cycle earlier than the case where BE/FWFT is LOW.

Document #: 38-06023 Rev. *C

Page 19 of 39

CY7C43646

CY7C43666

CY7C43686

Switching Waveforms (continued)

FIFO2 Master Reset Loading X1 and Y1 with a Preset Value of Eight ^{[25, 26]}

CLKC

CLKA

t_RSTS

MRS2

t_FWS

t_BES

t_BEH

BE/FWFT

t_SPMS

t_FSS

t_SPMH

t_FSH

SPM

FS1/SEN,

FS0,SD

t_WFF

t_RSF

FFC/IRC

t_RSF

EFA/ORA

AEA

AFC

t_RSF

MBF2

Notes:

25. PRS2 and MBC must be HIGH during Master Reset until the rising edge of FFC/IRC goes HIGH.

26. If BE/FWFT is HIGH, then EFA/ORA will go LOW one CLKA cycle earlier than the case where BE/FWFT is LOW.

Document #: 38-06023 Rev. *C

Page 20 of 39

CY7C43646

CY7C43666

CY7C43686

Switching Waveforms (continued)

FIFO1 Partial Reset (CY Standard and FWFT Modes)^{[24, 27]}

CLKA

CLKB

t_RSTS

t_RSTH

PRS1

t_WFF

t_RSF

FFA/IRA

t_RSF

EFB/ORB

t_RSF

AEB

t_RSF

AFA

t_RSF

MBF1

FIFO2 Partial Reset (CY Standard and FWFT Modes)^{[26, 28]}

CLKC

CLKA

t_RSTS

t_RSTH

PRS2

t_WFF

t_RSF

FFC/IRC

t_RSF

EFA/ORA

t_RSF

AEA

t_RSF

AFC

t_RSF

MBF1

Notes:

27. MRS1 must be HIGH during Partial Reset.

28. MRS2 must be HIGH during Partial Reset.

Document #: 38-06023 Rev. *C

Page 21 of 39

CY7C43646

CY7C43666

CY7C43686

Switching Waveforms (continued)

Parallel Programming of the Almost-Full Flag and Almost-Empty Flag Offset Values after Reset

[29]

(CY Standard and FWFT Modes)

CLKA

MRS1, MRS2

t_FSS

t_FSH

SPM

t_FSH

t_FSS

FS1/SEN,

FS0/SD

t_WFF

FFA/IRA

t_ENH

t_ENS

[30]

t_SKEW1

ENA

t_DH

t_DS

A₀₋₃₅

CLKC

First Word to

t_WF

AFA Offset (Y1)

AEA Offset (X2)

AEB Offset

AFC Offset

FFC/IRC

Serial Programming of the Almost-Full Flag and Almost-Empty Flag

Offset Values (CY Standard and FWFT Modes)^[31]

CLKA

MRS1, MRS2

t_FSSt_FSH

SPM

t_WFF

[32]

t_SKEW1

t_SENSt_SEN

FFA/IRA

t_SENS

t_FSS

t_SPH

t_SENH

t_SDH

FS1/SEN

t_SDS

t_SDH

t_SDS

FS0/SD ^[33]

AFA Offset (Y1) MSB

AEA Offset (X2)

CLKC

t_WFF

FFC/IRC

Notes:

29. CSA = LOW, W/RA = HIGH, MBA = LOW. It is not necessary to program offset register on consecutive clock cycles.

30. t

is the minimum time between the rising CLKA edge and a rising CLKB for FFC/IRC to transition HIGH in the next cycle. If the time between the rising edge

SKEW1

of CLKA and rising edge of CLKC is less than t

, then FFC/IRC may transition HIGH one cycle later than shown.

SKEW1

Document #: 38-06023 Rev. *C

Page 22 of 39

CY7C43646

CY7C43666

CY7C43686

Switching Waveforms (continued)

Port A Write Cycle Timing for FIFO1 (CY Standard and FWFT Modes)

t_CLK

t_CLKL

t_CLKH

CLKA

FFA/IRA

HIGH

t_ENS

t_ENH

CSA

t_ENSt_ENH

W/RA^[34]

MBA

t_ENSt_ENH

t_ENH

t_ENS

t_ENH

t_ENS

t_DS

t_ENS

ENA

t_DH

[35]

A_0–35

W2^[35]

W1

Port C Word Write Cycle Timing for FIFO2 (CY Standard and FWFT Modes)

CLKC

FFC/IRC

HIGH

t_ENH

t_ENSt_ENH

t_ENS

MBC

t_ENSt_ENH

t_ENH

WENC

C_0–17

t_DSt_DH

Port C Byte Write Cycle Timing for FIFO2 (CY Standard and FWFT Modes)

CLKC

FFC/IRC

MBC

HIGH

t_ENH

t_ENS

t_ENH

t_ENS

WENC

C_0–8

t_DS

t_DH

Notes:

31. It is not necessary to program offset register bits on consecutive clock cycles. FIFO write attempts are ignored until IRA is set HIGH.

32. t is the minimum time between the rising CLKA edge and a rising CLKC for FFC/IRC to transition HIGH in the next cycle. If the time between the rising edge

SKEW1

of CLKA and rising edge of CLKC is less than t

, then FFC/IRC may transition HIGH one cycle later than show.

SKEW1

33. Programmable offsets are written serially to the SD input in the order AFA offset (Y1), AEB offset (X1), AFC offset (Y2), and AEA offset (X2).

34. If W/RA switches from read to write before the assertion of CSA, t

35. Written to FIFO1.

= t +t

.

ENS

DIS ENS

Document #: 38-06023 Rev. *C

Page 23 of 39

CY7C43646

CY7C43666

CY7C43686

Switching Waveforms (continued)

Port B Byte Read Cycle Timing for FIFO1 (CY Standard and FWFT Modes) ^{[36, 1]}

CLKB

EFB/ORB

CSB

HIGH

MBB

t

_ENSt_ENH

RENB

t_DIS

t_A

t_MDV

t_A

t_A

[1]

t_A

No Opera-

t_EN

B_0–8

t_A

(Standard Mode)

t_DIS

t_MDV

t_A

OR

t_EN

B_0–8

(FWFT Mode)

Port B Word Read Cycle Timing for FIFO1 (CY Standard and FWFT Modes)

CLKB

EFB/ORB

CSB

MBB

ENB

t_ENH

t_EN

t_A

t_MDV

t_DIS

t_A

No Operation

B_0–17

t_EN

(Standard Mode)

Previous Data

t_A

t_DIS

OR

t_MDV

t_A

t_EN

B_0–17

(FWFT Mode)

Note:

36. Unused bytes B

contain all zeroes for byte-size reads.

9–17

Document #: 38-06023 Rev. *C

Page 24 of 39

CY7C43646

CY7C43666

CY7C43686

Switching Waveforms (continued)

[1]

Port A Byte Read Cycle Timing for FIFO2 (CY Standard and FWFT Modes)

t_CLK

t_CLKH

t_CLKL

CLKA

EFA/ORA

CSA

W/RA^[34]

MBA

t_ENSt_ENH

t_A

t_ENS

t_ENH

t_A

ENA

t_DIS

t_MDV

No Operation

W2^[37]

t_EN

A₀₋₃₅

W1^[37]

W2^[37]

Previous Data

t_A

(Standard Mode)

t_A

t_DIS

t_MDV

OR

t_EN

A₀₋₃₅

W3^[37]

W1^[37]

(FWFT Mode)

Note:

37. Read From FIFO2.

Document #: 38-06023 Rev. *C

Page 25 of 39

CY7C43646

CY7C43666

CY7C43686

Switching Waveforms (continued)

[38, 39]

ORB Flag Timing and First Data Word Fall Through when FIFO1 is Empty (FWFT Mode)

t_CLK

t_CLKH

t_CLKL

CLKA

CSA

LOW

HIGH

W/RA

t_ENSt_ENH

t_ENS

MBA

t_ENH

ENA

FFA/IRA

HIGH

t_DSt_DH

W1

A_0–35

CLKB

[40]

t_CLKHt_CLKL

t_SKEW1

t_REF

t_CLK

EFB/ORB

CSB

FIFO1 Empty

LOW

MBB

t_ENSt_ENH

RENB

t_A

B_0–17

W1b

W1a

Old Data in FIFO1 Output Register

Notes:

38. SIZEB = LOW; If BE = HIGH, W1a is the most significant word, W1b is the least significant word. If BE = LOW, W1a is the least significant word, W1b is the most

significant word.

39. If SIZEB = HIGH (byte size), ORB is set LOW by the last byte read from FIFO2.

40. t

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

SKEW1

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

, then the transition of ORB HIGH and load of

SKEW1

the first word to the output register may occur one CLKB cycle later than shown.

Document #: 38-06023 Rev. *C

Page 26 of 39

CY7C43646

CY7C43666

CY7C43686

Switching Waveforms (continued)

EFB Flag Timing and First Data Read Fall Through when FIFO1 is Empty (CY Standard Mode)^{[38, 41]}

t_CLK

t_CLKH

t_CLKL

CLKA

CSA

LOW

HIGH

W/RA

MBA

t_ENH

t_ENS

t_ENH

ENA

FFA/IRA

A_0–35

HIGH

t_DSt_DH

W1

_[42]t_CLKHt_CLKL

t_SKEW1

CLKB

t_REF

t_CLK

EFB/ORB

FIFO1 Empty

CSB

LOW

MBB

RENB

t

_ENSt_ENH

t_A

W1a

B_0–17

W1b

Notes:

41. If SIZEB = HIGH (byte size), EFB is set LOW by the last byte read from FIFO2.

42. t 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

SKEW1

CLKA edge and rising CLKB edge is less than t

, then the transition of EFB HIGH may occur one CLKB cycle later than shown.

SKEW1

Document #: 38-06023 Rev. *C

Page 27 of 39

CY7C43646

CY7C43666

CY7C43686

Switching Waveforms (continued)

[43, 44]

ORA Flag Timing and First Data Word Fall Through when FIFO2 is Empty (FWFT Mode)

t_CLK

t_CLKH

t_CLKL

CLKC

MBC

t_ENH

t_ENS

t_ENH

t_ENS

WENC

HIGH

t_DS

FFC/IRC

t_DH

W1a

W1b

t_SKEW1

C_0–17

CLKA

[45]

t_CLKHt_CLKL

t_REF

t_CLK

FIFO2 Empty

LOW

EFA/ORA

CSA

LOW

W/RA

LOW

MBA

ENA

t_ENSENH

t

t_A

W1

A_0–35

Old Data in FIFO2 Output Register

Notes:

43. SIZEC = LOW; If BE = HIGH, W1a is the most significant word, W1b is the least significant word. If BE = LOW, W1a is the least significant word, W1b is the most

significant word.

44. If SIZEC = HIGH (byte size), t

is referenced to the rising CLKC edge that writes the last byte of the long word.

SKEW1

45. t

is the minimum time between a rising CLKC edge and a rising CLKA edge for ORA to transition HIGH and to clock the next word to the FIFO2 output

SKEW1

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

, then the transition of ORA HIGH and load of

SKEW1

the first word to the output register may occur one CLKA cycle later than shown.

Document #: 38-06023 Rev. *C

Page 28 of 39

CY7C43646

CY7C43666

CY7C43686

Switching Waveforms (continued)

EFA Flag Timing and First Data Read when FIFO2 is Empty (CY Standard Mode)^{[43, 44]}

t_CLK

t_CLKHt_CLKL

CLKC

t_ENH

t_ENS

MBC

t_ENH

t_ENS

WENC

FFC/IRC

C_0–17

HIGH

t_DS

t_DH

W1a

W1b

t_SKEW1

t_CLKHt_CLKL

[46]

CLKA

t_REF

t_CLK

EFA/IRA

CSA

FIFO2 Empty

LOW

W/RA

MBA

ENA

LOW

t_ENSt_ENH

t_A

A_0–35

W1

Notes:

46. t

is the minimum time between a rising CLKC edge and a rising CLKA edge for EFA to transition HIGH in the next CLKA cycle. If the time between the rising

SKEW1

CLKC edge and rising CLKA edge is less than t

, then the transition of EFA HIGH may occur one CLKA cycle later than shown.

SKEW1

Document #: 38-06023 Rev. *C

Page 29 of 39

CY7C43646

CY7C43666

CY7C43686

Switching Waveforms (continued)

IRA Flag Timing and First Available Write when FIFO1 is Full (FWFT Mode)^{[47, 48]}

t_CLK

t_CLKL

t_CLKH

CLKB

CSB

MBB

LOW

t_ENSt_ENH

RENB

EFB/ORB

B_0–17

HIGH

t_A

Word A

Word B

[49]

t_CLKHt_CLKL

t_SKEW1

CLKA

t_WFF

t_CLK

FFA/IRA

CSA

FIFO1 Full

LOW

HIGH

W/RA

t

_ENSt_ENH

MBA

ENA

t_{ENS ENH}

t

t_DS

t_DH

A_0–35

To FIFO1

Notes:

47. SIZEB = LOW; If BE = HIGH, Word A is the most significant word of the last long word in FIFO1, Word B is the least significant word. If BE = LOW, Word A is the

least significant word of the last long word in FIFO1, Word B is the most significant word.

48. If SIZEB = HIGH (byte size), t

is referenced to the rising CLKB edge that reads the last byte write of the long word.

SKEW1

49. t

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 the time between the rising

SKEW1

CLKB edge and rising CLKA edge is less than t

, then IRA may transition HIGH one CLKA cycle later than shown.

SKEW1

Document #: 38-06023 Rev. *C

Page 30 of 39

CY7C43646

CY7C43666

CY7C43686

Switching Waveforms (continued)

[47,48]

FFA Flag Timing and First Available Write when FIFO1 is Full (CY Standard Mode)

t_CLK

t_CLKHt_CLKL

CLKB

CSB

LOW

MBB

LOW

t_ENt_ENH

ENB

EFB/ORB

B_0–17

HIGH

t_A

Word B

Word A

[50]

t

t_CLKL

t_SKEW1

CLKH

CLKA

t_WFF

t_CLK

FFA/IRA

CSA

FIFO1 Full

LOW

W/RA

HIGH

t_ENH

t_ENS

MBA

ENA

t_ENS

t_ENH

t_DSt_DH

A₀₋₃₅

Note:

50. t

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

SKEW1

CLKB edge and rising CLKA edge is less than t

, then the transition of FFA HIGH may occur one CLKA cycle later than shown.

SKEW1

Document #: 38-06023 Rev. *C

Page 31 of 39

CY7C43646

CY7C43666

CY7C43686

Switching Waveforms (continued)

IRC Flag Timing and First Available Write when FIFO2 is Full (FWFT Mode)^{[51, 52]}

t_CLK

t_CLKL

t_CLKH

CLKA

CSA

LOW

W/RA

MBA

t_ENSENH

t

ENA

EFA/ORA

A_0–35

HIGH

t_A

Previous Word in

FIFO2 Output Registe_[r_53]

Next Word From FIFO2

t_CLKHt_CLKL

t_SKEW1

CLKC

t_WFF

t_CLK

FFC/IRC

FIFO2 Full

t_ENH

t_ENS

MBC

t_ENH

t_ENS

WENC

t_DSt_DH

Word A

C_0–17

Word B

Notes:

51. SIZEC = LOW; If BE = HIGH, Word A is the most significant word of the last long word in FIFO2, Word B is the least significant word. If BE = LOW, Word A is the

least significant word of the last long word in FIFO2, Word B is the most significant word.

52. If SIZEC = HIGH (byte size), IRC is set LOW by the last byte write of the long word.

53. t

is the minimum time between a rising CLKA edge and a rising CLKC edge for IRC to transition HIGH in the next CLKB cycle. If the time between the rising

SKEW1

CLKA edge and rising CLKC edge is less than t

, then the transition of IRC HIGH may occur one CLKC cycle later than shown.

SKEW1

Document #: 38-06023 Rev. *C

Page 32 of 39

CY7C43646

CY7C43666

CY7C43686

Switching Waveforms (continued)

[51, 54]

FFC Flag Timing and First Available Write when FIFO2 is Full (CY Standard Mode)

t_CLK

t_CLKL

t_CLKH

CLKA

CSA

LOW

W/RA

MBA

LOW

t_ENS

t_ENH

ENA

EFA/ORA

A_0–35

HIGH

t_A

Previous Word in

FIFO2 Output Register

Next Word From FIFO2

t_CLKHt_CLKL

[55]

t_SKEW1

CLKC

t_WFF

t_CLK

FFC/IRC

FIFO2 Full

t

_ENSt_ENH

MBC

t_ENH

t_ENS

WENC

t_DSt_DH

Word A

C_0–17

Word B

Timing for AEB when FIFO1 is Almost Empty (CY Standard and FWFT Modes)^{[56, 57, 2]}

CLKA

ENA

t_ENS

t_ENH

CLKB

[58]

t_SKEW2

t_PAE

t_ENH

(X1+1) Word in FIFO1

AEB

t_PAE

(X1+1)Words in FIFO1

t_ENS

X1 Word in FIFO1

RENB

Notes:

54. If SIZEC = HIGH (byte size), FFC is set LOW by the last byte write of the long word.

55. t is the minimum time between a rising CLKA edge and a rising CLKB edge for FFC to transition HIGH in the next CLKB cycle. If the time between the rising

SKEW1

CLKA edge and rising CLKC edge is less than t

, then the transition of FFC HIGH may occur one CLKC cycle later than shown.

SKEW1

Document #: 38-06023 Rev. *C

Page 33 of 39

CY7C43646

CY7C43666

CY7C43686

Switching Waveforms (continued)

Timing for AEA when FIFO2 is Almost Empty (CY Standard and FWFT Modes)^{[59, 60, 2]}

CLKC

t_ENH

t_ENS

WENC

CLKA

[61]

t_SKEW2

t_PAE

t_ENH

t_PAE

(X2+1) Words in FIFO2

t_ENS

(X2+1) Word in FIFO2

X2 Word in FIFO2

AEA

ENA

[2, 62, 63, 64]

Timing for AFA when FIFO1 is Almost Full (CY Standard and FWFT Modes)

[65]

t_SKEW2

CLKA

t_ENS

t_ENH

ENA

AFA

t_PAF

[D–(Y1+1)] Words in FIFO1

t_PAF

(D–Y1)Words in FIFO1

CLKB

RENB

t_ENH

t_ENS

[59, 2, 63, 66]

Timing for AFC when FIFO2 is Almost Full (CY Standard and FWFT Modes)

[67]

t_SKEW2

CLKC

t_ENH

t_ENS

WENC

t_PAF

AFC

t_PAF

[D–(Y2+1)] Words in FIFO2

(D–Y2)Words in FIFO2

CLKA

ENA

t_ENH

t_ENS

Notes:

56. FIFO1 Write (CSA = LOW, W/RA = LOW, MBA = LOW), FIFO1 Read (CSB = LOW, W/RB = HIGH, MBB = LOW). Data in the FIFO1 output register has been

read from the FIFO.

57. If Port B size is word or byte, AEB is set LOW by the last word or byte read from FIFO1, respectively.

58. t

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

SKEW2

CLKA edge and rising CLKB edge is less than t

, then AEB may transition HIGH one CLKB cycle later than shown.

SKEW2

59. FIFO2 Write (MBB = LOW), FIFO2 Read (CSA = LOW, W/RA = LOW, MBA = LOW). Data in the FIFO2 output register has been read from the FIFO.

60. If Port C size is word or byte, t is referenced to the rising CLKC edge that writes the last word or byte of the long word, respectively.

SKEW2

61. t

is the minimum time between a rising CLKC edge and a rising CLKA edge for AEA to transition HIGH in the next CLKA cycle. If the time between the rising

SKEW2

CLKC edge and rising CLKA edge is less than t

, then AEA may transition HIGH one CLKA cycle later than shown.

SKEW2

62. FIFO1 Write (CSA = LOW, W/RA = HIGH, MBA = LOW), FIFO1 Read (CSB = LOW, MBB = LOW). Data in the FIFO1 output register has been read from the FIFO.

63. D = Maximum FIFO Depth = 1K for the CY7C43646, 4K for the CY7C43666, and 16K for the CY7C43686.

64. If Port B size is word or byte, t

is referenced to the rising CLKB edge that writes the last word or byte of the long word, respectively.

SKEW2

65. t

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

SKEW2

CLKA edge and rising CLKB edge is less than t

, then AFA may transition HIGH one CLKB cycle later than shown.

SKEW2

66. If Port C size is word or byte, AFC is set LOW by the last word or byte write of the long word, respectively.

67. t is the minimum time between a rising CLKC edge and a rising CLKA edge for AFC to transition HIGH in the next CLKC cycle. If the time between the

SKEW2

rising CLKC edge and rising CLKA edge is less than t

, then AFC may transition HIGH one CLKA cycle later than shown.

SKEW2

Document #: 38-06023 Rev. *C

Page 34 of 39

CY7C43646

CY7C43666

CY7C43686

Switching Waveforms (continued)

Timing for Mail1 Register and MBF1 Flag (CY Standard and FWFT Modes)^[68,69]

CLKA

t_ENH

t_ENS

CSA

t_ENS

W/RA^[34]

MBA

t_ENH

t_DH

t_ENS

t_DS

ENA

A_0–35

CLKB

W1

t_PMF

MBF1

CSB

MBB

t_ENH

t_ENS

RENB

t_MDV

t_EN

t_DIS

t_PMR

FIFO1 Output Register

B_0–17

W1 (Remains valid in Mail1 Register after read)

Note:

68. If Port A is configured for word size, data can be written to the Mail1 Register using A

(A

are “don’t care” inputs). In this first case, B

will have valid

0-17

18-35

data. If Port B is configured for byte size, data can be written to the Mail1 Register using A

(A

are “don’t care” inputs). In this second case, B

will have

0–8

9–35

0–8

valid data (B

will be indeterminate).

9–17

69. Simultaneous writing to and reading from mailbox register is not allowed.

Document #: 38-06023 Rev. *C

Page 35 of 39

CY7C43646

CY7C43666

CY7C43686

Switching Waveforms (continued)

Timing for Mail2 Register and MBF2 Flag (CY Standard and FWFT Modes)^[69,70]

CLKC

MBC

t_ENH

t_ENS

WENC

C_0–17

CLKA

t_DH

t_DS

W1

t_PMF

MBF2

CSA

W/RA^[34]

MBA

ENA

A₀₋₃₅

t_ENS

t_ENH

t_MDV

FIFO2 Output Reg-

t_EN

t_PMR

t_DIS

W1 (Remains valid in Mail2 Register after

FIFO1 Retransmit Timing ^{[71, 72, 73, 74, 75]}

CLKA

CLKB

RT1

t_RSTH

t_RSTS

t

RTR

ENB

EFB/FFA

Notes:

70. If Port C is configured for word size, data can be written to the Mail2 register using C

. In this first case A

will have valid data (A

will be indeterminate).

18–35

0–17

0–8

0–17

If Port C is configured for byte size, data can be written to the Mail2 Register using B

(B

are “don’t care” inputs). In this second case, A

will have valid

9–17

0–8

data (A

will be indeterminate).

9–35

71. Retransmit is performed in the same manner for FIFO2.

72. Clocks are free-running in this case. CY standard mode only. Write operation should be prohibited one write clock cycle before the falling edge of RT1, and during

the retransmit operation, i.e. when RT1 is LOW and t after the RT1 rising edge.

RTR

73. The Empty and Full flags may change state during Retransmit as a result of the offset of the read and write pointers, but flags will be valid at t

.

RTR

74. For the AEA, AEB, AFA, and AFB flags, two clock cycle are necessary after t

to update these flags.

RTR

75. The number of 36-/18-/9-bit words written into the FIFO should be less than full depth minus 2/4/8 words between the reset of the FIFO (master or partial) and

the Retransmit setup.

Document #: 38-06023 Rev. *C

Page 36 of 39

CY7C43646

CY7C43666

CY7C43686

Ordering Information

1K x36/18x2 Tri Bus Synchronous FIFO

Speed

Package

Name

A128

Package

Type

128-lead Thin Quad Flat Package

Operating

Range

Commercial

(ns)

7

Ordering Code

CY7C43646-7AC

10

15

CY7C43646-10AC

CY7C43646-15AC

4K x36/18x2 Tri Bus Synchronous FIFO

Speed

Package

Name

A128

Package

Type

128-lead Thin Quad Flat Package

Operating

Range

Commercial

(ns)

7

Ordering Code

CY7C43666-7AC

10

15

CY7C43666-10AC

CY7C43666-15AC

16K x36/18x2 Tri Bus Synchronous FIFO

Speed

Package

Name

Package

Type

Operating

Range

(ns)

7

Ordering Code

CY7C43686-7AC

A128

128-lead Thin Quad Flat Package

Commercial

Industrial

10

15

CY7C43686-10AC

CY7C43686-15AC

CY7C43686–15AI

Document #: 38-06023 Rev. *C

Page 37 of 39

CY7C43646

CY7C43666

CY7C43686

Package Diagram

128-Lead Thin Plastic Quad Flatpack (14 x 20 x 1.4 mm) A128

51-85101-*B

All product and company names mentioned in this document are the trademarks of their respective holders.

Document #: 38-06023 Rev. *C

Page 38 of 39

of any circuitry other than circuitry embodied in a Cypress Semiconductor product. Nor does it convey or imply any license under patent or other rights. Cypress Semiconductor does not authorize

its products for use as critical components in life-support systems where a malfunction or failure may reasonably be expected to result in significant injury to the user. The inclusion of Cypress

Semiconductor products in life-support systems application implies that the manufacturer assumes all risk of such use and in doing so indemnifies Cypress Semiconductor against all charges.

CY7C43646

CY7C43666

CY7C43686

Document History Page

Document Title: CY7C43646/CY7C43666/CY7C43686 1K/4K/16K x36/x18/x2 Tri Bus FIFO

Document Number: 38-06023

Orig. of

REV. ECN No. Issue Date Change

Description of Change

**

106565

05/15/01

SZV

Change from Spec number: 38-00701 to 38-06023

*A

117174

08/28/02

OOR Added footnote to retransmit timing

Added note to retransmit section

*B

*C

122275

129118

12/26/02

09/30/03

RBI

JFU

Power-up requirements added to Maximum Ratings Information

Added mention of Port C behavior under Signal Description

Changed signal behavior of ORB/EFB, ORA/EFA, IRA/FFA, and IRC/FFC in timing

diagrams

Document #: 38-06023 Rev. *C

Page 39 of 39


型号：	CY7C43686-15AI
厂家：	CYPRESS
描述：	1K/4K/16K x36/x18/x2 Tri Bus FIFO 1K / 4K / 16K X36 / X18 / X2三总线FIFO 存储内存集成电路先进先出芯片时钟
文件：	总39页 (文件大小：641K)
中文：	中文翻译
下载：	下载PDF数据表文档文件

CY7C43686-15AI [CYPRESS]

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