CYD04S36V18-250BBXC - Cypress Semiconductor Corp.

FullFlex™ Synchronous

SDR Dual-Port SRAM

FullFlex

Cypress Semiconductor Corporation • 198 Champion Court • San Jose,CA 95134-1709 • 408-943-2600

Document #: 38-06082 Rev. *G Revised December 21, 2006

Features

• True dual-ported memory allows simultaneous access

to the shared array from each port

• Synchronous pipelined operation with Single Data Rate

(SDR) operation on each port

— SDR interface at 250 MHz

— Up to 36-Gb/s bandwidth (250 MHz * 72 bit * 2 ports)

• Selectable pipelined or flow-through mode

• 1.5V or 1.8V core power supply

• Commercial and Industrial temperature

• IEEE 1149.1 JTAG boundary scan

• Available in 484-ball PBGA Packages and 256-ball

FBGA packages

• FullFlex72 family

— 36-Mbit: 512K x 72 (CYD36S72V18)

— 18-Mbit: 256K x 72 (CYD18S72V18)

— 9-Mbit: 128K x 72 (CYD09S72V18)

— 4-Mbit: 64K x 72 (CYD04S72V18)

• FullFlex36 family

— 36-Mbit: 1M x 36 (CYD36S36V18)

— 18-Mbit: 512K x 36 (CYD18S36V18)

— 9-Mbit: 256K x 36 (CYD09S36V18)

— 4-Mbit: 128K x 36 (CYD04S36V18)

• FullFlex18 family

— 36-Mbit: 2M x 18 (CYD36S18V18)

— 18-Mbit: 1M x 18 (CYD18S18V18)

— 9-Mbit: 512K x 18 (CYD09S18V18)

— 4-Mbit: 256K x 18 (CYD04S18V18)

• Built-in deterministic access control to manage

address collisions

— Deterministic flag output upon collision detection

— Collision detection on back-to-back clock cycles

— First Busy Address readback

• Advanced features for improved high-speed data

transfer and flexibility

— Variable Impedance Matching (VIM)

— Echo clocks

— Selectable LVTTL (3.3V), Extended HSTL

(1.4V–1.9V), 1.8V LVCMOS, or 2.5V LVCMOS I/O on

each port

— Burst counters for sequential memory access

— Mailbox with interrupt flags for message passing

— Dual Chip Enables for easy depth expansion

Functional Description

The FullFlex™ Dual-Port SRAM families consist of 4-Mbit,

9-Mbit, 18-Mbit, and 36-Mbit synchronous, true dual-port static

RAMs that are high-speed, low-power 1.8V/1.5V CMOS. Two

ports are provided, allowing the array to be accessed simulta-

neously. Simultaneous access to a location triggers determin-

istic access control. For FullFlex72 these ports can operate

independently with 72-bit bus widths and each port can be

independently configured for two pipelined stages. Each port

can also be configured to operate in pipelined or flow-through

mode.

Advanced features include built-in deterministic access

control to manage address collisions during simultaneous

access to the same memory location, Variable Impedance

Matching (VIM) to improve data transmission by matching the

output driver impedance to the line impedance, and echo

clocks to improve data transfer.

To reduce the static power consumption, chip enables can be

used to power down the internal circuitry. The number of

cycles of latency before a change in CE0 or CE1 will enable

or disable the databus matches the number of cycles of read

latency selected for the device. In order for a valid write or read

to occur, both chip enable inputs on a port must be active.

Each port contains an optional burst counter on the input

address register. After externally loading the counter with the

initial address, the counter will increment the address inter-

nally.

Additional features of this device include a mask register and

a mirror register to control counter increments and

wrap-around. The counter-interrupt (CNTINT) flags notify the

host that the counter will reach maximum count value on the

next clock cycle. The host can read the burst-counter internal

address, mask register address, and busy address on the

address lines. The host can also load the counter with the

address stored in the mirror register by utilizing the retransmit

functionality. Mailbox interrupt flags can be used for message

passing, and JTAG boundary scan and asynchronous Master

Reset (MRST) are also available. The logic block diagram in

Figure 1 displays these features.

The FullFlex72 is offered in a 484-ball plastic BGA package.

The FullFlex36 and FullFlex18 are offered in both 484-ball and

256-ball fine pitch BGA packages.

FullFlex

Document #: 38-06082 Rev. *G Page 2 of 51

Notes:

1. The CYD36S18V18 device has 21 address bits. The CYD36S36V18 and the CYD18S18V18 devices have 20 address bits. The CYD36S72V18, CYD18S36V18,

and the CYD09S18V18 devices have 19 address bits. The CYD18S72V18, CYD09S36V18, and the CYD04S18V18 devices have 18 address bits. The

CYD09S72V18 and the CYD04S36V18 devices have 17 address bits. The CYD04S72V18 has 16 address bits.

2. The FullFlex72 family of devices has 72 data lines. The FullFlex36 family of devices has 36 data lines. The FullFlex18 family of devices has 18 data lines.

3. The FullFlex72 family of devices has eight byte enables. The FullFlex36 family of devices has four byte enables. The FullFlex18 family of devices has two byte

enables.

FTSELL

PORTSTD[1:0]L

DQ[71:0]L

BE [7:0]

R/W

FTSELR

PORTSTD[1:0]R

DQ [71:0]R

BE [7:0]

CE0R

CE1R

OER

R/W

A [20:0]L

CNT/MSK

ADSL

CNTENL

CNTRSTL

RETL

CNTINT

WRPL

A [20:0]R

CNT/MSK

ADSR

CNTENR

CNTRSTR

RETR

CNTINT

WRPR

CONFIG Block CONFIG Block

Control

Address &

Counter Logic Address &

Counter Logic

INTL

TRST

TMS

TDI

TDO

TCK

JTAG

MRST

READY

LowSPDR

READYL

LowSPDL

RESET

LOGIC

INTR

BUSYLBUSYR

Mailboxes

Collision Detection Logic

Dual Ported Array

Figure 1. FullFlex72 18-Mbit (CYD18S72V18) Block Diagram[1, 2, 3]

CQENLCQENR

CE0L

CE1L

OEL

CQ1R

CQ0R

CQ0L

CQ1L

ZQ0R

ZQ1R

ZQ0L

ZQ1L

FullFlex

Document #: 38-06082 Rev. *G Page 3 of 51

Notes:

4. Leaving this pin DNU disables VIM.

5. Leave this ball unconnected for CYD18S72V18, CYD09S72V18 and CYD04S72V18.

6. Leave this ball unconnected for CYD09S72V18 and CYD04S72V18.

7. Leave this ball unconnected for CYD04S72V18.

FullFlex72 SDR 484-ball BGA Pinout (Top View)

1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22

ADNU DQ61

DQ59

DQ57

DQ54

DQ51

DQ48

DQ45

DQ42

DQ39

DQ36

DQ39

DQ42

DQ45

DQ48

DQ51

DQ54

DQ57

DQ59

DQ61

DNU

BDQ63

DQ62

DQ60

DQ58

DQ55

DQ52

DQ49

DQ46

DQ43

DQ40

DQ37

DQ40

DQ43

DQ46

DQ49

DQ52

DQ55

DQ58

DQ60

DQ62

DQ63

CDQ65

DQ64

VSS VSS DQ56

DQ53

DQ50

DQ47

DQ44

DQ41

DQ38

DQ41

DQ44

DQ47

DQ50

DQ53

DQ56

VSS VSS DQ64

DQ65

DQ67

DQ66

VSS VSS VSS CQ1L CQ1L VSS LOW

SPDL

PORT

STD0

ZQ0L

[4] BUSY

CNTI

NTL

PORT

STD1

DNU CQ1R CQ1R VSS VSS VSS DQ66

DQ67

EDQ69

DQ68

VDDI

VSS VSS VDDI

VDDI

VTTL VTTL VTTL VDDI

VDDI

DNU VSS VDDI

DQ68

DQ69

FDQ71

DQ70

CE1L CE0L VDDI

VDDI

VCO

VDDI

CE0R CE1R DQ70

DQ71

GA0L A1L RETL BE4L VDDI

VDDI

VREF

VSS VSS VSS VSS VSS VSS VSS VSS VREF

VDDI

BE4R RETR A1R A0R

HA2L A3L WRP

BE5L VDDI

VDDI

VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VDDI

VDDI

BE5R WRP

A3R A2R

JA4L A5L READ

BE6L VDDI

VDDI

VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VDDI

VDDI

BE6R READ

A5R A4R

KA6L A7L ZQ1L

[4] BE7L VTTL VCO

VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VCO

VDDI

BE7R ZQ1R

[4] A7R A6R

LA8L A9L CL OEL VTTL VCO

VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VCO

VTTL OER CR A9R A8R

MA10L A11L VSS BE3L VTTL VCO

VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VCO

VTTL BE3R VSS A11R A10R

NA12L A13L ADSL BE2L VDDI

VCO

VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VCO

VTTL BE2R ADSR A13R A12R

A14L A15L CNT/

MSKL

BE1L VDDI

VDDI

VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VDDI

VDDI

BE1R CNT/

MSK

A15R A14R

RA16L

[7] A17L

[6] CNTE

BE0L VDDI

VDDI

VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VDDI

VDDI

BE0R CNTE

A17R

[6] A16R

[7]

TA18L

[5] DNU CNTR

STL

INTL VDDI

VDDI

VREF

VSS VSS VSS VSS VSS VSS VSS VSS VREF

VDDI

INTR CNTR

STR

DNU A18R

[5]

UDQ35

DQ34

R/WL CQE

VDDI

VCO

VDDI

CQE

R/WR DQ34

DQ35

VDQ33

DQ32

FTSE

VDDI

DNU VDDI

VDDI

VTTL VTTL VTTL VDDI

VDDI

TRST VDDI

FTSE

DQ32

DQ33

DQ31

DQ30

VSS MRST VSS CQ0L CQ0L DNU PORT

STD1

CNTI

NTR

BUSY

ZQ0R

[4] PORT

STD0

LOW

SPDR

VSS CQ0R CQ0R VSS TDI TDO DQ30

DQ31

YDQ29

DQ28

VSS VSS DQ20

DQ17

DQ14

DQ11

DQ8L DQ5L DQ2L DQ2R DQ5R DQ8R DQ11

DQ14

DQ17

DQ20

TMS TCK DQ28

DQ29

AA DQ27

DQ26

DQ24

DQ22

DQ19

DQ16

DQ13

DQ10

DQ7L DQ4L DQ1L DQ1R DQ4R DQ7R DQ10

DQ13

DQ16

DQ19

DQ22

DQ24

DQ26

DQ27

AB DNU DQ25

DQ23

DQ21

DQ18

DQ15

DQ12

DQ9L DQ6L DQ3L DQ0L DQ0R DQ3R DQ6R DQ9R DQ12

DQ15

DQ18

DQ21

DQ23

DQ25

DNU

FullFlex

Document #: 38-06082 Rev. *G Page 4 of 51

FullFlex36 SDR 484-ball BGA Pinout (Top View)[8]

1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22

ADNU DNU DNU DNU DNU DQ33

DQ30

DQ27

DQ24

DQ21

DQ18

DQ21

DQ24

DQ27

DQ30

DQ33

DNU DNU DNU DNU DNU

BDNU DNU DNU DNU DNU DQ34

DQ31

DQ28

DQ25

DQ22

DQ19

DQ22

DQ25

DQ28

DQ31

DQ34

DNU DNU DNU DNU DNU

CDNU DNU VSS VSS DNU DQ35

DQ32

DQ29

DQ26

DQ23

DQ20

DQ23

DQ26

DQ29

DQ32

DQ35

DNU VSS VSS DNU DNU

DNU DNU VSS VSS VSS CQ1L CQ1L VSS LOW

SPDL

PORT

STD0

ZQ0L

[4] BUSY

CNTI

NTL

PORT

STD1

DNU CQ1R CQ1R VSS VSS VSS DNU DNU

EDNU DNU VDDI

VSS VSS VDDI

VDDI

VTTL VTTL VTTL VDDI

VDDI

DNU VSS VDDI

DNU DNU

FDNU DNU CE1L CE0L VDDI

VDDI

VCO

VDDI

CE0R CE1R DNU DNU

GA0L A1L RETL BE2L VDDI

VDDI

VREF

VSS VSS VSS VSS VSS VSS VSS VSS VREF

VDDI

BE2R RETR A1R A0R

HA2L A3L WRP

BE3L VDDI

VDDI

VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VDDI

VDDI

BE3R WRP

A3R A2R

JA4L A5L READ

DNU VDDI

VDDI

VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VDDI

VDDI

DNU READ

A5R A4R

KA6L A7L ZQ1L

[4] DNU VTTL VCO

VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VCO

VDDI

DNU ZQ1R

[4] A7R A6R

LA8L A9L CL OEL VTTL VCO

VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VCO

VTTL OER CR A9R A8R

MA10L A11L VSS DNU VTTL VCO

VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VCO

VTTL DNU VSS A11R A10R

NA12L A13L ADSL DNU VDDI

VCO

VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VCO

VTTL DNU ADSR A13R A12R

A14L A15L CNT/

MSKL

BE1L VDDI

VDDI

VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VDDI

VDDI

BE1R CNT/

MSK

A15R A14R

RA16L A17L CNTE

BE0L VDDI

VDDI

VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VDDI

VDDI

BE0R CNTE

A17R A16R

TA18L A19L CNTR

STL

INTL VDDI

VDDI

VREF

VSS VSS VSS VSS VSS VSS VSS VSS VREF

VDDI

INTR CNTR

STR

A19R A18R

UDNU DNU R/WL CQE

VDDI

VCO

VDDI

CQE

R/WR DNU DNU

VDNU DNU FTSE

VDDI

DNU VDDI

VDDI

VTTL VTTL VTTL VDDI

VDDI

TRST VDDI

FTSE

DNU DNU

DNU DNU VSS MRST VSS CQ0L CQ0L DNU PORT

STD1

CNTI

NTR

BUSY

ZQ0R

[4] PORT

STD0

LOW

SPDR

VSS CQ0R CQ0R VSS TDI TDO DNU DNU

YDNU DNU VSS VSS DNU DQ17

DQ14

DQ11

DQ8L DQ5L DQ2L DQ2R DQ5R DQ8R DQ11

DQ14

DQ17

DNU TMS TCK DNU DNU

AA DNU DNU DNU DNU DNU DQ16

DQ13

DQ10

DQ7L DQ4L DQ1L DQ1R DQ4R DQ7R DQ10

DQ13

DQ16

DNU DNU DNU DNU DNU

AB DNU DNU DNU DNU DNU DQ15

DQ12

DQ9L DQ6L DQ3L DQ0L DQ0R DQ3R DQ6R DQ9R DQ12

DQ15

DNU DNU DNU DNU DNU

Note:

8. Use this pinout only for device CYD36S36V18 of the FullFlex36 family.

FullFlex

Document #: 38-06082 Rev. *G Page 5 of 51

FullFlex18 SDR 484-ball BGA Pinout (Top View)[9]

1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22

ADNU DNU DNU DNU DNU DNU DNU DNU DQ15

DQ12

DQ9L DQ9R DQ12

DQ15

DNU DNU DNU DNU DNU DNU DNU DNU

BDNU DNU DNU DNU DNU DNU DNU DNU DQ16

DQ13

DQ10

DQ13

DQ16

DNU DNU DNU DNU DNU DNU DNU DNU

CDNU DNU VSS VSS DNU DNU DNU DNU DQ17

DQ14

DQ11

DQ14

DQ17

DNU DNU DNU DNU VSS VSS DNU DNU

DNU DNU VSS VSS VSS CQ1L CQ1L VSS LOW

SPDL

PORT

STD0

ZQ0L

[4] BUSY

CNTI

NTL

PORT

STD1

DNU CQ1R CQ1R VSS VSS VSS DNU DNU

EDNU DNU VDDI

VSS VSS VDDI

VDDI

VTTL VTTL VTTL VDDI

VDDI

DNU VSS VDDI

DNU DNU

FDNU DNU CE1L CE0L VDDI

VDDI

VCO

VDDI

CE0R CE1R DNU DNU

GA0L A1L RETL BE1L VDDI

VDDI

VREF

VSS VSS VSS VSS VSS VSS VSS VSS VREF

VDDI

BE1R RETR A1R A0R

HA2L A3L WRP

DNU VDDI

VDDI

VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VDDI

VDDI

DNU WRP

A3R A2R

JA4L A5L READ

DNU VDDI

VDDI

VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VDDI

VDDI

DNU READ

A5R A4R

KA6L A7L ZQ1L

[4] DNU VTTL VCO

VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VCO

VDDI

DNU ZQ1R

[4] A7R A6R

LA8L A9L CL OEL VTTL VCO

VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VCO

VTTL OER CR A9R A8R

MA10L A11L VSS DNU VTTL VCO

VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VCO

VTTL DNU VSS A11R A10R

NA12L A13L ADSL DNU VDDI

VCO

VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VCO

VTTL DNU ADSR A13R A12R

A14L A15L CNT/

MSKL

DNU VDDI

VDDI

VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VDDI

VDDI

DNU CNT/

MSK

A15R A14R

RA16L A17L CNTE

BE0L VDDI

VDDI

VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VDDI

VDDI

BE0R CNTE

A17R A16R

TA18L A19L CNTR

STL

INTL VDDI

VDDI

VREF

VSS VSS VSS VSS VSS VSS VSS VSS VREF

VDDI

INTR CNTR

STR

A19R A18R

UA20L DNU R/WL CQE

VDDI

VCO

VDDI

CQE

R/WR DNU A20R

VDNU DNU FTSE

VDDI

DNU VDDI

VDDI

VTTL VTTL VTTL VDDI

VDDI

TRST VDDI

FTSE

DNU DNU

DNU DNU VSS MRST VSS CQ0L CQ0L DNU PORT

STD1

CNTI

NTR

BUSY

ZQ0R

[4] PORT

STD0

LOW

SPDR

VSS CQ0R CQ0R VSS TDI TDO DNU DNU

YDNU DNU VSS VSS DNU DNU DNU DNU DQ8L DQ5L DQ2L DQ2R DQ5R DQ8R DNU DNU DNU DNU TMS TCK DNU DNU

AA DNU DNU DNU DNU DNU DNU DNU DNU DQ7L DQ4L DQ1L DQ1R DQ4R DQ7R DNU DNU DNU DNU DNU DNU DNU DNU

AB DNU DNU DNU DNU DNU DNU DNU DNU DQ6L DQ3L DQ0L DQ0R DQ3R DQ6R DNU DNU DNU DNU DNU DNU DNU DNU

Note:

9. Use this pinout only for device CYD36S18V18 of the FullFlex18 family.

FullFlex

Document #: 38-06082 Rev. *G Page 6 of 51

Notes:

10. Leave this ball unconnected for CYD09S36V18 and CYD04S36V18.

11. Leave this ball unconnected for CYD04S36V18.

FullFlex36 SDR 256-Ball BGA (Top View)

1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16

ADQ32L DQ30L DQ28L DQ26L DQ24L DQ22L DQ20L DQ18L DQ18R DQ20R DQ22R DQ24R DQ26R DQ28R DQ30R DQ32R

BDQ33L DQ31L DQ29L DQ27L DQ25L DQ23L DQ21L DQ19L DQ19R DQ21R DQ23R DQ25R DQ27R DQ29R DQ31R DQ33R

CDQ34L DQ35L RETL INTL CQ1L CQ1L DNU TRST MRST ZQ0R[4] CQ1R CQ1R INTR RETR DQ35R DQ34R

DA0L A1L WRPL VREFL FTSELL LOWSP

VSS VTTL VTTL VSS LOWSP

FTSELR VREFR WRPR A1R A0R

EA2L A3L CE0L CE1L VDDIOL VDDIOL VDDIOL VCORE VCORE VDDIOR VDDIOR VDDIOR CE1R CE0R A3R A2R

FA4L A5L CNTINTL BE3L VDDIOL VSS VSS VSS VSS VSS VSS VDDIOR BE3R CNTINTR A5R A4R

GA6L A7L BUSYL BE2L ZQ0L[4] VSS VSS VSS VSS VSS VSS VDDIOR BE2R BUSYR A7R A6R

HA8L A9L CL VTTL VCORE VSS VSS VSS VSS VSS VSS VCORE VTTL CR A9R A8R

JA10L A11L VSS PORTST

D1L

VCORE VSS VSS VSS VSS VSS VSS VCORE PORTST

D1R

VSS A11R A10R

KA12L A13L OEL BE1L VDDIOL VSS VSS VSS VSS VSS VSS VDDIOR BE1R OER A13R A12R

LA14L A15L ADSL BE0L VDDIOL VSS VSS VSS VSS VSS VSS VDDIOR BE0R ADSR A15R A14R

MA16L A17L[11] R/WL CQENL VDDIOL VDDIOL VDDIOL VCORE VCORE VDDIOR VDDIOR VDDIOR CQENR R/WR A17R[11] A16R

NA18L[10] DNU CNT/MS

VREFL PORTST

D0L

READYL ZQ1L[4] VTTL VTTL ZQ1R[4] READY

PORTST

D0R

VREFR CNT/MS

DNU A18R[10]

PDQ16L DQ17L CNTENL CNTRST

CQ0L CQ0L TCK TMS TDO TDI CQ0R CQ0R CNTRST

CNTENR DQ17R DQ16R

RDQ15L DQ13L DQ11L DQ9L DQ7L DQ5L DQ3L DQ1L DQ1R DQ3R DQ5R DQ7R DQ9R DQ11R DQ13R DQ15R

TDQ14L DQ12L DQ10L DQ8L DQ6L DQ4L DQ2L DQ0L DQ0R DQ2R DQ4R DQ6R DQ8R DQ10R DQ12R DQ14R

FullFlex

Document #: 38-06082 Rev. *G Page 7 of 51

Notes:

12. Leave this ball unconnected for CYD09S18V18 and CYD04S18V18.

13. Leave this ball unconnected for CYD04S18V18.

FullFlex18 SDR 256-Ball BGA (Top View)

12345678910111213141516

ADNU DNU DNU DQ17L DQ16L DQ13L DQ12L DQ9L DQ9R DQ12R DQ13R DQ16R DQ17R DNU DNU DNU

BDNU DNU DNU DNU DQ15L DQ14L DQ11L DQ10L DQ10R DQ11R DQ14R DQ15R DNU DNU DNU DNU

CDNU DNU RETL INTL CQ1L CQ1L DNU TRST MRST ZQ0R[4] CQ1R CQ1R INTR RETR DNU DNU

DA0L A1L WRPL VREFL FTSELL LOWSP

VSS VTTL VTTL VSS LOWSP

FTSELR VREFR WRPR A1R A0R

EA2L A3L CE0L CE1L VDDIOL VDDIOL VDDIOL VCORE VCORE VDDIOR VDDIOR VDDIOR CE1R CE0R A3R A2R

FA4L A5L CNTINTL DNU VDDIOL VSS VSS VSS VSS VSS VSS VDDIOR DNU CNTINTR A5R A4R

GA6L A7L BUSYL DNU ZQ0L[4] VSS VSS VSS VSS VSS VSS VDDIOR DNU BUSYR A7R A6R

HA8L A9L CL VTTL VCORE VSS VSS VSS VSS VSS VSS VCORE VTTL CR A9R A8R

JA10L A11L VSS PORTST

D1L

VCORE VSS VSS VSS VSS VSS VSS VCORE PORTST

D1R

VSS A11R A10R

KA12L A13L OEL BE1L VDDIOL VSS VSS VSS VSS VSS VSS VDDIOR BE1R OER A13R A12R

LA14L A15L ADSL BE0L VDDIOL VSS VSS VSS VSS VSS VSS VDDIOR BE0R ADSR A15R A14R

MA16L A17L R/WL CQENL VDDIOL VDDIOL VDDIOL VCORE VCORE VDDIOR VDDIOR VDDIOR CQENR R/WR A17R A16R

NA18L[13] A19L[12] CNT/MS

VREFL PORTST

D0L

READYL ZQ1L[4] VTTL VTTL ZQ1R[4] READY

PORTST

D0R

VREFR CNT/MS

A19R[12] A18R[13]

PDNU DNU CNTENL CNTRST

CQ0L CQ0L TCK TMS TDO TDI CQ0R CQ0R CNTRST

CNTENR DNU DNU

RDNU DNU DNU DNU DQ6L DQ5L DQ2L DQ1L DQ1R DQ2R DQ5R DQ6R DNU DNU DNU DNU

TDNU DNU DNU DQ8L DQ7L DQ4L DQ3L DQ0L DQ0R DQ3R DQ4R DQ7R DQ8R DNU DNU DNU

FullFlex

Document #: 38-06082 Rev. *G Page 8 of 51

Table 1. Selection Guide

–250 –200 –167 Unit

fMAX[15] 250 200 167 MHz

Max. Access Time (Clock to Data) 2.64 3.3 4.0 ns

Typical Operating Current ICC 930[14] 800[14] 700[14] mA

Typical Standby Current for ISB3 (Both Ports CMOS Level) 210[14] 210[14] 210[14] mA

Pin Definitions

Left Port Right Port Description

A[20:0]LA[20:0]RAddress Inputs.[1]

DQ[71:0]LDQ[71:0]RData Bus Input/Output.[2]

BE[7:0]LBE[7:0]RByte Select Inputs.[3] Asserting these signals enables Read and Write operations to

the corresponding bytes of the memory array.

BUSYLBUSYRPort Busy Output. When there is an address match and both chip enables are active

for both ports, an external BUSY signal is asserted on the fifth clock cycles from when

the collision occurs.

CLCRClock Signal. Maximum clock input rate is fMAX.

CE0LCE0RActive LOW Chip Enable Input.

CE1LCE1RActive HIGH Chip Enable Input.

CQENLCQENREcho Clock Enable Input. Assert HIGH to enable echo clocking on respective port.

CQ0LCQ0REcho Clock Signal Output for DQ[35:0] for FullFlex72 devices. Echo Clock Signal

Output for DQ[17:0] for FullFlex36 devices. Echo Clock Signal Output for DQ[8:0] for

FullFlex18 devices.

CQ0LCQ0RInverted Echo Clock Signal Output for DQ[35:0] for FullFlex72 devices. Inverted

Echo Clock Signal Output for DQ[17:0] for FullFlex36 devices. Inverted Echo Clock

Signal Output for DQ[8:0] for FullFlex18 devices.

CQ1LCQ1REcho Clock Signal Output for DQ[71:36] for FullFlex72 devices. Echo Clock Signal

Output for DQ[35:18] for FullFlex36 devices. Echo Clock Signal Output for DQ[17:9]

for FullFlex18 devices.

CQ1LCQ1RInverted Echo Clock Signal Output for DQ[71:36] for FullFlex72 devices. Inverted

Echo Clock Signal Output for DQ[35:18] for FullFlex36 devices. Inverted Echo Clock

Signal Output for DQ[17:9] forFullFlex18 devices.

ZQ[1:0]LZQ[1:0]RVIM Output Impedance Matching Input. To use, connect a calibrating resistor

between ZQ and ground. The resistor must be five times larger than the intended line

impedance driven by the dual-port. Assert HIGH or leave DNU to disable Variable

Impedance Matching.

OELOEROutput Enable Input. This asynchronous signal must be asserted LOW to enable the

DQ data pins during Read operations.

INTLINTRMailbox Interrupt Flag Output. The mailbox permits communications between ports.

The upper two memory locations can be used for message passing. INTL is asserted

LOW when the right port writes to the mailbox location of the left port, and vice versa.

An interrupt to a port is deasserted HIGH when it reads the contents of its mailbox.

LowSPDLLowSPDRPort Low Speed Select Input. Assert this pin LOW to disable the DLL. For operation

at less than 100 MHz, assert this pin LOW.

PORTSTD[1:0]L[16] PORTSTD[1:0]R[16] Port Clock/Address/Control/Data/Echo Clock/I/O Standard Select Input. Assert

these pins LOW/LOW for LVTTL, LOW/HIGH for HSTL, HIGH/LOW for 2.5V LVCMOS,

and HIGH/HIGH for 1.8V LVCMOS, respectively. These pins must be driven by VTTL

referenced levels.

Notes:

14. For 18-Mbit x72 commercial configuration only, please refer to the electrical characteristics section for complete information.

15. SDR mode with two pipelined stages.

16. PORTSTD[1:0]L and PORTSTD[1:0]R have internal pull-down resistors.

FullFlex

Document #: 38-06082 Rev. *G Page 9 of 51

Selectable I/O Standard

The FullFlex device families also offer the option of choosing

one of four port standards for the device. Each port can

independently select standards from single-ended HSTL class

I, single-ended LVTTL, 2.5V LVCMOS, or 1.8V LVCMOS. The

selection of the standard is determined by the PORTSTD pins

for each port. These pins should be connected to either an

LVTTL or 2.5V LVCMOS power suppy. This will determine the

input clock, address, control, data, and Echo clock standard

for each port as shown in Table 2. Please note that only 1.8V

LVCMOS and HSTL are supported for 4-Mbit, 9-Mbit, 18-Mbit

devices running at 250 MHz, and for 36-Mbit devices running

at 200 MHz.

Clocking

Separate clocks synchronize the operations on each port.

Each port has one clock input C. In this mode, all the transac-

tions on the address, control, and data will be on the C rising

R/WLR/WRRead/Write Enable Input. Assert this pin LOW to Write to, or HIGH to Read from the

dual-port memory array.

READYLREADYRPort DLL Ready Output. This signal will be asserted LOW when the DLL and Variable

Impedance Matching circuits have completed calibration. This is a wired OR capable

output.

CNT/MSKLCNT/MSKRPort Counter/Mask Select Input. Counter control input.

ADSLADSRPort Counter Address Load Strobe Input. Counter control input.

CNTENLCNTENRPort Counter Enable Input. Counter control input.

CNTRSTLCNTRSTRPort Counter Reset Input. Counter control input.

CNTINTLCNTINTRPort Counter Interrupt Output. This pin is asserted LOW one cycle before the

unmasked portion of the counter is incremented to all “1s”.

WRPLWRPRPort Counter Wrap Input. When the burst counter reaches the maximum count, on

the next counter increment WRP can be set LOW to load the unmasked counter bits

to 0 or set HIGH to load the counter with the value stored in the mirror register.

RETLRETRPort Counter Retransmit Input. Assert this pin LOW to reload the initial address for

repeated access to the same segment of memory.

VREFLVREFRPort External HSTL I/O Reference Input. This pin is left DNU when HSTL is not used.

VDDIOLVDDIORPort Data I/O Power Supply.

FTSELLFTSELRPort Flow-through Mode Select Input. Assert this pin LOW to select Flow-through

mode. Assert this pin HIGH to select Pipelined mode.

MRST Master Reset Input. MRST is an asynchronous input signal and affects both ports.

Asserting MRST LOW performs all of the reset functions as described in the text. A

MRST operation is required at power-up. This pin must be driven by a VDDIOL refer-

enced signal.

TMS JTAG Test Mode Select Input. It controls the advance of JTAG TAP state machine.

State machine transitions occur on the rising edge of TCK. Operation for LVTTL or 2.5V

LVCMOS.

TDI JTAG Test Data Input. Data on the TDI input will be shifted serially into selected

registers. Operation for LVTTL or 2.5V LVCMOS.

TRST JTAG Reset Input. Operation for LVTTL or 2.5V LVCMOS.

TCK JTAG Test Clock Input. Operation for LVTTL or 2.5V LVCMOS.

TDO JTAG Test Data Output. TDO transitions occur on the falling edge of TCK. TDO is

normally three-stated except when captured data is shifted out of the JTAG TAP.

Operation for LVTTL or 2.5V LVCMOS.

VSS Ground Inputs.

VCORE Device Core Power Supply.

VTTL LVTTL Power Supply.

Pin Definitions (continued)

Left Port Right Port Description

Table 2. Port Standard Selection

PORTSTD1 PORTSTD0 I/O Standard

VSS VSS LVTTL

VSS VTTL HSTL

VTTL VSS 2.5V LVCMOS

VTTL VTTL 1.8V LVCMOS

FullFlex

Document #: 38-06082 Rev. *G Page 10 of 51

edge. All transactions on the address, control, data input,

output, and byte enables will occur on the C rising edge.

Selectable Pipelined/Flow-through Mode

To meet data rate and throughput requirements, the FullFlex

families offer selectable pipelined or flow-through mode. Echo

clocks are not supported in flow-through mode and the DLL

must be disabled.

Flow-through mode is selected by the FTSEL pin. Strapping

this pin HIGH selects pipelined mode. Strapping this pin LOW

selects flow-through mode.

DLL

The FullFlex familes of devices have an on-chip DLL. Enabling

the DLL reduces the clock to data valid (tCD) time allowing

more set-up time for the receiving device. For operation below

100 MHz, the DLL must be disabled. This is selectable by

strapping LowSPD low.

Whenever the operating frequency is altered beyond the Clock

Input Cycle to Cycle Jitter spec, the DLL is required to be reset

followed by 1024 clocks before any valid operation.

LowSPD pins can be used to reset the DLL(s) for a single port

independent of all other circuitry. MRST can be used to reset

all DLLs on the chip, for information on DLL lock and reset

time, please see the Master Reset section below.

Echo Clocking

As the speed of data increases, on-board delays caused by

parasitics make providing accurate clock trees extremely

difficult. To counter this problem, the FullFlex families incor-

porate Echo Clocks. Echo Clocks are enabled on a per port

basis. The dual-port receives input clocks that are used to

clock in the address and control signals for a read operation.

The dual-port retransmits the input clocks relative to the data

output. The buffered clocks are provided on the CQ1/CQ1 and

CQ0/CQ0 outputs. Each port has a pair of Echo clocks. Each

clock is associated with half the data bits. The output clock will

match the corresponding ports I/O configuration.

To enable Echo clock outputs, tie CQEN HIGH. To disable

Echo clock outputs, tie CQEN LOW.

Deterministic Access Control

Deterministic Access Control is provided for ease of design.

The circuitry detects when both ports are accessing the same

location and provides an external BUSY flag to the port on

which data may be corrupted. The collision detection logic

saves the address in conflict (Busy Address) to a readable

address will be written to the Busy Address register.

If both ports are accessing the same location at the same time

and only one port is doing a write, if tCCS is met, then the data

being written to and read from the address is valid data. For

example, if the right port is reading and the left port is writing

and the left ports clock meets tCCS, then the data being read

from the address by the right port will be the old data. In the

same case, if the right ports clock meets tCCS, then the data

being read out of the address from the right port will be the new

data. In the above case, if tCCS is violated by the either ports

clock with respect to the other port and the right port gets the

external BUSY flag, the data from the right port is corrupted.

Table 4 shows the tCCS timing that must be met to guarantee

the data.

Table 5 shows that, in the case of the left port writing and the

right port reading, when an external BUSY flag is asserted on

the right port, the data read out of the device will not be

guaranteed.

The value in the busy address register can be read back to the

address lines. The required input control signals for this

function are shown in Table 8. The value in the busy address

amount of latency as a data read operation. After an initial

address match, the BUSY flag is asserted and the address

under contention is saved in the busy address register. All

following address matches cause the BUSY flag to be

generated, however, none of the addresses are saved into the

busy address register. Once a busy readback is performed,

the address of the first match that happens at least two clocks

cycles after the busy readback is saved into the busy address

Table 3. Data Pin Assignment

BE Pin Name Data Pin Name

BE[7] DQ[71:63]

BE[6] DQ[62:54]

BE[5] DQ[53:45]

BE[4] DQ[44:36]

BE[3] DQ[35:27]

BE[2] DQ[26:18]

BE[1] DQ[17:9]

BE[0] DQ[8:0]

Figure 2. SDR Echo Clock Delay

Input Clock

Echo Clock

Data Out

Echo Clock

Table 4. tCCS Timing for All Operating Modes

Port A—Early Arriving Port Port B—Late Arriving Port tCCS

C Rise to Opposite C Rise Set-up Time for Non-corrupt Data UnitMode Active Edge Mode Active Edge

SDR C SDR C tCYC(min) – 0.5 ns

FullFlex

Document #: 38-06082 Rev. *G Page 11 of 51

Variable Impedance Matching (VIM)

Each port contains a Variable Impedance Matching circuit to

set the impedance of the I/O driver to match the impedance of

the on-board traces. The impedance is set for all outputs

except JTAG and is done on a per port basis. To take

advantage of the VIM feature, connect a calibrating resistor

(RQ) that is five times the value of the intended line impedance

from the ZQ pin to VSS. The output impedance is then

adjusted to account for drifts in supply voltage and temper-

ature every 1024 clock cycles. If a port’s clock is suspended,

the VIM circuit will retain its last setting until the clock is

restarted. On restart, it will then resume periodic adjustment.

In the case of a significant change in device temperature or

supply voltage, recalibration will happen every 1024 clock

cycles. A Master Reset will initialize the VIM circuitry. Ta bl e 6

shows the VIM parameters and Table 7 describes the VIM

operation modes.

In order to disable VIM, the ZQ pin must be connected to

VDDIO of the relative supply for the I/Os before a Master

Reset.

Address Counter and Mask Register Operations[1]

Each port of the FullFlex family contains a programmable burst

address counter. The burst counter contains four registers: a

counter register, a mask register, a mirror register, and a busy

address register.

The counter register contains the address used to access the

RAM array. It is changed only by the master reset (MRST),

Counter Reset, Counter Load, Retransmit, and Counter

Increment operations.

The mask register value affects the Counter Increment and

Counter Reset operations by preventing the corresponding

bits of the counter register from changing. It also affects the

counter interrupt output (CNTINT). The mask register is only

changed by Mask Reset, Mask Load, and MRST. The Mask

Load operation loads the value of the address bus into the

mask register. The mask register defines the counting range

of the counter register. The mask register is divided into two or

three consecutive regions. Zero or more “0s” define the

masked region and one or more “1s” define the unmasked

portion of the counter register. The counter register may only

be divided into up to three regions. The region containing the

least significant bits must be no more than two “0s”. Bits one

and zero may be “10” respectively, masking the least signif-

icant counter bit and causing the counter to increment by two

instead of one. If bits one and zero are “00”, the two least

significant bits are masked and the counter will increment by

four instead of one. For example, in the case of a 256Kx72

Table 5. Deterministic Access Control Logic

Left Port Right Port Left Clock Right Clock BUSYLBUSYRDescription

Read Read X X H H No Collision

Write Read >tCCS 0 H H Read OLD Data

0>t

CCS H H Read NEW Data

<tCCS 0 H H Read OLD Data

H L Data Not Guaranteed

0<t

CCS H H Read NEW Data

H L Data Not Guaranteed

Read Write >tCCS 0 H H Read NEW Data

0>t

CCS H H Read OLD Data

<tCCS 0 H H Read NEW Data

L H Data Not Guaranteed

0<t

CCS H H Read OLD Data

L H Data Not Guaranteed

Write Write 0 >–tCCS & <tCCS L L Array Data Corrupted

0>t

CCS L H Array Stores Right Port Data

>tCCS 0 H L Array Stores Left Port Data

Table 6. Variable Impedance Matching Parameters

Parameter Min. Max. Unit Tolerance

RQ Value 100 275 Ω± 2%

Output Impedance 20 55 Ω± 15%

Reset Time N/A 1024 Cycles N/A

Update Time N/A 1024 Cycles N/A

Table 7. Variable Impedance Matching Operation

RQ Connection Output Configuration

100Ω - 275Ω to VSS Output Driver Impedance = RQ/5 ±

15% at Vout = VDDIO/2

ZQ to VDDIO VIM Disabled. Rout < 20Ω at Vout =

VDDIO/2

FullFlex

Document #: 38-06082 Rev. *G Page 12 of 51

configuration, a mask register value of 003FC divides the

mask register into three regions. With bit 0 being the least

significant bit and bit 17 being the most significant bit, the two

least significant bits are masked, the next eight bits are

unmasked, and the remaining bits are masked.

The mirror register is used to reload the counter register on

retransmit operations (see “retransmit” below) and wrap

functions (see “counter increment” below). The last value

loaded into the counter register is stored in the mirror register.

The mirror register is only changed by master reset (MRST),

Counter Reset, and Counter Load.

Table 8 summarizes the operations of these registers and the

required input control signals. All signals except MRST are

synchronized to the ports clock.

Counter Load Operation[1]

The address counter and mirror registers are both loaded with

the address value presented on the address lines. This value

ranges from 0 to 1FFFFF.

Mask Load Operation[1]

The mask register is loaded with the address value presented

on the address bus. This value ranges from 0 to 1FFFFF

though not all values permit correct increment operations.

Permitted values are in the form of 2n–1, 2n–2, or 2n–4. The

counter register can only be segmented in up to three regions.

From the most significant bit to the least significant bit,

permitted values have zero or more “0s”, one or more “1s”, and

the least significant two bits can be “11”, “10”, or “00”. Thus

1FFFFE, 07FFFF, and 003FFC are permitted values but

02FFFF, 003FFA, and 07FFE4 are not.

Counter Readback Operation

The internal value of the counter register can be read out on

the address lines. The address will be valid tCA after the

selected number of latency cycles configured by FTSEL. The

data bus (DQ) is tri-stated on the cycle that the address is

presented on the address lines. Figure 3 shows a block

diagram of this logic.

Mask Readback Operation

The internal value of the mask register can be read out on the

address lines. The address will be valid tCA after the selected

number of latency cycles configured by FTSEL. The data bus

(DQ) is tri-stated on the cycle that the address is presented on

the address lines. Figure 3 shows a block diagram of the

operation.

Counter Reset Operation

All unmasked bits of the counter and mirror registers are reset

to “0”. All masked bits remain unchanged. A mask reset

followed by a counter reset will reset the counter and mirror

registers to 00000.

Mask Reset Operation

The mask register is reset to all “1s”, which unmasks every bit

of the burst counter.

FullFlex

Document #: 38-06082 Rev. *G Page 13 of 51

Notes:

17. “X” = “Don’t Care”, “H” = HIGH, “L” = LOW.

18. Counter operation and mask register operation is independent of chip enables.

Table 8. Burst Counter and Mask Register Control Operation (Any Port) [17, 18]

CMRSTCNTRST CNT/MSK CNTEN ADS RET Operation Description

X L X X X X X Master Reset Reset address counter to all 0s, mask register

to all 1s, and busy address to all 0’s.

H L H X X X Counter Reset Reset counter and mirror unmasked portion to

all 0s.

H L L X X X Mask Reset Reset mask register to all 1s.

H H H L L X Counter Load Load burst counter and mirror with external

address value presented on address lines.

H H L L L X Mask Load Load mask register with value presented on the

address lines.

H H H L H L Retransmit Load counter with value in the mirror register

HH H LHHCounter

Increment

Internally increment address counter value.

H H H H H H Counter Hold Constantly hold the address value for multiple

clock cycles.

HH H HLHCounter

Readback

Read out counter internal value on address

lines.

H H L H L H Mask

Readback

Read out mask register value on address lines.

H H L H H L Busy Address

Readback

Read out first busy address after last busy

address readback

HH L LHXReserved

HH L HLLReserved

HH L HHHReserved

HH H HLLReserved

HH H HHLReserved

FullFlex

Document #: 38-06082 Rev. *G Page 14 of 51

Increment Operation[1]

Once the address counter is initially loaded with an external

address, the counter can internally increment the address

value and address the entire memory array. Only the

unmasked bits of the counter register are incremented. In

order for a counter bit to change, the corresponding bit in the

mask register must be “1”. If the two least significant bits of the

mask register are “11”, the burst counter will increment by one.

If the two least significant bits are “10”, the burst counter will

increment by two, and if they are “00”, the burst counter will

increment by four. If all unmasked counter bits are incre-

mented to “1” and WRP is deasserted, the next increment will

wrap the counter back to the initially loaded value. The cycle

before the increment that results in all unmasked counter bits

to become “1s”, a counter interrupt flag (CNTINT) is asserted

if the counter is incremented again. This increment will cause

the counter to reach its maximum value and the next increment

will return the counter register to its initial value that was stored

in the mirror register if WRP is deasserted. If WRP is asserted,

the unmasked portion of the counter is filled with “0” instead.

The example shown in Figure 4 shows an example of the

CYDD36S18V18 device with the mask register loaded with a

mask value of 00007F unmasking the seven least significant

bits. Setting the mask register to this value allows the counter

to access the entire memory space. The address counter is

then loaded with an initial value of 000005 assuming WRP is

deasserted. The masked bits, the seventh address through the

twenty-first address, do not increment in an increment

operation. The counter address will start at address 000005

and will increment its internal address value until it reaches the

mask register value of 00007F. The counter wraps around the

memory block to location 000005 at the next count. CNTINT

is issued when the counter reaches the maximum –1 count.

Hold Operation

The value of all three registers can be constantly maintained

unchanged for an unlimited number of clock cycles. Such

operation is useful in applications where wait states are

needed, or when address is available a few cycles ahead of

data in a shared bus interface.

Retransmit

Retransmit allows repeated access to the same block of

memory without the need to reload the initial address. An

internal mirror register stores the address counter value last

loaded. While RET is asserted low, the counter will continue to

wrap back to the value in the mirror register independent of the

state of WRP

Counter Interrupt

The counter interrupt (CNTINT) is asserted LOW one clock

cycle before an increment operation that results in the

unmasked portion of the counter register being all “1s”. It is

deasserted by counter reset, counter load, mask reset, mask

load, and MRST.

Counting by Two

When the two least significant bits of the mask register are

“10,” the counter increments by two.

Counting by Four

When the two least significant bits of the mask register are

“00”, the counter increments by four.

Mailbox Interrupts

The upper two memory locations can be used for message

passing and permit communications between ports. Table 9

shows the interrupt operation for both ports. The highest

memory location is the mailbox for the right port and the

maximum address – 1 is the mailbox for the left port.

When one port Writes to the other port’s mailbox, the INT flag

of the port that the mailbox belongs to is asserted LOW. The

INT flag remains asserted until the mailbox location is read by

the other port. When a port reads its mailbox, the INT flag is

deasserted high after one cycle of latency with respect to the

input clock of the port to which the mailbox belongs and is

independent of OE.

Table 9 shows that in order to set the INTR flag, a Write

operation by the left port to address 1FFFFF will assert INTR

LOW. A valid Read of the 1FFFFF location by the right port will

reset INTR HIGH after one cycle of latency with respect to the

right port’s clock. At least one byte enable has to be activated

to set or reset the mailbox interrupt.

FullFlex

Document #: 38-06082 Rev. *G Page 15 of 51

From

Mask

Mirror Counter

Address

Decode

RAM

Array

Wrap

Increment

Logic

Wrap

Detect

From

Mask

From

Counter

Bit 0

and 1

Wrap

Figure 3. Counter, Mask, and Mirror Logic Block Diagram[1]

20 20

Load/Increment

CNT/MSK

CNTEN

CNTRST

Decode

Logic

AMask

Counter/

Address

From

Address

Lines To Readback

and Address

Decode

MRST

RET

FullFlex

Document #: 38-06082 Rev. *G Page 16 of 51

Master Reset

The FullFlex family of Dual-Ports undergo a complete reset

when MRST is asserted. MRST must be driven by VDDIOL

referenced levels. The MRST can be asserted asynchronously

to the clocks and must remain asserted for at least tRS. Once

asserted MRST deasserts READY, initializes the internal burst

counters, internal mirror registers, and internal Busy

Addresses to zero, and initializes the internal mask register to

all “1s”. All mailbox interrupts (INT), Busy Address Outputs

(BUSY), and burst counter interrupts (CNTINT) are

deasserted upon master reset. Additionally, MRST must not

be released until all power supplies including VREF are fully

ramped, all port clocks and mode select inputs (LOWSPD, ZQ,

CQEN, DDRON, FTSEL, and PORTSTD) are valid and stable.

This begins calibration of the DLL and VIM circuits. READY

will be asserted within 1024 clock cycles. READY is a wired

OR capable output with a strong pull-up and weak pull-down.

Up to four outputs may be connected together. For faster

pull-down of the signal, connect a 250 Ohm resistor to VSS. If

the DLL and VIM circuits are disabled for a port, the port will

be operational within five clock cycles. However, the READY

will be asserted within 160 clock cycles.

IEEE 1149.1 Serial Boundary Scan (JTAG)

The FullFlex families incorporate an IEEE 1149.1 serial

boundary scan test access port (TAP). The TAP operates

using JEDEC-standard 3.3V or 2.5V I/O logic levels depending

on the VTTL power supply. It is composed of four input

connections and one output connection required by the test

logic defined by the standard.

Notes:

19. CE is internal signal. CE = LOW if CE0 = LOW and CE1 = HIGH. For a single Read operation, CE only needs to be asserted once at the rising edge of the C and

can be deasserted after that. Data will be out after the following C edge and will be tri-stated after the next C edge.

20. OE is “Don’t Care” for mailbox operation.

21. At least one of BE0, BE1, BE2, BE3, BE4, BE5, BE6, or BE7 must be LOW.

22. The “X” in this diagram represents the counter’s upper bits.

220 219 2621

2522

242320

220 219 2621

2522

242320

220 219 2621

2522

242320

220 219 2621

2522

242320

0s 1

0111

Xs 0

X001

Xs 1

X111

Xs 0

X001

Masked Address Unmasked Address

Mask

LSB

Address

Counter

LSB

CNTINT

Example:

Load

Counter-Mask

Load

Address

Counter = 000005

Max

Address

Value

Max + 1

Address

Value

Figure 4. Programmable Counter-Mask Register Operation with WRP deasserted[1, 22]

Table 9. Interrupt Operation Example[1, 17, 19, 20, 21]

Function

Left Port Right Port

R/WLCELA0L–20L INTLR/WRCERA0R–20R INTR

Set Right INTR Flag L L Max. Address X X X X L

Reset Right INTR Flag X X X X H L Max. Address H

Set Left INTL Flag X X X L L L Max. Address–1 X

Reset Left INTL Flag H L Max. Address–1 H X X X X

FullFlex

Document #: 38-06082 Rev. *G Page 17 of 51

Table 10.JTAG IDCODE Register Definitions

Part Number Configuration Value

CYD36S72V18 512Kx72 0C026069h (x2)

CYD36S36V18 1024Kx36 0C023069h

CYD36S18V18 2048Kx36 0C024069h

CYD18S72V18 256Kx72 0C025069h

CYD18S36V18 512Kx36 0C026069h

CYD18S18V18 1024Kx18 0C027069h

CYD09S72V18 128Kx72 0C028069h

CYD09S36V18 256Kx36 0C029069h

CYD09S18V18 512Kx18 0C02A069h

CYD04S72V18 64Kx72 0C02B069h

CYD04S36V18 128Kx36 0C02C069h

CYD04S18V18 256Kx18 0C02D069h

Table 11.Scan Registers Sizes

Instruction 4

Bypass 1

Identification 32

Boundary Scan n[23]

Table 12.Instruction Identification Codes

Instruction Code Description

EXTEST 0000 Captures the Input/Output ring contents. Places the BSR between the TDI and TDO.

BYPASS 1111 Places the BYR between TDI and TDO.

IDCODE 1011 Loads the IDR with the vendor ID code and places the register between TDI and TDO.

HIGHZ 0111 Places BYR between TDI and TDO. Forces all FullFlex72 and FullFlex36 output drivers

to a High-Z state.

CLAMP 0100 Controls boundary to 1/0. Places BYR between TDI and TDO.

SAMPLE/PRELOAD 1000 Captures the input/output ring contents. Places BSR between TDI and TDO.

RESERVED All other codes Other combinations are reserved. Do not use other than the above.

Note:

23. Details of the boundary scan length can be found in the BSDL file for the device.

FullFlex

Document #: 38-06082 Rev. *G Page 18 of 51

Maximum Ratings

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

lines, not tested.)

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

Ambient Temperature with

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

Supply Voltage to Ground Potential .............. –0.5V to + 4.1V

DC Voltage Applied to

Outputs in High-Z State.......................–0.5V to VDDIO + 0.5V

DC Input Voltage.................................–0.5V to VDDIO + 0.5V

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

Static Discharge Voltage ...........................................> 2200V

(JEDEC JESD8-6, JESD8-B)

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

Operating Range

Range Ambient Temperature VCORE

Commercial 0°C to +70°C 1.8V ± 100 mV

1.5V ± 80 mV

Industrial –40°C to +85°C 1.8V ± 100 mV

1.5V ± 80 mV

Power Supply Requirements

Min. Typ. Max.

LVTTL VDDIO 3.0V3.3V3.6V

2.5V LVCMOS VDDIO 2.3V 2.5V 2.7V

HSTL VDDIO 1.4V1.5V1.9V

1.8V LVCMOS VDDIO 1.7V 1.8V 1.9V

3.3V VTTL 3.0V 3.3V 3.6V

2.5V VTTL 2.3V 2.5V 2.7V

HSTL VREF 0.68V 0.75V 0.95V

Electrical Characteristics Over the Operating Range

Parameter Description Configuration

All Speed Bins[24] Unit

Min. Typ. Max.

VOH Output HIGH Voltage

(VDDIO = Min., IOH = –8 mA)

LVTTL 2.4[25] V

(VDDIO = Min., IOH = –4 mA) HSTL (DC)[26] VDDIO – 0.4[25] V

(VDDIO = Min., IOH = –4 mA) HSTL (AC)[26] VDDIO – 0.5[25] V

(VDDIO = Min., IOH = –6 mA) 2.5V LVCMOS 1.7[25] V

(VDDIO = Min., IOH = –4 mA) 1.8V LVCMOS VDDIO – 0.45[25] V

VOL Output HIGH Voltage

(VDDIO = Min., IOL = 8 mA)

LVTTL 0.4[25] V

(VDDIO = Min., IOL = 4 mA) HSTL(DC)[26] 0.4[25] V

(VDDIO = Min., IOL = 4 mA) HSTL (AC)[26] 0.5[25] V

(VDDIO = Min., IOL = 6 mA) 2.5V LVCMOS 0.7[25] V

(VDDIO = Min., IOL = 4 mA) 1.8V LVCMOS 0.45[25] V

VIH Input HIGH Voltage LVTTL 2 VDDIO + 0.3 V

HSTL(DC)[26] VREF + 0.1 VDDIO + 0.3 V

2.5V LVCMOS 1.7 V

1.8V LVCMOS 1.26 V

VIL Input LOW Voltage LVTTL –0.3 0.8 V

HSTL(DC)[26] –0.3 VREF – 0.1 V

2.5V LVCMOS 0.7 V

1.8V LVCMOS 0.36 V

Notes:

24. LVTTL and 2.5V LVCMOS are not available for 4-Mbit, 9-Mbit, 18-Mbit devices running at 250 MHz and 36-Mbit devices running at 200 MHz.

25. These parameters are met with VIM disabled.

26. The (DC) specifications are measured under steady state conditions. The (AC) specifications are measured while switching at speed. AC VIH/VIL in HSTL mode

are measured with 1V/ns input edge rates

FullFlex

Document #: 38-06082 Rev. *G Page 19 of 51

READY

VOH

Output HIGH Voltage

(VDDIO = Min., IOH = –24 mA)

LVTTL 2.7[25] V

(VDDIO = Min., IOH = –12 mA) HSTL(DC)[26] VDDIO – 0.4[25] V

(VDDIO = Min., IOH = –12 mA) HSTL (AC)[26] VDDIO – 0.5[25] V

(VDDIO = Min., IOH = –15 mA) 2.5V LVCMOS 2.0[25] V

(VDDIO = Min., IOH = –12 mA) 1.8V LVCMOS VDDIO – 0.45[25] V

READY

VOL

Output HIGH Voltage

(VDDIO = Min., IO = 0.12 mA)

LVTTL 0.4[25] V

(VDDIO = Min., IOL = 0.12 mA) HSTL(DC)[26] 0.4[25] V

(VDDIO = Min., IOL = 0.12 mA) HSTL (AC)[26] 0.5[25] V

(VDDIO = Min., IOL = 0.15 mA) 2.5V LVCMOS 0.7[25] V

(VDDIO = Min., IOL = 0.08 mA) 1.8V LVCMOS 0.45[25] V

IOZ Output Leakage Current –10 10 µA

IIX1 Input Leakage Current Except

TDI, TMS, MRST

–10 10 µA

IIX2 Input Leakage Current TDI,

TMS, MRST

–300 10 µA

IIX3 Input Leakage Current

PORTSTD, DDRON

–10 300 µA

Electrical Characteristics Over the Operating Range (continued)

Parameter Description Configuration

All Speed Bins[24] Unit

Min. Typ. Max.

FullFlex

Document #: 38-06082 Rev. *G Page 20 of 51

Electrical Characteristics Over the Operating Range

Parameter Description Configuration

–250[24] –200[24] –167 –133

UnitTyp. Max. Typ. Max. Typ. Max. Typ. Max.

ICC Operating Current

(VCORE = Max.,IOUT = 0 mA)

Outputs Disabled

512Kx72 Com. N/A N/A 1440 1800 1280 1620 1120 1430 mA

Ind. N/A N/A N/A N/A 1330 1730 1170 1550 mA

1024Kx36 Com. N/A N/A 1180 1500 1050 1350 930 1220 mA

Ind. N/A N/A N/A N/A 1110 1470 980 1330 mA

2048Kx18 Com. N/A N/A 1130 1430 1000 1290 890 1160 mA

Ind. N/A N/A N/A N/A 1060 1410 940 1280 mA

256Kx72 Com. 930 1140 800 980 700 880 N/A N/A mA

Ind. N/A N/A 820 1030 730 930 N/A N/A mA

512Kx36 Com. 750 920 640 800 570 720 N/A N/A mA

Ind. N/A N/A 670 860 590 780 N/A N/A mA

1024Kx18 Com. 710 880 610 770 540 690 N/A N/A mA

Ind. N/A N/A 640 830 570 750 N/A N/A mA

128Kx72 Com. 770 930 640 790 560 700 N/A N/A mA

Ind. N/A N/A 660 830 580 740 N/A N/A mA

256Kx36 Com. 630 740 540 640 470 570 N/A N/A mA

Ind. N/A N/A 550 670 490 600 N/A N/A mA

512Kx18 Com. 660 770 550 660 480 580 N/A N/A mA

Ind. N/A N/A 570 690 500 610 N/A N/A mA

64Kx72 Com. 740 880 620 740 540 650 N/A N/A mA

Ind. N/A N/A 630 770 550 680 N/A N/A mA

128Kx36 Com. 610 690 510 590 450 520 N/A N/A mA

Ind. N/A N/A 520 600 460 530 N/A N/A mA

256Kx18 Com. 630 720 530 610 460 530 N/A N/A mA

Ind. N/A N/A 540 620 470 550 N/A N/A mA

FullFlex

Document #: 38-06082 Rev. *G Page 21 of 51

ISB1 Standby Current

(Both Ports TTL Level)

CEL and CER ≥ VIH, f = fMAX

512Kx72 Com. N/A N/A 1000 1250 920 1160 830 1060 mA

Ind. N/A N/A N/A N/A 970 1260 880 1170 mA

1024Kx36 Com. N/A N/A 910 1140 820 1050 740 960 mA

Ind. N/A N/A N/A N/A 880 1160 790 1080 mA

2048Kx18 Com. N/A N/A 890 1110 810 1030 730 940 mA

Ind. N/A N/A N/A N/A 860 1140 780 1050 mA

256Kx72 Com. 570 700 500 630 460 580 N/A N/A mA

Ind. N/A N/A 530 680 490 630 N/A N/A mA

512Kx36 Com. 520 640 460 570 410 530 N/A N/A mA

Ind. N/A N/A 480 630 440 580 N/A N/A mA

1024Kx18 Com. 500 620 450 560 410 520 N/A N/A mA

Ind. N/A N/A 470 610 430 570 N/A N/A mA

128Kx72 Com. 460 560 400 490 360 450 N/A N/A mA

Ind. N/A N/A 420 540 380 490 N/A N/A mA

256Kx36 Com. 430 500 380 440 340 400 N/A N/A mA

Ind. N/A N/A 390 470 360 430 N/A N/A mA

512Kx18 Com. 450 520 390 460 350 410 N/A N/A mA

Ind. N/A N/A 410 480 370 440 N/A N/A mA

64Kx72 Com. 440 520 380 450 340 400 N/A N/A mA

Ind. N/A N/A 390 480 350 430 N/A N/A mA

128Kx36 Com. 410 450 360 400 320 360 N/A N/A mA

Ind. N/A N/A 360 410 330 370 N/A N/A mA

256Kx18 Com. 420 470 370 410 320 370 N/A N/A mA

Ind. N/A N/A 370 420 330 380 N/A N/A mA

Electrical Characteristics Over the Operating Range (continued)

Parameter Description Configuration

–250[24] –200[24] –167 –133

UnitTyp. Max. Typ. Max. Typ. Max. Typ. Max.

FullFlex

Document #: 38-06082 Rev. *G Page 22 of 51

ISB2 Standby Current

(One Port TTL or CMOS

Level)

CEL | CER ≥ VIH, f = fMAX

512Kx72 Com. N/A N/A 1300 1570 1160 1410 1020 1260 mA

Ind. N/A N/A N/A N/A 1210 1520 1070 1370 mA

1024Kx36 Com. N/A N/A 1090 1330 980 1210 870 1100 mA

Ind. N/A N/A N/A N/A 1030 1330 920 1210 mA

2048Kx18 Com. N/A N/A 1040 1270 930 1160 830 1050 mA

Ind. N/A N/A N/A N/A 980 1270 880 1160 mA

256Kx72 Com. 760 890 650 790 580 710 N/A N/A mA

Ind. N/A N/A 680 840 610 760 N/A N/A mA

512Kx36 Com. 630 760 550 670 490 610 N/A N/A mA

Ind. N/A N/A 570 730 520 670 N/A N/A mA

1024Kx18 Com. 600 730 520 640 470 580 N/A N/A mA

Ind. N/A N/A 550 690 490 640 N/A N/A mA

128Kx72 Com. 620 730 520 630 460 560 N/A N/A mA

Ind. N/A N/A 550 670 480 610 N/A N/A mA

256Kx36 Com. 540 610 460 530 400 470 N/A N/A mA

Ind. N/A N/A 480 560 430 500 N/A N/A mA

512Kx18 Com. 550 620 460 530 410 480 N/A N/A mA

Ind. N/A N/A 480 560 430 510 N/A N/A mA

64Kx72 Com. 590 680 500 580 440 510 N/A N/A mA

Ind. N/A N/A 510 610 450 550 N/A N/A mA

128Kx36 Com. 510 560 440 480 380 420 N/A N/A mA

Ind. N/A N/A 450 500 390 440 N/A N/A mA

256Kx18 Com. 520 570 440 490 390 430 N/A N/A mA

Ind. N/A N/A 450 500 400 450 N/A N/A mA

Electrical Characteristics Over the Operating Range (continued)

Parameter Description Configuration

–250[24] –200[24] –167 –133

UnitTyp. Max. Typ. Max. Typ. Max. Typ. Max.

FullFlex

Document #: 38-06082 Rev. *G Page 23 of 51

Electrical Characteristics Over the Operating Range

Parameter Description Configuration

All Speed Bins[24]

UnitTyp. Max.

ISB3 Standby Current

(Both Ports CMOS Level)

CEL and CER ≥ VCORE – 0.2V, f = 0

512Kx72 Com. 410 590 mA

Ind. 460 700 mA

1024Kx36 Com. 410 590 mA

Ind. 460 700 mA

2048Kx18 Com. 410 590 mA

Ind. 460 700 mA

256Kx72 Com. 210 300 mA

Ind. 230 350 mA

512Kx36 Com. 210 300 mA

Ind. 230 350 mA

1024Kx18 Com. 210 300 mA

Ind. 230 350 mA

128Kx72 Com. 150 200 mA

Ind. 170 220 mA

256Kx36 Com. 150 200 mA

Ind. 170 220 mA

512Kx18 Com. 150 200 mA

Ind. 170 220 mA

64Kx72 Com. 130 150 mA

Ind. 140 170 mA

128Kx36 Com. 130 150 mA

Ind. 140 170 mA

256Kx18 Com. 130 150 mA

Ind. 140 170 mA

Table 13.Capacitance

Signals Packages

CYDD18S72V18

CYDD09S72V18

CYDD04S72V18

CYDD18S36V18

CYDD09S36V18

CYDD04S36V18

CYDD18S18V18

CYDD09S18V18

CYDD04S18V18

CYDD36S72V18

CYDD36S36V18

CYDD36S18V18

OE 12 pF 12 pF 20 pF 20 pF

BE, DQ 10 pF 18 pF 16 pF 30 pF

All other signals 10 pF 10 pF 16 pF 16 pF

FullFlex

Document #: 38-06082 Rev. *G Page 24 of 51

AC Test Load and Waveforms

Figure 5. Output Test Load for LVTTL/CMOS

Figure 6. Output Test Load for HSTL

Figure 7. HSTL Input Waveform

Output

50 Ohm 50 Ohm

VTH = 1.5V for LVTTL

VTH = 50% VDDIO for 2.5V CM O S

VTH = 50% VDDIO for 1.8V CM O S

RQ =250 Ohm

Device under

te s t

VREF

VREF = NC

Test Point

C = 10pF

READY

R=250 O hm VTH

Output

50 O hm 50 O hm

VTH = 50% VDDIO

RQ=250 Ohm

D evice under

te s t

VREF

VREF = 0.75V

Test Point

C = 10pF for S D

R =250 O hm

READY

VTH

FullFlex

Document #: 38-06082 Rev. *G Page 25 of 51

Switching Characteristics Over the Operating Range

Table 14.SDR Mode, Signals effected by DLL

Parameter Description

DLL ON (LOWSPD=1)[29] DLL OFF

(LOWSPD=0)[29]

–250[24] –200[24] –167 –133 Uni

tMin. Max. Min. Max. Min. Max. Min. Max. Min. Max.

tCD2[33] C Rise to DQ Valid

for Pipelined Mode

2.64[28,

32] 3.30[28,

32] 4.00[28,

32] 4.50[28,

32] 6.00[28,

32] ns

tCCQ[33] C Rise to CQ Rise 1.00 2.64[32] 1.00 3.30[32] 1.00 4.00[32] 1.00 4.50[32] 1.00 6.00[32 ns

tCKHZ2[27, 33] C Rise to DQ

Output High Z in

Pipelined Mode

1.00 2.64[28,

32] 1.00 3.30[28,

32] 1.00 4.00[28,

32] 1.00 4.50[28,

32] 1.00 6.00[28,

32] ns

tCKLZ2[27, 33] C Rise to DQ

Output Low Z in

Pipelined Mode

1.00 1.00 1.00 1.00 1.00 ns

Table 15.SDR Mode

Parameter Description

–250[24] –200[24] –167 –133

UnitMin. Max. Min. Max. Min. Max. Min. Max.

fMAX

(PIPELINED)

Maximum Operating

Frequency for Pipelined

Mode

100 250 100 200 100 167 100 133 MHz

fMAX

(FLOW-

THROUGH)

Maximum Operating

Frequency for Flow-through

Mode

100 77 66.7 55.6 MHz

tCYC

(PIPELINED)

C Clock Cycle Time for

Pipelined Mode

4.00[32] 10.00 5.00[32] 10.00 6.00[32] 10.00 7.00[32] 10.00 ns

tCYC

(FLOW-

THROUGH)

C Clock Cycle Time for

Flow-through Mode

10.00[32] 13.00[32] 15.00[32] 18.00[32] ns

tCKD C Clock Duty Time 45 55 45 55 45 55 45 55 %

tSD Data Input

Set-up Time

to C Rise

HSTL

1.8V LVCMOS

1.20[28,32] 1.50[28,32] 1.70[28,32] 1.80[28,32] ns

2.5V LVCMOS

3.3V LVTTL

1.45[28,32] 1.75[28,32] 1.95[28,32] 2.05[28,32] ns

tHD[30, 31] Data Input Hold Time after C

Rise

0.5 0.5 0.5 0.5 ns

tSAC Address &

Control

Input Setup

Time to C

Rise

HSTL

1.8V LVCMOS

1.20[28,30,

32] 1.50[28,30,

32] 1.70[28,30,

32] 1.80[28,30,

32] ns

2.5V LVCMOS

3.3V LVTTL

1.45[28,30,

32] 1.75[28,30,

32] 1.95[28,30,

32] 2.05[28,30,

32] ns

tHAC[30] Address & Control Input

Hold Time after C Rise

0.50 0.50 0.60 0.70 ns

tOE Output Enable to Data Valid 3.40[28,32] 4.40[28,

32] 5.00[28

,32] 5.50[28,

32] ns

tOLZ[27] OE to Low Z 1.00 1.00 1.00 1.00 ns

Notes:

27. Parameters specified with the load capacitance in Figure 5 and Figure 6.

28. For the x18 devices, add 200 ps to this parameter in the table above.

29. Test conditions assume a signal transition time of 2 V/ns.

30. add 100ps to this timing for 36M devices.

31. add 200ps to this timing for 36M x72 devices

32. Add 15% to this parameter if a VCORE of 1.5V is used.

33. This parameter assumes input clock cycle to cycle jitter of +/- 0ps.

FullFlex

Document #: 38-06082 Rev. *G Page 26 of 51

tOHZ[27] OE to High Z 1.00 3.40[28,32] 1.00 4.40[28,

32] 1.00 5.00[28

,32] 1.00 5.50[28,

32] ns

tCD1 C Rise to DQ Valid for

Flow-through Mode

(LowSPD = 1)

7.20[28,32] 9.00[28,

32] 11.00

[28,32] 13.00

[28,32] ns

tCA1 C Rise to Address Readback

Valid for Flow-through Mode

7.20[32] 9.00[32] 11.00

[32] 13.00

[32] ns

tCA2 C Rise to Address Readback

Valid for Pipelined Mode

4.00[32] 5.00[32] 6.00[32

]7.50[32] ns

tDC[33] DQ Output Hold after C Rise 1.00 1.00 1.00 1.00 ns

tJIT Clock Input Cycle to Cycle

Jitter

+/- 200 +/- 200 +/- 200 +/- 200 ps

tCQHQV[33] Echo Clock

(CQ) High to

Output Valid

HSTL

1.8V LVCMOS

0.60[28] 0.70[28] 0.80[28

]0.90[28] ns

2.5V LVCMOS

3.3V LVTTL

0.70[28] 0.80[28] 0.90[28

]1.00[28] ns

tCQHQX[33] Echo Clock

(CQ) High to

Output Hold

HSTL

1.8V LVCMOS

–0.60 –0.70 –0.80 –0.90 ns

2.5V LVCMOS

3.3V LVTTL

–0.75 –0.85 –0.95 –1.05 ns

tCKHZ1[27] C Rise to DQ Output High Z

in Flow-through Mode

1.00 7.20[28,32] 1.00 9.00[28,

32] 1.00 11.00

[28,32] 1.00 13.00

[28,32] ns

tCKLZ1[27] C Rise to DQ Output Low Z

in Flow-through Mode

1.00 1.00 1.00 1.00 ns

tAC Address Output Hold after C

Rise

1.00 1.00 1.00 1.00 ns

tCKHZA1[27] C Rise to Address Output

High Z for Flow-through

Mode

1.00 7.20[32] 1.00 9.00[32] 1.00 11.00

[32] 1.00 13.00

[32] ns

tCKHZA2[27] C Rise to Address Output

High Z for Pipelined Mode

1.00 4.00[32] 1.00 5.00[32] 1.00 6.00[32

]1.00 7.50[32] ns

tCKLZA[27] C Rise to Address Output

Low Z

1.00 1.00 1.00 1.00 ns

tSCINT C Rise to CNTINT Low 1.00 2.64[32] 1.00 3.30[32] 1.00 4.00[32

]1.00 4.50[32] ns

tRCINT C Rise to CNTINT High 1.00 2.64[32] 1.00 3.30[32] 1.00 4.00[32

]1.00 4.50[32] ns

tSINT C Rise to INT Low 0.50 6.00[32] 0.50 7.00[32] 0.50 8.00[32

]0.50 8.50[32] ns

tRINT C Rise to INT High 0.50 6.00[32] 0.50 7.00[32] 0.50 8.00[32

]0.50 8.50[32] ns

tBSY C Rise to BUSY Valid 1.00 2.64[32] 1.00 3.30[32] 1.00 4.00[32

]1.00 4.50[32] ns

Table 15.SDR Mode

Parameter Description

–250[24] –200[24] –167 –133

UnitMin. Max. Min. Max. Min. Max. Min. Max.

Table 16.Master Reset Timing

Parameter Description

–250[24] –200[24] –167 –133

UnitMin. Max. Min. Max. Min. Max. Min. Max.

tPUP Power-Up Time 1 1 1 1 ms

tRS Master Reset Pulse Width 5 5 5 5 cycles

FullFlex

Document #: 38-06082 Rev. *G Page 27 of 51

tRSR Master Reset Recovery Time 5 5 5 5 cycles

tRSF Master Reset to Outputs Inactive/Hi Z 12 15 18 22.50 ns

tRDY[34] Master Reset Release to Port Ready 1024 1024 1024 1024 cycles

tCORDY[35] C Rise to Port Ready 8[32] 9.5[32] 11[32] 13[32] ns

Table 17.JTAG Timing

Parameter Description

–250[24] –200[24] –167 –133

UnitMin. Max. Min. Max. Min. Max. Min. Max.

fJTAG JTAG TAP Controller Frequency 20 20 20 20 MHz

tTCYC TCK Cycle Time 50 50 50 50 ns

tTH TCK High Time 20 20 20 20 ns

tTL TCK Low Time 20 20 20 20 ns

tTMSS TMS Set-up to TCK Rise 10 10 10 10 ns

tTMSH TMS Hold to TCK Rise 10 10 10 10 ns

tTDIS TDI Set-up to TCK Rise 10 10 10 10 ns

tTDIH TDI Hold to TCK Rise 10 10 10 10 ns

tTDOV TCK Low to TDO Valid 10 10 10 10 ns

tTDOX TCK Low to TDO Invalid 0 0 0 0 ns

tJXZ TCK Low to TDO High Z 15 15 15 15 ns

tJZX TCK Low to TDO Active 15 15 15 15 ns

Notes:

34. READY is a wired OR capable output with a weak pull-down. For a decreased falling delay, connect a 250-Ω resistor to VSS.

35. Add this propagation delay after tRDY for all Master Reset Operations.

Table 16.Master Reset Timing

Parameter Description

–250[24] –200[24] –167 –133

UnitMin. Max. Min. Max. Min. Max. Min. Max.

Switching Waveforms

JTAG Timing

Test Clock

Test Mode Select

TCK

TMS

Test Data-In

TDI

Test D ata -Ou t

TDO

tTCYC

tTMSH

tTL

tTH

tTMSS

tTDIS tTDIH

tTDOX tTDOV

FullFlex

Document #: 38-06082 Rev. *G Page 28 of 51

Master Reset[34]

READ Cycle for Pipelined Mode

Switching Waveforms (continued)

tPUP tRS

tRSF

tRSR

VCORE

MRST

READY

All Address

& Data

All Other

Inputs

tRDY tCORDY

tCYC

R/W

2 Pipelined stages

AnAn+1 An+2 An+3 An+4 An+5 An+6

DQx-1 DQxDQnDQn+1 DQn+2 DQn+3 DQn+4

tDC tCD2

tSAC tHAC

FullFlex

Document #: 38-06082 Rev. *G Page 29 of 51

WRITE Cycle for Pipelined and Flow-through Modes

READ with Address Counter Advance for Pipelined Mode

Switching Waveforms (continued)

tCYC

R/W

AAnAn+1 An+2 An+3 An+4 An+5 An+6

DQnDQn+1 DQn+2 DQn+3 DQn+4 DQn+5 DQn+6

2 Pipelined stages

tSD tHD

tCYC

DQx-1 DQxDQnDQn+1 DQn+2

Internal

ADS

ddress

CNTEN

An+1 An+2 An+3

DQn+3

FullFlex

Document #: 38-06082 Rev. *G Page 30 of 51

READ with Address Counter Advance for Flow-through Mode

Switching Waveforms (continued)

tCYC

tSAC tHAC

tHAC

tDC

tCD1

tSAC

READ EXTERNAL ADDRESS READ WITH COUNTERCOUNTER HOLDREAD WITH COUNTER

DQx DQn + 1 DQn + 2 DQn + 3 DQn + 4DQn

CNTEN

ADS

FullFlex

Document #: 38-06082 Rev. *G Page 31 of 51

Port-to-Port WRITE–READ for Pipelined Mode

Chip Enable READ for Pipelined Mode

Switching Waveforms (continued)

DQn

Left Port

R/WL

Right Port

R/WR

DQn

tCD2 tDC

tSAC tHAC

tCYC

tCCS

DQL

DQR

R/W

AAnAn+1 An+2 An+3 An+4 An+5 An+6

tSAC tHAC

tCYC

CE0

CE1

DQ DQnDQn+3

tCD2 tDC tCKLZ2

FullFlex

Document #: 38-06082 Rev. *G Page 32 of 51

OE Controlled WRITE for Pipelined Mode

OE Controlled WRITE for Flow-through Mode

Switching Waveforms (continued)

R/W

AAx+1 Ax+2 Ax+3 AnAn+1 An+2 An+3

tCYC

DQx-1 DQx

DQx+1

DQnDQn+1 DQn+2 DQn+3

tOHZ

R/W

AAx+1 Ax+2 Ax+3 AnAn+1 An+2 An+3

tCYC

DQxDQx+1

DQx+2

DQnDQn+1 DQn+2 DQn+3

tOHZ

FullFlex

Document #: 38-06082 Rev. *G Page 33 of 51

Byte-Enable READ for Pipelined Mode

Switching Waveforms (continued)

R/W

AAnAn+1 An+2 An+3

tCYC

BE7

BE6

BE5

BE4

BE3

BE2

BE1

BE0

DQ63:71

DQ54:62

DQ45:53

DQ36:44

DQ27:35

DQ18:26

DQ9:17

DQ0:8

DQn+1(63:71)

DQn+1(54:62)

DQn+1(27:35)

DQn+2(45:53)

DQn+2(36:44)

DQn+2(18:26)

DQn+3(9:17)

DQn+3(0:8)

tCKLZ2 tCKHZ2

FullFlex

Document #: 38-06082 Rev. *G Page 34 of 51

Port-to-Port WRITE-to-READ for Flow-through Mode

Busy Address Readback for Pipelined and Flow-through Modes, DDRON = CNT/MSK = RET = LOW[36]

Note:

36. Amatch is the matching address which will be reported on the address bus of the losing port. The counter operation selected for reporting the address is “Busy

Address Readback.”

Switching Waveforms (continued)

tHD

tSD

tCD1

tDC

tSAC tHAC

tCD1

tCCS

tHAC

tSAC

MATCH

VALID

NO MATCH

MATCH

VALID VALID

R/WL

DQL

R/W R

DQR

Internal Amatch+2 Amatch+3 Amatch+4

tCYC

BUSY

CNTEN

ADS

External

Amatch

tCA2 tAC

Address

Pipelined

~Amatch

tCA1 tAC

Flow-through

Address

External

Address

FullFlex

Document #: 38-06082 Rev. *G Page 35 of 51

Read Cycle for Flow-through Mode

READ-to-WRITE for Pipelined Mode (OE = VIL)[37,38,39]

Notes:

37. When OE = VIL, the last read operation is allowed to complete before the DQ bus is tri-stated and the user is allowed to drive write data.

38. Two dummy writes should be issued to accomplish bus turnaround. The 3rd instruction is the first valid write.

39. Chip enable or all byte enables should be held inactive during the two dummy writes to avoid data corruption.

Switching Waveforms (continued)

tCYC

tSAC tHAC

tCKHZ1

tDC

tOE

tOLZ

tOHZ

tDCtCD1

tCKLZ1

tHACtSAC

CE1

CE0

An + 1 An + 3An + 2

DQn DQn + 1 DQn + 2

R/W

BEn

AAxAnAn+1 An+2

tCYC

DQx-2 DQx-1 DQxDQnDQn+1 DQn+2

tCH

tCL

tSAC tHAC tSAC tHAC

tDC

tCD2 tCKHZ2 tSD tHD

R/W

tCKLZ2

FullFlex

Document #: 38-06082 Rev. *G Page 36 of 51

READ-to-WRITE for Pipelined Mode (OE Controlled)[40,41]

Notes:

40. OE should be deasserted and tOHZ allowed to elapse before the first write operation is issued.

41. Any write scheduled to complete after OE is deasserted will be preempted.

Switching Waveforms (continued)

R/W

AAxAx+1 Ax+2 AnAn+1 An+2 An+3

tCYC

DQx-2 DQx-1

DQxDQnDQn+1 DQn+2 DQn+3

tSAC tHAC

tOHZ tSD tHD

FullFlex

Document #: 38-06082 Rev. *G Page 37 of 51

Read-to-Write-to-Read for Flow-through Mode (OE = LOW)

Switching Waveforms (continued)

tHDtSD

tSAC

tCKHZ1

tDC

tCD1

tSAC

tCYC

tHAC

tDC

tCD1tCD1

tCKLZ1

READ READWRITENOP

An An + 1 An + 2 An + 2 An + 3 An + 4

DQn + 2

DQn DQn + 1 DQn + 3

R/W

BEn

CE1

DQOUT

DQIN

tHAC

CE0

FullFlex

Document #: 38-06082 Rev. *G Page 38 of 51

Read-to-Write-to-Read for Flow-through Mode (OE Controlled)

Switching Waveforms (continued)

tCD1

tCKLZ1

tHDtSD

tOHZ

tDCtCD1

tHAC

tSAC

tCYC

tDC

tCD1

tOE

READ READWRITE

An An + 1 An + 2 An + 3 An + 4 An + 5

DQn + 2 DQn + 3

DQn DQn + 4

R/W

BEn

CE1

DQOUT

DQIN

tHAC

tSAC

CE0

FullFlex

Document #: 38-06082 Rev. *G Page 39 of 51

BUSY Timing, WRITE-WRITE Collision for Pipelined and Flow-through Modes, Clock Timing Violates tCCS. (Flag Both

Ports)

Switching Waveforms (continued)

Port A

R/W

tBSY tBSY

BUSY

Port B

< tCCS

R/W

tBSY tBSY

BUSY

Losing Port

R/W

tBSY tBSY

BUSY

Winning Port

R/W

tccs

Match

BUSY Timing, WRITE-WRITE Collision for Pipelined and Flow-through Modes, Clock Timing Meets tCCS. (Flag Losing

Port)

BUSY

FullFlex

Document #: 38-06082 Rev. *G Page 40 of 51

Read with Echo Clock for Pipelined Mode (CQEN = HIGH)

Switching Waveforms (continued)

R/W

AAnAn+1 An+2 An+3 An+4 An+5 An+6

DQx-1 DQxDQnDQn+1 DQn+2 DQn+3 DQn+4

tSAC tHAC

CQ1

CQ0

tCCQ

tCQHQV tCQHQX

FullFlex

Document #: 38-06082 Rev. *G Page 41 of 51

Mailbox Interrupt Output

Switching Waveforms (continued)

tCYC

R/WL

DQL

INTR

R/WR

DQR

AMAX

DQMAX

AMAX

tSINT tRINT

FullFlex

Document #: 38-06082 Rev. *G Page 42 of 51

Ordering Information

512K

72 (36 Mbit) 1.8V/1.5V Synchronous CYD36S72V18 Dual-Port SRAM

Speed

(MHz) Ordering Code

Package

Name Package Type

Operating

Range

200 CYD36S72V18-200BGXC BY0DA

484-ball Grid Array 27 mm x 27 mm with 1.0 mm pitch (Lead-Free)

Commercial

CYD36S72V18-200BGC BG0DA

484-ball Grid Array 27 mm x 27 mm with 1.0 mm pitch (Leaded)

Commercial

167 CYD36S72V18-167BGXC BY0DA

484-ball Grid Array 27 mm x 27 mm with 1.0 mm pitch (Lead-Free)

Commercial

CYD36S72V18-167BGC BG0DA

484-ball Grid Array 27 mm x 27 mm with 1.0 mm pitch (Leaded)

Commercial

CYD36S72V18-167BGXI BY0DA

484-ball Grid Array 27 mm x 27 mm with 1.0 mm pitch (Lead-Free)

Industrial

CYD36S72V18-167BGI BG0DA

484-ball Grid Array 27 mm x 27 mm with 1.0 mm pitch (Leaded)

Industrial

133 CYD36S72V18-133BGXC BY0DA

484-ball Grid Array 27 mm x 27 mm with 1.0 mm pitch (Lead-Free)

Commercial

CYD36S72V18-133BGC BG0DA

484-ball Grid Array 27 mm x 27 mm with 1.0 mm pitch (Leaded)

Commercial

CYD36S72V18-133BGXI BY0DA

484-ball Grid Array 27 mm x 27 mm with 1.0 mm pitch (Lead-Free)

Industrial

CYD36S72V18-133BGI BG0DA

484-ball Grid Array 27 mm x 27 mm with 1.0 mm pitch (Leaded)

Industrial

256K

72 (18 Mbit) 1.8V/1.5V Synchronous CYD18S72V18 Dual-Port SRAM

Speed

(MHz) Ordering Code

Package

Name Package Type

Operating

Range

250 CYD18S72V18-250BGXC BY484

484-ball Grid Array 23 mm x 23 mm with 1.0 mm pitch (Lead-Free)

Commercial

CYD18S72V18-250BGC BG484

484-ball Grid Array 23 mm x 23 mm with 1.0 mm pitch (Leaded)

Commercial

200 CYD18S72V18-200BGXC BY484

484-ball Grid Array 23 mm x 23 mm with 1.0 mm pitch (Lead-Free)

Commercial

CYD18S72V18-200BGC BG484

484-ball Grid Array 23 mm x 23 mm with 1.0 mm pitch (Leaded)

Commercial

CYD18S72V18-200BGXI BY484

484-ball Grid Array 23 mm x 23 mm with 1.0 mm pitch (Lead-Free)

Industrial

CYD18S72V18-200BGI BG484

484-ball Grid Array 23 mm x 23 mm with 1.0 mm pitch (Leaded)

Industrial

167 CYD18S72V18-167BGXC BY484

484-ball Grid Array 23 mm x 23 mm with 1.0 mm pitch (Lead-Free)

Commercial

CYD18S72V18-167BGC BG484

484-ball Grid Array 23 mm x 23 mm with 1.0 mm pitch (Leaded)

Commercial

CYD18S72V18-167BGXI BY484

484-ball Grid Array 23 mm x 23 mm with 1.0 mm pitch (Lead-Free)

Industrial

CYD18S72V18-167BGI BG484

484-ball Grid Array 23 mm x 23 mm with 1.0 mm pitch (Leaded)

Industrial

128K

72 (9 Mbit) 1.8V/1.5V Synchronous CYD09S72V18 Dual-Port SRAM

Speed

(MHz) Ordering Code

Package

Name Package Type

Operating

Range

250 CYD09S72V18-250BGXC BY484

484-ball Grid Array 23 mm x 23 mm with 1.0 mm pitch (Lead-Free)

Commercial

CYD09S72V18-250BGC BG484

484-ball Grid Array 23 mm x 23 mm with 1.0 mm pitch (Leaded)

Commercial

200 CYD09S72V18-200BGXC BY484

484-ball Grid Array 23 mm x 23 mm with 1.0 mm pitch (Lead-Free)

Commercial

CYD09S72V18-200BGC BG484

484-ball Grid Array 23 mm x 23 mm with 1.0 mm pitch (Leaded)

Commercial

CYD09S72V18-200BGXI BY484

484-ball Grid Array 23 mm x 23 mm with 1.0 mm pitch (Lead-Free)

Industrial

CYD09S72V18-200BGI BG484

484-ball Grid Array 23 mm x 23 mm with 1.0 mm pitch (Leaded)

Industrial

167 CYD09S72V18-167BGXC BY484

484-ball Grid Array 23 mm x 23 mm with 1.0 mm pitch (Lead-Free)

Commercial

CYD09S72V18-167BGC BG484

484-ball Grid Array 23 mm x 23 mm with 1.0 mm pitch (Leaded)

Commercial

CYD09S72V18-167BGXI BY484

484-ball Grid Array 23 mm x 23 mm with 1.0 mm pitch (Lead-Free)

Industrial

CYD09S72V18-167BGI BG484

484-ball Grid Array 23 mm x 23 mm with 1.0 mm pitch (Leaded)

Industrial

FullFlex

Document #: 38-06082 Rev. *G Page 43 of 51

64K

72 (4 Mbit) 1.8V/1.5V Synchronous CYD04S72V18 Dual-Port SRAM

Speed

(MHz) Ordering Code

Package

Name Package Type

Operating

Range

250 CYD04S72V18-250BGXC BY484

484-ball Grid Array 23 mm x 23 mm with 1.0 mm pitch (Lead-Free)

Commercial

CYD04S72V18-250BGC BG484

484-ball Grid Array 23 mm x 23 mm with 1.0 mm pitch (Leaded)

Commercial

200 CYD04S72V18-200BGXC BY484

484-ball Grid Array 23 mm x 23 mm with 1.0 mm pitch (Lead-Free)

Commercial

CYD04S72V18-200BGC BG484

484-ball Grid Array 23 mm x 23 mm with 1.0 mm pitch (Leaded)

Commercial

CYD04S72V18-200BGXI BY484

484-ball Grid Array 23 mm x 23 mm with 1.0 mm pitch (Lead-Free)

Industrial

CYD04S72V18-200BGI BG484

484-ball Grid Array 23 mm x 23 mm with 1.0 mm pitch (Leaded)

Industrial

167 CYD04S72V18-167BGXC BY484

484-ball Grid Array 23 mm x 23 mm with 1.0 mm pitch (Lead-Free)

Commercial

CYD04S72V18-167BGC BG484

484-ball Grid Array 23 mm x 23 mm with 1.0 mm pitch (Leaded)

Commercial

CYD04S72V18-167BGXI BY484

484-ball Grid Array 23 mm x 23 mm with 1.0 mm pitch (Lead-Free)

Industrial

CYD04S72V18-167BGI BG484

484-ball Grid Array 23 mm x 23 mm with 1.0 mm pitch (Leaded)

Industrial

1024K

36 (36 Mbit) 1.8V/1.5V Synchronous CYD36S36V18 Dual-Port SRAM

Speed

(MHz) Ordering Code

Package

Name Package Type

Operating

Range

200 CYD36S36V18-200BGXC BY0DA

484-ball Grid Array 27 mm x 27 mm with 1.0 mm pitch (Lead-Free)

Commercial

CYD36S36V18-200BGC BG0DA

484-ball Grid Array 27 mm x 27 mm with 1.0 mm pitch (Leaded)

Commercial

167 CYD36S36V18-167BGXC BY0DA

484-ball Grid Array 27 mm x 27 mm with 1.0 mm pitch (Lead-Free)

Commercial

CYD36S36V18-167BGC BG0DA

484-ball Grid Array 27 mm x 27 mm with 1.0 mm pitch (Leaded)

Commercial

CYD36S36V18-167BGXI BY0DA

484-ball Grid Array 27 mm x 27 mm with 1.0 mm pitch (Lead-Free)

Industrial

CYD36S36V18-167BGI BG0DA

484-ball Grid Array 27 mm x 27 mm with 1.0 mm pitch (Leaded)

Industrial

133 CYD36S36V18-133BGXC BY0DA

484-ball Grid Array 27 mm x 27 mm with 1.0 mm pitch (Lead-Free)

Commercial

CYD36S36V18-133BGC BG0DA

484-ball Grid Array 27 mm x 27 mm with 1.0 mm pitch (Leaded)

Commercial

CYD36S36V18-133BGXI BY0DA

484-ball Grid Array 27 mm x 27 mm with 1.0 mm pitch (Lead-Free)

Industrial

CYD36S36V18-133BGI BG0DA

484-ball Grid Array 27 mm x 27 mm with 1.0 mm pitch (Leaded)

Industrial

512K

36 (18 Mbit) 1.8V/1.5V Synchronous CYD18S36V18 Dual-Port SRAM

Speed

(MHz) Ordering Code

Package

Name Package Type

Operating

Range

250 CYD18S36V18-250BBXC BW0BC

256-ball Grid Array 19 mm x 19 mm with 1.0 mm pitch (Lead-Free)

Commercial

CYD18S36V18-250BBC BB0BC

256-ball Grid Array 19 mm x 19 mm with 1.0 mm pitch (Leaded)

Commercial

200 CYD18S36V18-200BBXC BW0BC

256-ball Grid Array 19 mm x 19 mm with 1.0 mm pitch (Lead-Free)

Commercial

CYD18S36V18-200BBC BB0BC

256-ball Grid Array 19 mm x 19 mm with 1.0 mm pitch (Leaded)

Commercial

CYD18S36V18-200BBXI BW0BC

256-ball Grid Array 19 mm x 19 mm with 1.0 mm pitch (Lead-Free)

Industrial

CYD18S36V18-200BBI BB0BC

256-ball Grid Array 19 mm x 19 mm with 1.0 mm pitch (Leaded)

Industrial

167 CYD18S36V18-167BBXC BW0BC

256-ball Grid Array 19 mm x 19 mm with 1.0 mm pitch (Lead-Free)

Commercial

CYD18S36V18-167BBC BB0BC

256-ball Grid Array 19 mm x 19 mm with 1.0 mm pitch (Leaded)

Commercial

CYD18S36V18-167BBXI BW0BC

256-ball Grid Array 19 mm x 19 mm with 1.0 mm pitch (Lead-Free)

Industrial

CYD18S36V18-167BBI BB0BC

256-ball Grid Array 19 mm x 19 mm with 1.0 mm pitch (Leaded)

Industrial

Ordering Information (continued)

FullFlex

Document #: 38-06082 Rev. *G Page 44 of 51

256K

36 (9 Mbit) 1.8V/1.5V Synchronous CYD09S36V18 Dual-Port SRAM

Speed

(MHz) Ordering Code

Package

Name Package Type

Operating

Range

250 CYD09S36V18-250BBXC BW0BD

256-ball Grid Array 17 mm x 17 mm with 1.0 mm pitch (Lead-Free)

Commercial

CYD09S36V18-250BBC BB256

256-ball Grid Array 17 mm x 17 mm with 1.0 mm pitch (Leaded)

Commercial

200 CYD09S36V18-200BBXC BW0BD

256-ball Grid Array 17 mm x 17 mm with 1.0 mm pitch (Lead-Free)

Commercial

CYD09S36V18-200BBC BB256

256-ball Grid Array 17 mm x 17 mm with 1.0 mm pitch (Leaded)

Commercial

CYD09S36V18-200BBXI BW0BD

256-ball Grid Array 17 mm x 17 mm with 1.0 mm pitch (Lead-Free)

Industrial

CYD09S36V18-200BBI BB256

256-ball Grid Array 17 mm x 17 mm with 1.0 mm pitch (Leaded)

Industrial

167 CYD09S36V18-167BBXC BW0BD

256-ball Grid Array 17 mm x 17 mm with 1.0 mm pitch (Lead-Free)

Commercial

CYD09S36V18-167BBC BB256

256-ball Grid Array 17 mm x 17 mm with 1.0 mm pitch (Leaded)

Commercial

CYD09S36V18-167BBXI BW0BD

256-ball Grid Array 17 mm x 17 mm with 1.0 mm pitch (Lead-Free)

Industrial

CYD09S36V18-167BBI BB256

256-ball Grid Array 17 mm x 17 mm with 1.0 mm pitch (Leaded)

Industrial

128K

36 (4 Mbit) 1.8V/1.5V Synchronous CYD04S36V18 Dual-Port SRAM

Speed

(MHz) Ordering Code

Package

Name Package Type

Operating

Range

250 CYD04S36V18-250BBXC BW0BD

256-ball Grid Array 17 mm x 17 mm with 1.0 mm pitch (Lead-Free)

Commercial

CYD04S36V18-250BBC BB256

256-ball Grid Array 17 mm x 17 mm with 1.0 mm pitch (Leaded)

Commercial

200 CYD04S36V18-200BBXC BW0BD

256-ball Grid Array 17 mm x 17 mm with 1.0 mm pitch (Lead-Free)

Commercial

CYD04S36V18-200BBC BB256

256-ball Grid Array 17 mm x 17 mm with 1.0 mm pitch (Leaded)

Commercial

CYD04S36V18-200BBXI BW0BD

256-ball Grid Array 17 mm x 17 mm with 1.0 mm pitch (Lead-Free)

Industrial

CYD04S36V18-200BBI BB256

256-ball Grid Array 17 mm x 17 mm with 1.0 mm pitch (Leaded)

Industrial

167 CYD04S36V18-167BBXC BW0BD

256-ball Grid Array 17 mm x 17 mm with 1.0 mm pitch (Lead-Free)

Commercial

CYD04S36V18-167BBC BB256

256-ball Grid Array 17 mm x 17 mm with 1.0 mm pitch (Leaded)

Commercial

CYD04S36V18-167BBXI BW0BD

256-ball Grid Array 17 mm x 17 mm with 1.0 mm pitch (Lead-Free)

Industrial

CYD04S36V18-167BBI BB256

256-ball Grid Array 17 mm x 17 mm with 1.0 mm pitch (Leaded)

Industrial

2048K

18 (36 Mbit) 1.8V/1.5V Synchronous CYD36S18V18 Dual-Port SRAM

Speed

(MHz) Ordering Code

Package

Name Package Type

Operating

Range

200 CYD36S18V18-200BGXC BY0DA

484-ball Grid Array 27 mm x 27 mm with 1.0 mm pitch (Lead-Free)

Commercial

CYD36S18V18-200BGC BG0DA

484-ball Grid Array 27 mm x 27 mm with 1.0 mm pitch (Leaded)

Commercial

167 CYD36S18V18-167BGXC BY0DA

484-ball Grid Array 27 mm x 27 mm with 1.0 mm pitch (Lead-Free)

Commercial

CYD36S18V18-167BGC BG0DA

484-ball Grid Array 27 mm x 27 mm with 1.0 mm pitch (Leaded)

Commercial

CYD36S18V18-167BGXI BY0DA

484-ball Grid Array 27 mm x 27 mm with 1.0 mm pitch (Lead-Free)

Industrial

CYD36S18V18-167BGI BG0DA

484-ball Grid Array 27 mm x 27 mm with 1.0 mm pitch (Leaded)

Industrial

133 CYD36S18V18-133BGXC BY0DA

484-ball Grid Array 27 mm x 27 mm with 1.0 mm pitch (Lead-Free)

Commercial

CYD36S18V18-133BGC BG0DA

484-ball Grid Array 27 mm x 27 mm with 1.0 mm pitch (Leaded)

Commercial

CYD36S18V18-133BGXI BY0DA

484-ball Grid Array 27 mm x 27 mm with 1.0 mm pitch (Lead-Free)

Industrial

CYD36S18V18-133BGI BG0DA

484-ball Grid Array 27 mm x 27 mm with 1.0 mm pitch (Leaded)

Industrial

Ordering Information (continued)

FullFlex

Document #: 38-06082 Rev. *G Page 45 of 51

1024K

18 (18 Mbit) 1.8V/1.5V Synchronous CYD18S18V18 Dual-Port SRAM

Speed

MHz) Ordering Code

Package

Name Package Type

Operating

Range

250 CYD18S18V18-250BBXC BW0BC

256-ball Grid Array 19 mm x 19 mm with 1.0 mm pitch (Lead-Free)

Commercial

CYD18S18V18-250BBC BB0BC

256-ball Grid Array 19 mm x 19 mm with 1.0 mm pitch (Leaded)

Commercial

200 CYD18S18V18-200BBXC BW0BC

256-ball Grid Array 19 mm x 19 mm with 1.0 mm pitch (Lead-Free)

Commercial

CYD18S18V18-200BBC BB0BC

256-ball Grid Array 19 mm x 19 mm with 1.0 mm pitch (Leaded)

Commercial

CYD18S18V18-200BBXI BW0BC

256-ball Grid Array 19 mm x 19 mm with 1.0 mm pitch (Lead-Free)

Industrial

CYD18S18V18-200BBI BB0BC

256-ball Grid Array 19 mm x 19 mm with 1.0 mm pitch (Leaded)

Industrial

167 CYD18S18V18-167BBXC BW0BC

256-ball Grid Array 19 mm x 19 mm with 1.0 mm pitch (Lead-Free)

Commercial

CYD18S18V18-167BBC BB0BC

256-ball Grid Array 19 mm x 19 mm with 1.0 mm pitch (Leaded)

Commercial

CYD18S18V18-167BBXI BW0BC

256-ball Grid Array 19 mm x 19 mm with 1.0 mm pitch (Lead-Free)

Industrial

CYD18S18V18-167BBI BB0BC

256-ball Grid Array 19 mm x 19 mm with 1.0 mm pitch (Leaded)

Industrial

512K

18 (9 Mbit) 1.8V/1.5V Synchronous CYD09S18V18 Dual-Port SRAM

Speed

(MHz) Ordering Code

Package

Name Package Type

Operating

Range

250 CYD09S18V18-250BBXC BW0BD

256-ball Grid Array 17 mm x 17 mm with 1.0 mm pitch (Lead-Free)

Commercial

CYD09S18V18-250BBC BB256

256-ball Grid Array 17 mm x 17 mm with 1.0 mm pitch (Leaded)

Commercial

200 CYD09S18V18-200BBXC BW0BD

256-ball Grid Array 17 mm x 17 mm with 1.0 mm pitch (Lead-Free)

Commercial

CYD09S18V18-200BBC BB256

256-ball Grid Array 17 mm x 17 mm with 1.0 mm pitch (Leaded)

Commercial

CYD09S18V18-200BBXI BW0BD

256-ball Grid Array 17 mm x 17 mm with 1.0 mm pitch (Lead-Free)

Industrial

CYD09S18V18-200BBI BB256

256-ball Grid Array 17 mm x 17 mm with 1.0 mm pitch (Leaded)

Industrial

167 CYD09S18V18-167BBXC BW0BD

256-ball Grid Array 17 mm x 17 mm with 1.0 mm pitch (Lead-Free)

Commercial

CYD09S18V18-167BBC BB256

256-ball Grid Array 17 mm x 17 mm with 1.0 mm pitch (Leaded)

Commercial

CYD09S18V18-167BBXI BW0BD

256-ball Grid Array 17 mm x 17 mm with 1.0 mm pitch (Lead-Free)

Industrial

CYD09S18V18-167BBI BB256

256-ball Grid Array 17 mm x 17 mm with 1.0 mm pitch (Leaded)

Industrial

256K

18 (4 Mbit) 1.8V/1.5V Synchronous CYD04S18V18 Dual-Port SRAM

Speed

(MHz) Ordering Code

Package

Name Package Type

Operating

Range

250 CYD04S18V18-250BBXC BW0BD

256-ball Grid Array 17 mm x 17 mm with 1.0 mm pitch (Lead-Free)

Commercial

CYD04S18V18-250BBC BB256

256-ball Grid Array 17 mm x 17 mm with 1.0 mm pitch (Leaded)

Commercial

200 CYD04S18V18-200BBXC BW0BD

256-ball Grid Array 17 mm x 17 mm with 1.0 mm pitch (Lead-Free)

Commercial

CYD04S18V18-200BBC BB256

256-ball Grid Array 17 mm x 17 mm with 1.0 mm pitch (Leaded)

Commercial

CYD04S18V18-200BBXI BW0BD

256-ball Grid Array 17 mm x 17 mm with 1.0 mm pitch (Lead-Free)

Industrial

CYD04S18V18-200BBI BB256

256-ball Grid Array 17 mm x 17 mm with 1.0 mm pitch (Leaded)

Industrial

167 CYD04S18V18-167BBXC BW0BD

256-ball Grid Array 17 mm x 17 mm with 1.0 mm pitch (Lead-Free)

Commercial

CYD04S18V18-167BBC BB256

256-ball Grid Array 17 mm x 17 mm with 1.0 mm pitch (Leaded)

Commercial

CYD04S18V18-167BBXI BW0BD

256-ball Grid Array 17 mm x 17 mm with 1.0 mm pitch (Lead-Free)

Industrial

CYD04S18V18-167BBI BB256

256-ball Grid Array 17 mm x 17 mm with 1.0 mm pitch (Leaded)

Industrial

Ordering Information (continued)

FullFlex

Document #: 38-06082 Rev. *G Page 46 of 51

Package Diagrams

BOTTOM VIEW

TOP VIEW

10987654321

PIN 1 CORNER

0.20(4X)

Ø0.25MCAB

Ø0.05 M C

Ø0.45±0.05(256X)-CPLD DEVICES (37K & 39K)

0.25 C

0.70±0.05

SEATING PLANE

0.15 C

16 15 14 13 12 11

161513 141210 11928765431

Ø0.50 (256X)-ALL OTHER DEVICES

+0.10

-0.05

A1 0.36 0.56

A 1.40 MAX. 1.70 MAX.

REFERENCE JEDEC MO-192

15.00

1.00

0.35

17.00±0.10

7.50

15.00

17.00±0.10

1.00

-0.05

+0.10

256-ball Leaded FBGA (17 x 17 mm) BB256

51-85108-*F

256-ball Lead-Free FBGA (17 x 17 mm) BW256

FullFlex

Document #: 38-06082 Rev. *G Page 47 of 51

Package Diagrams (continued)

Package Weight - 1.1 grams

0.70 (REF)

0.56 (REF)

SEATING PLANE

-C-

PIN A1 CORNER

56810

TOP VIEW

0.15 C

1.70 MAX.

0.35 +0.10/-0.05 0.25 C

0.15(4X)

-A-

-B-

19.00 +/- 0.10

15.00 (REF)

1.00 (REF)

19.00 +/- 0.10

15.00 (REF)

1.00 (REF)

1412 16

11 13 15 16 14 12

15 13

A1 CORNER

Ø0.05 M C

10 6

Ø0.50 (256 X)

Ø0.25 M C A B

BOTTOM VIEW

Jedec Outline - Design Guide 4.14

256-ball Leaded FBGA (19 x 19 x 1.7 mm) BB256

001-00915-*A

256-ball Lead-Free FBGA (19 x 19 x 1.7 mm) BW256

FullFlex

Document #: 38-06082 Rev. *G Page 48 of 51

Package Diagrams (continued)

Ø0.50~Ø0.70(484X)

0.97 REF.

0.20 C

0.56 REF.

SEATING PLANE

-C-

30° TYP.

0.40~0.60

0.132.03 ±

PIN #1 CORNER

1.00

20.00 REF.

3.20*45°(4x)

20.00 REF.

-A-

0.20(4X)

-B-

23.00±0.20

21.00

23.00±0.20

21.00

Ø1.00(3X) REF.

359

10 12

1614

13 15

17 21

20 22 22

21 17

18 16 1214

11 9

1.00

8642

Package Weight - 2.0 grams

Jedec Outline - Design Guide 4.14

0.25 C

0.35 C

484-ball Leaded PBGA (23 mm x 23 mm x 2.03 mm) BG484

51-85218-**

484-ball Lead-Free PBGA (23 mm x 23 mm x 2.03 mm) BY484

FullFlex

Document #: 38-06082 Rev. *G Page 49 of 51

FullFlex is a trademark of Cypress Semiconductor Corporation. All product and company names mentioned in this document are

trademarks of their respective holders.

Package Diagrams (continued)

484-ball Leaded PBGA (27 mm x 27 mm x 2.33 mm) BG484S

001-07825-**

484-ball Lead-Free PBGA (27 mm x 27 mm x 2.33 mm) BY484S

FullFlex

Document #: 38-06082 Rev. *G Page 50 of 51

of any circuitry other than circuitry embodied in a Cypress product. Nor does it convey or imply any license under patent or other rights. Cypress products are not warranted nor intended to be

used for medical, life support, life saving, critical control or safety applications, unless pursuant to an express written agreement with Cypress. Furthermore, Cypress 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

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

Document History Page

Document Title: FullFlex™ Synchronous SDR Dual-Port SRAM

Document Number: 38-06082

REV. ECN NO.

Issue

Date

Orig. of

Change Description of Change

** 302411 See ECN YDT New data sheet

*A 334036 See ECN YDT Corrected typo on page 1

Reproduced PDF file to fix formatting errors

*B 395800 See ECN SPN Added statement about no echo clocks for flow-through mode

Updated electrical characteristics

Added note 16 and 17 (1.5V timing)

Added note 33 (timing for x18 devices)

Updated input edge rate (note 34)

Updated table 5 on deterministic access control logic

Added description of busy readback in deterministic access control section

Changed dummy write descriptions

Updated ZQ pins connection details

Updated note 24, B0 to BE0

Added power supply requirements to MRST and VC_SEL

Added note 4 (VIM disable)

Updated supply voltage to ground potential to 4.1V

Updated parameters on table 15

Updated and added parameters to table 16

Updated x72 pinout to SDR only pinout

Updated 484 PBGA pin diagram

Updated the pin definition of MRST

Updated the pin definition of VC_SEL

Updated READY description to include Wired OR note

Updated master reset to include wired OR note for READY

Updated minimum VOH value for the 1.8V LVCMOS configuration

Updated electrical characteristics to include IOH and IOL values

Updated electrical characteristics to include READY

Added IIX3

Updated maximum input capacitance

Added Notes 33 and 34Removed Notes 15 and 17

Updated Pin Definitions for CQ0, CQ0, CQ1, and CQ1

Removed -100 Speed bin from Table.1 Selection Guide

Changed voltage name from VDDQ to VDDIO

Changed voltage name from VDD to VCORE

Moved the Mailbox Interrupt Timing Diagram to be the final timing diagram

Updated the Package Type for the CYD36S18V18 parts

Updated the Package Type for the CYD18S18V18 parts

Updated the Package Type for the CYD18S36V18 parts

Included the Package Diagram for the 256-Ball FBGA (19 x 19 mm) BW256

Included an OE Controlled Write for Flow-through Mode Switching Waveform

Included a Read with Echo Clock Switching Waveform

Updated Figure 5 and Figure 6

Updated Electrical Characteristics for READY VOH and READY V

Updated Electrical Characteristics for VOH and VOL for the -167 and -133 speeds

Included a Unit column for Table 5

Removed Switching Characteristic tCA from chart

Included tOHZ in Switching Waveform OE Controlled Write for Pipelined Mode

Included tCKLZ2 in Waveform Read-to-Write-to-Read for Flow-through Mode

*C 402238 SEE ECN KGH Updated AC Test Load and Waveforms

Included FullFlex36 SDR 484-ball BGA Pinout (Top View)

Included FullFlex18 SDR 484-ball BGA Pinout (Top View)

Included Timing Parameter tCORDY

FullFlex

Document #: 38-06082 Rev. *G Page 51 of 51

*D 458131 SEE ECN YDT Changed ordering information with lead-free part numbers

Removed VC_SEL

Added I/O and core voltage adders

Removed references to bin drop for LVTTL/2.5V LVCMOS and 1.5V core modes

Updated Cin and Cout

Updated ICC, ISB1, ISB2 and ISB3 tables

Updated busy address read back timing diagram

Added HTSL input waveform

Removed HSTL (AC) from DC tables

Added 484-ball 27 mmx27 mmx2.33 mm PBGA package

*E 470031 SEE ECN YDT Changed VOL of 1.8V LVCMOS to 0.45V

Updated tRSF

VREF is DNU when HSTL is not used

Formatted pin description table

Changed VDDIO pins for 36M x 36 and 36M x 18 pinouts

Changed 36Mx72 JTAG IDCODE

*F 500001 SEE ECN YDT DLL Change, added Clock Input Cycle to Cycle Jitter

Modified DLL description

Changed Input Capaciance Table

Changed tCCS number

Added note 31

*G 627539 SEE ECN QSL change all NC to DNU

corrected switching waveform for (CQEN = High) from both Pipeline and

Flowthrough mode to only pipeline mode

Modified Master Reset Description

Modified switching characteristics tables, extraced signals effected by the DLL into

one table and combine all other signals into one table

updated package name

Added footnote for tHD, tHAC and tSAC

changed note 26 description

Document Title: FullFlex™ Synchronous SDR Dual-Port SRAM

Document Number: 38-06082

REV. ECN NO.

Issue

Date

Orig. of

Change Description of Change