CYPRESS CYD18S72V

CYD04S72V
CYD09S72V
CYD18S72V
PRELIMINARY
FLEx72™ 3.3V 64K/128K/256K x 72
Synchronous Dual-Port RAM
Features
Functional Description
• True dual-ported memory cells that allow simultaneous
access of the same memory location
• Synchronous pipelined operation
• Family of 4-Mbit, 9-Mbit and 18-Mbit devices
• Pipelined output mode allows fast operation
• 0.18-micron CMOS for optimum speed and power
• High-speed clock to data access
• 3.3V low power
— Active as low as 225 mA (typ)
•
•
•
•
•
•
•
The FLEx72 family includes 4-Mbit, 9-Mbit and 18-Mbit
pipelined, synchronous, true dual-port static RAMs that are
high-speed, low-power 3.3V CMOS. Two ports are provided,
permitting independent, simultaneous access to any location
in memory. The result of writing to the same location by more
than one port at the same time is undefined. Registers on
control, address, and data lines allow for minimal set-up and
hold time.
During a Read operation, data is registered for decreased
cycle time. Each port contains a burst counter on the input
address register. After externally loading the counter with the
initial address, the counter will increment the address internally (more details to follow). The internal write pulse width is
independent of the duration of the R/W input signal. The
internal write pulse is self-timed to allow the shortest possible
cycle times.
— Standby as low as 55 mA (typ)
Mailbox function for message passing
Global master reset
Separate byte enables on both ports
Commercial and industrial temperature ranges
IEEE 1149.1-compatible JTAG boundary scan
484-ball FBGA (1 mm pitch)
Counter wrap around control
— Internal mask register controls counter wrap-around
A HIGH on CE0 or LOW on CE1 for one clock cycle will power
down the internal circuitry to reduce the static power
consumption. One cycle with chip enables asserted is required
to reactivate the outputs.
Additional features include: readback of burst-counter internal
address value on address lines, counter-mask registers to
control the counter wrap-around, counter interrupt (CNTINT)
flags, readback of mask register value on address lines,
retransmit functionality, interrupt flags for message passing,
JTAG for boundary scan, and asynchronous Master Reset
(MRST).
— Counter-interrupt flags to indicate wrap-around
— Memory block retransmit operation
• Counter readback on address lines
• Mask register readback on address lines
• Dual Chip Enables on both ports for easy depth
expansion
• Seamless Migration to Next Generation Dual Port
Family
The CYD18S72V device have limited features. Please see
“Address Counter and Mask Register Operations[16]” on
page 6 for details.
Seamless Migration to Next Generation Dual Port Family
Cypress offers a migration path for all devices to the
next-generation devices in the Dual-Port family with a
compatible footprint. Please contact Cypress Sales for more
details
Table 1. Product Selection Guide
Density
4-Mbit
(64K x 72)
9-Mbit
(128K x 72)
18-Mbit
(256K x 72)
CYD04S72V
CYD09S72V
CYD18S72V
Max. Speed (MHz)
167
167
133
Max. Access Time - clock to Data (ns)
4.0
4.0
5.0
Part Number
Typical operating current (mA)
Package
Cypress Semiconductor Corporation
Document #: 38-06069 Rev. *D
•
225
270
410
484-ball FBGA
23mm x 23mm
484-ball FBGA
23mm x 23mm
484-ball FBGA
23mm x 23mm
3901 North First Street
•
San Jose, CA 95134
•
408-943-2600
Revised June 23, 2004
CYD04S72V
CYD09S72V
CYD18S72V
PRELIMINARY
.
Logic Block Diagram[1]
FTSELL
PORTST[1:0]L
FTSELR
CONFIG Block
CONFIG Block
PORTST[1:0]R
DQ[71:0]L
BE [7:0]L
CE0L
CE1L
OEL
IO
Control
IO
Control
DQ [71:0]R
BE [7:0]R
CE0R
CE1R
OER
R/WR
R/WL
Dual Ported Array
BUSYL
A [17:0]L
CNT/MSKL
ADSL
CNTENL
CNTRSTL
RETL
CNTINTL
CL
Arbitration Logic
Address &
Counter Logic
BUSYR
Address &
Counter Logic
WRPL
A [17:0]R
CNT/MSKR
ADSR
CNTENR
CNTRSTR
RETR
CNTINTR
CR
WRPR
JTAG
TRST
TMS
TDI
TDO
TCK
RESET
LOGIC
MRST
READYR
LowSPDR
Mailboxes
INTL
INTR
READYL
LowSPDL
Note:
1. CYD04S72V have 16 address bits, CYD09S72V have 17 address bits and CYD18S72V have 18 bits.
Document #: 38-06069 Rev. *D
Page 2 of 26
CYD04S72V
CYD09S72V
CYD18S72V
PRELIMINARY
Pin Configuration
484-ball BGA
Top View
CYD04S72V / CYD09S72V / CYD18S72V
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
A
NC
DQ6
1L
DQ5
9L
DQ5
7L
DQ5
4L
DQ5
1L
DQ4
8L
DQ4
5L
DQ4
2L
DQ3
9L
DQ3
6L
DQ3
6R
DQ3
9R
DQ4
2R
DQ4
5R
DQ4
8R
DQ5
1R
DQ5
4R
DQ5
7R
DQ5
9R
DQ6
1R
NC
B
DQ6
3L
DQ6
2L
DQ6
0L
DQ5
8L
DQ5
5L
DQ5
2L
DQ4
9L
DQ4
6L
DQ4
3L
DQ4
0L
DQ3
7L
DQ3
7R
DQ4
0R
DQ4
3R
DQ4
6R
DQ4
9R
DQ5
2R
DQ5
5R
DQ5
8R
DQ6
0R
DQ6
2R
DQ6
3R
DQ6
5L
DQ6
4L
VSS
VSS
DQ5
6L
DQ5
3L
DQ5
0L
DQ4
7L
DQ4
4L
DQ4
1L
DQ3
8L
DQ3
8R
DQ4
1R
DQ4
4R
DQ4
7R
DQ5
0R
DQ5
3R
DQ5
6R
VSS
VSS
C
DQ6
4R
DQ6
5R
DQ6
7L
DQ6
6L
VSS
VSS
VSS
NC
REV
L[2,4]
LOW
SPD
L[2,4]
POR
TST
D0L
[2, 5]
NC
BUS
YL
CNTI
NTL
POR
TST
D1L
REV
R[2,4]
[2, 5]
[2, 5]
NC
VSS
VSS
VSS
DQ6
6R
DQ6
7R
DQ6
9L
DQ6
8L
VDD
IOL
VSS
VSS
VDD
IOL
VDD
IOL
VDD
IOL
VDDI
OL
VDDI
OL
VTT
L
VTT
L
VTTL
VDDI
OR
VDD
IOR
VDD
IOR
VDD
IOR
NC
VSS
VDD
IOR
DQ6
8R
DQ6
9R
DQ7
1L
DQ7
0L
CE1
L[8]
CE0
L [9]
VDD
IOL
VDD
IOL
VDD
IOL
VDD
IOL
VDDI
OL
VCO
RE
VCO
RE
VCO
RE
VCO
RE
VDDI
OR
VDD
IOR
VDD
IOR
VDD
IOR
VDD
IOR
CE0
R [9]
CE1
R[8]
DQ7
0R
DQ7
1R
A0L
A1L
RET
L[2,3]
BE4
L
VDD
IOL
VDD
IOL
VRE
FL
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VRE
FR
VDD
IOR
VDD
IOR
BE4
R
RET
R[2,3]
A1R
A0R
NC
[2, 5]
[2, 5]
D
E
F
G
[2, 5]
[10]
[2,4]
NC
[2, 5]
[2, 4]
[2, 4]
A2L
A3L
WRP
L[2,3]
BE5
L
VDD
IOL
VDD
IOL
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VDD
IOR
VDD
IOR
BE5
R
WRP
R[2,3]
A3R
A2R
A4L
A5L
REA
DYL
BE6
L
VDD
IOL
VDD
IOL
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VDD
IOR
VDD
IOR
BE6
R
REA
DYR
A5R
A4R
H
[2, 5]
J
[2, 5]
A6L
A7L
NC
BE7
L
VTT
L
VCO
RE
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VCO
RE
VDD
IOR
BE7
R
NC
A7R
A6R
A8L
A9L
CL
OEL
VTT
L
VCO
RE
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VCO
RE
VTT
L
OER
CR
A9R
A8R
A10L
A11L
REV
L [2,4]
BE3
L
VTT
L
VCO
RE
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VCO
RE
VTT
L
BE3
R
REV
R[2,4]
A11
R
A10
R
A12L
A13L
ADS
L [9]
BE2
L
VDD
IOL
VCO
RE
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VCO
RE
VTT
L
BE2
R
ADS
R [9]
A13
R
A12
R
A14L
A15L
CNT/
MSK
L[8]
BE1
L
VDD
IOL
VDD
IOL
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VDD
IOR
VDD
IOR
BE1
R
CNT/
MSK
R[8]
A15
R
A14
R
A16L
A17L
CNT
ENL
BE0
L
VDD
IOL
VDD
IOL
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VDD
IOR
VDD
IOR
BE0
R
CNT
ENR
A17
R
A16
R
K
L
M
N
P
[6]
[7]
[9]
R
[9]
[7]
[6]
A18L
NC
CNT
RST
L [8]
INTL
VDD
IOL
VDD
IOL
VRE
FL
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VRE
FR
VDD
IOR
VDD
IOR
INTR
CNT
RST
R[8]
NC
A18
R
DQ3
5L
DQ3
4L
R/W
L
REV
L [2,4]
VDD
IOL
VDD
IOL
VDD
IOL
VDD
IOL
VDDI
OL
VCO
RE
VCO
RE
VCO
RE
VCO
RE
VDDI
OR
VDD
IOR
VDD
IOR
VDD
IOR
VDD
IOR
REV
R[2,4]
R/W
R
DQ3
4R
DQ3
5R
DQ3
3L
DQ3
2L
FTS
ELL
VDD
IOL
NC
VDD
IOL
VDD
IOL
VDD
IOL
VDDI
OL
VTTL
VTT
L
VTT
L
VDDI
OR
VDDI
OR
VDD
IOR
VDD
IOR
VDD
IOR
TRS
T[2, 5]
VDD
IOR
FTS
ELR
DQ3
2R
DQ3
3R
DQ3
1L
DQ3
0L
VSS
MRS
T
VSS
NC
REV
L[2,4]
POR
TST
D1R
CNTI
NTR
BUS
YR
[2, 5]
NC
POR
TST
D0R
LOW
SPD
R[2,4]
REV
R[2,4]
[2, 5]
[2, 5]
NC
VSS
TDI
TDO
DQ3
0R
DQ3
1R
DQ2
8L
VSS
VSS
DQ2
0L
DQ1
7L
DQ1
4L
DQ1
1L
DQ8
L
DQ5
L
DQ2
L
DQ2
R
DQ5
R
DQ8
R
DQ1
1R
DQ1
4R
DQ1
7R
DQ2
0R
TMS
TCK
Y
DQ2
9L
DQ2
8R
DQ2
9R
A
A
DQ2
7L
DQ2
6L
DQ2
4L
DQ2
2L
DQ1
9L
DQ1
6L
DQ1
3L
DQ1
0L
DQ7
L
DQ4
L
DQ1
L
DQ1
R
DQ4
R
DQ7
R
DQ1
0R
DQ1
3R
DQ1
6R
DQ1
9R
DQ2
2R
DQ2
4R
DQ2
6R
DQ2
7R
A
B
NC
DQ2
5L
DQ2
3L
DQ2
1L
DQ1
8L
DQ1
5L
DQ1
2L
DQ9
L
DQ6
L
DQ3
L
DQ0
L
DQ0
R
DQ3
R
DQ6
R
DQ9
R
DQ1
2R
DQ1
5R
DQ1
8R
DQ2
1R
DQ2
3R
DQ2
5R
NC
[2,5]
T
U
V
[2,3]
NC
[2, 5]
[2, 4]
[2, 5]
[2, 4]
[2, 5]
[2, 5]
W
2.
3.
4.
5.
6.
7.
8.
9.
10.
[10]
[2,4]
NC
[2,3]
[2,5]
This ball will represent a next generation Dual-Port feature. For more information about this feature, contact Cypress Sales
Connect this ball to VDDIO. For more information about this next generation Dual-Port feature contact Cypress Sales.
Connect this ball to VSS. For more information about this next generation Dual-Port feature, contact Cypress Sales.
Leave this ball unconnected. For more information about this feature, contact Cypress Sales.
Leave this ball unconnected for a 64K x 72 configuration.
Leave this ball unconnected for 128K x 72 and 64K x72 configurations.
These balls are not applicable for CYD18S72V device. They need to be tied to VDDIO.
These balls are not applicable for CYD18S72V device. They need to be tied to VSS.
These balls are not applicable for CYD18S72V device. They need to be no connected.
Document #: 38-06069 Rev. *D
Page 3 of 26
CYD04S72V
CYD09S72V
CYD18S72V
PRELIMINARY
Pin Definitions
Left Port
Right Port
Description
A0L–A17L
A0R–A17R
BE0L–BE7L
BE0R–BE7R
Byte Enable Inputs. Asserting these signals enables Read and Write operations to the corresponding bytes of the memory array.
BUSYL[2,5]
BUSYR[2,5]
Port Busy Output. When the collision is detected, a BUSY is asserted.
CL
CR
CE0L[9]
CE0R[9]
Active Low Chip Enable Input.
CE1L[8]
CE1R[8]
Active High Chip Enable Input.
DQ0L–DQ71L
DQ0R–DQ71R
OEL
OER
Output Enable Input. This asynchronous signal must be asserted LOW to
enable the DQ data pins during Read operations.
INTL
INTR
Mailbox 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.
LowSPDL[2,4]
LowSPDR[2,4]
Address Inputs.
Input Clock Signal.
Data Bus Input/Output.
Port Low Speed Select Input. When operating at less than 100 MHz, the
LowSPD disables the port DLL.
PORTSTD[1:0]L[2,4,5] PORTSTD[1:0]R[2,4,5] Port Address/Control/Data I/O Standard Select Input.
R/WL
R/WR
Read/Write Enable Input. Assert this pin LOW to write to, or HIGH to Read
from the dual port memory array.
READYL[2,5]
READYR[2,5]
Port Ready Output. This signal will be asserted when a port is ready for normal
operation.
CNT/MSKL[8]
CNT/MSKR[8]
Port Counter/Mask Select Input. Counter control input.
ADSL[9]
ADSR[9]
CNTENL[9]
CNTENR[9]
Port Counter Enable Input. Counter control input.
CNTRSTL[8]
CNTRSTR[8]
Port Counter Reset Input. Counter control input.
CNTINTL[10]
CNTINTR[10]
Port Counter Interrupt Output. This pin is asserted LOW when the unmasked
portion of the counter is incremented to all “1s”.
WRPL[2,3]
WRPR[2,3]
Port Counter Wrap Input. After the burst counter reaches the maximum count,
if WRP is low, the unmasked counter bits will be set to 0. If high, the counter
will be loaded with the value stored in the mirror register.
RETL[2,3]
RETR[2,3]
Port Counter Retransmit Input. Counter control input.
FTSELL[2,3]
FTSELR[2,3]
Flow-Through Select. Use this pin to select Flow-Through mode. When is
de-asserted, the device is in pipelined mode.
VREFL[2,5]
VREFR[2,5]
Port External High-Speed IO Reference Input.
VDDIOL
VDDIOR
Port IO Power Supply.
REV[2,4]L
REV[2,4]R
Reserved pins for future features.
MRST
TRST[2,5]
TMS
Document #: 38-06069 Rev. *D
Port Counter Address Load Strobe Input. Counter control input.
Master Reset Input. MRST is an asynchronous input signal and affects both
ports. A master reset operation is required at power-up.
JTAG Reset Input.
JTAG Test Mode Select Input. It controls the advance of JTAG TAP state
machine. State machine transitions occur on the rising edge of TCK.
Page 4 of 26
CYD04S72V
CYD09S72V
CYD18S72V
PRELIMINARY
Pin Definitions (continued)
Left Port
Right Port
Description
TDI
JTAG Test Data Input. Data on the TDI input will be shifted serially into selected
registers.
TCK
JTAG Test Clock Input.
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.
VSS
Ground Inputs.
Core Power Supply.
VCORE
LVTTL Power Supply.
VTTL
Master Reset
The FLEx72 family devices undergo a complete reset by
taking the MRST input LOW. MRST input can switch
asynchronously to the clocks. MRST initializes the internal
burst counters to zero, and the counter mask registers to all
ones (completely unmasked). MRST also forces the mailbox
interrupt (INT) flags and the Counter Interrupt (CNTINT) flags
HIGH. MRST must be performed on the FLEx72 family
devices after power-up.
Mailbox Interrupts
The upper two memory locations may be used for message
passing and permit communications between ports. Table 2
shows the interrupt operation for both ports using 18Mbit
device as an example. The highest memory location, 3FFFF
is the mailbox for the right port and 3FFFE is the mailbox for
the left port. Table 2.shows that in order to set the INTR flag, a
write operation by the left port to address 3FFFF will assert
INTR LOW. At least one byte has to be active for a write to
generate an interrupt. A valid Read of the 3FFFF location by
the right port will reset INTR HIGH. At least one byte has to be
active in order for a read to reset the interrupt. When one port
writes to the other port’s mailbox, the INT of the port that the
mailbox belongs to is asserted LOW.
The INT is reset when the owner (port) of the mailbox reads
the contents of the mailbox. The interrupt flag is set in
a flow-thru mode (i.e., it follows the clock edge of the writing
port). Also, the flag is reset in a flow-thru mode (i.e., it follows
the clock edge of the reading port).
Each port can read the other port’s mailbox without resetting
the interrupt. And each port can write to its own mailbox
without setting the interrupt. If an application does not require
message passing, INT pins should be left open.
Table 2. Interrupt Operation Example [1, 11, 12, 13]
Left Port
Function
Right Port
R/WL
CEL
A0L–17L
INTL
R/WR
CER
A0R–17R
INTR
Set Right INTR Flag
L
L
3FFFF
X
X
X
X
L
Reset Right INTR Flag
X
X
X
X
H
L
3FFFF
H
Set Left INTL Flag
X
X
X
L
L
L
3FFFE
X
Reset Left INTL Flag
H
L
3FFFE
H
X
X
X
X
Note:
11. 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 CLK and can be deasserted after that. Data will be out after the following CLK edge and will be three-stated after the next CLK edge.
12. OE is “Don’t Care” for mailbox operation.
13. At least one of BE0 or BE7 must be LOW.
Document #: 38-06069 Rev. *D
Page 5 of 26
CYD04S72V
CYD09S72V
CYD18S72V
PRELIMINARY
Table 3. Address Counter and Counter Mask Register Control Operation (Any Port) [14,15 ]
CLK
MRST
X
L
CNT/MSK CNTRST ADS CNTEN
X
X
X
X
Master Reset
Operation
Reset address counter to all 0s and mask
register to all 1s.
Description
H
H
L
X
X
Counter Reset
Reset counter unmasked portion to all 0s.
H
H
H
L
L
Counter Load
Load counter with external address value
presented on address lines.
H
H
H
L
H
Counter Readback Read out counter internal value on address
lines.
H
H
H
H
L
Counter Increment Internally increment address counter value.
H
H
H
H
H
Counter Hold
Constantly hold the address value for
multiple clock cycles.
H
L
L
X
X
Mask Reset
Reset mask register to all 1s.
H
L
H
L
L
Mask Load
Load mask register with value presented on
the address lines.
H
L
H
L
H
Mask Readback
Read out mask register value on address
lines.
H
L
H
H
X
Reserved
Operation undefined
Note:
14. X” = “Don’t Care,” “H” = HIGH, “L” = LOW.
15. Counter operation and mask register operation is independent of chip enables.
Address Counter and Mask Register Operations[16]
This section describes the features only apply to 4Mbit and
9Mbit devices, not to 18Mbit device. Each port have a
programmable burst address counter. The burst counter
contains three registers: a counter register, a mask register,
and a mirror register.
The counter register contains the address used to access the
RAM array. It is changed only by the Counter Load, Increment,
Counter Reset, and by master reset (MRST) operations.
The mask register value affects the 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 changed only
by the Mask Load and Mask Reset operations, and by the
MRST. The mask register defines the counting range of the
counter register. It divides the counter register into two
regions: zero or more “0s” in the most significant bits define
the masked region, one or more “1s” in the least significant bits
define the unmasked region. Bit 0 may also be “0,” masking
the least significant counter bit and causing the counter to
increment by two instead of one.
The mirror register is used to reload the counter register on
increment operations (see “retransmit,” below). It always
contains the value last loaded into the counter register, and is
changed only by the Counter Load, and Counter Reset operations, and by the MRST.
Table 3 summarizes the operation of these registers and the
required input control signals. The MRST control signal is
asynchronous. All the other control signals in Table 3
(CNT/MSK, CNTRST, ADS, CNTEN) are synchronized to the
port’s CLK. All these counter and mask operations are
independent of the port’s chip enable inputs (CE0 and CE1)
Document #: 38-06069 Rev. *D
Counter enable (CNTEN) inputs are provided to stall the
operation of the address input and utilize the internal address
generated by the internal counter for fast, interleaved memory
applications. A port’s burst counter is loaded when the port’s
address strobe (ADS) and CNTEN signals are LOW. When the
port’s CNTEN is asserted and the ADS is deasserted, the
address counter will increment on each LOW to HIGH
transition of that port’s clock signal. This will Read/Write one
word from/into each successive address location until CNTEN
is deasserted. The counter can address the entire memory
array, and will loop back to the start. Counter reset (CNTRST)
is used to reset the unmasked portion of the burst counter to
0s. A counter-mask register is used to control the counter
wrap.
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, as will master reset (MRST).
Counter Load Operation
The address counter and mirror registers are both loaded with
the address value presented at the address lines.
Counter Increment Operation
Once the address counter register is initially loaded with an
external address, the counter can internally increment the
address value, potentially addressing the entire memory array.
Only the unmasked bits of the counter register are incremented. The corresponding bit in the mask register must be
a “1” for a counter bit to change. The counter register is incremented by 1 if the least significant bit is unmasked, and by 2
if it is masked. If all unmasked bits are “1,” the next increment
Page 6 of 26
PRELIMINARY
will wrap the counter back to the initially loaded value. If an
Increment results in all the unmasked bits of the counter being
“1s,” a counter interrupt flag (CNTINT) is asserted. The next
Increment will return the counter register to its initial value,
which was stored in the mirror register. The counter address
can instead be forced to loop to 00000 by externally
connecting CNTINT to CNTRST.[17] An increment that results
in one or more of the unmasked bits of the counter being “0”
will de-assert the counter interrupt flag. The example in
Figure 2 shows the counter mask register loaded with a mask
value of 0003Fh unmasking the first 6 bits with bit “0” as the
LSB and bit “16” as the MSB. The maximum value the mask
register can be loaded with is 1FFFFh. 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 8h. The base address bits (in this case, the 6th
address through the 16th address) are loaded with an address
value but do not increment once the counter is configured for
increment operation. The counter address will start at address
8h. The counter will increment its internal address value till it
reaches the mask register value of 3Fh. The counter wraps
around the memory block to location 8h at the next count.
CNTINT is issued when the counter reaches its maximum
value.
Counter 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.
Counter Interrupt
The counter interrupt (CNTINT) is asserted LOW when an
increment operation results in the unmasked portion of the
counter register being all “1s.” It is deasserted HIGH when an
Increment operation results in any other value. It is also
de-asserted by Counter Reset, Counter Load, Mask Reset and
Mask Load operations, and by MRST.
Counter Readback Operation
The internal value of the counter register can be read out on
the address lines. Readback is pipelined; the address will be
valid tCA2 after the next rising edge of the port’s clock. If
address readback occurs while the port is enabled (CE0 LOW
and CE1 HIGH), the data lines (DQs) will be three-stated.
Figure 1 shows a block diagram of the operation.
CYD04S72V
CYD09S72V
CYD18S72V
Retransmit
Retransmit is a feature that allows the Read of a block of
memory more than once without the need to reload the initial
address. This eliminates the need for external logic to store
and route data. It also reduces the complexity of the system
design and saves board space. An internal “mirror register” is
used to store the initially loaded address counter value. When
the counter unmasked portion reaches its maximum value set
by the mask register, it wraps back to the initial value stored in
this “mirror register.” If the counter is continuously configured
in increment mode, it increments again to its maximum value
and wraps back to the value initially stored into the “mirror
register.” Thus, the repeated access of the same data is
allowed without the need for any external logic.
Mask Reset Operation
The mask register is reset to all “1s,” which unmasks every bit
of the counter. Master reset (MRST) also resets the mask
register to all “1s.”
Mask Load Operation
The mask register is loaded with the address value presented
at the address lines. Not all values permit correct increment
operations. Permitted values are of the form 2n – 1 or 2n – 2.
From the most significant bit to the least significant bit,
permitted values have zero or more “0s,” one or more “1s,” or
one “0.” Thus 1FFFF, 003FE, and 00001 are permitted values,
but 1F0FF, 003FC, and 00000 are not.
Mask Readback Operation
The internal value of the mask register can be read out on the
address lines. Readback is pipelined; the address will be valid
tCM2 after the next rising edge of the port’s clock. If mask
readback occurs while the port is enabled (CE0 LOW and CE1
HIGH), the data lines (DQs) will be three-stated. Figure 1
shows a block diagram of the operation.
Counting by Two
When the least significant bit of the mask register is “0,” the
counter increments by two. This may be used to connect the
x72 devices as a 144-bit single port SRAM in which the
counter of one port counts even addresses and the counter of
the other port counts odd addresses. This even-odd address
scheme stores one half of the 144-bit data in even memory
locations, and the other half in odd memory locations.
Notes:
16. The CYD04S72V has 16 address bits and a maximum address value of FFFF. The CYD09S72V has 17 address bits and a maximum address value of 1FFFF.
The CYD18S72V has 18 address bits and a maximum address value of 3FFFF.
17. CNTINT and CNTRST specs are guaranteed by design to operate properly at speed grade operating frequency when tied together.
Document #: 38-06069 Rev. *D
Page 7 of 26
CYD04S72V
CYD09S72V
CYD18S72V
PRELIMINARY
CNT/MSK
CNTEN
Decode
Logic
ADS
CNTRST
MRST
Bidirectional
Address
Lines
Mask
Register
Counter/
Address
Register
Address
RAM
Decode
Array
CLK
From
Address
Lines
Load/Increment
17
Mirror
From
Mask
Register
Increment
Logic
Wrap
17
From
Mask
From
Counter
17
To Readback
and Address
Decode
0
0
17
Counter
1
1
17
17
Bit 0
+1
Wrap
Detect
1
+2
Wrap
0
1
0
17
To
Counter
Figure 1. Counter, Mask, and Mirror Logic Block Diagram[1]
Document #: 38-06069 Rev. *D
Page 8 of 26
CYD04S72V
CYD09S72V
CYD18S72V
PRELIMINARY
Example:
Load
Counter-Mask
Register = 3F
CNTINT
H
0 0
0s
216 215
H
X X
Xs
216 215
Max
Address
Register
L
H
1
1
1
X X
X X
216 215
Unmasked Address
X 0 0
1
0
0
Xs
X 1 1
1
Mask
Register
bit-0
0
26 25 24 23 22 21 20
216 215
Max + 1
Address
Register
1
26 25 24 23 22 21 20
Masked Address
Load
Address
Counter = 8
0 1 1
1 1
1
Address
Counter
bit-0
26 25 24 23 22 21 20
Xs
X 0
0
1
0 0
0
26 25 24 23 22 21 20
Figure 2. Programmable Counter-Mask Register Operation[1, 18]
IEEE 1149.1 Serial Boundary Scan (JTAG)[19]
The FLEx72 incorporates an IEEE 1149.1 serial boundary
scan test access port (TAP). The TAP controller functions in a
manner that does not conflict with the operation of other
devices using 1149.1-compliant TAPs. The TAP operates
using JEDEC-standard 3.3V I/O logic levels. It is composed of
three input connections and one output connection required by
the test logic defined by the standard.
Performing a TAP Reset
A reset is performed by forcing TMS HIGH (VDD) for five rising
edges of TCK. This reset does not affect the operation of the
FLEx72 family and may be performed while the device is
operating. An MRST must be performed on the FLEx72 after
power-up.
Performing a Pause/Restart
When a SHIFT-DR PAUSE-DR SHIFT-DR is performed the
scan chain will output the next bit in the chain twice. For
example, if the value expected from the chain is 1010101, the
device will output a 11010101. This extra bit will cause some
testers to report an erroneous failure for the FLEx72 in a scan
test. Therefore the tester should be configured to never enter
the PAUSE-DR state.
Boundary Scan Hierarchy for FLEx72 Family
Internally, the CYD04S72V and CYD09S72V have two DIEs
while CYD18S72V have four DIEs. Each DIE contains all the
circuitry required to support boundary scan testing. The
circuitry includes the TAP, TAP controller, instruction register,
and data registers. The circuity and operation of the DIE
boundary scan are described in detail below. The scan chain
of each DIE is connected serially to form the scan chain of the
FLEx72 family as shown in Figure 3. TMS and TCK are
connected in parallel to each DIE to drive all 4 TAP controllers
in unison. In many cases, each DIE will be supplied with the
same instruction. In other cases, it might be useful to supply
different instructions to each DIE. One example would be
testing the device ID of one DIE while bypassing the others.
Each pin of FLEx72 family is typically connected to multiple
DIEs. For connectivity testing with the EXTEST instruction, it
is desirable to check the internal connections between DIEs
as well as the external connections to the package. This can
be accomplished by merging the netlist of the devices with the
netlist of the user’s circuit board. To facilitate boundary scan
testing of the devices, Cypress provides the BSDL file for each
DIE, the internal netlist of the device, and a description of the
device scan chain. The user can use these materials to easily
integrate the devices into the board’s boundary scan
environment. Further information can be found in the Cypress
application note Using JTAG Boundary Scan For System In a
Package (SIP) Dual-Port SRAMs.
Notes:
18. The “X” in this diagram represents the counter upper bits.
19. Boundary scan is IEEE 1149.1-compatible. See “Performing a Pause/Restart” for deviation from strict 1149.1 compliance.
Document #: 38-06069 Rev. *D
Page 9 of 26
CYD04S72V
CYD09S72V
CYD18S72V
PRELIMINARY
18 Mbit
4 Mbit/9 Mbit
TDO
TDO
TDO
D2
TDI
TDO
D4
TDI
TDO
D2
TDI
TDO
D1
TDI
TDO
D3
TDI
TDO
D1
TDI
TDI
TDI
Figure 3. Scan Chain
Table 4. Identification Register Definitions
Instruction Field
Value
Description
Revision Number(31:28)
0h
Cypress Device(27:12)
C002h
Defines Cypress DIE number for CYD18S72V and
CYD09S72V.
C001h
Defines Cypress DIE number for CYD04S72V
Cypress JDEC ID(11:1)
034h
ID Register Presence (0)
1
Reserved for version number
Allows unique identification of FLEx72 family device vendor
Indicates the presence of an ID register
Table 5. Scan Registers Sizes
Register Name
Bit Size
Instruction
4
Bypass
1
Identification
32
Boundary Scan
n [20]
Table 6. 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 FLEx72 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.
NBSRST
1100
Resets the non-boundary scan logic. Places BYR between TDI and TDO.
RESERVED
All other codes
Other combinations are reserved. Do not use other than the above.
Note:
20. See details in the device BSDL files
Document #: 38-06069 Rev. *D
Page 10 of 26
CYD04S72V
CYD09S72V
CYD18S72V
PRELIMINARY
DC Input Voltage .............................. –0.5V to VDD + 0.5V[22]
Maximum Ratings [21]
Output Current into Outputs (LOW)............................. 20 mA
(Above which the useful life may be impaired. For user guidelines, not tested.)
Static Discharge Voltage........................................... > 2000V
Storage Temperature ................................ –65°C to + 150°C
(JEDEC JESD22-A114-2000B)
Ambient Temperature with
Power Applied............................................–55°C to + 125°C
Latch-up Current..................................................... > 200 mA
Operating Range
Supply Voltage to Ground Potential .............. –0.5V to + 4.6V
DC Voltage Applied to
Outputs in High-Z State..........................–0.5V to VDD + 0.5V
Ambient
Temperature
Range
VDD
VCORE
0°C to +70°C
3.3V
± 165 mV
1.8V
± 100 mV
–40°C to +85°C
3.3V
± 165 mV
1.8V
± 100mV
Commercial
Industrial
Electrical Characteristics Over the Operating Range
-167
Parameter
Description
Part No.
VOH
Output HIGH Voltage (VDD = Min., IOH= –4.0
mA)
VOL
Output LOW Voltage (VDD = Min., IOL= +4.0
mA)
Min.
Typ.
-133
Max. Min.
2.4
Typ.
-100
Max.
2.4
VIH
Input HIGH Voltage
Input LOW Voltage
2.0
IOZ
Output Leakage Current
–10
10
–10
10
IIX1
Input Leakage Current Except TDI, TMS,
MRST
–10
10
–10
IIX2
Input Leakage Current TDI, TMS, MRST
–0.1
1.0
–0.1
ICC
Operating Current
(VDD = Max.,IOUT = 0 mA),
Outputs Disabled
ISB1
Standby Current
(Both Ports TTL Level)
CEL and CER ≥ VIH, f = fMAX
ISB2
300
CYD04S72V
CYD09S72V
90
115
Standby Current
(One Port TTL Level)
CEL | CER ≥ VIH, f = fMAX
CYD04S72V
CYD09S72V
160
ISB3
Standby Current (Both Ports
CMOS Level) CEL and CER ≥
VDD – 0.2V, f = 0
CYD04S72V
CYD09S72V
ISB4
Standby Current
(One Port CMOS Level)
CEL | CER ≥ VIH, f = fMAX
CYD04S72V
CYD09S72V
ISB5
Operating Current
(VDDIO = Max,Iout=0mA,f=0)
Outputs Disabled
CYD18S72V
ICORE
Core Operating Current for (VDD = Max.,IOUT
= 0 mA), Outputs Disabled
Unit
0.4
V
2.0
0.8
225
Max
V
0.4
VIL
CYD04S72V
CYD09S72V
Typ
2.4
0.4
2.0
Min.
V
0.8
0.8
V
-10
10
µA
10
-10
10
µA
1.0
-0.1
1.0
mA
225
300
410
580
90
115
mA
210
160
210
mA
55
75
55
75
mA
160
210
160
210
mA
CYD18S72V
mA
315
75
0
0
0
0
0
450
mA
75
mA
0
mA
Capacitance [23]
Part#
Parameter
Description
Test Conditions
TA = 25°C, f = 1 MHz,
VDD = 3.3V
Max.
Unit
20
pF
10[24]
pF
CYD04S72V
CYD09S72V
CIN
Input Capacitance
COUT
Output Capacitance
CYD18S72V
CIN
Input Capacitance
40
pF
COUT
Output Capacitance
20
pF
Note:
21. The voltage on any input or I/O pin can not exceed the power pin during power-up.
22. Pulse width < 20 ns.
23. COUT also references CI/O
Document #: 38-06069 Rev. *D
Page 11 of 26
CYD04S72V
CYD09S72V
CYD18S72V
PRELIMINARY
AC Test Load and Waveforms
3.3V
Z0 = 50Ω
R = 50Ω
R1 = 590 Ω
OUTPUT
OUTPUT
C = 10 pF
C = 5 pF
VTH = 1.5V
(a) Normal Load (Load 1)
(b) Three-state Delay (Load 2)
3.0V
ALL INPUT PULSES
R2 = 435 Ω
90%
90%
10%
10%
Vss
< 2 ns
< 2 ns
Switching Characteristics Over the Operating Range
-167
Parameter
Description
-133
-100
CYD04S72V
CYD09S72V
CYD04S72V
CYD09S72V
CYD18S72V
CYD18S72V
Min.
Min.
Min.
Min.
Max.
Max.
Max
Max
Unit
100
MHz
fMAX2
Maximum Operating
Frequency
tCYC2
Clock Cycle Time
6.0
7.5
7.5
10
ns
tCH2
Clock HIGH Time
2.7
3.0
3.4
4.5
ns
tCL2
Clock LOW Time
2.7
3.0
3.4
4.5
ns
tR[25]
tF[25]
Clock Rise Time
tSA
Address Set-up Time
2.3
2.5
2.2
2.7
ns
tHA
Address Hold Time
0.6
0.6
1.0
1.0
ns
tSB
Byte Select Set-up Time
2.3
2.5
2.2
2.7
ns
tHB
Byte Select Hold Time
0.6
0.6
1.0
1.0
ns
tSC
Chip Enable Set-up Time
2.3
2.5
NA
NA
ns
tHC
Chip Enable Hold Time
0.6
0.6
NA
NA
ns
tSW
R/W Set-up Time
2.3
2.5
2.2
2.7
ns
tHW
R/W Hold Time
0.6
0.6
1.0
1.0
ns
tSD
Input Data Set-up Time
2.3
2.5
2.2
2.7
ns
tHD
Input Data Hold Time
0.6
0.6
1.0
1.0
ns
tSAD
ADS Set-up Time
2.3
2.5
NA
NA
ns
tHAD
ADS Hold Time
0.6
0.6
NA
NA
ns
tSCN
CNTEN Set-up Time
2.3
2.5
NA
NA
ns
tHCN
CNTEN Hold Time
0.6
0.6
NA
NA
ns
tSRST
CNTRST Set-up Time
2.3
2.5
NA
NA
ns
167
2.0
Clock Fall Time
Document #: 38-06069 Rev. *D
133
133
2.0
2.0
2.0
2.0
3.0
2.0
3.0
ns
ns
Page 12 of 26
CYD04S72V
CYD09S72V
CYD18S72V
PRELIMINARY
Switching Characteristics Over the Operating Range (continued)
-167
Parameter
Description
-133
-100
CYD04S72V
CYD09S72V
CYD04S72V
CYD09S72V
CYD18S72V
CYD18S72V
Min.
Min.
Min.
Min.
Max.
Max.
Max
Max
Unit
tHRST
CNTRST Hold Time
0.6
0.6
NA
NA
ns
tSCM
CNT/MSK Set-up Time
2.3
2.5
NA
NA
ns
tHCM
CNT/MSK Hold Time
0.6
0.6
NA
NA
ns
tOE
Output Enable to Data Valid
tOLZ
4.0
[26, 27]
OE to Low Z
0
[26, 27]
OE to High Z
0
tOHZ
4.4
0
4.0
0
5.5
0
4.4
0
5.5
0
5.5
0
ns
ns
5.5
ns
tCD2
Clock to Data Valid
4.0
4.4
5.0
5.2
ns
tCA2
Clock to Counter Address Valid
4.0
4.4
NA
NA
ns
tCM2
Clock to Mask Register
Readback Valid
4.0
4.4
NA
NA
ns
tDC
Data Output Hold After Clock
HIGH
1.0
tCKHZ[26, 27]
Clock HIGH to Output High Z
0
4.0
0
4.4
0
4.7
0
5.0
ns
tCKLZ[26, 27]
Clock HIGH to Output Low Z
1.0
4.0
1.0
4.4
1.0
4.7
1.0
5.0
ns
tSINT
Clock to INT Set Time
0.5
6.7
0.5
7.5
0.5
7.5
0.5
10
ns
tRINT
Clock to INT Reset Time
0.5
6.7
0.5
7.5
0.5
7.5
0.5
10
ns
tSCINT
Clock to CNTINT Set Time
0.5
5.0
0.5
5.7
NA
NA
NA
NA
ns
tRCINT
Clock to CNTINT Reset time
0.5
5.0
0.5
5.7
NA
NA
NA
NA
ns
1.0
1.0
1.0
ns
Port to Port Delays
tCCS
Clock to Clock Skew
5.2
6.0
5.7
8.0
ns
cycles
Master Reset Timing
tRS
Master Reset Pulse Width
5.0
5.0
5.0
5.0
tRSS
Master Reset Set-up Time
6.0
6.0
6.0
8.5
ns
tRSR
Master Reset Recovery Time
5.0
5.0
5.0
5.0
cycles
tRSF
Master Reset to Outputs
Inactive
10.0
10.0
10.0
10.0
ns
tRSCNTINT
Master Reset to Counter
Interrupt Flag Reset Time
10.0
10.0
NA
NA
ns
Notes:
24. Except INT and CNTINT which are 20pF
25. Except JTAG signal (tr and tf < 10ns max)
26. This parameter is guaranteed by design, but is not production tested
27. Test conditions used are Load 2
Document #: 38-06069 Rev. *D
Page 13 of 26
CYD04S72V
CYD09S72V
CYD18S72V
PRELIMINARY
JTAG Timing Characteristics
CYD04S72V
CYD09S72V
CYD18S72V
-167/-133/-100
Parameter
Description
Min.
Max.
Unit
10
MHz
fJTAG
Maximum JTAG TAP Controller Frequency
tTCYC
TCK Clock Cycle Time
100
ns
tTH
TCK Clock HIGH Time
40
ns
tTL
TCK Clock LOW Time
40
ns
tTMSS
TMS Set-up to TCK Clock Rise
10
ns
tTMSH
TMS Hold After TCK Clock Rise
10
ns
tTDIS
TDI Set-up to TCK Clock Rise
10
ns
tTDIH
TDI Hold After TCK Clock Rise
10
tTDOV
TCK Clock LOW to TDO Valid
tTDOX
TCK Clock LOW to TDO Invalid
ns
30
0
ns
ns
Switching Waveforms
tTH
Test Clock
TCK
tTMSS
tTL
tTCYC
tTMSH
Test Mode Select
TMS
tTDIS
tTDIH
Test Data-In
TDI
Test Data-Out
TDO
tTDOX
tTDOV
Document #: 38-06069 Rev. *D
Page 14 of 26
CYD04S72V
CYD09S72V
CYD18S72V
PRELIMINARY
Switching Waveforms (continued)
Master Reset
tRS
MRST
tRSF
ALL
ADDRESS/
DATA
LINES
tRSS
ALL
OTHER
INPUTS
tRSR
INACTIVE
ACTIVE
TMS
CNTINT
INT
TDO
Read Cycle[11, 28, 29, 30, 31]
tCH2
tCYC2
tCL2
CLK
CE
tSC
tHC
tSB
tHB
tSW
tSA
tHW
tHA
tSC
tHC
BE0–BE7
R/W
ADDRESS
An
DATAOUT
An+1
1 Latency
An+2
tDC
tCD2
Qn
tCKLZ
An+3
Qn+1
tOHZ
Qn+2
tOLZ
OE
tOE
Notes:
28. OE is asynchronously controlled; all other inputs (excluding MRST and JTAG) are synchronous to the rising clock edge.
29. ADS = CNTEN = LOW, and MRST = CNTRST = CNT/MSK = HIGH.
30. The output is disabled (high-impedance state) by CE = VIH following the next rising edge of the clock.
31. Addresses do not have to be accessed sequentially since ADS = CNTEN = VIL with CNT/MSK = VIH constantly loads the address on the rising edge of the CLK.
Numbers are for reference only.
Document #: 38-06069 Rev. *D
Page 15 of 26
CYD04S72V
CYD09S72V
CYD18S72V
PRELIMINARY
Switching Waveforms (continued)
Bank Select Read[32, 33]
tCH2
tCYC2
tCL2
CLK
tHA
tSA
ADDRESS(B1)
A0
A1
A3
A2
A4
A5
tHC
tSC
CE(B1)
tCD2
tHC
tSC
tCD2
tHA
tSA
A0
ADDRESS(B2)
tDC
A1
tDC
tCKLZ
A3
A2
tCKHZ
Q3
Q1
Q0
DATAOUT(B1)
tCD2
tCKHZ
A4
A5
tHC
tSC
CE(B2)
tSC
tCD2
tHC
DATAOUT(B2)
tCKHZ
tCD2
Q4
Q2
tCKLZ
tCKLZ
Read-to-Write-to-Read (OE = LOW)[31, 34, 35, 36, 37]
tCH2 tCYC2tCL2
CLK
CE
tSC
tHC
tSW
tHW
R/W
tSW
tHW
An
ADDRESS
tSA
An+1
An+2
An+2
An+3
tSD tHD
tHA
DATAIN
An+2
tCD2
tDC
tCKHZ
Dn+2
Qn
DATAOUT
READ
NO OPERATION
WRITE
Notes:
32. In this depth-expansion example, B1 represents Bank #1 and B2 is Bank #2; each bank consists of one Cypress FLEx72 device from this data sheet. ADDRESS(B1)
= ADDRESS(B2).
33. ADS = CNTEN= BE0 – BE7 = OE = LOW; MRST = CNTRST = CNT/MSK = HIGH.
34. Output state (HIGH, LOW, or high-impedance) is determined by the previous cycle control signals.
35. During “No Operation,” data in memory at the selected address may be corrupted and should be rewritten to ensure data integrity.
36. CE0 = OE = BE0 – BE7 = LOW; CE1 = R/W = CNTRST = MRST = HIGH.
37. CE0 = BE0 – BE7 = R/W = LOW; CE1 = CNTRST = MRST = CNT/MSK = HIGH. When R/W first switches low, since OE = LOW, the Write operation cannot be
completed (labelled as no operation). One clock cycle is required to three-state the I/O for the Write operation on the next rising edge of CLK.
Document #: 38-06069 Rev. *D
Page 16 of 26
CYD04S72V
CYD09S72V
CYD18S72V
PRELIMINARY
Switching Waveforms (continued)
Read-to-Write-to-Read (OE Controlled)[31, 34, 36, 37]
tCH2
tCYC2
tCL2
CLK
CE
tSC
tHC
tSW tHW
R/W
ADDRESS
tSW
tHW
An
tSA
An+1
An+2
tHA
An+3
An+4
An+5
tSD tHD
Dn+2
DATAIN
Dn+3
tCD2
DATAOUT
tCD2
Qn
Qn+4
tOHZ
OE
READ
Read with Address Counter
tCH2
WRITE
READ
Advance[36]
tCYC2
tCL2
CLK
tSA
ADDRESS
tHA
An
tSAD
tHAD
ADS
tSAD
tHAD
tSCN
tHCN
CNTEN
tSCN
DATAOUT
tHCN
Qx–1
READ
EXTERNAL
ADDRESS
Document #: 38-06069 Rev. *D
tCD2
Qx
tDC
Qn
READ WITH COUNTER
Qn+1
COUNTER HOLD
Qn+2
Qn+3
READ WITH COUNTER
Page 17 of 26
CYD04S72V
CYD09S72V
CYD18S72V
PRELIMINARY
Switching Waveforms (continued)
Write with Address Counter Advance [37]
tCH2
tCYC2
tCL2
CLK
tSA
tHA
An
ADDRESS
INTERNAL
ADDRESS
An
tSAD
tHAD
tSCN
tHCN
An+1
An+2
An+3
An+4
ADS
CNTEN
Dn
DATAIN
tSD
tHD
WRITE EXTERNAL
ADDRESS
Document #: 38-06069 Rev. *D
Dn+1
Dn+1
WRITE WITH
COUNTER
Dn+2
WRITE COUNTER
HOLD
Dn+3
Dn+4
WRITE WITH COUNTER
Page 18 of 26
CYD04S72V
CYD09S72V
CYD18S72V
PRELIMINARY
Switching Waveforms (continued)
Counter Reset [38, 39]
tCYC2
tCH2 tCL2
CLK
tSA
INTERNAL
ADDRESS
Ax
tSW
tHW
tSD
tHD
An
1
0
Ap
Am
An
ADDRESS
tHA
Ap
Am
R/W
ADS
CNTEN
tSRST tHRST
CNTRST
DATAIN
D0
tCD2
tCD2
[51]
DATAOUT
Q0
COUNTER
RESET
WRITE
ADDRESS 0
tCKLZ
READ
ADDRESS 0
READ
ADDRESS 1
Qn
Q1
READ
ADDRESS An
READ
ADDRESS Am
Notes:
38. CE0 = BE0 – BE7= LOW; CE1 = MRST = CNT/MSK = HIGH.
39. No dead cycle exists during counter reset. A Read or Write cycle may be coincidental with the counter reset.
Document #: 38-06069 Rev. *D
Page 19 of 26
CYD04S72V
CYD09S72V
CYD18S72V
PRELIMINARY
Switching Waveforms (continued)
Readback State of Address Counter or Mask Register[40, 41, 42, 43]
tCYC2
tCH2 tCL2
CLK
tCA2 or tCM2
tSA tHA
EXTERNAL
ADDRESS
A0–A17
An*
An
INTERNAL
ADDRESS
An+1
An
An+2
An+3
An+4
tSAD tHAD
ADS
tSCN tHCN
CNTEN
tCD2
DATAOUT
Qx-1
Qn
READBACK
COUNTER
INTERNAL
ADDRESS
INCREMENT
Qx-2
LOAD
EXTERNAL
ADDRESS
tCKHZ
tCKLZ
Qn+1
Qn+2
Qn+3
Notes:
40. CE0 = OE = BE0 – BE7 = LOW; CE1 = R/W = CNTRST = MRST = HIGH.
41. Address in output mode. Host must not be driving address bus after tCKLZ in next clock cycle.
42. Address in input mode. Host can drive address bus after tCKHZ.
43. An * is the internal value of the address counter (or the mask register depending on the CNT/MSK level) being Read out on the address lines.
Document #: 38-06069 Rev. *D
Page 20 of 26
CYD04S72V
CYD09S72V
CYD18S72V
PRELIMINARY
Switching Waveforms (continued)
Left_Port (L_Port) Write to Right_Port (R_Port) Read[44, 45, 46]
tCH2
tCYC2
tCL2
CLKL
tHA
tSA
L_PORT
ADDRESS
An
tSW
tHW
R/WL
tCKHZ
tSD
L_PORT
tCKLZ
Dn
DATAIN
CLKR
tHD
tCYC2
tCL2
tCCS
tCH2
R_PORT
ADDRESS
tSA
tHA
An
R/WR
tCD2
R_PORT
Qn
DATAOUT
tDC
Notes:
44. CE0 = OE = ADS = CNTEN = BE0 – BE7 = LOW; CE1 = CNTRST = MRST = CNT/MSK = HIGH.
45. This timing is valid when one port is writing, and other port is reading the same location at the same time. If tCCS is violated, indeterminate data will be Read out.
46. If tCCS < minimum specified value, then R_Port will Read the most recent data (written by L_Port) only (2 * tCYC2 + tCD2) after the rising edge of R_Port's clock.
If tCCS > minimum specified value, then R_Port will Read the most recent data (written by L_Port) (tCYC2 + tCD2) after the rising edge of R_Port's clock.
Document #: 38-06069 Rev. *D
Page 21 of 26
CYD04S72V
CYD09S72V
CYD18S72V
PRELIMINARY
Switching Waveforms (continued)
Counter Interrupt and Retransmit[47, 48, 49, 50, 51]
tCH2
tCYC2
tCL2
CLK
tSCM
tHCM
CNT/MSK
ADS
CNTEN
COUNTER
INTERNAL
ADDRESS
1FFFC
1FFFD
1FFFE
tSCINT
1FFFF
Last_Loaded
Last_Loaded +1
tRCINT
CNTINT
Notes:
47. CE0 = OE = BE0 – BE7 = LOW; CE1 = R/W = CNTRST = MRST = HIGH.
48. CNTINT is always driven.
49. CNTINT goes LOW when the unmasked portion of the address counter is incremented to the maximum value.
50. The mask register assumed to have the value of 1FFFFh.
51. Retransmit happens if the counter remains in increment mode after it wraps to initially loaded value.
Document #: 38-06069 Rev. *D
Page 22 of 26
CYD04S72V
CYD09S72V
CYD18S72V
PRELIMINARY
Mailbox Interrupt Timing[52,53,54,55,56]
tCH2
tCYC2
tCL2
CLKL
tSA
L_PORT
ADDRESS
tHA
3FFFF
An+1
An
An+2
An+3
tSINT
tRINT
INTR
tCH2
tCYC2
tCL2
CLKR
tSA
R_PORT
ADDRESS
tHA
Am+1
Am
3FFFF
Am+3
Am+4
Table 7. Read / Write and Enable Operation (Any Port) [1,14,57,58,59]
Inputs
OE
Outputs
Operation
CE0
CE1
R/W
DQ0 – DQ71
X
H
X
X
High-Z
Deselected
X
X
L
X
High-Z
Deselected
X
L
H
L
DIN
Write
L
L
H
H
DOUT
Read
L
H
X
High-Z
Outputs Disabled
H
CLK
X
Notes:
52. CE0 = OE = ADS = CNTEN = LOW; CE1 = CNTRST = MRST = CNT/MSK = HIGH.
53. Address “1FFFF” is the mailbox location for R_Port.
54. L_Port is configured for Write operation, and R_Port is configured for Read operation.
55. At least one byte enable (B0 – B3) is required to be active during interrupt operations.
56. Interrupt flag is set with respect to the rising edge of the Write clock, and is reset with respect to the rising edge of the Read clock.
57. OE is an asynchronous input signal.
58. When CE changes state, deselection and Read happen after one cycle of latency.
59. CE0 = OE = LOW; CE1 = R/W = HIGH.
Document #: 38-06069 Rev. *D
Page 23 of 26
CYD04S72V
CYD09S72V
CYD18S72V
PRELIMINARY
Ordering Information
256K × 72 (18Mb) 3.3V Synchronous CYD18S72V Dual-Port SRAM
Speed
(MHz)
Ordering Code
Package
Name
Package Type
Operating Range
133
CYD18S72V-133BBC
BB484
484-ball Grid Array
Commercial
23mm x 23mm with 1.0mm pitch (FBGA)
100
CYD18S72V-100BBC
BB484
484-ball Grid Array
Commercial
23mm x 23mm with 1.0mm pitch (FBGA)
CYD18S72V-100BBI
BB484
484-ball Grid Array
Industrial
23mm x 23mm with 1.0mm pitch (FBGA)
128K × 72 (9Mb) 3.3V Synchronous CYD09S72V Dual-Port SRAM
167
CYD09S72V-167BBC
BB484
484-ball Grid Array
Commercial
23mm x 23mm with 1.0mm pitch (FBGA)
133
CYD09S72V-133BBC
BB484
484-ball Grid Array
Commercial
23mm x 23mm with 1.0mm pitch (FBGA)
CYD09S72V-133BBI
BB484
484-ball Grid Array
Industrial
23mm x 23mm with 1.0mm pitch (FBGA)
64K x 72 (4Mb) 3.3 Synchronous CYD04S72V Dual-Port SRAM
167
CYD04S72V-167BBC
BB484
484-ball Grid Array
Commercial
23mm x 23mm with 1.0mm pitch (FBGA)
133
CYD04S72V-133BBC
BB484
484-ball Grid Array
Commercial
23mm x 23mm with 1.0mm pitch (FBGA)
CYD04S72V-133BBI
BB484
484-ball Grid Array
Industrial
23mm x 23mm with 1.0mm pitch (FBGA)
Document #: 38-06069 Rev. *D
Page 24 of 26
CYD04S72V
CYD09S72V
CYD18S72V
PRELIMINARY
Package Diagram
484-ball FBGA (23 mm × 23 mm × 1.9 mm) BB484
51-85124-*D
FLEx72 is a trademark of Cypress Semiconductor. All product and company names mentioned in this document are the
trademarks of their respective holders.
Document #: 38-06069 Rev. *D
Page 25 of 26
© Cypress Semiconductor Corporation, 2004. The information contained herein is subject to change without notice. Cypress Semiconductor Corporation assumes no responsibility for the use
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.
PRELIMINARY
CYD04S72V
CYD09S72V
CYD18S72V
Document History Page
Document Title: FLEx72™ 3.3V 64K/128K/256K x 72 Synchronous Dual-Port RAM
Document Number: 38-06069
REV.
ECN NO.
Issue
Date
Orig. of
Change
Description of Change
**
125859
06/17/03
SPN
New Data Sheet
*A
128707
08/01/03
SPN
Added -133 speed bin
Updated spec values for ICC, tHA, tHB, tHW, tHD
Added new parameter ICC1
Added bank select read and read to write to read (OE=low) timing diagrams
*B
128997
09/18/03
SPN
Updated spec values for tOE, tOHZ, tCH2, tCL2, tHA, tHB, tHW, tHD, ICC, ISB5, tSA,
tSB,tSW,tSD, tCD2
Updated read to write (OE=low) timing diagram
Updated Master Reset values for tRS, tRSR, tRSF
Updated pinout
Updated VCORE voltage range
*C
129936
09/30/03
SPN
Updated Package Diagram
Updated tCD2 value on first page
Removed Preliminary Status
*D
233830
See ECN
WWZ
Added 4M and 9M x72 devices into the datasheet with updated pinout, pin
description table, power table, and timing table.
Changed the title and Added back Preliminary status to reflect the addition
of 4M and 9M devices.
Removed FLEX72-E word from the document.
Added counter related functions for 4M and 9M.
Removed standard JTAG description.
Updated block diagram.
Updated pinout with FTSEL and one more PORTSTD pins per port.
Updated tRSF of CYD18S72V value.
Document #: 38-06069 Rev. *D
Page 26 of 26