CYPRESS CY7C04312BV

CY7C0430BV
CY7C04312BV
CY7C04314BV
10 Gb/s 3.3V QuadPort™
DSE Family
Features
• QuadPort™ datapath switching element (DSE) family
allows four independent ports of access for data path
management and switching
• High-bandwidth data throughput up to 10 Gb/s
• 133-MHz[1] port speed x 18-bit-wide interface × 4 ports
• High-speed clock to data access 4.2 ns (max.)
• Synchronous pipelined devices
— 1-Mb, ½-Mb, and ¼-Mb switch arrays
— 64K/32K/16K × 18 device options
• 0.25-micron CMOS for optimum speed/power
• IEEE 1149.1 JTAG boundary scan
• Width and depth expansion capabilities
• BIST (Built-In Self-Test) controller
• Dual Chip Enables on all ports for easy depth expansion
• Separate upper-byte and lower-byte controls on all
ports
• Simple array partitioning (CY7C0430BV only)
— Internal mask register controls counter wrap-around
— Counter-Interrupt flags to indicate wrap-around
— Counter and mask registers readback on address
• 272-ball BGA package (27-mm × 27-mm × 1.27-mm ball
pitch)
• Commercial and industrial temperature ranges
• 3.3V low operating power
— Active = 750 mA (maximum)
— Standby = 15 mA (maximum
QuadPort DSE Family Applications
PORT 1
PORT 3
PORT 2
PORT 4
BUFFERED SWITCH
PORT 2
PORT 1
PORT 3
PORT 4
REDUNDANT DATA MIRROR
Note:
1. fMAX2 for commercial is 135 MHz and for industrial is 133 MHz.
Cypress Semiconductor Corporation
Document #: 38-06027 Rev. *A
•
3901 North First Street
•
San Jose
•
CA 95134 • 408-943-2600
Revised May 14, 2002
CY7C0430BV
CY7C04312BV
CY7C04314BV
PORT 1
PORT 2
PORT 4
PORT 3
DATA PATH AGGREGATOR
Processor 1
Pre-processed DATA Path
QuadPort
DSE Family
Processed DATA Path
Processor 2
DATA PATH MANAGER FOR
PARALLEL PACKET PROCESSING
Queue #1
PORT 1
PORT 3
Queue #2
PORT 2
PORT 4
DATA CLASSIFICATION ENGINE
Functional Description
The CY7C043XXBV is a family of 10 Gb/s, true four-ported
Datapath Switching Elements with port speeds of up to
133 MHz[1]. The members of the family include 1-Mb
(64K ×18), ½-Mb (32K x18), and ¼-Mb (16K × 18) options. All
four ports may be clocked at independent frequencies from
one another. Simultaneous reads are allowed for accesses to
the same address location; however, simultaneous reading
and writing to the same address is not allowed. Any port can
write to a certain location while other ports are reading that
location simultaneously, if the timing spec for port to port delay
(tCCS) is met. The result of writing to the same location by more
than one port at the same time is undefined.
Data is registered for decreased cycle time. Clock to data valid
tCD2 = 4.2 ns. Each port contains a burst counter on the input
Document #: 38-06027 Rev. *A
address register. After externally loading the counter with the
initial address the counter will self-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.
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 is required with chip enables asserted
to reactivate the outputs.
The CY7C0430BV (64K × 18 device) is the only member of
the family which contains burst contains for simple array partitioning. Counter enable 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
Page 2 of 37
CY7C0430BV
CY7C04312BV
CY7C04314BV
applications. A port’s burst counter is loaded with an external
address when the port’s Counter Load pin (CNTLD) is
asserted LOW. When the port’s Counter Increment pin
(CNTINC) is asserted, the address counter will increment on
each subsequent LOW-to- HIGH transition of that port’s clock
signal. This will read/write one word from/into each successive
address location until CNTINC is deasserted. The counter can
address the entire switch array and will loop back to the start.
Counter Reset (CNTRST) is used to reset the burst counter.
A counter-mask register is used to control the counter wrap.
The counter and mask register operations are described in
more details in the following sections.
The counter or mask register values can be read back on the
bidirectional address lines by activating MKRD or CNTRD,
respectively.
The new features included for the QuadPort DSE family
include: readback of burst-counter internal address value on
address lines, counter-mask registers to control the counter
wrap-around, readback of mask register value on address
lines, interrupt flags for message passing, BIST, JTAG for
boundary scan, and asynchronous Master Reset.
Top Level Logic Block Diagram
Port 1 Operation-control Logic Blocks[2]
Reset
Logic
MRST
UBP1
LBP1
Port-1
Control
Logic
R/WP1
OEP1
CE0P1
TMS
JTAG
Controller
TCK
TDI
CE1P1
CLKBIST
TDO
BIST
CLKP1
18
Port 1
I/O
I/O0P1- I/O17P1
CLKP1
A0P1–A15P1
MKLDP1
[4]
[4]
CNTLDP1
[4]
CNTINCP1
[4]
CNTRDP1
[4]
MKRDP1
[4]
Port 4 Logic Blocks[3]
16
Port 1
Counter/
Mask Reg/
Address
Decode
CNTRSTP1
INTP1
[4]
CNTINTP1
Port 1
16K/32K/64K × 18
QuadPort DSE
Array
Port 2
Port 2 Logic Blocks[3]
Port 4
Port 3
Port 3 Logic Blocks[3]
Notes:
2. Port 1 Control Logic Block is detailed on page 4.
3. Port 2, Port 3, and Port 4 Logic Blocks are similar to Port 1 Logic Blocks.
4. Counter functionality applies only to CY7C0430BV (64K × 18) device option. These pins are either GND or NC for CY7C04312BV and CY7C04314BV.
Document #: 38-06027 Rev. *A
Page 3 of 37
CY7C0430BV
CY7C04312BV
CY7C04314BV
Port 1 Operation-Control Logic Block Diagram
(Address Readback is independent of CEs)
R/WP1
W
UBP1
CE0P1
CE1P1
LBP1
OEP1
I/O9P1–I/O17P1
I/O0P1–I/O8P1
9
Port-1
I/O
Control
9
Addr.
Read
Port 1
Readback
Register
MRST
16
t1
Port 1
Address
Decision
Logic
MRST
CNTINTP1[4]
Document #: 38-06027 Rev. *A
Decode
LBP1
UBP1
R/WP1
CE0P1
CE1P1
OEP1
CLKP1
MRST
2
CLKP1
Port 1
Counter/
Address
Register
16K/32K/64K × 18
QuadPort
DSE Array
Po
rt
3
Priority
rt
Po
MKLDP1[4]
CNTINCP1[4]
CNTLDP1[4]
CNTRSTP1[4]
4
CNTRDP1[4]
MKRDP1[4]
rt
Po
Port 1
Mask Register
Po
r
A0P1–A15P1
Port 1
Interrupt
Logic
INTP1
Page 4 of 37
CY7C0430BV
CY7C04312BV
CY7C04314BV
Pin Configuration
272-ball Grid Array (BGA)
Top View
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
A
LB
P1
I/O17
P2
I/O15
P2
I/O13
P2
I/O11
P2
I/O9
P2
I/O16
P1
I/O14
P1
I/O12
P1
I/O10
P1
I/O10
P4
I/O12
P4
I/O14
P4
I/O16
P4
I/O9
P3
I/O11
P3
I/O13
P3
I/O15
P3
I/O17
P3
LB
P4
B
VDD1
UB
P1
I/O16
P2
I/O14
P2
I/O12
P2
I/O10
P2
I/O17
P1
I/O13
P1
I/O11
P1
TMS
TDI
I/O11
P4
I/O13
P4
I/O17
P4
I/O10
P3
I/O12
P3
I/O14
P3
I/O16
P3
UB
P4
VDD1
C
A14
P1[9]
A15
P1[8]
CE1
P1
CE0
P1
R/W
P1
I/O15
P1
VSS2
VSS2
I/O9
P1
TCK
TDO
I/O9
P4
VSS2
VSS2
I/O15
P4
R/W
P4
CE0
P4
CE1
P4
A15
P4[8]
A14
P4[9]
D
VSS1
A12
P1
A13
P1
OE
P1
VDD2
VSS2
VSS2
VDD2
VDD
VSS
VSS
VDD
VDD2
VSS2
VSS2
VDD2
OE
P4
A13
P4
A12
P4
VSS1
E
A10
P1
A11
P1
MKRD
P1
CNTRD
P1[6]
CNTRD
P4 [6]
MKRD
P4
A11
P4
A10
P4
F
A7
P1
A8
P1
A9
P1
CNTINT
P1[7]
CNTINT
P4[7]
A9
P4
A8
P4
A7
P4
G
VSS1
A5
P1
A6
P1
CNTINC
P1[6]
CNTINC
P4[6]
A6
P4
A5
P4
VSS1
H
A3
P1
A4
P1
MKLD
P1
CNTLD
P1[6]
CNTLD
P4[6]
MKLD
P4[6]
A4
P4
A3
P4
J
VDD1
A1
P1
A2
P1
VDD
GND[5]
GND[5]
GND[5]
GND[5]
VDD
A2
P4
A1
P4
VDD1
K
A0
P1
INT
P1
CNTRST
P1[6]
CLK
P1
GND[5]
GND[5]
GND[5]
GND[5]
CLK
P4
CNTRST
P4[6]
INT
P4
A0
P4
L
A0
P2
INT
P2
CNTRST
P2[6]
VSS
GND[5]
GND[5]
GND[5]
GND[5]
VSS
CNTRST
P3[6]
INT
P3
A0
P3
M
VDD1
A1
P2
A2
P2
CLK
P2
GND[5]
GND[5]
GND[5]
GND[5]
CLK
P3
A2
P3
A1
P3
VDD1
N
A3
P2
A4
P2
MKLD
P2
CNTLD
P2[6]
CNTLD
P3[6]
MKLD
P3[6]
A4
P3
A3
P3
P
VSS1
A5
P2
A6
P2
CNTINC
P2[6]
CNTINC
P3[6]
A6
P3
A5
P3
VSS1
R
A7
P2
A8
P2
A9
P2
CNTINT
P2[7]
CNTINT
P3[7]
A9
P3
A8
P3
A7
P3
T
A10
P2
A11
P2
MKRD
P2
CNTRD
P2[6]
CNTRD
P3[6]
MKRD
P3[6]
A11
P3
A10
P3
U
VSS1
A12
P2
A13
P2
OE
P2
VDD2
VSS2
VSS2
VDD2
VDD
VSS
VSS
VDD
VDD2
VSS2
VSS2
VDD2
OE
P3
A13
P3
A12
P3
VSS1
V
A14
P2[9]
A15
P2[8]
CE1
P2
CE0
P2
R/W
P2
I/O6
P2
VSS2
VSS2
I/O0
P2
NC
NC
I/O0
P3
VSS2
VSS2
I/O6
P3
R/W
P3
CE0
P3
CE1
P3
A15
P3[8]
A14
P3[9]
W
VDD1
UB
P2
I/O7
P1
I/O5
P1
I/O3
P1
I/O1
P1
I/O8
P2
I/O4
P2
I/O2
P2
MRST
CLKBIST
I/O2
P3
I/O4
P3
I/O8
P3
I/O1
P4
I/O3
P4
I/O5
P4
I/O7
P4
UB
P3
VDD1
Y
LB
P2
I/O8
P1
I/O6
P1
I/O4
P1
I/O2
P1
I/O0
P1
1/O7
P2
I/O5
P2
I/O3
P2
I/O1
P2
I/O1
P3
I/O3
P3
I/O5
P3
I/O7
P3
I/O0
P4
I/O2
P4
I/O4
P4
I/O6
P4
I/O8
P4
LB
P3
Notes:
5.
6.
7.
8.
9.
Central Leads are for thermal dissipation only. They are connected to device VSS.
Pin is VSS for CY7C04312BV and CY7C04314BV devices.
Pin is NC for CY7C04312BV and CY7C04314BV devices.
Pin is VSS for CY7C04312BV and CY7C04314BV devices.
Pin is VSS for CY7C04314BV devices.
Document #: 38-06027 Rev. *A
Page 5 of 37
CY7C0430BV
CY7C04312BV
CY7C04314BV
Selection Guide
fMAX2
CY7C04312BV
-133
CY7C04312BV
-100
Unit
133[1]
100
MHz
Max Access Time (Clock to Data)
4.2
5.0
ns
Max Operating Current ICC
750
600
mA
Max Standby Current for ISB1 (All ports TTL Level)
200
150
mA
Max Standby Current for ISB3 (All ports CMOS Level)
15
15
mA
Pin Definitions
Port 1
Port 2
Port 3
Port 4
Description
A0P1–A15P1
A0P2–A15P2
A0P3–A15P3
A0P4–A15P4
Address Input/Output.
I/O0P1–I/O17P1
I/O0P2–I/O17P2
I/O0P3–I/O17P3
I/O0P4–I/O17P4
Data Bus Input/Output.
CLKP1
CLKP2
CLKP3
CLKP4
Clock Input. This input can be free running or strobed.
Maximum clock input rate is fMAX.
LBP1
LBP2
LBP3
LBP4
Lower Byte Select Input. Asserting this signal LOW
enables read and write operations to the lower byte. For
read operations both the LB and OE signals must be
asserted to drive output data on the lower byte of the data
pins.
UBP1
UBP2
UBP3
UBP4
Upper Byte Select Input. Same function as LB, but to
the upper byte.
CE0P1,CE1P1
CE0P2,CE1P2
CE0P3,CE1P3
CE0P4,CE1P4
Chip Enable Input. To select any port, both CE0 AND
CE1 must be asserted to their active states (CE0 ≤ VIL
and CE1 ≥ VIH).
OEP1
OEP2
OEP3
OEP4
Output Enable Input. This signal must be asserted LOW
to enable the I/O data lines during read operations. OE
is asynchronous input.
R/WP1
R/WP2
R/WP3
R/WP4
Read/Write Enable Input. This signal is asserted LOW
to write to the dual port memory array. For read operations, assert this pin HIGH.
MRST
Master Reset Input. This is one signal for All Ports.
MRST is an asynchronous input. Asserting MRST LOW
performs all of the reset functions as described in the text.
A MRST operation is required at power-up.
CNTRSTP1[6]
CNTRSTP2[6]
CNTRSTP3[6]
CNTRSTP4[6]
Counter Reset Input. Asserting this signal LOW resets
the burst address counter of its respective port to zero.
CNTRST is second to MRST in priority with respect to
counter and mask register operations.
MKLDP1[6]
MKLDP2[6]
MKLDP3[6]
MKLDP4[6]
Mask Register Load Input. Asserting this signal LOW
loads the mask register with the external address
available on the address lines. MKLD operation has
higher priority over CNTLD operation.
CNTLDP1[6]
CNTLDP2[6]
CNTLDP3[6]
CNTLDP4[6]
Counter Load Input. Asserting this signal LOW loads
the burst counter with the external address present on
the address pins.
CNTINCP1[6]
CNTINCP2[6]
CNTINCP3[6]
CNTINCP4[6]
Counter Increment Input. Asserting this signal LOW
increments the burst address counter of its respective
port on each rising edge of CLK.
Document #: 38-06027 Rev. *A
Page 6 of 37
CY7C0430BV
CY7C04312BV
CY7C04314BV
Pin Definitions (continued)
Port 1
Port 2
Port 3
CNTRDP1[6]
CNTRDP2[6]
CNTRDP3
MKRDP1[6]
MKRDP2[6]
CNTINTP1[7]
INTP1
[6]
Port 4
Description
CNTRDP4[6]
Counter Readback Input. When asserted LOW, the
internal address value of the counter will be read back on
the address lines. During CNTRD operation, both
CNTLD and CNTINC must be HIGH. Counter readback
operation has higher priority over mask register readback
operation. Counter readback operation is independent of
port chip enables. If address readback operation occurs
with chip enables active (CE0 = LOW, CE1 = HIGH), the
data lines (I/Os) will be three-stated. The readback timing
will be valid after one no-operation cycle plus tCD2 from
the rising edge of the next cycle.
MKRDP3[6]
MKRDP4[6]
Mask Register Readback Input. When asserted LOW,
the value of the mask register will be readback on
address lines. During mask register readback operation,
all counter and MKLD inputs must be HIGH (see Counter
and Mask Register Operations truth table). Mask register
readback operation is independent of port chip enables.
If address readback operation occurs with chip enables
active (CE0 = LOW, CE1 = HIGH), the data lines (I/Os)
will be three-stated. The readback will be valid after one
no-operation cycle plus tCD2 from the rising edge of the
next cycle.
CNTINTP2[7]
CNTINTP3[7]
CNTINTP4[7]
Counter Interrupt Flag Output. Flag is asserted LOW
for one clock cycle when the counter wraps around to
location zero.
INTP2
INTP3
INTP4
Interrupt Flag Output. Interrupt permits communications between all four ports. The upper four memory
locations can be used for message passing. Example of
operation: INTP4 is asserted LOW when another port
writes to the mailbox location of Port 4. Flag is cleared
when Port 4 reads the contents of its mailbox. The same
operation is applicable to ports 1, 2, and 3.
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.
TCK
JTAG Test Clock Input. This can be CLK of any port or
an external clock connected to the JTAG TAP.
TDI
JTAG Test Data Input. This is the only data input. TDI
inputs will shift data serially in to the selected register.
TDO
JTAG Test Data Output. This is the only data output.
TDO transitions occur on the falling edge of TCK. TDO
normally three-stated except when captured data is
shifted out of the JTAG TAP.
CLKBIST
BIST Clock Input.
GND
Thermal Ground for Heat Dissipation.
VSS
Ground Input.
VDD
Power Input.
VSS1
Address Lines Ground Input.
VDD1
Address Lines Power Input.
VSS2
Data Lines Ground Input.
VDD2
Data Lines Power Input.
Document #: 38-06027 Rev. *A
Page 7 of 37
CY7C0430BV
CY7C04312BV
CY7C04314BV
Maximum Ratings
Output Current into Outputs (LOW)............................. 20 mA
(Above which the useful life may be impaired. For user guidelines, not tested.)
Static Discharge Voltage .......................................... > 2200V
Storage Temperature ................................ –65°C to + 150°C
Latch-up Current..................................................... > 200 mA
Ambient Temperature with
Power Applied............................................–55°C to + 125°C
Operating Range
Supply Voltage to Ground Potential .............. –0.5V to + 4.6V
Range
DC Voltage Applied to
Outputs in High-Z State .........................–0.5V to VCC + 0.5V
Commercial
Ambient Temperature
Industrial
DC Input Voltage....................................–0.5V to VCC + 0.5V
VDD
0°C to +70°C
3.3V ± 150 mV
–40°C to +85°C
3.3V ± 150 mV
Electrical Characteristics Over the Operating Range
CY7C043XXBV
-133
Parameter
Description
Min.
Typ.
-100
Max.
2.4
Min.
Typ.
Max.
Unit
2.4
VOH
Output HIGH Voltage
(VCC = Min., IOH = –4.0 mA)
VOL
Output LOW Voltage
(VCC = Min., IOH = +4.0 mA)
VIH
Input HIGH Voltage
VIL
Input LOW Voltage
IOZ
Output Leakage Current
ICC
Operating Current (VCC = Max., IOUT = 0 mA)
Outputs Disabled, CE = VIL, f = fmax
350
700
ISB1
Standby Current (four ports toggling at TTL
Levels,0 active)
CE1-4 ≥ VIH, f = fMAX
80
ISB2
Standby Current (four ports toggling at TTL
Levels, 1 active) CE1 | CE2 | CE3 | CE4 < VIL,
f = fMAX
ISB3
ISB4
V
0.4
2.0
0.4
V
2.0
V
0.8
0.8
V
10
µA
300
550
mA
200
60
150
mA
150
300
125
250
mA
Standby Current (four ports CMOS Level, 0
active) CE1–4 ≥ VIH, f = 0
1.5
15
1.5
15
mA
Standby Current (four ports CMOS Level, 1
active and toggling) CE1 | CE2 | CE3 | CE4 <
VIL, f = fMAX
110
290
85
240
mA
–10
10
–10
JTAG TAP Electrical Characteristics Over the Operating Range
Parameter
Description
Test Conditions
VOH1
Output HIGH Voltage
IOH = −4.0 mA
VOL1
Output LOW Voltage
IOL = 4.0 mA
VIH
Input HIGH Voltage
VIL
Input LOW Voltage
IX
Input Leakage Current
Min.
Max.
Unit
2.4
V
0.4
V
2.0
GND ≤ VI ≤ VDD
V
–100
0.8
V
100
µA
Capacitance
Parameter
Description
CIN (All Pins)
Input Capacitance
COUT (All Pins)
Output Capacitance
CIN (CLK Pins)
Input Capacitance
COUT (CLK Pins)
Output Capacitance
Document #: 38-06027 Rev. *A
Test Conditions
TA = 25°C, f = 1 MHz,
VCC = 3.3V
Max.
Unit
10
pF
10
pF
15
pF
15
pF
Page 8 of 37
CY7C0430BV
CY7C04312BV
CY7C04314BV
AC Test Load
Z0 = 50Ω
OUTPUT
R = 50Ω
OUTPUT
C [10]
Z0 = 50Ω
R = 50Ω
5 pF
VTH = 1.5V
VTH = 1.5V
(a) Normal Load
OUTPUT
Z0 = 50Ω
R = 50Ω
5 pF
VTH = 3.3V
1.5V
(b) Three-State Delay
50Ω
TDO
Z0 =50Ω
C = 10 pF
3.0V
GND
10%
90%
GND
tF
tR
(c) TAP Load
90%
10%
All Input Pulses
Note:
10. Test conditions: C = 10 pF.
Document #: 38-06027 Rev. *A
Page 9 of 37
CY7C0430BV
CY7C04312BV
CY7C04314BV
Switching Characteristics Over the Industrial Operating Range
[11]
CY7C04312BV
-133
Parameter
Description
Min.
-100
Max.
Min.
Max.
Unit
100
MHz
fMAX2[12]
tCYC2[12]
Maximum Frequency
Clock Cycle Time
7.5
10
ns
tCH2
Clock HIGH Time
3
4
ns
tCL2
Clock LOW Time
3
4
ns
tR
Clock Rise Time
2
3
ns
tF
Clock Fall Time
2
3
ns
tSA
Address Set-up Time
2.3
3
ns
tHA
Address Hold Time
0.7
0.7
ns
tSC
Chip Enable Set-up Time
2.3
3
ns
tHC
Chip Enable Hold Time
0.7
0.7
ns
tSW
R/W Set-up Time
2.3
3
ns
tHW
R/W Hold Time
0.7
0.7
ns
tSD
Input Data Set-up Time
2.3
3
ns
tHD
Input Data Hold Time
0.7
0.7
ns
tSB
Byte Set-up Time
2.3
3
ns
tHB
Byte Hold Time
0.7
0.7
ns
tSCLD
CNTLD Set-up Time
2.3
3
ns
tHCLD
CNTLD Hold Time
0.7
0.7
ns
tSCINC
CNTINC Set-up Time
2.3
3
ns
tHCINC
CNTINC Hold Time
0.7
0.7
ns
tSCRST
CNTRST Set-up Time
2.3
3
ns
tHCRST
CNTRST Hold Time
0.7
0.7
ns
tSCRD
CNTRD Set-up Time
2.3
3
ns
tHCRD
CNTRD Hold Time
0.7
0.7
ns
tSMLD
MKLD Set-up Time
2.3
3
ns
tHMLD
MKLD Hold Time
0.7
0.7
ns
tSMRD
MKRD Set-up Time
2.3
3
ns
tHMRD
MKRD Hold Time
0.7
0.7
ns
tOE
Output Enable to Data Valid
tOLZ[13]
OE to Low-Z
1
[13]
OE to High-Z
1
tOHZ
133
6.5
8
1
6
1
4.2
ns
ns
7
ns
5
ns
tCD2
Clock to Data Valid
tCA2
Clock to Counter Address Readback Valid
4.7
5
ns
tCM2
Clock to Mask Register Readback Valid
4.7
5
ns
tDC
Data Output Hold After Clock HIGH
1
tCKHZ[14]
Clock HIGH to Output High-Z
1
6.8
ns
tCKLZ[14]
Clock HIGH to Output Low-Z
1
1
4.8
1
1
ns
ns
Notes:
11. If data is simultaneously written and read to the same address location and tCCS is violated, the data read from the address, as well as the subsequent data
remaining in the address is undefined.
12. fMAX2 for commercial is 135 MHz. tCYC2 Min. for commercial is 7.4 ns.
13. This parameter is guaranteed by design, but it is not production tested.
14. Valid for both address and data outputs.
Document #: 38-06027 Rev. *A
Page 10 of 37
CY7C0430BV
CY7C04312BV
CY7C04314BV
Switching Characteristics Over the Industrial Operating Range (continued)[11]
CY7C04312BV
-133
Parameter
Description
-100
Min.
Max.
Min.
Max.
Unit
1
7.5
1
10
ns
tSINT
Clock to INT Set Time
tRINT
Clock to INT Reset Time
1
7.5
1
10
ns
tSCINT
Clock to CNTINT Set Time
1
7.5
1
10
ns
tRCINT
Clock to CNTINT Reset Time
1
7.5
1
10
ns
Master Reset Timing
tRS
Master Reset Pulse Width
7.5
10
ns
tRSR
Master Reset Recovery Time
7.5
10
ns
tROF
Master Reset to Output Flags Reset Time
6.5
8
ns
Port to Port Delays
tCCS[11]
Clock to Clock Set-up Time (time required after a write
before you can read the same address location)
6.5
9
ns
JTAG Timing and Switching Waveforms
CY7C043XXBV
–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
20
ns
tTMSH
TMS Hold After TCK Clock Rise
20
ns
tTDIS
TDI Set-up to TCK Clock Rise
20
ns
tTDIH
TDI Hold after TCK Clock Rise
20
tTDOV
TCK Clock Low to TDO Valid
tTDOX
TCK Clock Low to TDO Invalid
fBIST
Maximum CLKBIST Frequency
tBH
CLKBIST High Time
6
ns
tBL
CLKBIST Low Time
6
ns
Document #: 38-06027 Rev. *A
ns
20
ns
50
MHz
0
ns
Page 11 of 37
CY7C0430BV
CY7C04312BV
CY7C04314BV
tTH
tTL
Test Clock
TCK
tTCYC
tTMSH
tTMSS
Test Mode Select
TMS
tTDIS
tTDIH
Test Data-In
TDI
Test Data-Out
TDO
tTDOX
tTDOV
Switching Waveforms
Master Reset[15]
tCH2
tCYC2
tCL2
CLK
tRS
MRST
ALL
ADDRESS/
DATA
LINES
tRSF
ALL
OTHER
INPUTS
tRSR
INACTIVE
tS
ACTIVE
TMS[16]
CNTINT
INT
TDO
Notes:
15. tS is the set-up time required for all input control signals.
16. To Reset the test port without resetting the device, TMS must be held low for five clock cycles.
Document #: 38-06027 Rev. *A
Page 12 of 37
CY7C0430BV
CY7C04312BV
CY7C04314BV
Switching Waveforms (continued)
Read Cycle[17, 18, 19, 20, 21]
tCYC2
tCH2
tCL2
CLK
CE
tSC
tHC
tSB
tHB
tSW
tSA
tHW
tHA
tSC
tHC
LB
UB
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:
17. OE is asynchronously controlled; all other inputs (excluding MRST) are synchronous to the rising clock edge.
18. CNTLD = VIL, MKLD = VIH, CNTINC = x, and MRST = CNTRST = VIH.
19. The output is disabled (high-impedance state) by CE = VIH following the next rising edge of the clock.
20. Addresses do not have to be accessed sequentially. Note 18 indicates that address is constantly loaded on the rising edge of the CLK. Numbers are for reference
only.
21. CE is internal signal. CE = VIL if CE0 = VIL and CE1 = VIH.
Document #: 38-06027 Rev. *A
Page 13 of 37
CY7C0430BV
CY7C04312BV
CY7C04314BV
Switching Waveforms (continued)
Bank Select Read[22, 23]
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
tCKHZ
Q3
Q1
Q0
DATAOUT(B1)
tCD2
tCKHZ
tDC
tCKLZ
A3
A2
A4
A5
tHC
tSC
CE(B2)
tSC
tCD2
tHC
DATAOUT(B2)
tCKHZ
tCD2
Q4
Q2
tCKLZ
tCKLZ
Read-to-Write-to-Read (OE = VIL)[24, 25, 26, 27]
tCH2
tCYC2
tCL2
CLK
CE
tSC
tHC
tSW
tHW
R/W
tSW
tHW
An
ADDRESS
tSA
An+1
An+2
An+2
tHA
DATAIN
An+3
An+4
tSD tHD
tCD2
tCKHZ
Dn+2
tCD2
Qn
DATAOUT
Qn+3
tCKLZ
Read
No Operation
Write
Read
Notes:
22. In this depth expansion example, B1 represents Bank #1 and B2 is Bank #2; Each bank consists of one QuadPort DSE device from this data sheet.
ADDRESS(B1) = ADDRESS(B2).
23. LB = UB = OE = CNTLD = VIL; MRST = CNTRST= MKLD = VIH.
24. Output state (HIGH, LOW, or high-impedance) is determined by the previous cycle control signals.
25. LB = UB = CNTLD = VIL; MRST = CNTRST = MKLD = VIH.
26. Addresses do not have to be accessed sequentially since CNTLD = VIL constantly loads the address on the rising edge of the CLK; numbers are for reference only.
27. During “No Operation,” data in memory at the selected address may be corrupted and should be rewritten to ensure data integrity.
Document #: 38-06027 Rev. *A
Page 14 of 37
CY7C0430BV
CY7C04312BV
CY7C04314BV
Switching Waveforms (continued)
Read-to-Write-to-Read (OE Controlled)[24, 25, 26, 27]
tCH2
tCYC2
tCL2
CLK
CE
tSC
tHC
tSW tHW
R/W
tSW
tHW
An
An+1
An+2
An+3
An+4
An+5
ADDRESS
tSA
tHA
tSD tHD
Dn+2
DATAIN
Dn+3
tCD2
tCD2
DATAOUT
Qn
Qn+4
tOHZ
tCKLZ
OE
Read
Write
Read
Read with Address Counter Advance[28, 29]
tCH2
tCYC2
tCL2
CLK
tSA
ADDRESS
tHA
An
tSCLD
tHCLD
CNTLD
tSCINC
tHCINC
CNTINC
tCD2
DATAOUT
Qx–1
Qx
Read
External
Address
Qn
tDC
Read with Counter
Qn+1
Qn+2
Counter Hold
Qn+3
Read with Counter
Notes:
28. CE0 = OE = LB = UB = VIL; CE1 = R/W = CNTRST = MRST = MKLD = MKRD = CNTRD = VIH.
29. The “Internal Address” is equal to the “External Address” when CNTLD = VIL.
Document #: 38-06027 Rev. *A
Page 15 of 37
CY7C0430BV
CY7C04312BV
CY7C04314BV
Switching Waveforms (continued)
Write with Address Counter Advance [29, 30, 31]
tCH2
tCYC2
tCL2
CLK
tSA
tHA
An
ADDRESS
INTERNAL
ADDRESS
An
tSCLD
tHCLD
tSCINC
tHCINC
An+1
An+2
An+3
An+4
CNTLD
CNTINC
Dn
DATAIN
tSD
tHD
Write External
Address
Dn+1
Dn+1
Write with
Counter
Dn+2
Write Counter
Hold
Dn+3
Dn+4
Write with Counter
Notes:
30. CE0 = LB = UB = R/W = VIL; CE1 = CNTRST = MRST = MKLD = MKRD = CNTRD = VIH.
31. Counter operation is only available on the CY7C0430BV. The CY7C04312BV and CY7C04314BV do not support the counter functions.
Document #: 38-06027 Rev. *A
Page 16 of 37
CY7C0430BV
CY7C04312BV
CY7C04314BV
Switching Waveforms (continued)
Counter Reset [26, 31, 32, 33]
tCH2
tCYC2
tCL2
CLK
tSA
An
ADDRESS
INTERNAL
ADDRESS
tHA
AX
A0
tSW
An+1
A1
An
An+1
tHW
R/W
tHCLD
tSCLD
CNTLD
CNTINC
tSCRST
An+2
tHCRST
CNTRST
tSD
DATAIN
tHD
D0
DATAOUT
Q0
Counter
Reset
Write
Address 0
Read
Address 0
Read
Address 1
Q1
Qn
Read
Address n
Notes:
32. CE0 = LB = UB = VIL; CE1 = MRST = MKLD = MKRD = CNTRD = VIH.
33. No dead cycle exists during counter reset. A Read or Write cycle may be coincidental with the counter reset.
Document #: 38-06027 Rev. *A
Page 17 of 37
CY7C0430BV
CY7C04312BV
CY7C04314BV
Switching Waveforms (continued)
Load and Read Address Counter[31, 34]
tCH2
tCYC2
tCL2
Note 35
CLK
tHA
tSA
A0-A15
tCKLZ
Note 36
tCA2
tCKHZ
An+2[37]
An
tSCLD
tHCLD
CNTLD
CNTINC
tSCINC
tHCINC
tSCRD
tHCRD
CNTRD
INTERNAL
ADDRESS
An
An+1
Qx–1
Qx
Load
External
Address
An+2
An+2
tDC
tCD2
DATAOUT
An+2
tCKHZ
Qn
Qn+1
Read Data with Counter
Qn+2
tCKLZ
Qn+2
Read
Internal
Address
Notes:
34. CE0 = OE = LB = UB = VIL; CE1 = R/W = CNTRST = MRST = MKLD = MKRD = VIH.
35. Address in output mode. Host must not be driving address bus after time tCKLZ in next clock cycle.
36. Address in input mode. Host can drive address bus after tCKHZ.
37. This is the value of the address counter being read out on the address lines.
Document #: 38-06027 Rev. *A
Page 18 of 37
CY7C0430BV
CY7C04312BV
CY7C04314BV
Switching Waveforms (continued)
Load and Read Mask Register [31, 38]
tCH2
tCYC2
tCL2
Note 35
CLK
tHA
tSA
A0-A15
tCKLZ
Note 36
tCA2
tCKHZ
An [39]
An
tSMLD
tHMLD
MKLD
tSMRD
tHMRD
MKRD
MASK
INTERNAL
VALUE
An
An
An
Load
Mask Register
Value
An
An
Read
Mask Register
Value
Notes:
38. CE0 = OE = LB = UB = VIL; CE1 = R/W = CNTRST = MRST = CNTLD = CNTRD = CNTINC =VIH.
39. This is the value of the Mask Register read out on the address lines.
Document #: 38-06027 Rev. *A
Page 19 of 37
CY7C0430BV
CY7C04312BV
CY7C04314BV
Switching Waveforms (continued)
Port 1 Write to Port 2 Read[40, 41, 42]
tCH2
tCYC2
tCL2
CLKP1
tHA
tSA
PORT-1
ADDRESS
An
tSW
tHW
R/WP1
tCKHZ
tSD
PORT-1
tCKLZ
Dn
DATAIN
CLKP2
tHD
tCYC2
tCL2
tCCS
tCH2
tSA
PORT-2
ADDRESS
tHA
An
R/WP2
tCD2
PORT-2
Qn
DATAOUT
tDC
Notes:
40. CE0 = OE = LB = UB = CNTLD =VIL; CE1 = CNTRST = MRST = MKLD = MKRD = CNTRD = CNTINC =VIH.
41. This timing is valid when one port is writing, and one or more of the three other ports is reading the same location at the same time. If tCCS is violated, indeterminate
data will be read out.
42. If tCCS< minimum specified value, then Port 2 will read the most recent data (written by Port 1) only (2*tCYC2 + tCD2) after the rising edge of Port 2’s clock. If
tCCS > minimum specified value, then Port 2 will read the most recent data (written by Port 1) (tCYC2 + tCD2) after the rising edge of Port 2’s clock.
Document #: 38-06027 Rev. *A
Page 20 of 37
CY7C0430BV
CY7C04312BV
CY7C04314BV
Switching Waveforms (continued)
Counter Interrupt [31, 43, 44, 45]
tCH2
tCYC2
tCL2
CLK
EXTERNAL
ADDRESS
007Fh
xx7Dh
tSMLD
tHMLD
MKLD
tSCLD
tHCLD
CNTLD
tHCINC
tSCINC
CNTINC
COUNTER
INTERNAL
ADDRESS
xx7Dh
An
xx7Eh
xx7Fh
xx00h
xx00h
tSCINT
CNTINT
tRCINT
Mailbox Interrupt Timing[46, 47, 48, 49, 50]
tCH2
tCYC2
tCL2
CLKP1
tSA
PORT-1
ADDRESS
tHA
An+1
An
FFFE
An+2
An+3
tSINT
tRINT
INTP2
tCH2
tCYC2
tCL2
CLKP2
tSA
PORT-2
ADDRESS
Am
tHA
Am+1
FFFE
Am+3
Am+4
Notes:
43. CE0 = OE = LB = UB = VIL; CE1 = R/W = CNTRST = MRST = CNTRD = MKRD = VIH.
44. CNTINT is always driven.
45. CNTINC goes LOW as the counter address masked portion is incremented from xx7Fh to xx00h. The “x” is “Don’t Care.”
46. CE0 = OE = LB = UB = CNTLD =VIL; CE1 = CNTRST = MRST = CNTRD = CNTINC = MKRD = MKLD =VIH.
47. Address “FFFE” is the mailbox location for Port 2.
48. Port 1 is configured for Write operation, and Port 2 is configured for Read operation.
49. Port 1 and Port 2 are used for simplicity. All four ports can write to or read from any mailbox.
50. 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.
Document #: 38-06027 Rev. *A
Page 21 of 37
CY7C0430BV
CY7C04312BV
CY7C04314BV
Table 1. Read/Write and Enable Operation (Any Port)[51, 52, 53]
Inputs
CLK
Outputs
CE0
CE1
R/W
I/O0–I/O17
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
OE
H
X
Operation
Outputs Disabled
Table 2. Address Counter and Counter-Mask Register Control Operation (Any Port)[31, 51, 54, 55]
CLK MRST CNTRST MKLD CNTLD CNTINC CNTRD MKRD
X
Mode
Operation
L
X
X
X
X
X
X
MasterReset
Counter/Address Register Reset and Mask
Register Set (resets entire chip as per reset
state table)
H
L
X
X
X
X
X
Reset
Counter/Address Register Reset
H
H
L
X
X
X
X
Load
Load of Address Lines into Mask Register
H
H
H
L
X
X
X
Load
Load of Address Lines into Counter/Address
Register
H
H
H
H
L
X
X
Increment Counter Increment
H
H
H
H
H
L
X
Readback Readback Counter on Address Lines
H
H
H
H
H
H
L
Readback Readback Mask Register on Address Lines
H
H
H
H
H
H
H
Hold
Counter Hold
Notes:
51. “X” = “Don’t Care,” “H” = VIH, “L” = VIL.
52. OE is an asynchronous input signal.
53. When CE changes state, deselection and read happen after one cycle of latency.
54. CE0 = OE = VIL; CE1 = R/W = VIH.
55. Counter operation and mask register operation are independent of Chip Enables.
Document #: 38-06027 Rev. *A
Page 22 of 37
CY7C0430BV
CY7C04312BV
CY7C04314BV
Master Reset
The QuadPort DSE device undergoes a complete reset by
taking its Master Reset (MRST) input LOW. The Master Reset
input can switch asynchronously to the clocks. A Master Reset
initializes the internal burst counters to zero, and the counter
mask registers to all ones (completely unmasked). A Master
Reset also forces the Mailbox Interrupt (INT) flags and the
Counter Interrupt (CNTINT) flags HIGH, resets the BIST
controller, and takes all registered control signals to a
deselected read state.[56] A Master Reset must be performed
on the QuadPort DSE device after power-up.
Interrupts
The upper four memory locations may be used for message
passing and permit communications between ports. Table 3
shows the interrupt operation for all ports. For the 1-Mb
QuadPort DSE device, the highest memory location FFFF is
the mailbox for Port 1, FFFE is the mailbox for Port 2, FFFD is
the mailbox for Port 3, and FFFC is the mailbox for Port 4.
Table 3 shows that in order to set Port 1 INTP1 flag, a write by
any other port to address FFFF will assert INTP1 LOW. A read
of FFFF location by Port 1 will reset INTP1 HIGH. When one
port writes to the other port’s mailbox, the Interrupt flag (INT)
of the port that the mailbox belongs to is asserted LOW. The
Interrupt is reset when the owner (port) of the mailbox reads
the contents of the mailbox. The interrupt flag is set in a
flow-through mode (i.e., it follows the clock edge of the writing
port). Also, the flag is reset in a flow-through 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. If an application does not require message
passing, INT pins should be treated as no-connect and should
be left floating. When two ports or more write to the same
mailbox at the same time INT will be asserted but the contents
of the mailbox are not guaranteed to be valid.
Table 3. Interrupt Operation Example
Port 1
Function
Port 2
Port 3
Port 4
INTP
A0P1–15P1
INTP1
A0P2–15P2
INTP2
A0P3–15P3
INTP3
A0P4–15P4
X
L
FFFF
X
FFFF
X
FFFF
X
Reset Port 1 INTP1 Flag
FFFF
H
X
X
X
X
X
X
Set Port 2 INTP2 Flag
FFFE
X
X
L
FFFE
X
FFFE
X
X
X
FFFE
H
X
X
X
X
FFFD
X
FFFD
X
X
L
FFFD
X
X
X
X
X
FFFD
H
X
X
FFFC
X
FFFC
X
FFFC
X
X
L
X
X
X
X
X
X
FFFC
H
Set Port 1 INTP1 Flag
Reset Port 2 INTP2 Flag
Set Port 3 INTP3 Flag
Reset Port 3 INTP3 Flag
Set Port 4 INTP4 Flag
Reset Port 4 INTP4 Flag
4
Note:
56. During Master Reset the control signals will be set to a deselected read state: CE0I = LBI = UBI = R/WI = MKLDI = MKRDI = CNTRDI = CNTRSTI = CNTLDI =
CNTINCI = VIH; CE1I = VIL. The “I” suffix on all these signals denotes that these are the internal registered equivalent of the associated pin signals.
Address Counter Control Operations[31]
Counter enable inputs are provided to stall the operation of the
address input and utilize the internal address generated by the
internal counter for the fast interleaved memory applications.
A port’s burst counter is loaded with the port’s Counter Load
pin (CNTLD). When the port’s Counter Increment (CNTINC) is
asserted, 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
CNTINC is deasserted. Depending on the mask register state,
the counter can address the entire memory array and will loop
back to start. Counter Reset (CNTRST) is used to reset the
Burst Counter (the Mask Register value is unaffected). When
using the counter in readback mode, the internal address
value of the counter will be read back on the address lines
when Counter Readback Signal (CNTRD) is asserted.
Document #: 38-06027 Rev. *A
Figure 1 provides a block diagram of the readback operation.
Table 2 lists control signals required for counter operations.
The signals are listed based on their priority. For example,
Master Reset takes precedence over Counter Reset, and
Counter Load has lower priority than Mask Register Load
(described below). All counter operations are independent of
Chip Enables (CE0 and CE1). When the address readback
operation is performed the data I/Os are three-stated (if CEs
are active) and one-clock cycle (no-operation cycle) latency is
experienced. The address will be read at time tCA2 from the
rising edge of the clock following the no-operation cycle. The
read back address can be either of the burst counter or the
mask register based on the levels of Counter Read signal
(CNTRD) and Mask Register Read signal (MKRD). Both
signals are synchronized to the port's clock as shown in
Table 2. Counter read has a higher priority than mask read.
Page 23 of 37
CY7C0430BV
CY7C04312BV
CY7C04314BV
Readback
Register
CNTRD
MKRD
Addr.
Readback
MKLD = 1
Memory
Array
Mask
Register
Bidirectional
Address Lines
Counter/
Address
Register
CNTINC = 1
CNTLD = 1
CNTRST = 1
CLK
Figure 1. Counter and Mask Register Read Back on Address Lines
Counter-Mask Register[31]
Example:
Load
Counter-Mask
Register = 3F
CNTINT
H
0
0
0’s
215 214
H
X X
X’s
215 214
Max
Address
Register
H
X X
L
X X
215 214
1
1
1
1
Mask
Register
bit-0
Counter Address
X 0
0
1
0
0
0
26 25 24 23 22 21 20
X’s
215 214
Max + 1
Address
Register
1
26 25 24 23 22 21 20
Blocked Address
Load
Address
Counter = 8
0 1
X 1 1
1
1
1
Address
Counter
bit-0
1
26 25 24 23 22 21 20
X’s
X 0
0
0
0 0
0
26 25 24 23 22 21 20
Figure 2. Programmable Counter-Mask Register Operation[57]
The burst counter has a mask register that controls when and
where the counter wraps. An interrupt flag (CNTINT) is
asserted for one clock cycle when the unmasked portion of the
counter address wraps around from all ones (CNTINC must be
asserted) to all zeros. The example in Figure 2 shows the
counter mask register loaded with a mask value of 003F
Document #: 38-06027 Rev. *A
unmasking the first 6 bits with bit “0” as the LSB and bit “15”
as the MSB. The maximum value the mask register can be
loaded with is FFFF. 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 XXX8.
The “blocked” addresses (in this case, the 6th address through
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the 15th address) are loaded with an address but do not
increment once loaded. The counter address will start at
address XXX8. With CNTINC asserted LOW, the counter will
increment its internal address value till it reaches the mask
register value of 3F and wraps around the memory block to
location XXX0. Therefore, the counter uses the mask-register
to define wrap-around point. The mask register of every port
is loaded when MKLD (mask register load) for that port is
LOW. When MKRD is LOW, the value of the mask register can
be read out on address lines in a manner similar to counter
read back operation (see Table 2 for required conditions).
When the burst counter is loaded with an address higher than
the mask register value, the higher addresses will form the
masked portion of the counter address and are called blocked
addresses. The blocked addresses will not be changed or
affected by the counter increment operation. The only
exception is mask register bit 0. It can be masked to allow the
address counter to increment by two. If the mask register bit 0
is loaded with a logic value of “0,” then address counter bit 0
is masked and can not be changed during counter increment
operation. If the loaded value for address counter bit 0 is “0,”
the counter will increment by two and the address values are
even. If the loaded value for address counter bit 0 is “1,” the
counter will increment by two and the address values are odd.
This operations allows the user to achieve a 36-bit interface
using any two ports, where 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 36-bit word in even memory locations, and the other half
in odd memory locations. CNTINT will be asserted when the
unmasked portion of the counter wraps to all zeros. Loading
mask register bit 0 with “1” allows the counter to increment the
address value sequentially.
Table 2 groups the operations of the mask register with the
operations of the address counter. Address counter and mask
register signals are all synchronized to the port's clock CLK.
Master reset (MRST) is the only asynchronous signal listed on
Table 2. Signals are listed based on their priority going from
left column to right column with MRST being the highest. A
LOW on MRST will reset both counter register to all zeros and
mask register to all ones. On the other hand, a LOW on
CNTRST will only clear the address counter register to zeros
and the mask register will remain intact.
There are four operations for the counter and mask register:
1. Load operation: When CNTLD or MKLD is LOW, the address counter or the mask register is loaded with the address value presented at the address lines. This value ranges from 0 to FFFF (64K). The mask register load operation
has a higher priority over the address counter load operation.
2. Increment: Once the address counter is loaded with an external address, the counter can internally increment the address value by asserting CNTINC LOW. The counter can
address the entire memory array (depend on the value of
the mask register) and loop back to location 0. The increment operation is second in priority to load operation.
3. Readback: the internal value of either the burst counter or
the mask register can be read out on the address lines when
CNTRD or MKRD is LOW. Counter readback has higher
priority over mask register readback. A no-operation delay
cycle is experienced when readback operation is performed. The address will be valid after tCA2 (for counter
Document #: 38-06027 Rev. *A
readback) or tCM2 (for mask readback) from the following
port's clock rising edge. Address readback operation is independent of the port's chip enables (CE0 and CE1). If address readback occurs while the port is enabled (chip enables active), the data lines (I/Os) will be three-stated.
4. Hold operation: In order to hold the value of the address
counter at certain address, all signals in Table 2 have to be
HIGH. This operation has the least priority. This operation
is useful in many applications where wait states are needed
or when address is available few cycles ahead of data.
The counter and mask register operations are totally
independent of port chip enables.
IEEE 1149.1 Serial Boundary Scan (JTAG) and
Memory Built-In-Self-Test (MBIST)
The CY7C0430BV incorporates a serial boundary scan test
access port (TAP). This port is fully compatible with IEEE
Standard 1149.1-2001[58]. 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. Memory BIST circuitry will also
be controlled through the TAP interface. All MBIST instructions
are compliant to the JTAG standard. An external clock
(CLKBIST) is provided to allow the user to run BIST at speeds
up to 50 MHz. CLKBIST is multiplexed internally with the ports
clocks during BIST operation.
Disabling the JTAG Feature
It is possible to operate the QuadPort DSE device without
using the JTAG feature. To disable the TAP controller, TCK
must be tied LOW (VSS) to prevent clocking of the device. TDI
and TMS are internally pulled up and may be unconnected.
They may alternately be connected to VDD through a pull-up
resistor. TDO should be left unconnected. CLKBIST must be
tied LOW to disable the MBIST. Upon power-up, the device will
come up in a reset state which will not interfere with the
operation of the device.
Test Access Port (TAP)–Test Clock (TCK)
The test clock is used only with the TAP controller. All inputs
are captured on the rising edge of TCK. All outputs are driven
from the falling edge of TCK.
Test Mode Select
The TMS input is used to give commands to the TAP controller
and is sampled on the rising edge of TCK. It is allowable to
leave this pin unconnected if the TAP is not used. The pin is
pulled up internally, resulting in a logic HIGH level.
Test Data-In (TDI)
The TDI pin is used to serially input information into the
registers and can be connected to the input of any of the
registers. The register between TDI and TDO is chosen by the
instruction that is loaded into the TAP instruction register. For
information on loading the instruction register, see the TAP
Controller State Diagram. TDI is internally pulled up and can
be unconnected if the TAP is unused in an application. TDI is
connected to the most significant bit (MSB) on any register.
Notes:
57. The “X” in this diagram represents the counter upper-bits.
58. Master Reset will reset the JTAG controller.
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Test Data Out (TDO)
TAP Instruction Set
The TDO output pin is used to serially clock data-out from the
registers. The output is active depending upon the current
state of the TAP state machine (see TAP Controller State
Diagram (FSM)). The output changes on the falling edge of
TCK. TDO is connected to the least significant bit (LSB) of any
register.
Sixteen different instructions are possible with the 4-bit
instruction register. All combinations are listed in Table 6,
Instruction Codes. Seven of these instructions (codes) are
listed as RESERVED and should not be used. The other nine
instructions are described in detail below.
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 QuadPort DSE device and may be performed while the
device is operating. At power-up, the TAP is reset internally to
ensure that TDO comes up in a High-Z state.
TAP Registers
Registers are connected between the TDI and TDO pins and
allow data to be scanned into and out of the QuadPort DSE
device test circuitry. Only one register can be selected at a
time through the instruction registers. Data is serially loaded
into the TDI pin on the rising edge of TCK. Data is output on
the TDO pin on the falling edge of TCK.
Instruction Register
Four-bit instructions can be serially loaded into the instruction
register. This register is loaded when it is placed between the
TDI and TDO pins as shown in the following JTAG/BIST
Controller diagram. Upon power-up, the instruction register is
loaded with the IDCODE instruction. It is also loaded with the
IDCODE instruction if the controller is placed in a reset state
as described in the previous section.
When the TAP controller is in the CaptureIR state, the two
least significant bits are loaded with a binary “01” pattern to
allow for fault isolation of the board level serial test path.
Bypass Register
To save time when serially shifting data through registers, it is
sometimes advantageous to skip certain devices. The bypass
register is a single-bit register that can be placed between TDI
and TDO pins. This allows data to be shifted through the
QuadPort DSE device with minimal delay. The bypass register
is set LOW (VSS) when the BYPASS instruction is executed.
Boundary Scan Register
The boundary scan register is connected to all the input and
output pins on the QuadPort DSE device. The boundary scan
register is loaded with the contents of the QuadPort DSE
device Input and Output ring when the TAP controller is in the
Capture-DR state and is then placed between the TDI and
TDO pins when the controller is moved to the Shift-DR state.
The EXTEST, and SAMPLE/PRELOAD instructions can be
used to capture the contents of the Input and Output ring.
Identification (ID) Register
The ID register is loaded with a vendor-specific, 32-bit code
during the Capture-DR state when the IDCODE command is
loaded in the instruction register. The IDCODE is hardwired
into the QuadPort DSE device and can be shifted out when the
TAP controller is in the Shift-DR state. The ID register has a
vendor code and other information described in the Identification Register Definitions table.
Document #: 38-06027 Rev. *A
The TAP controller used in this QuadPort DSE device is fully
compatible[58] with the 1149.1 convention. The TAP controller
can be used to load address, data or control signals into the
QuadPort DSE device and can preload the Input or output
buffers. The QuadPort DSE device implements all of the
1149.1 instructions except INTEST. Table 6 lists all instructions.
Instructions are loaded into the TAP controller during the
Shift-IR state when the instruction register is placed between
TDI and TDO. During this state, instructions are shifted
through the instruction register through the TDI and TDO pins.
To execute the instruction once it is shifted in, the TAP
controller needs to be moved into the Update-IR state.
EXTEST
EXTEST is a mandatory 1149.1 instruction which is to be
executed whenever the instruction register is loaded with all 0s.
EXTEST allows circuitry external to the QuadPort DSE device
package to be tested. Boundary-scan register cells at output pins
are used to apply test stimuli, while those at input pins capture
test results.
IDCODE
The IDCODE instruction causes a vendor-specific, 32-bit code
to be loaded into the identification register. It also places the
identification register between the TDI and TDO pins and
allows the IDCODE to be shifted out of the device when the
TAP controller enters the Shift-DR state. The IDCODE
instruction is loaded into the instruction register upon
power-up or whenever the TAP controller is given a test logic
reset state.
High-Z
The High-Z instruction causes the bypass register to be
connected between the TDI and TDO pins when the TAP
controller is in a Shift-DR state. It also places all QuadPort
DSE device outputs into a High-Z state.
SAMPLE/PRELOAD
SAMPLE/PRELOAD is a 1149.1 mandatory instruction. When
the SAMPLE/PRELOAD instructions loaded into the
instruction register and the TAP controller in the Capture-DR
state, a snapshot of data on the inputs and output pins is
captured in the boundary scan register.
The user must be aware that the TAP controller clock can only
operate at a frequency up to 10 MHz, while the QuadPort DSE
device clock operates more than an order of magnitude faster.
Because there is a large difference in the clock frequencies, it
is possible that during the Capture-DR state, an input or output
will undergo a transition. The TAP may then try to capture a
signal while in transition (metastable state). This will not harm
the device, but there is no guarantee as to the value that will
be captured. Repeatable results may not be possible.
To guarantee that the boundary scan register will capture the
correct value of a signal, the QuadPort DSE device signal
must be stabilized long enough to meet the TAP controller’s
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capture set-up plus hold times. Once the data is captured, it is
possible to shift out the data by putting the TAP into the
Shift-DR state. This places the boundary scan register
between the TDI and TDO pins. If the TAP controller goes into
the Update-DR state, the sampled data will be updated.
connected between TDI and TDO during the internal scan
(INT_SCAN) operation. The MRR will contain the total number
of fail read cycles of the entire MBIST sequence. MRR[0] (bit
0) is the Pass/Fail bit. A “1” indicates some type of failure
occurred, and a “0” indicates entire memory pass.
BYPASS
In order to run BIST in non-debug mode, the two-bit MBIST
Control Register (MCR) is loaded with the default value “00”,
and the TAP controller’s finite state machine (FSM), which is
synchronous to TCK, transitions to Run Test/Idle state. The
entire MBIST test will be performed with a deterministic
number of TCK cycles depending on the TCK and CLKBIST
frequency.
tCYC [ CLKBIST ]
t CYC = -------------------------------------------- × m + SPC
tCYC [ TCK ]
When the BYPASS instruction is loaded in the instruction
register and the TAP is placed in a Shift-DR state, the bypass
register is placed between the TDI and TDO pins. The
advantage of the BYPASS instruction is that it shortens the
boundary scan path when multiple devices are connected
together on a board.
CLAMP
The optional CLAMP instruction allows the state of the signals
driven from QuadPort DSE device pins to be determined from
the boundary-scan register while the BYPASS register is
selected as the serial path between TDI and TDO. CLAMP
controls boundary cells to 1 or 0.
tCYC is total number of TCK cycles required to run MBIST.
CYBIST
Once the entire MBIST sequence is completed, supplying
extra TCK or CLKBIST cycles will have no effect on the MBIST
controller state or the pass-fail status.
CYBIST instruction provides the user with a means of running
a user-accessible self-test function within the QuadPort DSE
device as a result of a single instruction. This permits all
components on a board that offer the CYBIST instruction to
execute their self-tests concurrently, providing a quick check
for the board. The QuadPort DSE device MBIST provides two
modes of operation once the TAP controller is loaded with the
CYBIST instruction:
Non-Debug Mode (Go-NoGo)
The non-debug mode is a go-nogo test used simply to run
BIST and obtain pass-fail information after the test is run. In
addition to that, the total number of failures encountered can
be obtained. This information is used to aid the debug mode
(explained next) of operation. The pass-fail information and
failure count is scanned out using the JTAG interface. An
MBIST Result Register (MRR) will be used to store the
pass-fail results. The MRR is a 25-bit register that will be
Document #: 38-06027 Rev. *A
SPC is the Synchronization Padding Cycles (4–6 cycles).
m is a constant represents the number of read and write operations required to run MBIST algorithms (31195136).
Debug Mode
With the CYBIST instruction loaded and the MCR loaded with
the value of “01,” and the FSM transitions to RUN_TEST/IDLE
state, the MBIST goes into CYBIST-debug mode. The debug
mode will be used to provide complete failure analysis information at the board level. It is recommended that the user runs
the non-debug mode first and then the debug mode in order to
save test time and to set an upper bound on the number of
scan outs that will be needed. The failure data will be scanned
out automatically once a failure occurs using the JTAG TAP
interface. The failure data will be represented by a 100-bit
packet given below. The 100-bit Memory Debug Register
(MDR) will be connected between TDI and TDO, and will be
shifted out on TDO, which is synchronized to TCK.
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99
1
98
1
62
97
P3_IO(17-9)
P4_IO(17-9)
61
P4_IO(8-0)
25
P2_IO(17-9)
P1_IO(17-9)
26
P3_IO(8-0)
P2_IO(8-0)
P1_IO(8-0)
10
A(15-0)
9
MBIST_State
4
3
P/F
2
TD
1
0
1
1
Figure 3. MBIST Debug Register Packet
Figure 3 is a representation of the 100-bit MDR packet. The
packet follows a two-bit header that has a logic “1” value, and
represents two TCK cycles. MDR[97:26] represent the BIST
comparator values of all four ports (each port has 18 data
lines). A value of “1” indicates a bit failure. The scanned out
data is from LSB to MSB. MDR[25:10] represent the failing
address (MSB to LSB). The state of the BIST controller is
scanned out using MDR[9:4]. Bit 2 is the Test Done bit. A “0”
in bit 2 means test not complete. The user has to monitor this
bit at every packet to determine if more failure packets need
to be scanned out at the end of the BIST operations. If the
value is “0” then BIST must be repeated to capture the next
failing packet. If it is “1,” it means that the last failing packets
have been scanned out. A trailer similar to the header represents the end of a packet.
MCR_SCAN
This instruction will connect the Memory BIST Control
Register (MCR) between TDI and TDO. The default value
Document #: 38-06027 Rev. *A
(upon master reset) is “00.” Shift_DR state will allow modifying
the MCR to extend the MBIST functionality.
MBIST Control States
Thirty-five states are listed in Table 7. Four data algorithms are
used in debug mode: moving inversion (MIA), march_2 (M2A),
checkerboard (CBA), and unique address algorithm (UAA).
Only Port 1 can write MIA, M2A, and CBA data to the memory.
All four ports can read any algorithm data from the QuadPort
DSE device memory. Ports 2, 3, and 4 will only write UAA data.
Boundary Scan Cells (BSC)
Table 9 lists all QuadPort DSE family I/Os with their associated
BSC. Note that the cells have even numbers. Every I/O has
two boundary scan cells. Bidirectional signals (address lines,
datalines) require two cells so that one (the odd cell) is used
to control a three-state buffer. Input only and output only
signals have an extra dummy cell (odd cells) that are used to
ease device layout.
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TAP Controller State Diagram (FSM)[59]
1
TEST-LOGIC
RESET
0
0
RUN_TEST/
IDLE
1
1
1
SELECT
DR-SCAN
SELECT
IR-SCAN
0
0
1
1
CAPTURE-IR
CAPTURE-DR
0
0
SHIFT-IR
0
SHIFT-DR
1
0
1
1
EXIT1-DR
1
EXIT1-IR
0
0
PAUSE-DR
0
0
PAUSE-IR
1
1
0
0
EXIT2-IR
EXIT2-DR
1
1
UPDATE-DR
1
0
UPDATE-IR
1
0
Note:
59. The “0”/”1” next to each state represents the value at TMS at the rising edge of TCK.
Document #: 38-06027 Rev. *A
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JTAG/BIST TAP Controller Block Diagram
0
Bypass Register (BYR)
1
0
MBIST Control Register (MCR)
3 2
1
0
Instruction Register (IR)
24 23
0
MBIST Result Register (MRR)
TDI
31 30 29
TDO
0
Identification Register (IDR)
99
Selection
Circuitry
(MUX)
0
MBIST Debug Register (MDR)
391
0
Boundary Scan Register (BSR)
BIST
CONTROLLER
TAP
CONTROLLER
CLKBIST
TCK
TMS
MRST
MEMORY
CELL
Table 4. Identification Register Definitions
Instruction Field
Value
Description
Revision Number (31:28)
1h
Reserved for version number
Cypress Device ID (27:12)
C000h
Defines Cypress part number
Cypress JEDEC ID (11:1)
34h
Allows unique identification of QuadPort DSE device vendor
ID Register Presence (0)
1
Indicate the presence of an ID register
Document #: 38-06027 Rev. *A
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Table 5. Scan Registers Sizes
Register Name
Bit Size
Instruction (IR)
4
Bypass (BYR)
1
Identification (IDR)
32
MBIST Control (MCR)
2
MBIST Result (MRR)
25
MBIST Debug (MDR)
100
Boundary Scan (BSR)
392
Table 6. Instruction Identification Codes
Instruction
Code
Description
EXTEST
0000
Captures the Input/Output ring contents. Places the boundary scan register (BSR)
between the TDI and TDO.
BYPASS
1111
Places the bypass register (BYR) between TDI and TDO.
IDCODE
0111
Loads the ID register (IDR) with the vendor ID code and places the register
between TDI and TDO.
HIGHZ
0110
Places the BYR between TDI and TDO. Forces all QuadPort DSE device output
drivers to a High-Z state.
CLAMP
0101
Controls boundary to 1/0. Uses BYR.
SAMPLE/PRELOAD
0001
Captures the Input/Output ring contents. Places the boundary scan register (BSR)
between TDI and TDO.
CYBIST
1000
Invokes MBIST. Places the MBIST Debug register (MDR) between TDI and TDO.
INT_SCAN
0010
Scans out pass-fail information. Places MBIST Result Register (MRR) between TDI
and TDO.
MCR_SCAN
0011
Presets CYBIST mode. Places MBIST Control Register (MCR) between TDI and
TDO.
RESERVED
All other codes
Seven combinations are reserved. Do not use other than the above.
Table 7. MBIST Control States
States Code
State Name
Description
000001
movi_zeros
Port 1 write all zeros to the QuadPort DSE device memory using Moving
Inversion Algorithm (MIA).
000011
movi_1_upcnt
Up count from 0 to 64K (depth of QuadPort DSE device). All ports read 0s,
then Port 1 writes 1s to all memory locations using MIA, then all ports read
1s. MIA read0_write1_read1 (MIA_r0w1r1).
000010
movi_0_upcnt
Up count from 0 to 64K. All ports read 1s, then Port 1 writes 0s, then all ports
read 0s (MIA_r1w0r0).
000110
movi_1_downcnt
Down count from 64K to 0. MIA_r0w1r1.
000111
movi_0_downcnt
Down count MIA_r1w0r0.
000101
movi_read
Read all 0s.
000100
mar2_zeros
Port 1 write all zeros to memory using March2 Algorithm (M2A).
001100
mar2_1_upcnt
Up count M2A_r0w1r1.
001101
mar2_0_upcnt
Up count M2A_r1w0r0.
001111
mar2_1_downcnt
Down count M2A_r0w1r1.
Document #: 38-06027 Rev. *A
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Table 7. MBIST Control States (continued)
States Code
State Name
Description
001110
mar2_0_downcnt
Down count M2A_r1w0r0.
001010
mar2_read
Read all 0s.
001011
chkr_w
Port 1 writes topological checkerboard data to memory.
001001
chkr_r
All ports read topological checkerboard data.
001000
n_chkr_w
Port 1 write inverse topological checkerboard data.
011000
n_chkr_r
All ports read inverse topological checkerboard data.
011001
uaddr_zeros2
Port 2 write all zeros to memory using Unique Address Algorithm (UAA).
011011
uaddr_write2
Port 2 writes every address value into its memory location (UAA).
011010
uaddr_read2
All ports read UAA data.
011110
uaddr_ones2
Port 2 writes all ones to memory.
011111
n_uaddr_write2
Port 2 writes inverse address value into memory.
011101
n_uaddr_read2
All ports read inverse UAA data.
011001
uaddr_zeros3
Port 3 write all zeros to memory using Unique Address Algorithm (UAA).
011011
uaddr_write3
Port 3 writes every address value into its memory location (UAA).
011010
uaddr_read3
All ports read UAA data.
011110
uaddr_ones3
Port 3 writes all ones to memory.
011111
n_uaddr_write3
Port 3 writes inverse address value into memory.
011101
n_uaddr_read3
All ports read inverse UAA data.
011001
uaddr_zeros4
Port 4 write all zeros to memory using Unique Address Algorithm (UAA).
011011
uaddr_write4
Port 4 writes every address value into its memory location (UAA).
011010
uaddr_read4
All ports read UAA data.
011110
uaddr_ones4
Port 4 writes all ones to memory.
011111
n_uaddr_write4
Port 4 writes inverse address value into memory.
011101
n_uaddr_read4
All ports read inverse UAA data.
110010
complete
Test complete.
Table 9. Boundary Scan Order (continued)
Table 8. MBIST Control Register (MCR)
Signal Name
Bump (Ball) ID
Mode
00
Non-Debug
16
A7_P4
F20
01
Debug
18
A8_P4
F19
10
Reserved
20
A9_P4
F18
11
Reserved
22
A10_P4
E20
24
A11_P4
E19
26
A12_P4
D19
Table 9. Boundary Scan Order
Cell #
Cell #
MCR[1:0]
Signal Name
Bump (Ball) ID
2
A0_P4
K20
28
A13_P4
D18
4
A1_P4
J19
30
A14_P4
C20
A15_P4
C19
6
A2_P4
J18
32
8
A3_P4
H20
34
CNTINT_P4
F17
10
A4_P4
H19
36
CNTRST_P4
K18
12
A5_P4
G19
38
MKLD_P4
H18
G18
40
CNTLD_P4
H17
14
A6_P4
Document #: 38-06027 Rev. *A
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Table 9. Boundary Scan Order (continued)
Cell #
Signal Name
Bump (Ball) ID
Table 9. Boundary Scan Order (continued)
Cell #
Signal Name
Bump (Ball) ID
42
CNTINC_P4
G17
124
CLK_P3
M17
44
CNTRD_P4
E17
126
IO0_P4
Y15
46
MKRD_P4
E18
128
IO1_P4
W15
48
LB_P4
A20
130
IO2_P4
Y16
50
UB_P4
B19
132
IO3_P4
W16
52
OE_P4
D17
134
IO4_P4
Y17
54
R/W_P4
C16
136
IO5_P4
W17
56
CE1_P4
C18
138
IO6_P4
Y18
58
CE0_P4
C17
140
IO7_P4
W18
60
INT_P4
K19
142
IO8_P4
Y19
62
CLK_P4
K17
144
IO0_P3
V12
64
A0_P3
L20
146
IO1_P3
Y11
66
A1_P3
M19
148
IO2_P3
W12
68
A2_P3
M18
150
IO3_P3
Y12
70
A3_P3
N20
152
IO4_P3
W13
72
A4_P3
N19
154
IO5_P3
Y13
74
A5_P3
P19
156
IO6_P3
V15
76
A6_P3
P18
158
IO7_P3
Y14
78
A7_P3
R20
160
IO8_P3
W14
80
A8_P3
R19
162
IO0_P1
Y6
82
A9_P3
R18
164
IO1_P1
W6
84
A10_P3
T20
166
IO2_P1
Y5
86
A11_P3
T19
168
IO3_P1
W5
88
A12_P3
U19
170
IO4_P1
Y4
90
A13_P3
U18
172
IO5_P1
W4
92
A14_P3
V20
174
IO6_P1
Y3
94
A15_P3
V19
176
IO7_P1
W3
96
CNTINT_P3
R17
178
IO8_P1
Y2
98
CNTRST_P3
L18
180
IO0_P2
V9
100
MKLD_P3
N18
182
IO1_P2
Y10
102
CNTLD_P3
N17
184
IO2_P2
W9
104
CNTINC_P3
P17
186
IO3_P2
Y9
106
CNTRD_P3
T17
188
IO4_P2
W8
108
MKRD_P3
T18
190
IO5_P2
Y8
110
LB_P3
Y20
192
IO6_P2
V6
112
UB_P3
W19
194
IO7_P2
Y7
114
OE_P3
U17
196
IO8_P2
W7
116
R/W_P3
V16
198
A0_P2
L1
118
CE1_P3
V18
200
A1_P2
M2
120
CE0_P3
V17
202
A2_P2
M3
122
INT_P3
L19
204
A3_P2
N1
Document #: 38-06027 Rev. *A
Page 33 of 37
CY7C0430BV
CY7C04312BV
CY7C04314BV
Table 9. Boundary Scan Order (continued)
Cell #
Signal Name
Bump (Ball) ID
Table 9. Boundary Scan Order (continued)
Cell #
Signal Name
Bump (Ball) ID
206
A4_P2
N2
288
A14_P1
C1
208
A5_P2
P2
290
A15_P1
C2
210
A6_P2
P3
292
CNTINT_P1
F4
212
A7_P2
R1
294
CNTRST_P1
K3
214
A8_P2
R2
296
MKLD_P1
H3
216
A9_P2
R3
298
CNTLD_P1
H4
218
A10_P2
T1
300
CNTINC_P1
G4
220
A11_P2
T2
302
CNTRD_P1
E4
222
A12_P2
U2
304
MKRD_P1
E3
224
A13_P2
U3
306
LB_P1
A1
226
A14_P2
V1
308
UB_P1
B2
228
A15_P2
V2
310
OE_P1
D4
230
CNTINT_P2
R4
312
R/W_P1
C5
232
CNTRST_P2
L3
314
CE1_P1
C3
234
MKLD_P2
N3
316
CE0_P1
C4
236
CNTLD_P2
N4
318
INT_P1
K2
238
CNTINC_P2
P4
320
CLK_P1
K4
240
CNTRD_P2
T4
322
IO9_P2
A6
242
MKRD_P2
T3
324
IO10_P2
B6
244
LB_P2
Y1
326
IO11_P2
A5
246
UB_P2
W2
328
IO12_P2
B5
248
OE_P2
U4
330
IO13_P2
A4
250
R/W_P2
V5
332
IO14_P2
B4
252
CE1_P2
V3
334
IO15_P2
A3
254
CE0_P2
V4
336
IO16_P2
B3
256
INT_P2
L2
338
IO17_P2
A2
258
CLK_P2
M4
340
IO9_P1
C9
260
A0_P1
K1
342
IO10_P1
A10
262
A1_P1
J2
344
IO11_P1
B9
264
A2_P1
J3
346
IO12_P1
A9
266
A3_P1
H1
348
IO13_P1
B8
268
A4_P1
H2
350
IO14_P1
A8
270
A5_P1
G2
352
IO15_P1
C6
272
A6_P1
G3
354
IO16_P1
A7
274
A7_P1
F1
356
IO17_P1
B7
276
A8_P1
F2
358
IO9_P3
A15
278
A9_P1
F3
360
IO10_P3
B15
280
A10_P1
E1
362
IO11_P3
A16
282
A11_P1
E2
364
IO12_P3
B16
284
A12_P1
D2
366
IO13_P3
A17
286
A13_P1
D3
368
IO14_P3
B17
Document #: 38-06027 Rev. *A
Page 34 of 37
CY7C0430BV
CY7C04312BV
CY7C04314BV
Table 9. Boundary Scan Order (continued)
Cell #
Signal Name
Bump (Ball) ID
370
IO15_P3
A18
372
IO16_P3
B18
374
IO17_P3
A19
376
IO9_P4
C12
378
IO10_P4
A11
380
IO11_P4
B12
382
IO12_P4
A12
384
IO13_P4
B13
386
IO14_P4
A13
388
IO15_P4
C15
390
IO16_P4
A14
392
IO17_P4
B14
Ordering Information
10 Gb/s 3.3V QuadPort DSE Family 1 Mb (64K × 18)
Speed
(MHz)
133
100
Ordering Code
Package
Name
Package Type
Operating
Range
CY7C0430BV-133BGC
BG272
272-ball Grid Array (BGA)
Commercial
CY7C0430BV-133BGI
BG272
272-ball Grid Array (BGA)
Industrial
CY7C0430BV-100BGC
BG272
272-ball Grid Array (BGA)
Commercial
CY7C0430BV-100BGI
BG272
272-ball Grid Array (BGA)
Industrial
10 Gb/s 3.3V QuadPort DSE Family 1/2 Mb (32K x 18)
Speed
(MHz)
Ordering Code
Package
Name
Package Type
133
CY7C04312BV-133BGC
BG272
272-ball Grid Array (BGA)
100
CY7C04312BV-100BGC
BG272
272-ball Grid Array (BGA)
Operating
Range
Commercial
10 Gb/s 3.3V QuadPort DSE Family 1/4 Mb (16K x 18)
Speed
(MHz)
Ordering Code
Package
Name
Package Type
133
CY7C04314BV-133BGC
BG272
272-ball Grid Array (BGA)
100
CY7C04314BV-100BGC
BG272
272-ball Grid Array (BGA)
Document #: 38-06027 Rev. *A
Operating
Range
Commercial
Page 35 of 37
CY7C0430BV
CY7C04312BV
CY7C04314BV
Package Diagram
272-ball Ball Grid Array (27 x 27 x 1.27 mm) BG272
51-85130
QuadPort is a trademark of Cypress Semiconductor Corporation. All product and company names mentioned in this document
are the trademarks of their respective holders.
Document #: 38-06027 Rev. *A
Page 36 of 37
© Cypress Semiconductor Corporation, 2002. 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 Semiconductor product. Nor does it convey or imply any license under patent or other rights. Cypress Semiconductor does not authorize
its products for use as critical components in life-support systems where a malfunction or failure may reasonably be expected to result in significant injury to the user. The inclusion of Cypress
Semiconductor products in life-support systems application implies that the manufacturer assumes all risk of such use and in doing so indemnifies Cypress Semiconductor against all charges.
CY7C0430BV
CY7C04312BV
CY7C04314BV
Document Title: CY7C430BV, CY7C04312BV, CY7C04314BV 10 Gb/s 3.3V QuadPort DSE Family
Document Number: 38-06027
REV.
ECN NO.
Issue
Date
**
109906
09/10/01
SZV
Change from Spec number: 38-01052 to 38-06027
*A
115042
05/23/02
FSG
Remove Preliminary, TM from DSE.
Change RUNBIST to CYBIST.
Updated ISB values.
Added notes 9 and 14.
Increased commercial prime bin to 135 MHz.
Document #: 38-06027 Rev. *A
Orig. of
Change
Description of Change
Page 37 of 37