CY7C1510V18, CY7C1525V18
CY7C1512V18, CY7C1514V18
72-Mbit QDR™-II SRAM 2-Word
Burst Architecture
Features
Functional Description
■
Separate independent read and write data ports
❐ Supports concurrent transactions
■
250 MHz clock for high bandwidth
■
2-word burst on all accesses
■
Double Data Rate (DDR) interfaces on both read and write ports
(data transferred at 500 MHz) at 250 MHz
■
Two input clocks (K and K) for precise DDR timing
❐ SRAM uses rising edges only
■
Two input clocks for output data (C and C) to minimize clock
skew and flight time mismatches
■
Echo clocks (CQ and CQ) simplify data capture in high-speed
systems
■
Single multiplexed address input bus latches address inputs
for both read and write ports
■
Separate port selects for depth expansion
■
Synchronous internally self-timed writes
The CY7C1510V18, CY7C1525V18, CY7C1512V18, and
CY7C1514V18 are 1.8V Synchronous Pipelined SRAMs,
equipped with QDR™-II architecture. QDR-II architecture
consists of two separate ports: the read port and the write port to
access the memory array. The read port has dedicated data
outputs to support read operations and the write port has
dedicated data inputs to support write operations. QDR-II architecture has separate data inputs and data outputs to completely
eliminate the need to “turn-around” the data bus that exists with
common IO devices. Access to each port is through a common
address bus. Addresses for read and write addresses are
latched on alternate rising edges of the input (K) clock. Accesses
to the QDR-II read and write ports are completely independent
of one another. To maximize data throughput, both read and write
ports are equipped with DDR interfaces. Each address location
is associated with two 8-bit words (CY7C1510V18), 9-bit words
(CY7C1525V18), 18-bit words (CY7C1512V18), or 36-bit words
(CY7C1514V18) that burst sequentially into or out of the device.
Because data can be transferred into and out of the device on
every rising edge of both input clocks (K and K and C and C),
memory bandwidth is maximized while simplifying system
design by eliminating bus “turn-arounds”.
■
Available in x8, x9, x18, and x36 configurations
■
Full data coherency, providing most current data
■
Core VDD = 1.8V (±0.1V); IO VDDQ = 1.4V to VDD
■
Available in 165-Ball FBGA package (15 x 17 x 1.4 mm)
■
Offered in both Pb-free and non Pb-free packages
■
Variable drive HSTL output buffers
■
JTAG 1149.1 compatible test access port
■
Delay Lock Loop (DLL) for accurate data placement
Depth expansion is accomplished with port selects, which
enables each port to operate independently.
All synchronous inputs pass through input registers controlled by
the K or K input clocks. All data outputs pass through output
registers controlled by the C or C (or K or K in a single clock
domain) input clocks. Writes are conducted with on-chip
synchronous self-timed write circuitry.
Configurations
CY7C1510V18 – 8M x 8
CY7C1525V18 – 8M x 9
CY7C1512V18 – 4M x 18
CY7C1514V18 – 2M x 36
Selection Guide
Description
Maximum Operating Frequency
Maximum Operating Current
250 MHz
200 MHz
167 MHz
Unit
250
200
167
MHz
mA
x8
850
750
700
x9
850
750
700
x18
900
800
750
x36
1100
900
800
Cypress Semiconductor Corporation
Document #: 38-05489 Rev. *F
•
198 Champion Court
•
San Jose, CA 95134-1709
•
408-943-2600
Revised August 06, 2008
[+] Feedback
CY7C1510V18, CY7C1525V18
CY7C1512V18, CY7C1514V18
Logic Block Diagram (CY7C1510V18)
K
CLK
Gen.
DOFF
22
Address
Register
Read Add. Decode
K
Write
Reg
4M x 8 Array
Address
Register
Write
Reg
4M x 8 Array
A(21:0)
22
8
Write Add. Decode
D[7:0]
A(21:0)
RPS
Control
Logic
C
Read Data Reg.
C
CQ
16
VREF
WPS
8
Control
Logic
8
NWS[1:0]
Reg.
Reg. 8
Reg.
8
CQ
8
Q[7:0]
Logic Block Diagram (CY7C1525V18)
K
CLK
Gen.
DOFF
22
Address
Register
Read Add. Decode
K
Write
Reg
4M x 9 Array
Address
Register
Write
Reg
4M x 9 Array
A(21:0)
22
9
Write Add. Decode
D[8:0]
A(21:0)
RPS
Control
Logic
C
Read Data Reg.
C
CQ
18
VREF
WPS
9
Control
Logic
BWS[0]
Document #: 38-05489 Rev. *F
9
Reg.
Reg. 9
Reg.
9
CQ
9
Q[8:0]
Page 2 of 29
[+] Feedback
CY7C1510V18, CY7C1525V18
CY7C1512V18, CY7C1514V18
Logic Block Diagram (CY7C1512V18)
K
CLK
Gen.
DOFF
21
Address
Register
Read Add. Decode
K
Write
Reg
2M x 18 Array
Address
Register
Write
Reg
2M x 18 Array
A(20:0)
21
18
Write Add. Decode
D[17:0]
A(20:0)
RPS
Control
Logic
C
Read Data Reg.
C
CQ
36
VREF
WPS
18
Control
Logic
18
BWS[1:0]
Reg.
Reg. 18
Reg.
18
CQ
18
Q[17:0]
Logic Block Diagram (CY7C1514V18)
K
CLK
Gen.
DOFF
20
Address
Register
Read Add. Decode
K
Write
Reg
1M x 36 Array
Address
Register
Write
Reg
1M x 36 Array
A(19:0)
20
36
Write Add. Decode
D[35:0]
A(19:0)
RPS
Control
Logic
C
Read Data Reg.
C
CQ
72
VREF
WPS
36
Control
Logic
BWS[3:0]
Document #: 38-05489 Rev. *F
36
Reg.
Reg. 36
Reg.
36
CQ
36
Q[35:0]
Page 3 of 29
[+] Feedback
CY7C1510V18, CY7C1525V18
CY7C1512V18, CY7C1514V18
Pin Configuration
The pin configuration for CY7C1510V18, CY7C1525V18, CY7C1512V18, and CY7C1514V18 follow. [1]
165-Ball FBGA (15 x 17 x 1.4 mm) Pinout
CY7C1510V18 (8M x 8)
1
2
3
4
5
6
7
8
9
10
11
A
CQ
A
A
WPS
NWS1
K
NC/144M
RPS
A
A
CQ
B
NC
NC
NC
A
NC/288M
K
NWS0
A
NC
NC
Q3
C
NC
NC
NC
VSS
A
A
A
VSS
NC
NC
D3
D
NC
D4
NC
VSS
VSS
VSS
VSS
VSS
NC
NC
NC
E
NC
NC
Q4
VDDQ
VSS
VSS
VSS
VDDQ
NC
D2
Q2
F
NC
NC
NC
VDDQ
VDD
VSS
VDD
VDDQ
NC
NC
NC
G
NC
D5
Q5
VDDQ
VDD
VSS
VDD
VDDQ
NC
NC
NC
H
DOFF
VREF
VDDQ
VDDQ
VDD
VSS
VDD
VDDQ
VDDQ
VREF
ZQ
J
NC
NC
NC
VDDQ
VDD
VSS
VDD
VDDQ
NC
Q1
D1
K
NC
NC
NC
VDDQ
VDD
VSS
VDD
VDDQ
NC
NC
NC
L
NC
Q6
D6
VDDQ
VSS
VSS
VSS
VDDQ
NC
NC
Q0
M
NC
NC
NC
VSS
VSS
VSS
VSS
VSS
NC
NC
D0
N
NC
D7
NC
VSS
A
A
A
VSS
NC
NC
NC
P
NC
NC
Q7
A
A
C
A
A
NC
NC
NC
R
TDO
TCK
A
A
A
C
A
A
A
TMS
TDI
CY7C1525V18 (8M x 9)
1
2
3
4
5
6
7
8
9
10
11
A
CQ
A
A
WPS
NC
K
NC/144M
RPS
A
A
CQ
B
NC
NC
NC
A
NC
K
BWS0
A
NC
NC
Q4
C
NC
NC
NC
VSS
A
A
A
VSS
NC
NC
D4
D
NC
D5
NC
VSS
VSS
VSS
VSS
VSS
NC
NC
NC
E
NC
NC
Q5
VDDQ
VSS
VSS
VSS
VDDQ
NC
D3
Q3
F
NC
NC
NC
VDDQ
VDD
VSS
VDD
VDDQ
NC
NC
NC
G
NC
D6
Q6
VDDQ
VDD
VSS
VDD
VDDQ
NC
NC
NC
H
DOFF
VREF
VDDQ
VDDQ
VDD
VSS
VDD
VDDQ
VDDQ
VREF
ZQ
J
NC
NC
NC
VDDQ
VDD
VSS
VDD
VDDQ
NC
Q2
D2
K
NC
NC
NC
VDDQ
VDD
VSS
VDD
VDDQ
NC
NC
NC
L
NC
Q7
D7
VDDQ
VSS
VSS
VSS
VDDQ
NC
NC
Q1
M
NC
NC
NC
VSS
VSS
VSS
VSS
VSS
NC
NC
D1
N
NC
D8
NC
VSS
A
A
A
VSS
NC
NC
NC
P
NC
NC
Q8
A
A
C
A
A
NC
D0
Q0
R
TDO
TCK
A
A
A
C
A
A
A
TMS
TDI
Note
1. VSS/144M and VSS/288M are not connected to the die and can be tied to any voltage level.
Document #: 38-05489 Rev. *F
Page 4 of 29
[+] Feedback
CY7C1510V18, CY7C1525V18
CY7C1512V18, CY7C1514V18
Pin Configuration
(continued)
The pin configuration for CY7C1510V18, CY7C1525V18, CY7C1512V18, and CY7C1514V18 follow. [1]
165-Ball FBGA (15 x 17 x 1.4 mm) Pinout
CY7C1512V18 (4M x 18)
1
2
3
4
5
6
7
8
9
10
11
A
CQ
VSS/144M
A
WPS
BWS1
K
NC/288M
RPS
A
A
CQ
B
NC
Q9
D9
A
NC
K
BWS0
A
NC
NC
Q8
C
NC
NC
D10
VSS
A
A
A
VSS
NC
Q7
D8
D
NC
D11
Q10
VSS
VSS
VSS
VSS
VSS
NC
NC
D7
E
NC
NC
Q11
VDDQ
VSS
VSS
VSS
VDDQ
NC
D6
Q6
F
NC
Q12
D12
VDDQ
VDD
VSS
VDD
VDDQ
NC
NC
Q5
G
NC
D13
Q13
VDDQ
VDD
VSS
VDD
VDDQ
NC
NC
D5
H
DOFF
VREF
VDDQ
VDDQ
VDD
VSS
VDD
VDDQ
VDDQ
VREF
ZQ
J
NC
NC
D14
VDDQ
VDD
VSS
VDD
VDDQ
NC
Q4
D4
K
NC
NC
Q14
VDDQ
VDD
VSS
VDD
VDDQ
NC
D3
Q3
L
NC
Q15
D15
VDDQ
VSS
VSS
VSS
VDDQ
NC
NC
Q2
M
NC
NC
D16
VSS
VSS
VSS
VSS
VSS
NC
Q1
D2
N
NC
D17
Q16
VSS
A
A
A
VSS
NC
NC
D1
P
NC
NC
Q17
A
A
C
A
A
NC
D0
Q0
R
TDO
TCK
A
A
A
C
A
A
A
TMS
TDI
CY7C1514V18 (2M x 36)
1
2
3
4
5
6
7
8
9
10
11
A
CQ
VSS/288M
A
WPS
BWS2
K
BWS1
RPS
A
VSS/144M
CQ
B
Q27
Q18
D18
A
BWS3
K
BWS0
A
D17
Q17
Q8
C
D27
Q28
D19
VSS
A
A
A
VSS
D16
Q7
D8
D
D28
D20
Q19
VSS
VSS
VSS
VSS
VSS
Q16
D15
D7
E
Q29
D29
Q20
VDDQ
VSS
VSS
VSS
VDDQ
Q15
D6
Q6
F
Q30
Q21
D21
VDDQ
VDD
VSS
VDD
VDDQ
D14
Q14
Q5
G
D30
D22
Q22
VDDQ
VDD
VSS
VDD
VDDQ
Q13
D13
D5
H
DOFF
VREF
VDDQ
VDDQ
VDD
VSS
VDD
VDDQ
VDDQ
VREF
ZQ
J
D31
Q31
D23
VDDQ
VDD
VSS
VDD
VDDQ
D12
Q4
D4
K
Q32
D32
Q23
VDDQ
VDD
VSS
VDD
VDDQ
Q12
D3
Q3
L
Q33
Q24
D24
VDDQ
VSS
VSS
VSS
VDDQ
D11
Q11
Q2
M
D33
Q34
D25
VSS
VSS
VSS
VSS
VSS
D10
Q1
D2
N
D34
D26
Q25
VSS
A
A
A
VSS
Q10
D9
D1
P
Q35
D35
Q26
A
A
C
A
A
Q9
D0
Q0
R
TDO
TCK
A
A
A
C
A
A
A
TMS
TDI
Document #: 38-05489 Rev. *F
Page 5 of 29
[+] Feedback
CY7C1510V18, CY7C1525V18
CY7C1512V18, CY7C1514V18
Pin Definitions
Pin Name
IO
Pin Description
D[x:0]
InputData Input Signals. Sampled on the rising edge of K and K clocks during valid write operations.
Synchronous CY7C1510V18 − D[7:0]
CY7C1525V18 − D[8:0]
CY7C1512V18 − D[17:0]
CY7C1514V18 − D[35:0]
WPS
InputWrite Port Select − Active LOW. Sampled on the rising edge of the K clock. When asserted active, a
Synchronous write operation is initiated. Deasserting deselects the write port. Deselecting the write port ignores D[x:0].
NWS0,
NWS1
InputNibble Write Select 0, 1 − Active LOW (CY7C1510V18 Only). Sampled on the rising edge of the K and
Synchronous K clocks during write operations. Used to select which nibble is written into the device during the current
portion of the write operations. Nibbles not written remain unaltered.
NWS0 controls D[3:0] and NWS1 controls D[7:4].
All the Nibble Write Selects are sampled on the same edge as the data. Deselecting a Nibble Write Select
ignores the corresponding nibble of data and it is not written into the device.
BWS0,
BWS1,
BWS2,
BWS3
InputByte Write Select 0, 1, 2, and 3 − Active LOW. Sampled on the rising edge of the K and K clocks during
Synchronous write operations. Used to select which byte is written into the device during the current portion of the write
operations. Bytes not written remain unaltered.
CY7C1525V18 − BWS0 controls D[8:0].
CY7C1512V18 − BWS0 controls D[8:0] and BWS1 controls D[17:9].
CY7C1514V18 − BWS0 controls D[8:0], BWS1 controls D[17:9], BWS2 controls D[26:18] and BWS3 controls
D[35:27].
All the Byte Write Selects are sampled on the same edge as the data. Deselecting a Byte Write Select
ignores the corresponding byte of data and it is not written into the device.
A
InputAddress Inputs. Sampled on the rising edge of the K (read address) and K (write address) clocks during
Synchronous active read and write operations. These address inputs are multiplexed for both read and write operations.
Internally, the device is organized as 8M x 8 (2 arrays each of 4M x 8) for CY7C1510V18, 8M x 9
(2 arrays each of 4M x 9) for CY7C1525V18, 4M x 18 (2 arrays each of 2M x 18) for CY7C1512V18, and
2M x 36 (2 arrays each of 1M x 36) for CY7C1514V18. Therefore, only 22 address inputs are needed to
access the entire memory array of CY7C1510V18 and CY7C1525V18, 21 address inputs for
CY7C1512V18, and 20 address inputs for CY7C1514V18. These inputs are ignored when the appropriate
port is deselected.
Q[x:0]
OutputData Output Signals. These pins drive out the requested data during a read operation. Valid data is
Synchronous driven out on the rising edge of the C and C clocks during read operations, or K and K when in single
clock mode. When the read port is deselected, Q[x:0] are automatically tri-stated.
CY7C1510V18 − Q[7:0]
CY7C1525V18 − Q[8:0]
CY7C1512V18 − Q[17:0]
CY7C1514V18 − Q[35:0]
RPS
InputRead Port Select − Active LOW. Sampled on the rising edge of positive input clock (K). When active, a
Synchronous read operation is initiated. Deasserting deselects the read port. When deselected, the pending access is
allowed to complete and the output drivers are automatically tri-stated following the next rising edge of
the C clock. Each read access consists of a burst of four sequential transfers.
C
Input Clock
Positive Input Clock for Output Data. C is used in conjunction with C to clock out the read data from
the device. Use C and C together to deskew the flight times of various devices on the board back to the
controller. See Application Example on page 9 for further details.
C
Input Clock
Negative Input Clock for Output Data. C is used in conjunction with C to clock out the read data from
the device. Use C and C together to deskew the flight times of various devices on the board back to the
controller. See Application Example on page 9 for further details.
K
Input Clock
Positive Input Clock Input. The rising edge of K is used to capture synchronous inputs to the device
and to drive out data through Q[x:0] when in single clock mode. All accesses are initiated on the rising
edge of K.
K
Input Clock
Negative Input Clock Input. K is used to capture synchronous inputs being presented to the device and
to drive out data through Q[x:0] when in single clock mode.
Document #: 38-05489 Rev. *F
Page 6 of 29
[+] Feedback
CY7C1510V18, CY7C1525V18
CY7C1512V18, CY7C1514V18
Pin Definitions
Pin Name
(continued)
IO
Pin Description
CQ
Echo Clock
CQ Referenced with Respect to C. This is a free-running clock and is synchronized to the input clock
for output data (C) of the QDR-II. In single clock mode, CQ is generated with respect to K. The timing for
the echo clocks is shown in Switching Characteristics on page 23.
CQ
Echo Clock
CQ Referenced with Respect to C. This is a free-running clock and is synchronized to the input clock
for output data (C) of the QDR-II. In single clock mode, CQ is generated with respect to K. The timing for
the echo clocks is shown in the Switching Characteristics on page 23.
ZQ
Input
Output Impedance Matching Input. This input is used to tune the device outputs to the system data bus
impedance. CQ, CQ, and Q[x:0] output impedance are set to 0.2 x RQ, where RQ is a resistor connected
between ZQ and ground. Alternatively, connect this pin directly to VDDQ, which enables the minimum
impedance mode. This pin cannot be connected directly to GND or left unconnected.
DOFF
Input
DLL Turn Off − Active LOW. Connecting this pin to ground turns off the DLL inside the device. The timing
in the operation with the DLL turned off differs from those listed in this data sheet.
TDO
Output
TCK
Input
TCK Pin for JTAG.
TDI
Input
TDI Pin for JTAG.
TMS
Input
TMS Pin for JTAG.
NC
N/A
Not Connected to the Die. Can be tied to any voltage level.
VSS/144M
Input
Address expansion for 144M. Can be tied to any voltage level.
VSS/288M
Input
Address expansion for 288M. Can be tied to any voltage level.
VREF
VDD
VSS
VDDQ
InputReference
TDO for JTAG.
Reference Voltage Input. Static input used to set the reference level for HSTL inputs, outputs, and AC
measurement points.
Power Supply Power Supply Inputs to the Core of the Device.
Ground
Ground for the Device.
Power Supply Power Supply Inputs for the Outputs of the Device.
Document #: 38-05489 Rev. *F
Page 7 of 29
[+] Feedback
CY7C1510V18, CY7C1525V18
CY7C1512V18, CY7C1514V18
Functional Overview
The CY7C1510V18, CY7C1525V18, CY7C1512V18, and
CY7C1514V18 are synchronous pipelined Burst SRAMs with a
read port and a write port. The read port is dedicated to read
operations and the write port is dedicated to write operations.
Data flows into the SRAM through the write port and flows out
through the read port. These devices multiplex the address
inputs to minimize the number of address pins required. By
having separate read and write ports, the QDR-II completely
eliminates the need to turn-around the data bus and avoids any
possible data contention, thereby simplifying system design.
Each access consists of two 8-bit data transfers in the case of
CY7C1510V18, two 9-bit data transfers in the case of
CY7C1525V18, two 18-bit data transfers in the case of
CY7C1512V18, and two 36-bit data transfers in the case of
CY7C1514V18 in one clock cycle.
Accesses for both ports are initiated on the rising edge of the
positive input clock (K). All synchronous input timing is referenced from the rising edge of the input clocks (K and K) and all
output timing is referenced to the output clocks (C and C, or K
and K when in single clock mode).
All synchronous data inputs (D[x:0]) pass through input registers
controlled by the input clocks (K and K). All synchronous data
outputs (Q[x:0]) pass through output registers controlled by the
rising edge of the output clocks (C and C, or K and K when in
single clock mode).
All synchronous control (RPS, WPS, BWS[x:0]) inputs pass
through input registers controlled by the rising edge of the input
clocks (K and K).
CY7C1512V18 is described in the following sections. The same
basic descriptions apply to CY7C1510V18, CY7C1525V18, and
CY7C1514V18.
Read Operations
The CY7C1512V18 is organized internally as two arrays of 2M x
18. Accesses are completed in a burst of two sequential 18-bit
data words. Read operations are initiated by asserting RPS
active at the rising edge of the positive input clock (K). The
address is latched on the rising edge of the K clock. The address
presented to the address inputs is stored in the read address
register. Following the next K clock rise, the corresponding
lowest order 18-bit word of data is driven onto the Q[17:0] using
C as the output timing reference. On the subsequent rising edge
of C, the next 18-bit data word is driven onto the Q[17:0]. The
requested data is valid 0.45 ns from the rising edge of the output
clock (C and C or K and K when in single clock mode).
Synchronous internal circuitry automatically tri-states the outputs
following the next rising edge of the output clocks (C/C). This
enables for a seamless transition between devices without the
insertion of wait states in a depth expanded memory.
Write Operations
Write operations are initiated by asserting WPS active at the
rising edge of the positive input clock (K). On the same K clock
rise the data presented to D[17:0] is latched and stored into the
lower 18-bit write data register, provided BWS[1:0] are both
asserted active. On the subsequent rising edge of the negative
input clock (K), the address is latched and the information
Document #: 38-05489 Rev. *F
presented to D[17:0] is also stored into the write data register,
provided BWS[1:0] are both asserted active. The 36 bits of data
are then written into the memory array at the specified location.
When deselected, the write port ignores all inputs after the
pending write operations have been completed.
Byte Write Operations
Byte write operations are supported by the CY7C1512V18. A
write operation is initiated as described in the Write Operations
section. The bytes that are written are determined by BWS0 and
BWS1, which are sampled with each set of 18-bit data words.
Asserting the appropriate Byte Write Select input during the data
portion of a write latches the data being presented and writes it
into the device. Deasserting the Byte write select input during the
data portion of a write enables the data stored in the device for
that byte to remain unaltered. This feature can be used to
simplify read, modify, or write operations to a byte write
operation.
Single Clock Mode
The CY7C1510V18 can be used with a single clock that controls
both the input and output registers. In this mode the device
recognizes only a single pair of input clocks (K and K) that control
both the input and output registers. This operation is identical to
the operation if the device had zero skew between the K/K and
C/C clocks. All timing parameters remain the same in this mode.
To use this mode of operation, the user must tie C and C HIGH
at power on. This function is a strap option and not alterable
during device operation.
Concurrent Transactions
The read and write ports on the CY7C1512V18 operate
completely independently of one another. As each port latches
the address inputs on different clock edges, the user can read or
write to any location, regardless of the transaction on the other
port. The user can start reads and writes in the same clock cycle.
If the ports access the same location at the same time, the SRAM
delivers the most recent information associated with the
specified address location. This includes forwarding data from a
write cycle that was initiated on the previous K clock rise.
Depth Expansion
The CY7C1512V18 has a port select input for each port. This
enables for easy depth expansion. Both port selects are sampled
on the rising edge of the positive input clock only (K). Each port
select input can deselect the specified port. Deselecting a port
does not affect the other port. All pending transactions (read and
write) are completed before the device is deselected.
Programmable Impedance
An external resistor, RQ, must be connected between the ZQ pin
on the SRAM and VSS to enable the SRAM to adjust its output
driver impedance. The value of RQ must be 5X the value of the
intended line impedance driven by the SRAM. The allowable
range of RQ to guarantee impedance matching with a tolerance
of ±15% is between 175Ω and 350Ω, with VDDQ = 1.5V. The
output impedance is adjusted every 1024 cycles upon power up
to account for drifts in supply voltage and temperature.
Page 8 of 29
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CY7C1510V18, CY7C1525V18
CY7C1512V18, CY7C1514V18
Echo Clocks
DLL
Echo clocks are provided on the QDR-II to simplify data capture
on high-speed systems. Two echo clocks are generated by the
QDR-II. CQ is referenced with respect to C and CQ is referenced
with respect to C. These are free-running clocks and are
synchronized to the output clock of the QDR-II. In the single clock
mode, CQ is generated with respect to K and CQ is generated
with respect to K. The timing for the echo clocks is shown in
Switching Characteristics on page 23.
These chips use a DLL that is designed to function between 120
MHz and the specified maximum clock frequency. During power
up, when the DOFF is tied HIGH, the DLL is locked after 1024
cycles of stable clock. The DLL can also be reset by slowing or
stopping the input clocks K and K for a minimum of 30 ns.
However, it is not necessary to reset the DLL to lock to the
desired frequency. The DLL automatically locks 1024 clock
cycles after a stable clock is presented. The DLL may be
disabled by applying ground to the DOFF pin. For information
refer to the application note AN5062, DLL Considerations in
QDRII/DDRII/QDRII+/DDRII+.
Application Example
Figure 1 shows two QDR-II used in an application.
Figure 1. Application Example
SRAM #1
Vt
R
D
A
R
P
S
#
W
P
S
#
B
W
S
#
ZQ
CQ/CQ#
Q
C C# K K#
DATA IN
DATA OUT
Address
RPS#
BUS
WPS#
MASTER
BWS#
(CPU CLKIN/CLKIN#
or
Source K
ASIC)
Source K#
R = 250ohms
SRAM #2
R
P
S
#
D
A
R
W
P
S
#
B
W
S
#
ZQ R = 250ohms
CQ/CQ#
Q
C C# K K#
Vt
Vt
Delayed K
Delayed K#
R
Document #: 38-05489 Rev. *F
R = 50ohms Vt = Vddq/2
Page 9 of 29
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CY7C1510V18, CY7C1525V18
CY7C1512V18, CY7C1514V18
Truth Table
The truth table for CY7C1510V18, CY7C1525V18, CY7C1512V18, and CY7C1514V18 follow. [2, 3, 4, 5, 6, 7]
Operation
K
RPS WPS
DQ
DQ
Write Cycle:
Load address on the rising edge of K;
input write data on K and K rising edges.
L-H
X
L
D(A + 0) at K(t) ↑
Read Cycle:
Load address on the rising edge of K;
wait one and a half cycle; read data on C and C rising edges.
L-H
L
X
Q(A + 0) at C(t + 1) ↑ Q(A + 1) at C(t + 2) ↑
NOP: No Operation
L-H
H
H
D=X
Q = High-Z
D=X
Q = High-Z
Stopped
X
X
Previous State
Previous State
Standby: Clock Stopped
D(A + 1) at K(t) ↑
Write Cycle Descriptions
The write cycle description table for CY7C1510V18 and CY7C1512V18 follow. [2, 8]
BWS0/ BWS1/
K
K
L
L–H
–
L
L
–
L
H
L–H
L
H
–
H
L
L–H
H
L
–
H
H
L–H
H
H
–
NWS0
NWS1
L
Comments
During the data portion of a write sequence:
CY7C1510V18 − both nibbles (D[7:0]) are written into the device.
CY7C1512V18 − both bytes (D[17:0]) are written into the device.
L-H During the data portion of a write sequence:
CY7C1510V18 − both nibbles (D[7:0]) are written into the device.
CY7C1512V18 − both bytes (D[17:0]) are written into the device.
–
During the data portion of a write sequence:
CY7C1510V18 − only the lower nibble (D[3:0]) is written into the device, D[7:4] remains unaltered.
CY7C1512V18 − only the lower byte (D[8:0]) is written into the device, D[17:9] remains unaltered.
L–H During the data portion of a write sequence:
CY7C1510V18 − only the lower nibble (D[3:0]) is written into the device, D[7:4] remains unaltered.
CY7C1512V18 − only the lower byte (D[8:0]) is written into the device, D[17:9] remains unaltered.
–
During the data portion of a write sequence:
CY7C1510V18 − only the upper nibble (D[7:4]) is written into the device, D[3:0] remains unaltered.
CY7C1512V18 − only the upper byte (D[17:9]) is written into the device, D[8:0] remains unaltered.
L–H During the data portion of a write sequence:
CY7C1510V18 − only the upper nibble (D[7:4]) is written into the device, D[3:0] remains unaltered.
CY7C1512V18 − only the upper byte (D[17:9]) is written into the device, D[8:0] remains unaltered.
–
No data is written into the devices during this portion of a write operation.
L–H No data is written into the devices during this portion of a write operation.
Notes
2. X = “Don't Care,” H = Logic HIGH, L = Logic LOW, ↑represents rising edge.
3. Device powers up deselected with the outputs in a tri-state condition.
4. “A” represents address location latched by the devices when transaction was initiated. A + 0, A + 1 represents the internal address sequence in the burst.
5. “t” represents the cycle at which a Read/Write operation is started. t + 1, and t + 2 are the first, and second clock cycles respectively succeeding the “t” clock cycle.
6. Data inputs are registered at K and K rising edges. Data outputs are delivered on C and C rising edges, except when in single clock mode.
7. It is recommended that K = K and C = C = HIGH when clock is stopped. This is not essential, but permits most rapid restart by overcoming transmission line charging
symmetrically.
8. Is based on a write cycle that was initiated in accordance with the Write Cycle Descriptions table. NWS0, NWS1, BWS0, BWS1, BWS2 and BWS3 can be altered on
different portions of a write cycle, as long as the setup and hold requirements are achieved.
Document #: 38-05489 Rev. *F
Page 10 of 29
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CY7C1510V18, CY7C1525V18
CY7C1512V18, CY7C1514V18
Write Cycle Descriptions
The write cycle description table for CY7C1525V18 follow. [2, 8]
BWS0
K
K
Comments
L
L–H
–
During the Data portion of a write sequence, the single byte (D[8:0]) is written into the device.
L
–
L–H
During the Data portion of a write sequence, the single byte (D[8:0]) is written into the device.
H
L–H
–
No data is written into the device during this portion of a write operation.
H
–
L–H
No data is written into the device during this portion of a write operation.
Write Cycle Descriptions
The write cycle description table for CY7C1514V18 follow. [2, 8]
BWS0
BWS1
BWS2
BWS3
K
K
Comments
L
L
L
L
L–H
–
During the Data portion of a write sequence, all four bytes (D[35:0]) are written into
the device.
L
L
L
L
–
L
H
H
H
L–H
L
H
H
H
–
H
L
H
H
L–H
H
L
H
H
–
H
H
L
H
L–H
H
H
L
H
–
H
H
H
L
L–H
H
H
H
L
–
H
H
H
H
L–H
H
H
H
H
–
Document #: 38-05489 Rev. *F
L–H During the Data portion of a write sequence, all four bytes (D[35:0]) are written into
the device.
–
During the Data portion of a write sequence, only the lower byte (D[8:0]) is written
into the device. D[35:9] remains unaltered.
L–H During the Data portion of a write sequence, only the lower byte (D[8:0]) is written
into the device. D[35:9] remains unaltered.
–
During the Data portion of a write sequence, only the byte (D[17:9]) is written into
the device. D[8:0] and D[35:18] remains unaltered.
L–H During the Data portion of a write sequence, only the byte (D[17:9]) is written into
the device. D[8:0] and D[35:18] remains unaltered.
–
During the Data portion of a write sequence, only the byte (D[26:18]) is written into
the device. D[17:0] and D[35:27] remains unaltered.
L–H During the Data portion of a write sequence, only the byte (D[26:18]) is written into
the device. D[17:0] and D[35:27] remains unaltered.
–
During the Data portion of a write sequence, only the byte (D[35:27]) is written into
the device. D[26:0] remains unaltered.
L–H During the Data portion of a write sequence, only the byte (D[35:27]) is written into
the device. D[26:0] remains unaltered.
–
No data is written into the device during this portion of a write operation.
L–H No data is written into the device during this portion of a write operation.
Page 11 of 29
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CY7C1510V18, CY7C1525V18
CY7C1512V18, CY7C1514V18
IEEE 1149.1 Serial Boundary Scan (JTAG)
These SRAMs incorporate a serial boundary scan Test Access
Port (TAP) in the FBGA package. This part is fully compliant with
IEEE Standard #1149.1-1900. The TAP operates using JEDEC
standard 1.8V IO logic levels.
Disabling the JTAG Feature
It is possible to operate the SRAM 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 alternatively
be connected to VDD through a pull up resistor. TDO must be left
unconnected. Upon power up, the device comes up in a reset
state, which does not interfere with the operation of the device.
Test Access Port—Test Clock
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 (TMS)
The TMS input is used to give commands to the TAP controller
and is sampled on the rising edge of TCK. This pin may be left
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 on page 14. 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.
Instruction Register
Three-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 TAP Controller Block Diagram on
page 15. 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 Capture-IR 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 chips. The bypass
register is a single-bit register that can be placed between TDI
and TDO pins. This enables shifting of data through the SRAM
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 of the input and
output pins on the SRAM. Several No Connect (NC) pins are also
included in the scan register to reserve pins for higher density
devices.
The boundary scan register is loaded with the contents of the
RAM 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, SAMPLE/PRELOAD, and SAMPLE Z instructions can
be used to capture the contents of the input and output ring.
The Boundary Scan Order on page 18 shows the order in which
the bits are connected. Each bit corresponds to one of the bumps
on the SRAM package. The MSB of the register is connected to
TDI, and the LSB is connected to TDO.
Test Data-Out (TDO)
Identification (ID) Register
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 Instruction Codes on page 17).
The output changes on the falling edge of TCK. TDO is
connected to the least significant bit (LSB) of any 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 SRAM 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 Identification Register Definitions on
page 17.
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
SRAM and can be performed while the SRAM 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 to scan
the data in and out of the SRAM 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.
Document #: 38-05489 Rev. *F
TAP Instruction Set
Eight different instructions are possible with the three-bit
instruction register. All combinations are listed in Instruction
Codes on page 17. Three of these instructions are listed as
RESERVED and must not be used. The other five instructions
are described in this section in detail.
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 after it is shifted in, the TAP controller must be
moved into the Update-IR state.
Page 12 of 29
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CY7C1510V18, CY7C1525V18
CY7C1512V18, CY7C1514V18
IDCODE
BYPASS
The IDCODE instruction loads a vendor-specific, 32-bit code into
the instruction register. It also places the instruction register
between the TDI and TDO pins and shifts the IDCODE out of the
device when the TAP controller enters the Shift-DR state. The
IDCODE instruction is loaded into the instruction register at
power up or whenever the TAP controller is supplied a
Test-Logic-Reset state.
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.
SAMPLE Z
The SAMPLE Z instruction connects the boundary scan register
between the TDI and TDO pins when the TAP controller is in a
Shift-DR state. The SAMPLE Z command puts the output bus
into a High-Z state until the next command is supplied during the
Update IR state.
SAMPLE/PRELOAD
SAMPLE/PRELOAD is a 1149.1 mandatory instruction. When
the SAMPLE/PRELOAD instructions are loaded into the
instruction register and the TAP controller is in the Capture-DR
state, a snapshot of data on the input 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 20 MHz, while the SRAM 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 undergoes a
transition. The TAP may then try to capture a signal while in
transition (metastable state). This does not harm the device, but
there is no guarantee as to the value that is captured.
Repeatable results may not be possible.
To guarantee that the boundary scan register captures the
correct value of a signal, the SRAM signal must be stabilized
long enough to meet the TAP controller's capture setup plus hold
times (tCS and tCH). The SRAM clock input might not be captured
correctly if there is no way in a design to stop (or slow) the clock
during a SAMPLE/PRELOAD instruction. If this is an issue, it is
still possible to capture all other signals and simply ignore the
value of the CK and CK captured in the boundary scan register.
EXTEST
The EXTEST instruction drives the preloaded data out through
the system output pins. This instruction also connects the
boundary scan register for serial access between the TDI and
TDO in the Shift-DR controller state.
EXTEST OUTPUT BUS TRI-STATE
IEEE Standard 1149.1 mandates that the TAP controller be able
to put the output bus into a tri-state mode.
The boundary scan register has a special bit located at bit #108.
When this scan cell, called the “extest output bus tri-state,” is
latched into the preload register during the Update-DR state in
the TAP controller, it directly controls the state of the output
(Q-bus) pins, when the EXTEST is entered as the current
instruction. When HIGH, it enables the output buffers to drive the
output bus. When LOW, this bit places the output bus into a
High-Z condition.
This bit can be set by entering the SAMPLE/PRELOAD or
EXTEST command, and then shifting the desired bit into that cell,
during the Shift-DR state. During Update-DR, the value loaded
into that shift-register cell latches into the preload register. When
the EXTEST instruction is entered, this bit directly controls the
output Q-bus pins. Note that this bit is pre-set LOW to enable the
output when the device is powered up, and also when the TAP
controller is in the Test-Logic-Reset state.
Reserved
These instructions are not implemented but are reserved for
future use. Do not use these instructions.
After 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.
PRELOAD places an initial data pattern at the latched parallel
outputs of the boundary scan register cells before the selection
of another boundary scan test operation.
The shifting of data for the SAMPLE and PRELOAD phases can
occur concurrently when required, that is, while the data
captured is shifted out, the preloaded data can be shifted in.
Document #: 38-05489 Rev. *F
Page 13 of 29
[+] Feedback
CY7C1510V18, CY7C1525V18
CY7C1512V18, CY7C1514V18
TAP Controller State Diagram
The state diagram for the TAP controller follows. [9]
1
TEST-LOGIC
RESET
0
0
TEST-LOGIC/
IDLE
1
SELECT
DR-SCAN
1
1
SELECT
IR-SCAN
0
0
1
1
CAPTURE-DR
CAPTURE-IR
0
0
SHIFT-DR
0
SHIFT-IR
1
1
EXIT1-DR
1
EXIT1-IR
0
1
0
PAUSE-DR
0
PAUSE-IR
1
0
1
0
EXIT2-DR
0
EXIT2-IR
1
1
UPDATE-IR
UPDATE-DR
1
0
0
1
0
Note
9. The 0/1 next to each state represents the value at TMS at the rising edge of TCK.
Document #: 38-05489 Rev. *F
Page 14 of 29
[+] Feedback
CY7C1510V18, CY7C1525V18
CY7C1512V18, CY7C1514V18
TAP Controller Block Diagram
0
Bypass Register
2
Selection
Circuitry
TDI
1
0
Selection
Circuitry
Instruction Register
31
30
29
.
.
2
1
0
1
0
TDO
Identification Register
108
.
.
.
.
2
Boundary Scan Register
TCK
TAP Controller
TMS
TAP Electrical Characteristics
Over the Operating Range [10, 11, 12]
Parameter
Description
Test Conditions
Min
Max
Unit
VOH1
Output HIGH Voltage
IOH = −2.0 mA
1.4
V
VOH2
Output HIGH Voltage
IOH = −100 μA
1.6
V
VOL1
Output LOW Voltage
IOL = 2.0 mA
0.4
V
VOL2
Output LOW Voltage
IOL = 100 μA
0.2
V
VIH
Input HIGH Voltage
VIL
Input LOW Voltage
IX
Input and Output Load Current
0.65VDD VDD + 0.3
GND ≤ VI ≤ VDD
V
–0.3
0.35VDD
V
–5
5
μA
Notes
10. These characteristics pertain to the TAP inputs (TMS, TCK, TDI and TDO). Parallel load levels are specified in the Electrical Characteristics table.
11. Overshoot: VIH(AC) < VDDQ + 0.85V (Pulse width less than tCYC/2), Undershoot: VIL(AC) > −1.5V (Pulse width less than tCYC/2).
12. All Voltage referenced to Ground.
Document #: 38-05489 Rev. *F
Page 15 of 29
[+] Feedback
CY7C1510V18, CY7C1525V18
CY7C1512V18, CY7C1514V18
TAP AC Switching Characteristics
Over the Operating Range [13, 14]
Parameter
Description
Min
Max
Unit
20
MHz
tTCYC
TCK Clock Cycle Time
tTF
TCK Clock Frequency
tTH
TCK Clock HIGH
20
ns
tTL
TCK Clock LOW
20
ns
tTMSS
TMS Setup to TCK Clock Rise
5
ns
tTDIS
TDI Setup to TCK Clock Rise
5
ns
tCS
Capture Setup to TCK Rise
5
ns
tTMSH
TMS Hold after TCK Clock Rise
5
ns
tTDIH
TDI Hold after Clock Rise
5
ns
tCH
Capture Hold after Clock Rise
5
ns
50
ns
Setup Times
Hold Times
Output Times
tTDOV
TCK Clock LOW to TDO Valid
tTDOX
TCK Clock LOW to TDO Invalid
10
0
ns
ns
TAP Timing and Test Conditions
Figure 2 shows the TAP timing and test conditions. [14]
Figure 2. TAP Timing and Test Conditions
0.9V
ALL INPUT PULSES
1.8V
50Ω
0.9V
TDO
0V
Z0 = 50Ω
(a)
CL = 20 pF
tTH
GND
tTL
Test Clock
TCK
tTCYC
tTMSH
tTMSS
Test Mode Select
TMS
tTDIS
tTDIH
Test Data In
TDI
Test Data Out
TDO
tTDOV
tTDOX
Notes
13. tCS and tCH refer to the setup and hold time requirements of latching data from the boundary scan register.
14. Test conditions are specified using the load in TAP AC Test Conditions. tR/tF = 1 ns.
Document #: 38-05489 Rev. *F
Page 16 of 29
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CY7C1510V18, CY7C1525V18
CY7C1512V18, CY7C1514V18
Identification Register Definitions
Instruction Field
Value
CY7C1510V18
CY7C1525V18
CY7C1512V18
CY7C1514V18
000
000
000
000
Cypress Device ID
(28:12)
11010011010000100
11010011010001100
11010011010010100
Cypress JEDEC ID
(11:1)
00000110100
00000110100
00000110100
00000110100
1
1
1
1
Revision Number
(31:29)
ID Register
Presence (0)
Description
Version number.
11010011010100100 Defines the type of
SRAM.
Allows unique
identification of
SRAM vendor.
Indicates the
presence of an ID
register.
Scan Register Sizes
Register Name
Bit Size
Instruction
3
Bypass
1
ID
32
Boundary Scan
109
Instruction Codes
Instruction
Code
Description
EXTEST
000
Captures the input and output ring contents.
IDCODE
001
Loads the ID register with the vendor ID code and places the register between TDI and TDO.
This operation does not affect SRAM operation.
SAMPLE Z
010
Captures the input and output contents. Places the boundary scan register between TDI and
TDO. Forces all SRAM output drivers to a High-Z state.
RESERVED
011
Do Not Use: This instruction is reserved for future use.
SAMPLE/PRELOAD
100
Captures the input and output contents. Places the boundary scan register between TDI and
TDO. Does not affect the SRAM operation.
RESERVED
101
Do Not Use: This instruction is reserved for future use.
RESERVED
110
Do Not Use: This instruction is reserved for future use.
BYPASS
111
Places the bypass register between TDI and TDO. This operation does not affect SRAM
operation.
Document #: 38-05489 Rev. *F
Page 17 of 29
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CY7C1512V18, CY7C1514V18
Boundary Scan Order
Bit #
Bump ID
Bit #
Bump ID
Bit #
Bump ID
Bit #
Bump ID
0
6R
28
10G
56
6A
84
1J
1
6P
29
9G
57
5B
85
2J
2
6N
30
11F
58
5A
86
3K
3
7P
31
11G
59
4A
87
3J
4
7N
32
9F
60
5C
88
2K
5
7R
33
10F
61
4B
89
1K
6
8R
34
11E
62
3A
90
2L
7
8P
35
10E
63
2A
91
3L
8
9R
36
10D
64
1A
92
1M
9
11P
37
9E
65
2B
93
1L
10
10P
38
10C
66
3B
94
3N
3M
11
10N
39
11D
67
1C
95
12
9P
40
9C
68
1B
96
1N
13
10M
41
9D
69
3D
97
2M
14
11N
42
11B
70
3C
98
3P
15
9M
43
11C
71
1D
99
2N
16
9N
44
9B
72
2C
100
2P
17
11L
45
10B
73
3E
101
1P
18
11M
46
11A
74
2D
102
3R
19
9L
47
10A
75
2E
103
4R
20
10L
48
9A
76
1E
104
4P
21
11K
49
8B
77
2F
105
5P
22
10K
50
7C
78
3F
106
5N
23
9J
51
6C
79
1G
107
5R
24
9K
52
8A
80
1F
108
Internal
25
10J
53
7A
81
3G
26
11J
54
7B
82
2G
27
11H
55
6B
83
1H
Document #: 38-05489 Rev. *F
Page 18 of 29
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CY7C1512V18, CY7C1514V18
Power Up Sequence in QDR-II SRAM
QDR-II SRAMs must be powered up and initialized in a
predefined manner to prevent undefined operations.
Power Up Sequence
■
Apply power and drive DOFF either HIGH or LOW (All other
inputs can be HIGH or LOW).
❐ Apply VDD before VDDQ.
❐ Apply VDDQ before VREF or at the same time as VREF.
❐ Drive DOFF HIGH.
■
Provide stable DOFF (HIGH), power and clock (K, K) for 1024
cycles to lock the DLL.
DLL Constraints
■
DLL uses K clock as its synchronizing input. The input must
have low phase jitter, which is specified as tKC Var.
■
The DLL functions at frequencies down to 120 MHz.
■
If the input clock is unstable and the DLL is enabled, then the
DLL may lock onto an incorrect frequency, causing unstable
SRAM behavior. To avoid this, provide1024 cycles stable clock
to relock to the desired clock frequency.
~
~
Figure 3. Power Up Waveforms
K
K
~
~
Unstable Clock
> 1024 Stable clock
Start Normal
Operation
Clock Start (Clock Starts after V DD / V DDQ Stable)
VDD / VDDQ
DOFF
Document #: 38-05489 Rev. *F
V DD / V DDQ Stable (< +/- 0.1V DC per 50ns )
Fix High (or tie to VDDQ)
Page 19 of 29
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CY7C1512V18, CY7C1514V18
Maximum Ratings
Exceeding maximum ratings may impair the useful life of the
device. These user guidelines are not tested.
Current into Outputs (LOW) ........................................ 20 mA
Storage Temperature ................................. –65°C to +150°C
Latch-up Current ................................................... > 200 mA
Ambient Temperature with Power Applied.. –55°C to +125°C
Supply Voltage on VDD Relative to GND ........–0.5V to +2.9V
Supply Voltage on VDDQ Relative to GND.......–0.5V to +VDD
DC Applied to Outputs in High-Z ........ –0.5V to VDDQ + 0.5V
DC Input Voltage [11] .............................. –0.5V to VDD + 0.5V
Static Discharge Voltage (MIL-STD-883, M. 3015).. > 2001V
Operating Range
Range
Commercial
Industrial
Ambient
Temperature (TA)
VDD [15]
VDDQ [15]
0°C to +70°C
1.8 ± 0.1V
1.4V to
VDD
–40°C to +85°C
Electrical Characteristics
DC Electrical Characteristics
Over the Operating Range [12]
Parameter
Description
Test Conditions
Min
Typ
Max
Unit
1.7
1.8
1.9
V
1.4
1.5
VDD
Power Supply Voltage
VDDQ
IO Supply Voltage
VDD
V
VOH
Output HIGH Voltage
Note 16
VDDQ/2 – 0.12
VDDQ/2 + 0.12
V
VOL
Output LOW Voltage
Note 17
VDDQ/2 – 0.12
VDDQ/2 + 0.12
V
VOH(LOW)
Output HIGH Voltage
IOH = −0.1 mA, Nominal Impedance
VDDQ – 0.2
VDDQ
V
VOL(LOW)
Output LOW Voltage
IOL = 0.1 mA, Nominal Impedance
VSS
0.2
V
VIH
Input HIGH Voltage
VREF + 0.1
VDDQ + 0.3
V
VIL
Input LOW Voltage
–0.3
VREF – 0.1
V
IX
Input Leakage Current
GND ≤ VI ≤ VDDQ
−5
5
μA
IOZ
Output Leakage Current
GND ≤ VI ≤ VDDQ, Output Disabled
VREF
Input Reference Voltage [18] Typical Value = 0.75V
IDD
[19]
VDD Operating Supply
VDD = Max,
IOUT = 0 mA,
f = fMAX = 1/tCYC
−5
5
μA
0.95
V
(x8)
850
mA
0.68
250MHz
200MHz
167MHz
0.75
(x9)
850
(x18)
900
(x36)
1100
(x8)
750
(x9)
750
(x18)
800
(x36)
900
(x8)
700
(x9)
700
(x18)
750
(x36)
800
mA
mA
Notes
15. Power up: Assumes a linear ramp from 0V to VDD(min) within 200 ms. During this time VIH < VDD and VDDQ < VDD.
16. Output are impedance controlled. IOH = −(VDDQ/2)/(RQ/5) for values of 175 ohms