SONY CXK79M36C162GB

SONY ΣRAM™
CXK79M36C162GB
18Mb 1x2Lp HSTL High Speed Synchronous SRAMs (512Kb x 36)
33/4/5
Preliminary
Description
The CXK79M36C162GB is a high speed CMOS synchronous static RAM with common I/O pins. It is manufactured in compliance with the JEDEC-standard 209 pin BGA package pinout defined for SigmaRAM™ devices. It integrates input registers,
high speed RAM, output registers, and a two-deep write buffer onto a single monolithic IC. Double Data Rate (DDR) Pipelined
(PL) read operations and Late Write (LW) write operations are supported, providing a high-performance user interface. Positive
and negative output clocks are provided for applications requiring source-synchronous operation.
All address and control input signals are registered on the rising edge of the CK differential input clock.
During read operations, output data is driven valid twice, from both the rising and falling edges of CK, beginning one full cycle
after the address and control signals are registered.
During write operations, input data is registered twice, on both the rising and falling edges of CK, beginning one full cycle after
the address and control signals are registered.
Because two pieces of data are always transferred during read and write operations, the least significant address bit of the internal memory array is not available as an external address pin to this device. Consequently, the number of external address pins
available to the device is one less than the specified depth of the device (i.e. the 512Kb x 36 device has 18, not 19, external
address pins). And, the user cannot choose the order in which the two pieces of data are read. Read data is always provided in
the same order in which it is written.
Output drivers are series-terminated, and output impedance is programmable via the ZQ control pin. When an external resistor
RQ is connected between ZQ and VSS, the impedance of the SRAM’s output drivers is set to ~RQ/5.
300 MHz operation (600 Mbps) is obtained from a single 1.8V power supply. JTAG boundary scan interface is provided using
a subset of IEEE standard 1149.1 protocol.
Features
•
3 Speed Bins
Cycle Time / Data Access Time
-33
3.3ns / 1.8ns
-4
4.0ns / 2.1ns
-5
5.0ns / 2.3ns
• Single 1.8V power supply (VDD): 1.7V (min) to 1.95V (max)
• Dedicated output supply voltage (VDDQ): 1.4V (min) to VDD (max)
• HSTL-compatible I/O interface with dedicated input reference voltage (VREF): VDDQ/2 typical
• Common I/O
• Double Data Rate (DDR) data transfers
• Pipelined (PL) read operations
• Late Write (LW) write operations
• Burst capability with internally controlled Linear Burst address sequencing
• Burst length of two or four, with automatic address wrap
• Full read/write data coherency
• Differential input clocks (CK and CK)
• Data-referenced output clocks (CQ1, CQ1, CQ2, CQ2)
• Programmable output driver impedance via dedicated control pin (ZQ)
• Depth expansion capability (2 or 4 banks) via programmable chip enables (E2, E3, EP2, EP3)
• JTAG boundary scan (subset of IEEE standard 1149.1)
• 209 pin (11x19), 1mm pitch, 14mm x 22mm Ball Grid Array (BGA) package
18Mb 1x2Lp, HSTL, rev 1.1
1 / 25
November 8, 2002
SONY® ΣRAM
Preliminary
CXK79M36C162GB
512Kb x 36 Pin Assignment (Top View)
1
2
3
4
5
6
7
8
9
10
11
A
NC
NC
A
E2
A
ADV
A
E3
A
DQ
DQ
B
NC
NC
MCL (2)
NC
A
(x36)
W
A
MCL (2)
NC
DQ
DQ
C
NC
NC
NC
MCL (2)
NC
(144M)
E1
NC
NC
MCL (2)
DQ
DQ
D
NC
NC
VSS
VREF
NC
MCL
NC
VREF
VSS
DQ
DQ
E
NC
DQ
VDDQ
VDDQ
VDD
VDD
VDD
VDDQ
VDDQ
NC
DQ
F
DQ
DQ
VSS
VSS
VSS
ZQ
VSS
VSS
VSS
NC
NC
G
DQ
DQ
VDDQ
VDDQ
VDD
EP2
VDD
VDDQ
VDDQ
NC
NC
H
DQ
DQ
VSS
VSS
VSS
EP3
VSS
VSS
VSS
NC
NC
J
DQ
DQ
VDDQ
VDDQ
VDD
MCH
VDD
VDDQ
VDDQ
NC
NC
K
CQ2
CQ2
CK
CK
VSS
MCL
VSS
NC
NC
CQ1
CQ1
L
NC
NC
VDDQ
VDDQ
VDD
MCL
VDD
VDDQ
VDDQ
DQ
DQ
M
NC
NC
VSS
VSS
VSS
MCH
VSS
VSS
VSS
DQ
DQ
N
NC
NC
VDDQ
VDDQ
VDD
MCH
VDD
VDDQ
VDDQ
DQ
DQ
P
NC
NC
VSS
VSS
VSS
MCL
VSS
VSS
VSS
DQ
DQ
R
DQ
NC
VDDQ
VDDQ
VDD
VDD
VDD
VDDQ
VDDQ
DQ
NC
T
DQ
DQ
VSS
VREF
NC
MCL
NC
VREF
VSS
NC
NC
U
DQ
DQ
NC
A
NC
(72M)
A
NC
(36M)
A
NC
NC
NC
V
DQ
DQ
A
A
A
A1
A
A
A
NC
NC
W
DQ
DQ
TMS
TDI
A
MCL (1)
A
TDO
TCK
NC
NC
Notes:
1: Pin 6W is defined as Address Pin A0 in Single Data Rate (SDR) Common I/O SigmaRAMs. However, it must be tied “low”
in this device. The least significant address bit of the internal memory array is not available as an externally controlled address pin in Double Data Rate (DDR) Common I/O SigmaRAMs.
2. Pins 3B, 4C, 8B, and 9C are defined as Byte Write Enable Pins Bx in x36 Single Data Rate (SDR) Common I/O SigmaRAMs. However, they must be tied “low” in this device. Byte Write functionality is not supported in Double Data Rate
(DDR) Common I/O SigmaRAMs.
18Mb 1x2Lp, HSTL, rev 1.1
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November 8, 2002
SONY® ΣRAM
CXK79M36C162GB
Preliminary
Pin Description
Symbol
Type
Quantity
Description
A
Input
17
Address Inputs - Registered on the rising edge of CK.
A1
Input
1
Address Input 1 - Registered on the rising edge of CK. Initializes burst counter.
DQ
I/O
36
Data Inputs / Outputs - Registered on the rising and falling edges of CK during write
operations. Driven from the rising and falling edges of CK during read operations.
CK, CK
Input
2
Differential Input Clocks
CQ1, CQ1
CQ2, CQ2
Output
4
Output Clocks
E1
Input
1
Chip Enable Control Input - Registered on the rising edge of CK.
E1 = 0 enables the device to accept read and write commands.
E1 = 1 disables the device.
See the Clock Truth Table section for further information.
E2, E3
Input
2
Programmable Chip Enable Control Inputs - Registered on the rising edge of CK. See
the Clock Truth Table and Depth Expansion sections for further information.
EP2, EP3
Input
2
Programmable Chip Enable Active-Level Select Inputs - These pins must be tied
“high” or “low” at power-up. See the Clock Truth Table and Depth Expansion sections for further information.
ADV
Input
1
Address Advance Control Input - Registered on the rising edge of CK.
ADV = 0 loads a new address and begins a new operation when the device is
enabled.
ADV = 1 increments the address and continues the previous operation when the
device is enabled.
See the Clock Truth Table section for further information.
W
Input
1
Write Enable Control Input - Registered on the rising edge of CK.
W = 0 specifies a write operation when ADV = 0 and the device is enabled.
W = 1 specifies a read operation when ADV = 0 and the device is enabled.
See the Clock Truth Table section for further information.
ZQ
Input
1
Output Impedance Control Resistor Input - This pin must be tied to VSS through an
external resistor RQ at power-up. Output driver impedance is set to one-fifth the
value of RQ, nominally. See the Output Driver Impedance Control section for further
information.
VDD
14
1.8V Core Power Supply - Core supply voltage.
VDDQ
24
Output Power Supply - Output buffer supply voltage.
VREF
4
Input Reference Voltage - Input buffer threshold voltage.
VSS
30
Ground
TCK
Input
1
JTAG Clock
TMS
Input
1
JTAG Mode Select - Weakly pulled “high” internally.
TDI
Input
1
JTAG Data In - Weakly pulled “high” internally.
TDO
Output
1
JTAG Data Out
MCL
*Input*
10
Must Connect “Low” - May not be actual input pins.
MCH
*Input*
3
Must Connect “High” - May not be actual input pins.
52
No Connect - These pins are true no-connects, i.e. there is no internal chip connection
to these pins. They can be left unconnected or tied directly to VSS.
NC
18Mb 1x2Lp, HSTL, rev 1.1
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November 8, 2002
SONY® ΣRAM
Preliminary
CXK79M36C162GB
Clock Truth Table
CK
E1 E ADV W
(tn) (tn) (tn) (tn)
Previous
Operation
↑
X
F
0
X
X
↑
X
X
1
X
Bank Deselect
↑
1
T
0
X
X
↑
X
X
1
X
Deselect
↑
0
T
0
0
X
↑
X
X
1
X
Write
↑
0
T
0
1
X
↑
X
X
1
X
Read
Current Operation
DQ/CQ
(tn)
DQ/CQ
(tn+½)
DQ/CQ
(tn+1)
DQ/CQ
(tn+1½)
Bank Deselect
***
Hi-Z
Bank Deselect (Continue)
Hi-Z
Hi-Z
Deselect
***
Hi-Z/CQ
Hi-Z/CQ
Hi-Z/CQ
Deselect (Continue)
Write
Loads new address
Write Continue
Increments address by 2
Read
Loads new address
Read Continue
Increments address by 2
***
***
D1/CQ
D2/CQ
D1/CQ
D2/CQ
D3/CQ
D4/CQ
***
***
Q1/CQ
Q2/CQ
Q1/CQ
Q2/CQ
Q3/CQ
Q4/CQ
Notes:
1. “1” = input “high”; “0” = input “low”; “X” = input “don’t care”; “T” = input “true”; “F” = input “false”.
2. “***” indicates that the DQ input requirement or output state and the CQ output state are determined by the previous operation.
3. If E2 = EP2 and E3 = EP3 then E = “T” else E = “F”.
4. DQs are tri-stated in response to Bank Deselect, Deselect, and Write commands, one full cycle after the command is sampled.
5. CQs are tri-stated in response to Bank Deselect commands only, one full cycle after the command is sampled.
6. One (1) Continue operation may be initiated after a Read or Write operation is initiated to burst transfer four (4) distinct pieces of data per single external address input. If a second (2nd) Continue operation is initiated, the internal address wraps back
to the initial external (base) address.
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November 8, 2002
SONY® ΣRAM
Preliminary
CXK79M36C162GB
State Diagram
X,F,0,X or X,X,1,X
Bank
Deselect
0,T,0,1
0,T,0,0
1,T,0,X
X,F,0,X
Deselect
0,T,0,1
0,T,0,0
1,T,0,X or X,X,1,X
1,T,0,X
1,T,0,X
0,T,0,0
Read
Write
0,T,0,1
X,F,0,X
0,T,0,1
X,X,1,X
X,X,1,X
0,T,0,1
1,T,0,X
X,F,0,X
Read
Continue
X,F,0,X
0,T,0,0
0,T,0,0
0,T,0,0 0,T,0,1
X,X,1,X
Write
Continue
1,T,0,X
X,F,0,X
X,X,1,X
Notes:
1. The notation “X,X,X,X” controlling the state transitions above indicate the states of inputs E1, E, ADV, and W respectively.
2. “1” = input “high”; “0” = input “low”; “X” = input “don’t care”; “T” = input “true”; “F” = input “false”.
3. If E2 = EP2 and E3 = EP3 then E = “T” else E = “F”.
18Mb 1x2Lp, HSTL, rev 1.1
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November 8, 2002
SONY® ΣRAM
CXK79M36C162GB
Preliminary
•Burst (Continue) Operations
Because two pieces of data are always transferred during read and write operations, the least significant address bit (A0) of
the internal memory array is not available as an external address pin to these devices. Rather, the address bit is set to “0”
internally prior to the first data transfer and set to “1” internally prior to the second data transfer. Consequently, the two pieces
of data transferred during read and write operations are always read in the same address sequence in which they are written.
Burst operations follow the simple address sequence depicted in the table below:
A1
A1
Sequence Key
1st (Base) Address
0
1
A1
2nd Address
1
0
A1
One (1) Continue operation may be initiated after a Read or Write operation is initiated to burst transfer four (4) distinct pieces of data per single external address input. If a second (2nd) Continue operation is initiated, the internal address wraps back
to the initial external (base) address.
•Depth Expansion
Depth expansion in these devices is supported via programmable chip enables E2 and E3. The active levels of E2 and E3 are
programmable through the static inputs EP2 and EP3 respectively. When EP2 is tied “high”, E2 functions as an active-high
input. When EP2 is tied “low”, E2 functions as an active-low input. Similarly, when EP3 is tied “high”, E3 functions as an
active-high input. And, when EP3 is tied “low”, E3 functions as an active-low input.
The programmability of E2 and E3 allows four banks of depth expansion to be accomplished with no additional logic. By
programming E2 and E3 of four devices in a binary sequence (00, 01, 10, 11), and by driving E2 and E3 with external address
signals, the four devices can be made to look like one larger device.
When these devices are deselected via chip enable E1, the output clocks continue to toggle. However, when these devices
are deselected via programmable chip enables E2 or E3, the output clocks are forced to a Hi-Z state. See the Clock Truth
Table for further information.
•Output Driver Impedance Control
The impedance of the data and clock output drivers in these devices can be controlled via the static input ZQ. When an external impedance matching resistor (RQ) is connected between ZQ and VSS, output driver impedance is set to one-fifth the
value of the resistor, nominally. See the DC Electrical Characteristics section for further information.
Output driver impedance is updated whenever the data output drivers are in an inactive (High-Z) state. See the Clock Truth
Table section for information concerning which commands deactivate the data output drivers.
At power up, 8192 clock cycles followed by any command that deactivates the data output drivers are required to ensure that
the output impedance has reached the desired value.
Note: The impedance of the output drivers will drift somewhat due to changes in temperature and voltage. Consequently,
during operation, the output drivers should be deactivated periodically in order to update the output impedance and ensure
that it remains within specified tolerances.
•Power-Up Sequence
For reliability purposes, Sony recommends that power supplies power up in the following sequence: VSS, VDD, VDDQ, VREF,
and Inputs. VDDQ should never exceed VDD. If this power supply sequence cannot be met, a large bypass diode may be required between VDD and VDDQ. Please contact Sony Memory Application Department for further information.
18Mb 1x2Lp, HSTL, rev 1.1
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November 8, 2002
SONY® ΣRAM
Preliminary
CXK79M36C162GB
•Absolute Maximum Ratings
Parameter
Symbol
Rating
Units
Supply Voltage
VDD
-0.5 to +2.5
V
Output Supply Voltage
VDDQ
-0.5 to +2.3
V
VIN
-0.5 to VDDQ+0.5 (2.3V max)
V
Input Voltage (EP2, EP3)
(MCH pins 6J, 6M, 6N)
(MCL pins 6D, 6K, 6L, 6P, 6T)
VMIN
-0.5 to VDD+0.5 (2.5V max)
V
Input Voltage (TCK, TMS, TDI)
VTIN
-0.5 to VDD+0.5 (2.5V max)
V
Operating Temperature
TA
0 to 85
°C
Junction Temperature
TJ
0 to 110
°C
Storage Temperature
TSTG
-55 to 150
°C
Input Voltage (Address, Control, Data, Clock)
(MCL pins 3B, 8B, 4C, 9C, 6W)
Note: Stresses greater than those listed under “Absolute Maximum Ratings” may cause permanent damage to the device.
This is a stress rating only, and functional operation of the device at these or any other conditions other than those indicated
in the operational sections of this specification is not implied. Exposure to absolute maximum rating conditions for extended
periods may affect reliability.
•BGA Package Thermal Characteristics
Parameter
Junction to Case Temperature
Symbol
Rating
Units
ΘJC
3.6
°C/W
•I/O Capacitance
(TA = 25oC, f = 1 MHz)
Parameter
Input Capacitance
Symbol
Test conditions
Min
Max
Units
Address
CIN
VIN = 0V
---
3.5
pF
Control
CIN
VIN = 0V
---
3.5
pF
CK Clock
CKIN
VKIN = 0V
---
4.0
pF
Data
COUT
VOUT = 0V
---
4.5
pF
CQ Clock
COUT
VOUT = 0V
---
4.5
pF
Output Capacitance
Note: These parameters are sampled and are not 100% tested.
18Mb 1x2Lp, HSTL, rev 1.1
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November 8, 2002
SONY® ΣRAM
Preliminary
CXK79M36C162GB
•DC Recommended Operating Conditions
Parameter
(VSS = 0V, TA = 0 to 85oC)
Symbol
Min
Typ
Max
Units
Notes
Supply Voltage
VDD
1.7
1.8
1.95
V
Output Supply Voltage
VDDQ
1.4
---
VDD
V
Input Reference Voltage
VREF
VDDQ/2 - 0.1
VDDQ/2
VDDQ/2 + 0.1
V
1
Input High Voltage (Address, Control, Data)
VIH
VREF + 0.2
---
VDDQ + 0.3
V
2
Input Low Voltage (Address, Control, Data)
VIL
-0.3
---
VREF - 0.2
V
3
Input High Voltage (EP2, EP3, MCH)
VMIH
VREF + 0.3
---
VDD + 0.3
V
Input Low Voltage (EP2, EP3, MCL)
VMIL
-0.3
---
VREF - 0.3
V
Clock Input Signal Voltage
VKIN
-0.3
---
VDDQ + 0.3
V
Clock Input Differential Voltage
VDIF
0.4
---
VDDQ + 0.6
V
Clock Input Common Mode Voltage
VCM
VDDQ/2 - 0.1
VDDQ/2
VDDQ/2 + 0.1
V
2,3
1. The peak-to-peak AC component superimposed on VREF may not exceed 5% of the DC component.
2. VIH (max) AC = VDDQ + 0.9V for pulse widths less than one-quarter of the cycle time (tCYC/4).
3. VIL (min) AC = -0.9V for pulse widths less than one-quarter of the cycle time (tCYC/4).
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November 8, 2002
SONY® ΣRAM
Preliminary
CXK79M36C162GB
•DC Electrical Characteristics
Parameter
Symbol
Input Leakage Current
(Address, Control, Clock)
ILI
Input Leakage Current
(EP2, EP3)
(VDD = 1.8V ± 0.1V, VSS = 0V, TA = 0 to 85oC)
Test Conditions
Min
Typ
Max
Units
VIN = VSS to VDDQ
-5
---
5
uA
IMLI1
VMIN = VSS to VDD
-10
---
10
uA
Input Leakage Current
(MCH)
IMLI2
VMIN = VMIH (min) to VDD
-10
---
10
uA
Input Leakage Current
(MCL)
IMLI3
VMIN = VSS to VMIL (max)
-10
---
10
uA
VOUT = VSS to VDDQ
-10
---
10
uA
Output Leakage Current
ILO
Average Power Supply
Operating Current
IDD-33
IDD-4
IDD-5
IOUT = 0 mA
VIN = VIH or VIL
-------
-------
750
650
550
mA
Power Supply Deselect
Operating Current
IDD2
IOUT = 0 mA
VIN = VIH or VIL
---
---
250
mA
Output High Voltage
VOH
IOH = -7.0 mA
RQ = 250Ω
VDDQ - 0.4
---
---
V
Output Low Voltage
VOL
IOL = 7.0 mA
RQ = 250Ω
---
---
0.4
V
---
---
35
Ω
VOH, VOL = VDDQ/2
150Ω ≤ RQ ≤ 300Ω
(RQ/5)*
0.85
RQ/5
(RQ/5)*
1.15
Ω
VOH, VOL = VDDQ/2
51
---
---
Ω
VOH, VOL = VDDQ/2
RQ < 150Ω
Output Driver Impedance
ROUT
RQ > 300Ω
(60*0.85)
(30*1.15)
Notes
1
2
1. For maximum output drive (i.e. minimum impedance), the ZQ pin can be tied directly to VSS.
2. For minimum output drive (i.e. maximum impedance), the ZQ pin can be left unconnected or tied directly to VDDQ.
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November 8, 2002
SONY® ΣRAM
Preliminary
CXK79M36C162GB
•AC Electrical Characteristics
(VDD = 1.8V ± 0.1V, VSS = 0V, TA = 0 to 85oC)
-33
Parameter
-4
-5
Symbol
Units Notes
Min
Max
Min
Max
Min
Max
Input Clock Cycle Time
tKHKH
3.3
---
4.0
---
5.0
---
ns
Input Clock High Pulse Width
tKHKL
1.3
---
1.5
---
2.0
---
ns
Input Clock Low Pulse Width
tKLKH
1.3
---
1.5
---
2.0
---
ns
Address Input Setup Time
tAVKH
0.7
---
0.8
---
1.0
---
ns
Address Input Hold Time
tKHAX
0.4
---
0.5
---
0.5
---
ns
Control Input Setup Time
tBVKH
0.7
---
0.8
---
1.0
---
ns
1
Control Input Hold Time
tKHBX
0.4
---
0.5
---
0.5
---
ns
1
Data Input Setup Time
tDVKH
tDVKL
0.35
---
0.4
---
0.45
---
ns
Data Input Hold Time
tKHDX
tKLDX
0.3
---
0.35
---
0.4
---
ns
Input Clock High to Output Data Valid
Input Clock Low to Output Data Valid
tKHQV
tKLQV
---
1.8
---
2.1
---
2.3
ns
Input Clock High to Output Data Hold
Input Clock Low to Output Data Hold
tKHQX
tKLQX
0.5
---
0.5
---
0.5
---
ns
2
Input Clock High to Output Data Low-Z
tKHQX1
0.5
---
0.5
---
0.5
---
ns
2,3
Input Clock High to Output Data High-Z
tKHQZ
---
1.8
---
2.1
---
2.3
ns
2,3
Input Clock High to Output Clock High
Input Clock Low to Output Clock Low
tKHCH
tKLCL
0.5
1.8
0.5
2.1
0.5
2.3
ns
Input Clock High to Output Clock Low-Z
tKHCX1
0.5
---
0.5
---
0.5
---
ns
2,3
Input Clock High to Output Clock High-Z
tKHCZ
---
1.8
---
2.1
---
2.3
ns
2,3
Output Clock High to Output Data Valid
Output Clock Low to Output Data Valid
tCHQV
tCLQV
---
0.25
---
0.25
---
0.3
ns
2
Output Clock High to Output Data Hold
Output Clock Low to Output Data Hold
tCHQX
tCLQX
-0.25
---
-0.25
---
-0.3
---
ns
2
All parameters are measured from the mid-point of the object signal to the mid-point of the reference signal, unless otherwise noted.
1. These parameters apply to control inputs E1, E2, E3, ADV, and W.
2. These parameters are guaranteed by design through extensive corner lot characterization.
3. These parameters are measured at ± 50mV from steady state voltage.
18Mb 1x2Lp, HSTL, rev 1.1
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November 8, 2002
SONY® ΣRAM
CXK79M36C162GB
Preliminary
•AC Electrical Characteristics (Note)
The four AC timing parameters listed below are tested according to specific combinations of Output Clocks (CQs) and Output Data (DQs):
1. tCHQV -
Output Clock High to Output Data Valid (max)
2. tCLQV -
Output Clock Low to Output Data Valid (max)
3. tCHQX -
Output Clock High to Output Data Hold (min)
4. tCLQX -
Output Clock Low to Output Data Hold (min)
The specific CQ / DQ combinations are defined as follows:
512Kb x 36
CQs
1K, 2K
DQs
2E, 1F, 2F, 1G, 2G, 1H, 2H, 1J, 2J,
1R, 1T, 2T, 1U, 2U, 1V, 2V, 1W, 2W
10K, 11K 10A, 11A, 10B, 11B, 10C, 11C, 10D, 11D, 11E,
10L, 11L, 10M, 11M, 10N, 11N, 10P, 11P, 10R
18Mb 1x2Lp, HSTL, rev 1.1
11 / 25
November 8, 2002
SONY® ΣRAM
Preliminary
CXK79M36C162GB
•AC Test Conditions (VDDQ = 1.8V)
Parameter
(VDD = 1.8V ± 0.1V, VDDQ = 1.8V ± 0.1V, TA = 0 to 85°C)
Symbol
Conditions
Units
VREF
0.9
V
Input High Level
VIH
1.4
V
Input Low Level
VIL
0.4
V
Input Rise & Fall Time
2.0
V/ns
Input Reference Level
0.9
V
Input Reference Voltage
Notes
Clock Input High Voltage
VKIH
1.4
V
VDIF = 1.0V
Clock Input Low Voltage
VKIL
0.4
V
VDIF = 1.0V
Clock Input Common Mode Voltage
VCM
0.9
V
Clock Input Rise & Fall Time
2.0
V/ns
Clock Input Reference Level
CK/CK cross
V
Output Reference Level
0.9
V
Output Load Conditions
RQ = 250Ω
See Figure 1
below
Figure 1: AC Test Output Load (VDDQ = 1.8V)
0.9 V
16.7 Ω
50 Ω
50 Ω
5 pF
DQ
16.7 Ω
0.9 V
16.7 Ω
50 Ω
50 Ω
5 pF
18Mb 1x2Lp, HSTL, rev 1.1
12 / 25
November 8, 2002
SONY® ΣRAM
Preliminary
CXK79M36C162GB
•AC Test Conditions (VDDQ = 1.5V)
Parameter
(VDD = 1.8V ± 0.1V, VDDQ = 1.5V ± 0.1V, TA = 0 to 85°C)
Symbol
Conditions
Units
VREF
0.75
V
Input High Level
VIH
1.25
V
Input Low Level
VIL
0.25
V
Input Rise & Fall Time
2.0
V/ns
Input Reference Level
0.75
V
Input Reference Voltage
Notes
Clock Input High Voltage
VKIH
1.25
V
VDIF = 1.0V
Clock Input Low Voltage
VKIL
0.25
V
VDIF = 1.0V
Clock Input Common Mode Voltage
VCM
0.75
V
Clock Input Rise & Fall Time
2.0
V/ns
Clock Input Reference Level
CK/CK cross
V
Output Reference Level
0.75
V
Output Load Conditions
RQ = 250Ω
See Figure 2
below
Figure 2: AC Test Output Load (VDDQ = 1.5V)
0.75 V
16.7 Ω
50 Ω
50 Ω
5 pF
DQ
16.7 Ω
0.75 V
16.7 Ω
50 Ω
50 Ω
5 pF
18Mb 1x2Lp, HSTL, rev 1.1
13 / 25
November 8, 2002
SONY® ΣRAM
Preliminary
CXK79M36C162GB
One Bank Read-Write-Read Timing Diagram
Figure 3
Read
Read
Continue
Read
Deselect
Deselect
Write
Continue
Write
Write
Read
Deselect
Deselect
(Continue)
CK
CK
tAVKH tKHAX
A A1
A2
tKHKH
A3
tKHKL tKLKH
A4
A5
tBVKH tKHBX
E1
ADV
W
tKLQV
tKHQV
tKLQX
tKHQX
tKHQZ
tKHQX1
tDVKH tKHDX
Q11 Q12 Q13 Q14 Q21 Q22
tDVKL tKLDX
Q51 Q52
D31 D32 D33 D34 D41 D42
DQ
tCLQX
tCHQX
tCLQV
tCHQV
tKHCH
tKLCL
CQ
CQ
Note: In the diagram above, two Deselect operations are inserted between Read and Write operations to control the data bus transition
from output to input. This depiction is for clarity purposes only. It is NOT a requirement. Depending on the application, one Deselect operation may be sufficient.
Note: E1 = EP1 and E2 = EP2 in this example (not shown).
18Mb 1x2Lp, HSTL, rev 1.1
14 / 25
November 8, 2002
SONY® ΣRAM
Preliminary
CXK79M36C162GB
Two Bank Read-Write-Read Timing Diagram
Figure 4
B1:
B2:
Read
Write
B-Deselect B-Deselect B-Deselect
R-Continue B-Deselect Deselect B-Deselect B-Deselect B-Deselect
B-Deselect B-Deselect
Read
B-Deselect Deselect
Write
W-Continue B-Deselect
Read
Deselect
Deselect
CK
CK
A A1
A2
A3
A4
A5
E2
E1
ADV
W
Q11 Q12 Q13 Q14
DQ (B1)
D41 D42
Q21 Q22
Q51 Q52
DQ (B2)
D31 D32 D33 D34
tKHCZ
tKHCX1
CQ (B1)
CQ (B1)
CQ (B2)
CQ (B2)
Note: In the diagram above, two Deselect operations are inserted between Read and Write operations to control the data bus transition
from output to input. This depiction is for clarity purposes only. It is NOT a requirement. Depending on the application, one Deselect operation may be sufficient.
Note: Bank 1 EP1 = “low”, Bank 2 EP1 “high”, and Bank 1 and Bank 2 E2 = EP2 in this example (not shown).
18Mb 1x2Lp, HSTL, rev 1.1
15 / 25
November 8, 2002
SONY® ΣRAM
Preliminary
CXK79M36C162GB
•Test Mode Description
These devices provide a JTAG Test Access Port (TAP) and Boundary Scan interface using a limited set of IEEE std. 1149.1
functions. This test mode is intended to provide a mechanism for testing the interconnect between master (processor, controller, etc.), SRAMs, other components, and the printed circuit board.
In conformance with a subset of IEEE std. 1149.1, these devices contain a TAP Controller and four TAP Registers. The TAP
Registers consist of one Instruction Register and three Data Registers (ID, Bypass, and Boundary Scan Registers).
The TAP consists of the following four signals:
TCK:
TMS:
TDI:
TDO:
Test Clock
Test Mode Select
Test Data In
Test Data Out
Induces (clocks) TAP Controller state transitions.
Inputs commands to the TAP Controller. Sampled on the rising edge of TCK.
Inputs data serially to the TAP Registers. Sampled on the rising edge of TCK.
Outputs data serially from the TAP Registers. Driven from the falling edge of TCK.
Disabling the TAP
When JTAG is not used, TCK should be tied “low” to prevent clocking the SRAM. TMS and TDI should either be tied “high”
through a pull-up resistor or left unconnected. TDO should be left unconnected.
Note: Operation of the TAP does not disrupt normal SRAM operation except when the EXTEST-A or SAMPLE-Z instruction is selected. Consequently, TCK, TMS, and TDI can be controlled any number of ways without adversely affecting the
functionality of the device.
JTAG DC Recommended Operating Conditions
(VDD = 1.8V ± 0.1V, TA = 0 to 85°C)
Parameter
Symbol
Test Conditions
Min
Max
Units
JTAG Input High Voltage (TCK, TMS, TDI)
VTIH
---
VDD/2 + 0.3
VDD + 0.3
V
JTAG Input Low Voltage (TCK, TMS, TDI)
VTIL
---
-0.3
VDD/2 - 0.3
V
JTAG Output High Voltage (TDO)
VTOH
ITOH = -100uA
VDD - 0.1
---
V
JTAG Output Low Voltage (TDO)
VTOL
ITOL = 100uA
---
0.1
V
JTAG Output High Voltage (TDO)
VTOH
ITOH = -8mA
VDD - 0.4
---
V
JTAG Output Low Voltage (TDO)
VTOL
ITOL = 8mA
---
0.4
V
JTAG Input Leakage Current
ITLI
VTIN = VSS to VDD
-20
10
uA
JTAG Output Leakage Current
ITLO
VTOUT = VSS to VDD
-10
10
uA
(VDD = 1.8V ± 0.1V, TA = 0 to 85°C)
JTAG AC Test Conditions
Parameter
Symbol
Conditions
Units
JTAG Input High Level
VTIH
1.8
V
JTAG Input Low Level
VTIL
0.0
V
JTAG Input Rise & Fall Time
1.0
V/ns
JTAG Input Reference Level
0.9
V
JTAG Output Reference Level
0.9
V
JTAG Output Load Condition
18Mb 1x2Lp, HSTL, rev 1.1
Notes
See Fig. 1 (page 12)
16 / 25
November 8, 2002
SONY® ΣRAM
Preliminary
CXK79M36C162GB
JTAG AC Electrical Characteristics
Parameter
Symbol
Min
Max
Units
Notes
TCK Cycle Time
tTHTH
50
ns
TCK High Pulse Width
tTHTL
20
ns
TCK Low Pulse Width
tTLTH
20
ns
TMS Setup Time
tMVTH
5
ns
TMS Hold Time
tTHMX
5
ns
TDI Setup Time
tDVTH
5
ns
TDI Hold Time
tTHDX
5
ns
Capture Setup Time (Address, Control, Data, Clock)
tCS
5
ns
1
Capture Hold Time (Address, Control, Data, Clock)
tCH
8
ns
1
TCK Low to TDO Valid
tTLQV
TCK Low to TDO Hold
tTLQX
10
0
ns
ns
1. These parameters are guaranteed by design through extensive corner lot characterization.
JTAG Timing Diagram
Figure 5
tTHTL
tTLTH
tTHTH
TCK
tMVTH
tTHMX
TMS
tDVTH tTHDX
TDI
tTLQV
tTLQX
TDO
18Mb 1x2Lp, HSTL, rev 1.1
17 / 25
November 8, 2002
SONY® ΣRAM
Preliminary
CXK79M36C162GB
TAP Controller
The TAP Controller is a 16-state state machine that controls access to the various TAP Registers and executes the operations
associated with each TAP Instruction. State transitions are controlled by TMS and occur on the rising edge of TCK.
The TAP Controller enters the “Test-Logic Reset” state in one of two ways:
1. At power up.
2. When a logic “1” is applied to TMS for at least 5 consecutive rising edges of TCK.
The TDI input receiver is sampled only when the TAP Controller is in either the “Shift-IR” state or the “Shift-DR” state.
The TDO output driver is active only when the TAP Controller is in either the “Shift-IR” state or the “Shift-DR” state.
TAP Controller State Diagram
Figure 6
1
Test-Logic Reset
0
0
Run-Test / Idle
1
Select DR-Scan
1
Select IR-Scan
0
1
0
1
Capture-DR
Capture-IR
0
0
0
Shift-DR
1
1
Exit1-DR
Exit1-IR
0
0
0
Pause-DR
1
0
Exit2-IR
1
18Mb 1x2Lp, HSTL, rev 1.1
0
18 / 25
0
1
Update-DR
1
0
Pause-IR
1
Exit2-DR
0
Shift-IR
1
1
1
Update-IR
1
0
November 8, 2002
SONY® ΣRAM
CXK79M36C162GB
Preliminary
TAP Registers
TAP Registers are serial shift registers that capture serial input data (from TDI) on the rising edge of TCK, and drive serial
output data (to TDO) on the subsequent falling edge of TCK. They are divided into two groups: “Instruction Registers” (IR),
which are manipulated via the “IR” states in the TAP Controller, and “Data Registers” (DR), which are manipulated via the
“DR” states in the TAP Controller.
Instruction Register (IR - 3 bits)
The Instruction Register stores the various TAP Instructions supported by these devices. It is loaded with the IDCODE instruction at power-up, and when the TAP Controller is in the “Test-Logic Reset” and “Capture-IR” states. It is inserted between TDI and TDO when the TAP Controller is in the “Shift-IR” state, at which time it can be loaded with a new instruction.
However, newly loaded instructions are not executed until the TAP Controller has reached the “Update-IR” state.
The Instruction Register is 3 bits wide, and is encoded as follows:
Code
(2:0)
Instruction
Description
000
EXTEST-A
Loads the individual logic states of all signals composing the SRAM’s I/O ring into the
Boundary Scan Register when the TAP Controller is in the “Capture-DR” state, and inserts the
B-Scan Register between TDI and TDO when the TAP Controller is in the “Shift-DR” state.
Also enables the SRAM’s data and clock output drivers, and moves the contents of the B-Scan
Register associated with the data and clock output signals to the input side of the SRAM’s output register. The SRAM’s input clock can then be used to transfer the B-Scan Register contents
directly to the data and clock output pins (the input clock controls the SRAM’s output register). Note that newly captured and/or shifted B-Scan Register contents do not appear at the
input side of the SRAM’s output register until the TAP Controller has reached the “UpdateDR” state.
See the Boundary Scan Register description for more information.
001
IDCODE
Loads a predefined device- and manufacturer-specific identification code into the ID Register
when the TAP Controller is in the “Capture-DR” state, and inserts the ID Register between
TDI and TDO when the TAP Controller is in the “Shift-DR” state.
See the ID Register description for more information.
010
SAMPLE-Z
Loads the individual logic states of all signals composing the SRAM’s I/O ring into the
Boundary Scan Register when the TAP Controller is in the “Capture-DR” state, and inserts the
B-Scan Register between TDI and TDO when the TAP Controller is in the “Shift-DR” state.
Also disables the SRAM’s data and clock output drivers.
See the Boundary Scan Register description for more information.
011
PRIVATE
Do not use. Reserved for manufacturer use only.
100
SAMPLE
Loads the individual logic states of all signals composing the SRAM’s I/O ring into the
Boundary Scan Register when the TAP Controller is in the “Capture-DR” state, and inserts the
B-Scan Register between TDI and TDO when the TAP Controller is in the “Shift-DR” state.
See the Boundary Scan Register description for more information.
101
PRIVATE
Do not use. Reserved for manufacturer use only.
110
PRIVATE
Do not use. Reserved for manufacturer use only.
111
BYPASS
Loads a logic “0” into the Bypass Register when the TAP Controller is in the “Capture-DR”
state, and inserts the Bypass Register between TDI and TDO when the TAP Controller is in the
“Shift-DR” state.
See the Bypass Register description for more information.
Bit 0 is the LSB of the Instruction Register, and Bit 2 is the MSB. When the Instruction Register is selected, TDI serially
shifts data into the MSB, and the LSB serially shifts data out through TDO.
18Mb 1x2Lp, HSTL, rev 1.1
19 / 25
November 8, 2002
SONY® ΣRAM
Preliminary
CXK79M36C162GB
Bypass Register (DR - 1 bit)
The Bypass Register is one bit wide, and provides the minimum length serial path between TDI and TDO. It is loaded with
a logic “0” when the BYPASS instruction has been loaded in the Instruction Register and the TAP Controller is in the “Capture-DR” state. It is inserted between TDI and TDO when the BYPASS instruction has been loaded into the Instruction Register and the TAP Controller is in the “Shift-DR” state.
ID Register (DR - 32 bits)
The ID Register is loaded with a predetermined device- and manufacturer-specific identification code when the IDCODE
instruction has been loaded into the Instruction Register and the TAP Controller is in the “Capture-DR” state. It is inserted
between TDI and TDO when the IDCODE instruction has been loaded into the Instruction Register and the TAP Controller
is in the “Shift-DR” state.
The ID Register is 32 bits wide, and is encoded as follows:
Device
Revision Number
(31:28)
Part Number
(27:12)
Sony ID
(11:1)
Start Bit
(0)
512Kb x 36
xxxx
0000 0000 0101 1011
0000 1110 001
1
Bit 0 is the LSB of the ID Register, and Bit 31 is the MSB. When the ID Register is selected, TDI serially shifts data into the
MSB, and the LSB serially shifts data out through TDO.
Boundary Scan Register (DR - 84 bits)
The Boundary Scan Register is equal in length to the number of active signal connections to the SRAM (excluding the TAP
pins) plus a number of place holder locations reserved for functional and/or density upgrades. It is loaded with the individual
logic states of all signals composing the SRAM’s I/O ring when the EXTEST-A, SAMPLE, or SAMPLE-Z instruction has
been loaded into the Instruction Register and the TAP Controller is in the “Capture-DR” state. It is inserted between TDI and
TDO when the EXTEST-A, SAMPLE, or SAMPLE-Z instruction has been loaded into the Instruction Register and the TAP
Controller is in the “Shift-DR” state.
The Boundary Scan Register contains the following bits:
512Kb x 36
DQx
36
A, A1
18
CK, CK
2
CQ1, CQ2, CQ1, CQ2
4
E1, ADV, W
3
E2, E3, EP2, EP3
4
ZQ
1
Place Holder
16
Note: CK and CK are connected to a differential input receiver that generates a single-ended input clock to these devices.
Therefore, in order to capture deterministic values for these signals in the Boundary Scan Register, they must be at opposite
logic levels when sampled.
Note: When an external resistor RQ is connected between the ZQ pin and VSS, the value of the ZQ signal captured in the
Boundary Scan Register is non-deterministic.
18Mb 1x2Lp, HSTL, rev 1.1
20 / 25
November 8, 2002
SONY® ΣRAM
Preliminary
CXK79M36C162GB
Boundary Scan Register Bit Order Assignments
The tables below depict the order in which the bits are arranged in the Boundary Scan Register. Bit 1 is the LSB and bit 84
is the MSB. When the Boundary Scan Register is selected, TDI serially shifts data into the MSB, and the LSB serially shifts
data out through TDO.
512Kb x 36
Bit
Signal
Pad
Bit
Signal
Pad
Bit
Signal
1
Pad
NC (1)
5C
36
E3
8A
71
MCH
6J
2
NC (1)
5U
37
A
7B
72
A
3V
3
NC (1)
7U
38
A
7A
73
A
4V
MCL
(1)
6D
39
W
6B
74
A
4U
5
MCL
(1)
6K
40
ADV
6A
75
A
5V
6
MCL (1)
6P
41
E1
6C
76
A
6U
7
MCL
(1)
6T
42
A
5A
77
A
5W
MCH
(2)
6N
43
A
5B
78
MCL
6W
4
8
9
MCH
6M
44
E2
4A
79
A1
6V
10
MCL
6L
45
A
3A
80
A
7V
11
DQ
10R
46
ZQ
6F
81
A
8V
12
DQ
11P
47
MCL
4C
82
A
7W
13
DQ
10P
48
MCL
3B
83
A
8U
14
DQ
11N
49
DQ
2E
84
A
9V
15
DQ
10N
50
DQ
1F
16
DQ
11M
51
DQ
2F
17
DQ
10M
52
DQ
1G
18
DQ
11L
53
DQ
2G
19
DQ
10L
54
DQ
1H
20
CQ1
11K
55
DQ
2H
21
CQ1
10K
56
DQ
1J
22
DQ
11E
57
DQ
2J
22
DQ
10D
58
CQ2
1K
24
DQ
11D
59
CK
3K
25
DQ
10C
60
CK
4K
26
DQ
11C
61
CQ2
2K
27
DQ
10B
62
DQ
1R
28
DQ
11B
63
DQ
2T
29
DQ
11A
64
DQ
1T
30
DQ
10A
65
DQ
2U
31
MCL
9C
66
DQ
1U
32
MCL
8B
67
DQ
2V
33
EP3
6H
68
DQ
1V
34
EP2
6G
69
DQ
1W
35
A
9A
70
DQ
2W
Note 1: These NC and MCL pins are connected to VSS internally, regardless of pin connection externally.
Note 2: This MCH pin is connected to VDD internally, regardless of pin connection externally.
18Mb 1x2Lp, HSTL, rev 1.1
21 / 25
November 8, 2002
SONY® ΣRAM
Preliminary
CXK79M36C162GB
•Ordering Information
VDD
I/O Type
Configuration
Speed
(Cycle Time / Data Access Time)
CXK79M36C162GB-33
1.8V
HSTL
512Kb x 36
3.3ns / 1.8ns
CXK79M36C162GB-4
1.8V
HSTL
512Kb x 36
4.0ns / 2.1ns
CXK79M36C162GB-5
1.8V
HSTL
512Kb x 36
5.0ns / 2.3ns
Part Number
Sony reserves the right to change products and specifications without prior notice. This information does not convey any license
by any implication or otherwise under any patents or other right. Application circuits shown, if any, are typical examples illustrating the operation of the devices. Sony cannot assume responsibility for any problems arising out of the use of these circuits.
18Mb 1x2Lp, HSTL, rev 1.1
22 / 25
November 8, 2002
SONY® ΣRAM
Preliminary
CXK79M36C162GB
•(11x19) 209 Pin BGA Package Dimensions
209PIN BGA (PLASTIC)
2.0 ± 0.3
14.0
0.30
S
A
13.0
.0
C1
3-
x4
C1
0.20
S
W
V
U
T
R
P
N
M
L
K
J
H
G
F
E
D
C
B
A
S
.5
0.15
B
2.0
0.35
21.0
22.0
0.30 S B
7
1.
C
4PIN 1 INDEX
2.0
A
1.0
X
1.0
0.5 ± 0.1
1 2 3 4 5 6 7 8 9 10 11
209 - φ 0.6 ± 0.1
0.10 M
S
AB
S
DETAIL X
PACKAGE STRUCTURE
PRELIMINARY
SONY CODE
BGA-209P-01
JEITA CODE
P-BGA209-14X22-1.0
JEDEC CODE
18Mb 1x2Lp, HSTL, rev 1.1
PACKAGE MATERIAL
EPOXY RESIN
TERMINAL TREATMENT
COPPER-CLAD LAMINATE
TERMINAL MATERIAL
SOLDER
PACKAGE MASS
1.1g
23 / 25
November 8, 2002
SONY® ΣRAM
CXK79M36C162GB
Preliminary
•Revision History
Rev. #
Rev. Date
Description of Modifications
rev 0.0
02/23/01
Initial Version.
rev 0.1
07/06/01
1. Modified DC Electrical Characteristics section (p. 9).
Added IDD-33 and IDD-44 Average Power Supply Operating Current specifications.
2. Added 209 Pin BGA Package Dimensions (p. 24).
rev 0.2
02/22/02
1. Added BGA Package Thermal Characteristics (p. 8).
2. Modified AC Electrical Characteristics section (p. 11).
Removed “-44” bin. Added “-5” bin.
-4
tCHCL
tKHKL ± 0.12 to tKHKL ± 0.1
tCLCH
tKLKH ± 0.12 to tKLKH ± 0.1
3. Added JTAG ID Codes (p. 21).
4. Added JTAG Boundary Scan Register Bit Order Assignments (pp. 22-23).
rev 1.0
07/19/02
1. Modified Pin Assignment section (p. 2-4).
Pin 1K
CQ to CQ2
Pin 2K
CQ to CQ2
Pin 10K
CQ to CQ1
Pin 11K
CQ to CQ1
Pin 6J
M4 to MCH
Pin 6L
M2 to MCL
Pin 6M
M3 to MCH
2. Modified I/O Capacitance section (p. 8).
CKIN
3.5pF to 4.0pF
3. Modified DC Recommended Operating Conditions section (p. 9).
Combined -1.8 and -1.5 line items into one for VDDQ, VREF, and VCM.
VREF (min)
0.65V to VDDQ/2 - 0.1V
VREF (max)
1.0V to VDDQ/2 + 0.1V
VCM (min)
0.65V to VDDQ/2 - 0.1V
VCM (max)
1.0V to VDDQ/2 + 0.1V
Removed notes 1 and 2.
4. Modified DC Electrical Characteristics section (p. 10).
Added MCH and MCL Input Leakage Current specifications.
Reduced x36 Average Power Supply Operating Currents by 100mA.
Reduced x18 Average Power Supply Operating Currents by 50mA.
5. Modified AC Electrical Characteristics section (p. 11).
-33
tKHCH (max), tKLCL (max), tKHCZ
1.7ns to 1.8ns
-4
tKHCH (max), tKLCL (max), tKHCZ
2.0ns to 2.1ns
-5
tKHCH (max), tKLCL (max), tKHCZ
2.2ns to 2.3ns
6. Modified JTAG DC Recommended Operating Conditions section (p. 17).
VTIH (min)
1.2V to VDD/2 + 0.3V
VTIL (max)
0.6V to VDD/2 - 0.3V
ITLI (min)
-10uA to -20uA
7. Modified JTAG AC Electrical Characteristics section (p. 18).
tTHTH
20ns to 50ns
tTHTL, tTLTH
8ns to 20ns
Added tCS Capture Setup and tCH Capture Hold specifications.
8. Modified TAP Registers section (p. 20).
Instruction Register Codes 011, 110
Bypass to Private
9. Modified Boundary Scan Register Bit Order Assignments section (p. 22).
x36
Bit 29
10A to 11A
x36
Bit 30
11A to 10A
18Mb 1x2Lp, HSTL, rev 1.1
24 / 25
November 8, 2002
SONY® ΣRAM
Rev. #
rev 1.1
Rev. Date
11/08/02
18Mb 1x2Lp, HSTL, rev 1.1
CXK79M36C162GB
Preliminary
Description of Modifications
1. Removed x18 organization and all related references.
2. Modified Pin Description section (p. 3).
For NC pins, removed reference to VDD and VDDQ.
3. Modified AC Electrical Characteristics section (p. 10).
-33
tCHQV, tCLQV
0.2ns to 0.25ns
tCHQX, tCLQX
-0.2ns to -0.25ns
Removed tCHCL and tCLCH Output Clock High and Low Pulse Width specifications.
4. Modified JTAG AC Electrical Characteristics section (p. 17).
tCH
5ns to 8ns
Added Note 1 for tCS and tCH specifications.
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November 8, 2002