W641GG2KB

W641GG2KB
1-Gbit GDDR3 Graphics SDRAM
Table of Contents
1. GENERAL DESCRIPTION .......................................................................................................... 6
2. FEATURES .................................................................................................................................. 7
3. PIN CONFIGURATION ................................................................................................................ 8
3.1 Ballout 1-CS Non-Merged Mode (Top View, MF=0) ............................................................................... 8
3.2 Ballout 2-CS Non-Merged Mode (Top View, MF=0) ............................................................................... 9
3.3 Ballout Merged Mode (Top View, MF=0) .............................................................................................. 10
4. PIN DESCRIPTION .................................................................................................................... 11
4.1 Signal Description................................................................................................................................. 11
4.2 Addressing............................................................................................................................................ 12
5. STATE DIAGRAM ..................................................................................................................... 13
5.1 State Diagram for One Activated Bank ................................................................................................. 13
5.1.1 State diagram for one bank ............................................................................................................................. 13
5.1.2 Function Truth Table for more than one Activated Bank .................................................................................. 14
5.1.2.1 Function Truth Table ...................................................................................................................................................14
5.1.3 Function Truth Table for CKE .......................................................................................................................... 15
5.2 Functional Block Diagram in 1-CS Mode.............................................................................................. 16
5.3 Functional Block Diagram in 2-CS Mode .............................................................................................. 17
6. FUNCTIONAL DESCRIPTION ................................................................................................... 18
6.1 System Configurations ......................................................................................................................... 18
6.1.1 System Configurations in 1-CS Mode and 2-CS Mode ................................................................................... 18
6.1.2 Initialization in 1– CS mode ............................................................................................................................. 19
6.1.3 Initialization in 2– CS mode ............................................................................................................................. 20
6.1.3.1 Power Up Sequence ...................................................................................................................................................21
6.2 Mirror Function ..................................................................................................................................... 22
6.2.1 Ball Assignment with Mirror Function .............................................................................................................. 22
6.3 Commands ........................................................................................................................................... 23
6.3.1 Command Overview for 1-CS mode ................................................................................................................ 23
6.3.2 Command Overview for 2-CS mode ................................................................................................................ 24
6.3.3 Description of Command ................................................................................................................................. 25
6.3.4 Minimum delay from RD/A and WR/A to any other command (to another bank) with concurrent AP ............. 28
6.4 Boundary Scan ..................................................................................................................................... 28
6.4.1 General Description ......................................................................................................................................... 28
6.4.2 Disabling the scan feature ............................................................................................................................... 28
6.4.2.1 Internal Block Diagram (Reference only) ....................................................................................................................29
6.4.2.2 Boundary Scan Exit Order ...........................................................................................................................................29
6.4.2.3 Scan Pin Description ...................................................................................................................................................30
6.4.2.4 Scan DC Electrical Characteristics and Operating Condition.......................................................................................30
6.4.2.5 Scan Capture Timing...................................................................................................................................................31
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Publication Release Date : April 12, 2013
Revision : A01-001
W641GG2KB
1-Gbit GDDR3 Graphics SDRAM
6.4.2.6 Scan Shift Timing ........................................................................................................................................................31
6.4.2.7 Scan AC Electrical Characteristic ................................................................................................................................32
6.4.3 Scan Initialization ............................................................................................................................................. 32
6.4.3.1 Scan Initialization for Stand-Alone Mode .....................................................................................................................32
6.4.3.2 Scan Initialization for Stand-Alone mode ....................................................................................................................33
6.4.4 Scan Initialization in regular SGRAM operation ............................................................................................... 33
6.4.4.1 Scan Initialization Sequence within regular SGRAM Mode .........................................................................................34
6.4.5 Scan Exit Sequence ........................................................................................................................................ 34
6.4.5.1 Boundary Scan Exit Sequence ...................................................................................................................................35
6.4.5.2 Scan AC Electrical Parameter .....................................................................................................................................35
6.5 Programmable impedance output drivers and active terminations........................................................ 36
6.5.1 GDDR3 IO Driver and Termination .................................................................................................................. 36
6.5.1.1 Output Driver simplified schematic ..............................................................................................................................37
6.5.1.2 Range of external resistance ZQ .................................................................................................................................37
6.5.1.3 Termination Types and Activation ...............................................................................................................................37
6.5.2 Self Calibration for Driver and Termination ...................................................................................................... 38
6.5.2.1 Termination update Keep Out time after Auto refresh command ................................................................................38
6.5.2.2 Number of Legs used for Terminator and Driver Self Calibration ................................................................................39
6.5.2.3 Self Calibration of PMOS and NMOS Legs .................................................................................................................39
6.5.3 Dynamic Switching of DQ terminations ............................................................................................................ 40
6.5.3.1 ODT Disable Timing during a READ command ..........................................................................................................40
6.5.4 Output impedance and Termination DC Electrical Characteristics .................................................................. 41
6.5.4.1 DC Electrical Characteristic .........................................................................................................................................41
6.6 Mode Register Set Command (MRS) ................................................................................................... 42
6.6.1 Mode Register Set Command ......................................................................................................................... 42
6.6.2 Mode Registers................................................................................................................................................ 42
6.6.2.1 Mode Register (MRS) .................................................................................................................................................42
6.6.2.2 Mode Register (MRS) .................................................................................................................................................43
6.6.2.3 Mode Register Set Timing...........................................................................................................................................43
6.6.3 Burst Length and Burst Type ........................................................................................................................... 44
6.6.3.1 Burst Length................................................................................................................................................................44
6.6.3.2 Burst type ....................................................................................................................................................................44
6.6.4 CAS Latency .................................................................................................................................................... 44
6.6.5 Write Latency ................................................................................................................................................... 44
6.6.6 DLL Reset ........................................................................................................................................................ 45
6.6.7 Test mode ........................................................................................................................................................ 45
6.7 Extended Mode Register Set Command (EMRS1) ............................................................................... 45
6.7.1 Extended Mode Register Set Command ......................................................................................................... 46
6.7.2 Extended Mode Register 1 (EMRS1) .............................................................................................................. 46
6.7.2.1 Extended Mode Register 1 (EMRS1) ..........................................................................................................................47
6.7.2.2 Extended Mode Register Set Timing ..........................................................................................................................48
6.7.3 Chip Select Mode ............................................................................................................................................ 48
6.7.4 DLL .................................................................................................................................................................. 48
6.7.5 Write Recovery ................................................................................................................................................ 48
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Publication Release Date : April 12, 2013
Revision : A01-001
W641GG2KB
1-Gbit GDDR3 Graphics SDRAM
6.7.6 Termination Rtt ................................................................................................................................................ 48
6.7.7 Impedance Autocalibration of Output Buffer and Active Terminator ............................................................... 49
6.7.7.1 Impedance Options .....................................................................................................................................................49
6.7.7.2 Timing of Vendor Code and Revision ID Generation on DQ[7:0] ................................................................................49
6.7.8 Output Driver Impedance ................................................................................................................................. 50
6.7.9 Data Termination ............................................................................................................................................. 50
6.7.10 Address command termination ...................................................................................................................... 50
6.8 Extended Mode Register 2 Set Command (EMRS2) ............................................................................ 50
6.8.1 Extended Mode Register 2 Set Command ...................................................................................................... 51
6.8.2 Extended Mode Register 2 (EMRS2) .............................................................................................................. 51
6.8.2.1 Extended Mode Register 2 (EMRS2) ..........................................................................................................................52
6.8.2.2 Impedance Offsets ......................................................................................................................................................52
6.8.2.3 Merged Mode ..............................................................................................................................................................52
6.8.3 OCD Pull Down Offset ..................................................................................................................................... 52
6.8.4 ODT Pull Up Offset .......................................................................................................................................... 52
6.9 Extended Mode Register 3 (EMRS3) ................................................................................................... 53
6.10 Vendor Code and Revision ID............................................................................................................. 53
6.10.1 Vendor ID Code ............................................................................................................................................. 53
6.11 Bank / Row Activation (ACT) .............................................................................................................. 54
6.11.1 Activating a specific row ................................................................................................................................ 54
6.11.2 Bank Activation Timing .................................................................................................................................. 55
6.11.3 Bank Activation Timing on different rank in 2-CS mode ................................................................................ 55
6.11.4 Four Window Active tFAW............................................................................................................................. 55
6.11.5 Clock, CKE and command / Address Timings .............................................................................................. 56
6.12 Bank Activations with REFRESH ....................................................................................................... 56
6.12.1 Bank Activations with REFRESH Command................................................................................................. 56
6.13 Writes (WR) ........................................................................................................................................ 57
6.13.1 Write - Basic Information................................................................................................................................ 57
6.13.1.1 Write Command ........................................................................................................................................................58
6.13.1.2 Mapping of WDQS and DM Signals ..........................................................................................................................58
6.13.1.3 Basic Write Burst / DM Timing ..................................................................................................................................59
6.14 Write - Basic Sequence ...................................................................................................................... 60
6.15 Write - Consecutive Bursts ................................................................................................................. 61
6.15.1Gapless Bursts................................................................................................................................................ 61
6.15.1.1 Gapless Write Bursts ................................................................................................................................................61
6.15.2 Bursts with Gaps ............................................................................................................................................ 62
6.15.2.1 Consecutive Write Bursts with Gaps .........................................................................................................................62
6.15.3 Write with Autoprecharge .............................................................................................................................. 63
6.15.4 Write followed by Read .................................................................................................................................. 64
6.15.5 Write followed by Read on different ranks in 2-CS mode............................................................................... 65
6.15.6 Write followed by DTERDIS ........................................................................................................................... 66
6.15.7 Write with Autoprecharge followed by Read / Read with Autoprecharge on another bank ........................... 67
6.15.8 Write followed by Precharge on same bank ................................................................................................... 68
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Publication Release Date : April 12, 2013
Revision : A01-001
W641GG2KB
1-Gbit GDDR3 Graphics SDRAM
6.16 Reads (RD) ......................................................................................................................................... 69
6.16.1 Read - Basic Information ............................................................................................................................... 69
6.16.1.1 Read Command ........................................................................................................................................................70
6.16.1.2 Basic Read Burst Timing...........................................................................................................................................71
6.16.2 Read - Basic Sequence ................................................................................................................................. 72
6.16.2.1 Read Burst ................................................................................................................................................................72
6.16.3 Consecutive Read Bursts .............................................................................................................................. 73
6.16.3.1 Gapless Bursts ..........................................................................................................................................................73
6.16.4 Bursts with Gaps ............................................................................................................................................ 74
6.16.4.1 Consecutive Read Bursts with Gaps .........................................................................................................................74
6.16.5 Read followed by DTERDIS........................................................................................................................... 75
6.16.6 Read with Autoprecharge .............................................................................................................................. 76
6.16.7 Read followed by Write .................................................................................................................................. 77
6.16.8 Read followed by Precharge on the same Bank ............................................................................................ 78
6.17 Data Termination Disable (DTERDIS) ................................................................................................ 79
6.17.1 Data Terminal Disable Command ................................................................................................................. 79
6.17.1.1 DTERDIS Timing ......................................................................................................................................................80
6.17.2 DTERDIS followed by DTERDIS ................................................................................................................... 81
6.17.3 DTERDIS followed by READ ......................................................................................................................... 82
6.17.4 DTERDIS followed by Write ........................................................................................................................... 83
6.18 Precharge (PRE/PREALL) .................................................................................................................. 84
6.18.1 Precharge Command .................................................................................................................................... 84
6.18.2 BA2, BA1 and BA0 precharge bank selection within one rank ...................................................................... 85
6.18.3 Precharge Timing .......................................................................................................................................... 85
6.19 Auto Refresh Command (AREF)......................................................................................................... 86
6.19.1 Auto Refresh Command ................................................................................................................................ 86
6.19.2 Auto Refresh Cycle ........................................................................................................................................ 87
6.20 Self-Refresh........................................................................................................................................ 87
6.20.1 Self-Refresh Entry (SREFEN)........................................................................................................................ 87
6.20.1.1 Self-Refresh Entry Command ...................................................................................................................................88
6.20.1.2 Self Refresh Entry .....................................................................................................................................................89
6.21 Self-Refresh Exit (SREFEX) ............................................................................................................... 89
6.21.1 Self Refresh Exit Command .......................................................................................................................... 90
6.21.2 Self Refresh Exit ............................................................................................................................................ 90
6.22 Power-Down ....................................................................................................................................... 91
6.22.1 Power Down Command ................................................................................................................................. 91
6.22.2 Power-Down Mode ........................................................................................................................................ 92
7 ELECTRICAL CHARACTERISTICS ........................................................................................... 93
7.1 Absolute Maximum Ratings and Operation Conditions ......................................................................... 93
7.1.1 Absolute Maximum Rating ............................................................................................................................... 93
7.2 DC Operation Conditions ...................................................................................................................... 93
7.2.1 Recommended Power & DC Operation Conditions ......................................................................................... 93
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Publication Release Date : April 12, 2013
Revision : A01-001
W641GG2KB
1-Gbit GDDR3 Graphics SDRAM
7.2.1.1 Power & DC Operation Conditions (0 °C ≤ Tc ≤ 70 °C) ..............................................................................................93
7.3 DC & AC Logic Input Levels ................................................................................................................. 94
7.3.1 DC & AC Logic Input Levels (0 °C ≤ Tc ≤ 70 °C) ............................................................................................ 94
7.4 Differential Clock DC and AC Levels .................................................................................................... 95
7.4.1 Differential Clock DC and AC Input conditions (0 °C ≤ Tc ≤ 70°C) ................................................................. 95
7.5 Output Test Conditions ......................................................................................................................... 95
7.6 Pin Capacitances .................................................................................................................................. 96
7.6.1 Pin Capacitances (VDDQ = 1.8 V, TA = 25°C, f = 1 MHz) .............................................................................. 96
7.7 Driver current characteristics ................................................................................................................ 96
7.7.1 Driver IV characteristics at 40 Ohms ................................................................................................................ 96
7.7.1.1 40 Ohm Driver Pull-Down and Pull-up Characteristics ................................................................................................96
7.7.1.2 Programmed Driver IV Characteristics at 40 Ohm .......................................................................................................97
7.8 Termination current characteristics ....................................................................................................... 97
7.8.1 Termination IV Characteristic at 60 Ohms ....................................................................................................... 97
7.8.1.1 60 Ohm Active Termination Characteristic ..................................................................................................................98
7.8.1.2 Programmed Terminator Characteristics at 60 Ohm ...................................................................................................98
7.8.2 Termination IV Characteristic at 120 Ohms ..................................................................................................... 99
7.8.2.1 120 Ohm Active Termination Characteristic ................................................................................................................99
7.8.2.2 Programmed Terminator Characteristics of 120 Ohm ...............................................................................................100
7.8.3 Termination IV Characteristic at 240 Ohms ................................................................................................... 100
7.8.3.1 240 Ohm Active Termination Characteristic ..............................................................................................................100
7.8.3.2 Programmed Terminator Characteristics at 240 Ohm ...............................................................................................101
7.9 Operating Current Ratings.................................................................................................................. 102
7.10 AC Timings ....................................................................................................................................... 103
8. PACKAGE SPECIFICATION ................................................................................................... 106
9. ORDERING INFORMATION .................................................................................................... 107
10. REVISION HISTORY ............................................................................................................. 108
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Publication Release Date : April 12, 2013
Revision : A01-001
W641GG2KB
1-Gbit GDDR3 Graphics SDRAM
1. GENERAL DESCRIPTION
The W641GG2KB 1-Gbit GDDR3 GRAPHICS SDRAM is a high speed dynamic random-access memory designed for
applications requiring high bandwidth. It contains 1,073,741,824 bits. The device can be configured to operate in two
different modes:
• in 2-CS mode the chip is organized as two 512 Mbit memories of 8 banks each, with 4096 row locations and 512
column locations per bank.
• in 1-CS mode the chip is organized as one 1 Gbit memory, with 8192 row locations and 512 column locations per
bank.
The GDDR3 GRAPHICS SDRAM uses a double data rate architecture to achieve high speed operation. The double
data rate architecture is essentially a 4n prefetch architecture with an interface designed to transfer two data words per
clock cycle at the I/O pins. A single read or write access for the GDDR3 GRAPHICS SDRAM effectively consists of a
4n data transfer every two clock cycles at the internal DRAM core and four corresponding n-bit wide, one-half-clockcycle data transfers at the I/O pins.
Unidirectional data strobes are transmitted externally, along with data, for use in data capture at the receiver. RDQS is a
strobe transmitted by the GDDR3 GRAPHICS SDRAM during READs. WDQS is the data strobe sent by the memory
controller during WRITEs. RDQS is edge-aligned with data for READs and WDQS is center-aligned with data for
WRITEs.
The GDDR3 GRAPHICS SDRAM operates from a differential clock (CLK and CLK#; the crossing of CLK going High
and CLK# going Low will be referred to as the positive CLK edge). Commands (address and control signals) are
registered at the positive CLK edge. Input data is registered at both edges of WDQS, and output data is referenced to
both edges of RDQS, as well as to both edges of CLK.
Read and write accesses to the GDDR3 GRAPHICS SDRAM are burst oriented. The burst length can be programmed
to 4 or 8 and the two least significant bits of the burst address are ―Don‘t Care‖ and internally set to LOW. Accesses
start at a selected location and continue for a total of four or eight locations. Accesses begin with the registration of an
ACTIVE command, which is then followed by a READ or WRITE command. The address bits registered coincident with
the ACTIVE command are used to select the bank and the row to be accessed. The address bits registered coincident
with the READ or WRITE command are used to select the bank and the starting column location for the burst access.
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Publication Release Date : April 12, 2013
Revision : A01-001
W641GG2KB
1-Gbit GDDR3 Graphics SDRAM
2. FEATURES
•
Density: 1Gbit
•
•
•
Power supply (VDD, VDDQ): 1.8V  0.1V
Organization: 1 Chip Select x 8 banks x 4M words x 32
bits (1-CS mode) and 2 Chip Select x 8 banks x 2M words
x 32 bits (2-CS mode)
•
Auto precharge option for each burst access
•
Pseudo open drain outputs with 40 pulldown, 40 pullup
•
ODT: nom. values of 60, 120 or 240
Programmable termination and driver strength offsets
Programmable Write latency: 3 to 7
•
Eight internal banks per Chip Select for concurrent
operation
•
•
Refresh cycles: 8192 cycles/32ms
•
4n prefetch architecture: 128 bit per array Read or Write
access
•
•
•
Double-data rate architecture: two data transfers per clock
cycle
•
•
Single ended interface for data, address and command
Auto-refresh and self-refresh modes
ODT and output drive strength auto-calibration with
external resistor ZQ pin (240)
Programmable IO interface including on chip termination
(ODT)
•
Differential clock inputs CLK, CLK#
•
tRAS lockout support
•
Commands entered on each positive CLK edge
•
Vendor ID for device identification
•
Single ended Read strobe (RDQS) per byte, edge-aligned
with Read data
•
Mirror function with MF pin
•
Boundary Scan function with SEN pin
•
Single ended Write strobe (WDQS) per byte, centeraligned with Write data
•
tWR programmable for Writes with Auto-Precharge
•
Write data mask (DM) function
•
Calibrated output drive. Active termination support
•
DLL aligns DQ and RDQS transitions with CLK clock
edges for Reads
•
Short RAS to CAS timing for Writes
•
Operating case temperature range:
Tcase = 0°C to +70°C
•
Burst length (BL): 4 or 8
•
Sequential burst type only
•
Package: 136-ball WBGA.
Programmable CAS latency: 7 to 14
•
RoHS Compliant Product
•
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Publication Release Date : April 12, 2013
Revision : A01-001
W641GG2KB
1-Gbit GDDR3 Graphics SDRAM
3. PIN CONFIGURATION
3.1 Ballout 1-CS Non-Merged Mode (Top View, MF=0)
1
2
3
4
VDDQ
VDD
VSS
ZQ
VSSQ
DQ0
DQ1
VDDQ
DQ2
DQ3
VSSQ
WDQS0 RDQS0
5
6
7
8
9
10
11
12
A
MF
VSS
VDD
VDDQ
VSSQ
B
VSSQ
DQ9
DQ8
VSSQ
VDDQ
C
VDDQ
DQ11
DQ10
VDDQ
VSSQ
D
VSSQ
RDQS1 WDQS1
VSSQ
VDDQ
DQ4
DM0
VDDQ
E
VDDQ
DM1
DQ12
VDDQ
VDD
DQ6
DQ5
CAS#
F
CS0#
DQ13
DQ14
VDD
VSS
VSSQ
DQ7
BA0
G
BA1
DQ15
VSSQ
VSS
VREF
A1
RAS#
CKE
H
WE#
BA2
A5
VREF
VSS
A12
RAR
VDDQ
J
VDDQ
CLK#
CLK
VSS
VDD
A10
A2
A0
K
A4
A6
A8/AP
VDD
VSS
VSSQ
DQ25
A11
L
A7
DQ17
VSSQ
VSS
VDD
DQ24
DQ27
A3
M
A9
DQ19
DQ16
VDD
VDDQ
DQ26
DM3
VDDQ
N
VDDQ
DM2
DQ18
VDDQ
VSSQ
P
VSSQ
VSSQ
WDQS3 RDQS3
RDQS2 WDQS2
VSSQ
VDDQ
DQ28
DQ29
VDDQ
R
VDDQ
DQ21
DQ20
VDDQ
VSSQ
DQ30
DQ31
VSSQ
T
VSSQ
DQ23
DQ22
VSSQ
VDDQ
VDD
VSS
SEN
U
RES
VSS
VDD
VDDQ
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Publication Release Date : April 12, 2013
Revision : A01-001
W641GG2KB
1-Gbit GDDR3 Graphics SDRAM
3.2 Ballout 2-CS Non-Merged Mode (Top View, MF=0)
1
2
3
4
VDDQ
VDD
VSS
ZQ
VSSQ
DQ0
DQ1
VDDQ
DQ2
DQ3
VSSQ
WDQS0 RDQS0
5
6
7
8
9
10
11
12
A
MF
VSS
VDD
VDDQ
VSSQ
B
VSSQ
DQ9
DQ8
VSSQ
VDDQ
C
VDDQ
DQ11
DQ10
VDDQ
VSSQ
D
VSSQ
RDQS1 WDQS1
VSSQ
VDDQ
DQ4
DM0
VDDQ
E
VDDQ
DM1
DQ12
VDDQ
VDD
DQ6
DQ5
CAS#
F
CS0#
DQ13
DQ14
VDD
VSS
VSSQ
DQ7
BA0
G
BA1
DQ15
VSSQ
VSS
VREF
A1
RAS#
CKE
H
WE#
BA2
A5
VREF
VSS
RAR
CS1#
VDDQ
J
VDDQ
CLK#
CLK
VSS
VDD
A10
A2
A0
K
A4
A6
A8/AP
VDD
VSS
VSSQ
DQ25
A11
L
A7
DQ17
VSSQ
VSS
VDD
DQ24
DQ27
A3
M
A9
DQ19
DQ16
VDD
VDDQ
DQ26
DM3
VDDQ
N
VDDQ
DM2
DQ18
VDDQ
VSSQ
P
VSSQ
VSSQ
WDQS3 RDQS3
RDQS2 WDQS2
VSSQ
VDDQ
DQ28
DQ29
VDDQ
R
VDDQ
DQ21
DQ20
VDDQ
VSSQ
DQ30
DQ31
VSSQ
T
VSSQ
DQ23
DQ22
VSSQ
VDDQ
VDD
VSS
SEN
U
RES
VSS
VDD
VDDQ
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Publication Release Date : April 12, 2013
Revision : A01-001
W641GG2KB
1-Gbit GDDR3 Graphics SDRAM
3.3 Ballout Merged Mode (Top View, MF=0)
1
2
3
4
VDDQ
VDD
VSS
ZQ
VSSQ
DQ0
DQ1
VDDQ
DQ2
DQ3
VSSQ
WDQS0 RDQS0
5
6
7
8
9
10
11
12
A
MF
VSS
VDD
VDDQ
VSSQ
B
VSSQ
DQ9
DQ8
VSSQ
VDDQ
C
VDDQ
DQ11
DQ10
VDDQ
VSSQ
D
VSSQ
RDQS1 WDQS1
VSSQ
VDDQ
DQ4
DM0
VDDQ
E
VDDQ
DM1
DQ12
VDDQ
VDD
DQ6
DQ5
CAS#
F
CS0#
DQ13
DQ14
VDD
VSS
VSSQ
DQ7
BA0
G
BA1
DQ15
VSSQ
VSS
VREF
A1
RAS#
CKE
H
WE#
BA2
A5
VREF
VSS
RFU
A12/
CS1#
VDDQ
J
VDDQ
CLK#
CLK
VSS
VDD
A10
A2
A0
K
A4
A6
A8/AP
VDD
VSS
VSSQ
DQ25
A11
L
A7
DQ17
VSSQ
VSS
VDD
DQ24
DQ27
A3
M
A9
DQ19
DQ16
VDD
VDDQ
DQ26
DM3
VDDQ
N
VDDQ
DM2
DQ18
VDDQ
VSSQ
P
VSSQ
VSSQ
WDQS3 RDQS3
RDQS2 WDQS2
VSSQ
VDDQ
DQ28
DQ29
VDDQ
R
VDDQ
DQ21
DQ20
VDDQ
VSSQ
DQ30
DQ31
VSSQ
T
VSSQ
DQ23
DQ22
VSSQ
VDDQ
VDD
VSS
SEN
U
RES
VSS
VDD
VDDQ
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Publication Release Date : April 12, 2013
Revision : A01-001
W641GG2KB
1-Gbit GDDR3 Graphics SDRAM
4. PIN DESCRIPTION
4.1 Signal Description
Ball
CLK, CLK#
Type
Input
Detailed Function
Clock:CLK and CLK# are differential clock inputs. Command and address inputs are latched on the rising edge
of CLK. All latencies are referenced to CLK. CLK and CLK# are not internally terminated.
Clock Enable:CKE High activates and CKE Low deactivates internal clock, device input buffers and output
CKE
Input
drivers. Taking CKE Low provides Precharge Power-Down and Self Refresh operations (all banks idle), or Active
Power-Down (row active in any bank). CKE is synchronous for Power-Down entry and exit and for Self Refresh
entry. CKE must be maintained High throughout READ, WRITE and bus snoop bursts.
Input buffers excluding CLK, CLK# and CKE are disabled during Power-Down. Input buffers excluding CKE are
disabled during Self Refresh.
The value of CKE latched at power-up with RES going High determines the termination value of the address and
command inputs.
Chip Select:Chip Select: CS# Low enables, and CS# High disables the command decoder. All commands
CS0#,CS1#
Input
RAS#,CAS#,
WE#
Input
BA0-BA2
Input
except DTERDIS are masked when CS# is registered High, but internal command execution continues. CS#
provides for individual device selection on memory channels with multiple memory devices. CS# is considered
part of the command code.
In 1-CS mode only CS0# is available.
In 2-CS mode both CS0# and CS1# are available, and CS0# is exclusively used for Mode Register or Extended
Mode Register programming and self refresh entry.
Command Inputs: Command inputs: RAS#, CAS# and WE# (along with CS0# or CS1#) define the command
to be entered.
Bank Address Inputs: BA0-BA2 define to which bank an ACTIVE, READ, WRITE or PRECHARGE
command is being applied. BA0-BA2 also determine which Mode Register or Extended Mode Register is
accessed with a MODE REGISTER SET command.
Address Inputs: Address inputs: provide the row address for ACTIVE commands and the column address
A0-A11 (A12)
Input
and auto precharge function (A8) for READ and WRITE commands, to select one location out of the memory
array in the respective bank. A8 sampled during a PRECHARGE command determines whether the
PRECHARGE applies to one bank (A8 Low, bank selected by BA0- BA2) or all banks (A8 High). The address
inputs also provide the op-code during an MODE REGISTER SET command.
A12 is the MSB row address in 1-CS mode.
Data Inputs/Outputs: Data Input/Output: 32 bit data bus.
DQ0-DQ31
I/O
DM0-DM3
Input
RDQS0RDQS3
Output
WDQS0WDQS3
Input
ZQ
Reference ODT Impedance Reference: The ZQ ball is used to control the ODT impedance.
Input Data Masks: Input Data Mask: DM is an input mask signal for write data. Input data is masked when
DM is sampled High along with that input data during a WRITE access. DM is sampled on the rising and falling
edges of WDQS. DM0 is associated with DQ0-DQ7, DM1 with DQ8-DQ15, DM2 with DQ16-DQ23 and DM3 with
DQ24-DQ31.
Read Data Strobes: Output with read data. RDQS is edge-aligned with read data.
RDQS0 is associated with DQ0-DQ7, RDQS1 with DQ8-DQ15, RDQS2 with DQ16-DQ23 and RDQS3 with
DQ24-DQ31.
Write Data Strobes: WRITE Data strobe: Input with write data. WDQS is center-aligned to the input data.
WDQS0 is associated with DQ0-DQ7, WDQS1 with DQ8-DQ15, WDQS2 with DQ16-DQ23 and WDQS3 with
DQ24-DQ31.
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Publication Release Date : April 12, 2013
Revision : A01-001
W641GG2KB
1-Gbit GDDR3 Graphics SDRAM
Reset pin: The RES pin is a Vddq CMOS input. RES is not internally terminated. When RES is at LOW state
the chip goes into full reset. The chip stays in full reset until RES goes to HIGH state.
The Low to High transition of the RES signal is used to latch the CKE value to set the
value of the termination resistors of the address and command inputs. After exiting the
full reset a complete initialization is required since the full reset sets the internal settings
to default, including mode register bits.
RES
Input
MF
Input
ground plane. With MF set to HIGH, the command and address pins are reassigned in order to allow for an
easier routing on board for a back to back memory arrangement.
SEN
Input
Scan Enable: SEN is a VDDQ CMOS input. Must be tied to Ground when not in use.
VREF
Supply
Reference voltage for command, address and data inputs.
VDDQ
Supply
Isolated power for the input and output buffers.
VSSQ
Supply
Isolated ground for the input and output buffers.
VDD
Supply
Power Supply
VSS
Supply
Ground
Mirror function: MF is a VDDQ CMOS input. This pin must be hardwired on board either to a power or to a
RFU
Reserved
RAR
Reserved for alternate rank (see ballouts).
4.2 Addressing
2-CS Mode (CS0#,CS1#)
1-CS Mode (CS0#)
2
1
A0-A11
A0-A12
Column addresses
A2-A7,A9
A2-A7,A9
Bank address
BA0-BA2
BA0-BA2
A8/AP
A8/AP
2 KB
2 KB
8K/32 mS
8K/32 mS
Number of ranks
Row Address
Auto precharge
Page size
Refresh
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Publication Release Date : April 12, 2013
Revision : A01-001
W641GG2KB
1-Gbit GDDR3 Graphics SDRAM
5. STATE DIAGRAM
5.1 State Diagram for One Activated Bank
The following diagram shows all possible states and transitions for one activated bank. The other 7 banks of the
Graphics SDRAM are assumed to be in idle state.
5.1.1 State diagram for one bank
Single Bank
WR
ACT
PRE
WR/A
MRS
EMRS
AUTO
REFRESH
IDLE
RD/A
PDEN
PDEN
PDEX
SREN
RD
ACTIVE
PDEX
Active
POWER- DOWN
Precharge
SREX
SELF
REFRESH
All Banks
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Publication Release Date : April 12, 2013
Revision : A01-001
W641GG2KB
1-Gbit GDDR3 Graphics SDRAM
5.1.2 Function Truth Table for more than one Activated Bank
If there is more than one bank activated in the Graphics SDRAM, some commands can be performed in parallel due to the chip‘s
multibank architecture. The following table defines for which commands such a scheme is possible. All other transitions are illegal.
Notes 1-11 define the start and end of the actions belonging to a submitted command. This table is based on the assumption that
there are no other actions ongoing on bank n or bank m. If there are any actions ongoing on a third bank tRRD, tRTW and tWTR have to
be taken always into account.
5.1.2.1 Function Truth Table
Current State
Ongoing action on bank n
ACTIVATE
ACTIVE
1
Possible action in parallel on bank m
ACT, PRE, WRITE, WRITE/A, READ, READ/A2
WRITE3
ACT, PRE, WRITE, WRITE/A, READ, READ/A4
WRITE/A
ACT, PRE, WRITE, WRITE/A, READ6
READ7)
ACT, PRE, WRITE, WRITE/A, READ, READ/A8
READ/A
9)
ACT, PRE, WRITE, WRITE/A, READ, READ/A 8
PRECHARGE10
ACT, PRE, WRITE, WRITE/A, READ, READ/A11
PRECHARGE ALL 10
-
POWER DOWN ENTRY12
-
ACTIVATE 1)
ACT
POWER DOWN ENTRY 12
-
13
IDLE
-
AUTO REFRESH
SELF REFRESH ENTRY
12
-
MODE REGISTER SET (MRS)14
EXTENDED MRS
EXTENDED MRS 2
POWER DOWN
SELF REFRESH
-
14
-
14
-
POWER DOWN EXIT15
SELF REFRESH EXIT
-
16
-
Notes:
1. Action ACTIVATE starts with issuing the command and ends after tRCD.
2. During action ACTIVATE an ACT command on another bank is allowed considering tRRD or tRRD_RR, a PRE command on another bank is allowed
any time. WR, WR/A, RD and RD/A are always allowed.
3. Action WRITE starts with issuing the command and ends tWR after the first pos. edge of CLK following the last falling WDQS edge.
4. During action WRITE an ACT or a PRE command on another bank is allowed any time. A new WR or WR/A command on another bank must be
separated by at least one NOP from the ongoing WRITE. RD or RD/A are not allowed before tWTR or tWTR_RR is met.
5. Action WRITE/A starts with issuing the command and ends tWR after the first positive edge of CLK following the last falling WDQS edge.
6. During action WRITE/A an ACT or a PRE command on another bank is allowed any time. A new WR or WR/A command on another bank has to be
separated by at least one NOP from the ongoing command. RD is not allowed before or tWTR or tWTR_RR is met. RD/A is not allowed during an
ongoing WRITE/A action.
7. Action READ starts with issuing the command and ends with the first positive edge of CLK following the last falling edge of RDQS.
8. During action READ and READ/A an ACT or a PRE command on another bank is allowed any time. A new RD or RD/A command on another bank
has to be separated by at least one NOP from the ongoing command. A WR or WR/A command on another bank has to meet tRTW .
9. Action READ/A starts with issuing the command and ends with the first positive edge of CLK following the last falling edge of RDQS.
10. Action PRECHARGE and PRECHARGE ALL start with issuing the command and ends after tRP.
11. During Action ACTIVE an ACT command on another banks is allowed considering tRRD or tRRD_RR. A PRE command on another bank is allowed
any time. WR, WR/A, RD and RD/A are always allowed.
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Publication Release Date : April 12, 2013
Revision : A01-001
W641GG2KB
1-Gbit GDDR3 Graphics SDRAM
12. During POWER DOWN and SELF REFRESH only the EXIT commands are allowed.
13. AUTO REFRESH starts with issuing the command and ends after tRFC.
14. Actions MODE REGISTER SET, EXTENDED MODE REGISTER SET and EXTENDED MODE REGISTER 2 SET start with issuing the
command and ends after tMRD.
15. Action POWER DOWN EXIT starts with issuing the command and ends after tXPN.
16. Action SELF REFRESH EXIT starts with issuing the command and ends after tXSC.
5.1.3 Function Truth Table for CKE
CKE
N-1
CKE
n
L
L
L
H
H
L
CURRENT STATE
COMMAND
ACTION
Power Down
X
Stay in Power Down
Self Refresh
X
Stay in Self Refresh
Power Down
DESEL or NOP
Exit Power Down
Self Refresh
DESEL or NOP
Exit Self Refresh 5
All Banks Idle
DESEL or NOP
Entry Precharge Power Down
Bank(s) Active
DESEL or NOP
Entry Active Power Down
All Banks Idle
Auto Refresh
Entry Self Refresh
Notes:
1. CKEn is the logic step at clock edge n; CKEn-1 was the state of CKE at the previous clock edge.
2. Current state is the state of the GDDR3 Graphics RAM immediately prior to clock edge n.
3. COMMAND is the command registered at clock edge n, and ACTION is a result of COMMAND.
4. All states and sequences not shown are illegal or reserved.
5. DESEL or NOP commands should be issued on any clock edges occurring during the tXSR period. A minimum of 1000 clock cycles is required
before applying any other valid command.
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Publication Release Date : April 12, 2013
Revision : A01-001
W641GG2KB
1-Gbit GDDR3 Graphics SDRAM
5.2 Functional Block Diagram in 1-CS Mode
A0-A7,A9, A8/AP, A10-A11,A12
BA0-BA2
Address Buffer
Memory
Array
Back 1
8192
X512
X32 bit
Memory
Bank 6
Memory
Array
Back 2
8192
X512
X32 bit
Sense Amplifiers and Data Bus Buffer
8192
X512
X32 bit
Memory
Bank 5
Row
Decoder
Column Decoder
Memory
Array
Back 0
Row
Decoder
Sense Amplifiers and Data Bus Buffer
ZQ
Memory
Bank 4
Column Address Buffer
Column Decoder
MF
Row
Decoder
Sense Amplifiers and Data Bus Buffer
RES
Column Addresses A2-A7,A9
Row Address Buffer
Column Decoder
/WE
Refresh
Counter
Sense Amplifiers and Data Bus Buffer
/CAS
Row Addresses A0-A12, BA0-BA2
Column Decoder
/CS0
/RAS
Control Logic & Timing Generator
Mode Register
A8/AP
Row
Decoder
Memory
Bank 7
Memory
Array
Back 3
8192
X512
X32 bit
CKE
CLK
DQ0-DQ7
DQ8-DQ15
DQ16-DQ23
DQ24-DQ31
DQ24-DQ31
RDQS3
WDQS3
DM3
Input Buffers
DQ16-DQ23
RDQS2
WDQS2
DM2
Output Buffers
DQ8-DQ15
RDQS1
WDQS1
DM1
DLL
DQ0-DQ7
RDQS0
WDQS0
DM0
/CLK
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Publication Release Date : April 12, 2013
Revision : A01-001
W641GG2KB
1-Gbit GDDR3 Graphics SDRAM
5.3 Functional Block Diagram in 2-CS Mode
A0-A7,A9, A8/AP, A10-A11
BA0-BA2
Address Buffer
Mode Register
A8/AP
Row Addresses A0-A11, BA0-BA2
Refresh
Counter
Column Addresses A2-A7,A9
Row Address Buffer
Column Address Buffer
4096
X512
X32 bit
Memory
Bank 7
Memory
Array
Back 3
4096
X512
X32 bit
Bank 1
Memory
Array
Back 2
Row
Decoder
Bank 0
4096
X512
X32 bit
Memory
Bank 6
Sense Amplifiers and Data Bus Buffer
Memory
Array
Back 1
Row
Decoder
Column Decoder
4096
X512
X32 bit
Memory
Bank 5
Sense Amplifiers and Data Bus Buffer
ZQ
Memory
Array
Back 0
Row
Decoder
Column Decoder
MF
Memory
Bank 4
Sense Amplifiers and Data Bus Buffer
RES
Row
Decoder
Column Decoder
/WE
Sense Amplifiers and Data Bus Buffer
/CAS
Column Decoder
/CS0
/RAS
Control Logic & Timing Generator
/CS1
CKE
CLK
DQ0-DQ7
DQ8-DQ15
DQ16-DQ23
DQ24-DQ31
DQ24-DQ31
RDQS3
WDQS3
DM3
Input Buffers
DQ16-DQ23
RDQS2
WDQS2
DM2
Output Buffers
DQ8-DQ15
RDQS1
WDQS1
DM1
DLL
DQ0-DQ7
RDQS0
WDQS0
DM0
/CLK
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Publication Release Date : April 12, 2013
Revision : A01-001
W641GG2KB
1-Gbit GDDR3 Graphics SDRAM
6. FUNCTIONAL DESCRIPTION
This section describes the unitization sequence of the GDRAM. It has been divided into parts for each of the operations modes (1CS or 2-CS). In the initialization, and before the choice of the operation mode by Mode Registration Set command, the default
mode is 1-CS this implies a common initialization sequence up to point 7.
6.1 System Configurations
Figure shows typical system configurations for 1-CS mode and 2-CS mode.
2-CS mode is equivalent to a clamshell configuration with two 512Mbit devices (rank 0 and rank 1) sharing a common interface; it
benefits from the single physical pin load of this monolithic solution.
In 1-CS mode the device is addressed as a single 8-bank device, and the MSB row address A12 selects between the upper and
lower half of the die.
6.1.1 System Configurations in 1-CS Mode and 2-CS Mode
1-CS Mode
Controller
CS0#
CLK,CLK#
ADDR/CMD
DQ0-DQ31
DM0-DM3
WDQS0-WDQS3
RDQS0-RDQS3
2-CS Mode
1Gbit
GDDR3
SDRAM
Controller
1Gbit GDDR3
SDRAM
512Mbit
GDDR3 SDRAM
(Rank 0)
CS0#
CS1#
CLK,CLK#
ADDR/CMD
DQ0-DQ31
DM0-DM3
WDQS0-WDQS3
RDQS0-RDQS3
512Mbit
GDDR3 SDRAM
(Rank 1)
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Publication Release Date : April 12, 2013
Revision : A01-001
W641GG2KB
1-Gbit GDDR3 Graphics SDRAM
6.1.2 Initialization in 1– CS mode
The GDDR3 GRAPHICS SDRAM must be powered up and initialized in a predefined manner. Operational procedures other than
those specified may result in undefined operation or permanent damage to the device. The following sequence is highly
recommended for Power-Up:
1. Apply power (VDD, VDDQ, VREF). Apply VDD before or at the same time as VDDQ, apply VDDQ before or at the same time as VREF.
Maintain RES = Low and CS0 = High to ensure that all the DQ outputs will be in HiZ state, all active terminations off and the DLL
off. All other pins may be undefined.
2. Maintain stable conditions for 200 μs minimum for the GDDR3 to power up.
3. After clock is stable, set CKE to High or Low. After tATS minimum set RES to high. On the rising edge of RES, the CKE value is
latched to determine the address and command bus termination value. If CKE is sampled LOW the address termination value is
set to ZQ / 2. If CKE is sampled HIGH, the address and command bus termination is set to ZQ.
4. After tATH minimum, set CKE to high.
5. Wait a minimum of 700 cycles to calibrate and update the address and command termination impedances. Issue DESELECT on
the command bus during these 700 cycles.
6. Apply a PRECHARGE ALL command by holding CS0 low and wait for tRP to expire.
7. Issue an Extended Mode Register Set command to set the mode to 1-CS and activate the DLL. The mode selection will be done
using the bank address BA2 that will be set to low level for 1-CS mode (in Dual Rank Mode).
8. Issue an Mode Register Set command after tMRD is met to reset the DLL and define the operating parameters.
9. Wait 1000 cycles of clock input to lock the DLL. No Read command can be applied during this time. Since the impedance
calibration is already completed, the DLL mimic circuitry can use the actual programmed driver impedance value.
10. Issue a PRECHARGE ALL command to each of the programmed ranks or issue single bank precharge commands to each of the
8 banks to place the chip in an idle state.
11. Issue or more AUTO REFRESH commands.
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Publication Release Date : April 12, 2013
Revision : A01-001
W641GG2KB
1-Gbit GDDR3 Graphics SDRAM
6.1.3 Initialization in 2– CS mode
The GDDR3 GRAPHICS SDRAM must be powered up and initialized in a predefined manner. Operational procedures other than
those specified may result in undefined operation or permanent damage to the device. The following sequence is highly
recommended for Power-Up:
1. Apply power (VDD, VDDQ, VREF). Apply VDD before or at the same time as VDDQ, apply VDDQ before or at the same time as VREF.
Maintain RES = Low and CS0 = High to ensure that all the DQ outputs will be in HiZ state, all active terminations off and the DLL
off. All other pins may be undefined.
2. Maintain stable conditions for 200 μs minimum for the GDDR3 to power up.
3. After clock is stable, set CKE to High or Low. After tATS minimum set RES to high. On the rising edge of RES, the CKE value is
latched to determine the address and command bus termination value. If CKE is sampled LOW the address termination value is
set to ZQ / 2. If CKE is sampled HIGH, the address and command bus termination is set to ZQ
4. After tATH minimum, set CKE to high.
5. Wait a minimum of 700 cycles to calibrate and update the address and command termination impedances. Issue DESELECT on
the command bus during these 700 cycles.
6. Apply a PRECHARGE ALL command by holding CS0 low and wait for tRP to expire.
7. Issue an Extended Mode Register Set command to set the mode to 2-CS and activate the DLL. The mode selection will be done
using the bank address BA2 that will be set to high level for 2-CS mode (in Single Rank Mode).
8. Issue an Mode Register Set command after tMRD is met to reset the DLL and define the operating parameters.
9. Wait 1000 cycles of clock input to lock the DLL. No Read command can be applied during this time. Since the impedance
calibration is already completed, the DLL mimic circuitry can use the actual programmed driver impedance value.
10. Issue a PRECHARGE ALL command to each of the programmed ranks or issue single bank precharge commands to each of the
16 banks in 2-CS Mode, to place the chip in an idle state.
11. Issue or more AUTO REFRESH commands.
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Publication Release Date : April 12, 2013
Revision : A01-001
W641GG2KB
1-Gbit GDDR3 Graphics SDRAM
6.1.3.1 Power Up Sequence
VDD
VDDQ
VREF
tATS tATH
RES
CKE
CKE#
CLK
Com
DES
DES
PA
EMR
MRS
CODE
CODE
PA
ARF
ARF
ACT
DM
RA
All Banks
All Banks
A8
BA0,
BA1
RA
CODE
CODE
BA0=H,
BA1=L
BA0=L,
BA1=L
RA
RDQS
WDQS
DQ
min. 200 uS
VDD and
CLK stable
700 cycles
tRP
tMRD
tMRD
tRP
tRFC
tRFC
1000 cycles
MRS:MRS command
With DLL Reset
EMR: EMRS command
DES:Deselect
- 21 -
PA: PREALL command
ARF: AUTO REFRESH command
A.C.: Any command
Don’t Care
Publication Release Date : April 12, 2013
Revision : A01-001
W641GG2KB
1-Gbit GDDR3 Graphics SDRAM
6.2 Mirror Function
The GDDR3 GRAPHICS SDRAM provides a mirror function (MF) pin to change the physical location of the command and address
pins assisting in routing devices back to back. The MF ball should be tied directly to VSSQ or VDDQ depending on the control line
orientation desired. The pins affected by this Mirror Function mode are listed in Table. The CS1# and A12 pins are not affected
by Mirror Function.
6.2.1 Ball Assignment with Mirror Function
Signal
Signal
Signal
Signal
Ball
MF=0
MF=1
Ball
MF=0
MF=1
Ball
MF=0
MF=1
Ball
MF=0
MF=1
F4
CAS#
CS0#
H3
RAS#
BA2
K2
A10
A8/AP
K11
A8/AP
A10
F9
CS0#
CAS#
H4
CKE
WE#
K3
A2
A6
L4
A11
A7
G4
BA0
BA1
H9
WE#
CKE
K4
A0
A4
L9
A7
A11
G9
BA1
BA0
H10
BA2
RAS#
K9
A4
A0
M4
A3
A9
H2
A1
A5
H11
A5
A1
K10
A6
A2
M9
A9
A3
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Publication Release Date : April 12, 2013
Revision : A01-001
W641GG2KB
1-Gbit GDDR3 Graphics SDRAM
6.3 Commands
In the following table CKEn refers to the positive edge of CLK corresponding to the clock cycle when the command is given to the
Graphics SDRAM. CKEn-1 refers to the previous positive edge of CLK. For all command and address inputs CKEn is implied.
All input states or sequences not shown are illegal or reserved.
BA1
BA2
A8
A2-7 A9-11/12
L
X
H
X X
X L
H H
X
X
X
X
X
1
1,2
Note
BA0
H
WE#
H
CAS#
H
DESEL
RAS#
CS0#
Device Delselect
Code
CKE
n
Operation
CKE
n-1
6.3.1 Command Overview for 1-CS mode
Data Terminator Disable
DTERDIS
H
H
H
H
L
H
X
X
X
X
X
No Operation
NOP
H
H
L
H
H H
X
X
X
X
X
Mode Register Set
MRS
H
H
L
L
L
L
0
0
0
Extended Mode Register Set
EMRS
H
H
L
L
L
L
1
0
Extended Mode Register Set 2 EMRS2
H
H
L
L
L
L
0
1
Bank Activate
ACT
H
H
L
L
H H BA BA BA
Row Adress
Read
RD
H
H
L
H
L
H BA BA BA
L
Col.
Read w/ Autoprecharge
RD/A
H
H
L
H
L
H BA BA BA
H
Col.
Write
WR
H
H
L
H
L
L
BA BA BA
L
Col.
Write w/ Autoprecharge
WR/A
H
H
L
H
L
L
BA BA BA
H
Col.
Precharge
PRE
H
H
L
L
H
L
BA BA BA
L
X
Precharge All
PREALL
H
H
L
L
H
L
X
X
X
H
X
Auto Refresh
AREF
H
H
L
L
L
H
X
X
X
X
X
1,5
Power Down Mode Entry
PWDNEN
H
L
X
H
X X
H H
X
X
X
X
X
1,6
Power Down Mode Exit
PWDNEX
L
H
X
X
X X
X
X
X
X
X
1,7
Self Refresh Entry
SREFEN
H
L
L
L
L
H
X
X
X
X
X
1,8
Self Refresh Exit
SREFEX
L
H
X
X
X X
X
X
X
X
X
1,9
H
L
OPCODE
OPCODE
0
OPCODE
1,3
1,4
1,4
Notes:
1. X represents ―Don‘t Care‖.
2. This command is invoked when a Read is issued on another DRAM rank placed on the same command bus. Cannot be in power-down or selfrefresh state. The Read command will cause the data termination to be disabled.
3. BA0 - BA2 provide bank address, A0 - A11, A12 provide the row address.
4. BA0 - BA2 provide bank address, A2 - A7, A9 provide the column address, A8/AP controls Auto Precharge.
5. Auto Refresh and Self Refresh Entry differ only by the state of CKE.
6. PWDNEN is selected by issuing a DESEL or NOP at the first positive CLK edge following the HIGH to LOW transition of CKE.
7. First possible valid command after tXPN. During tXPN only NOP or DESEL commands are allowed.
8. Self Refresh is selected by issuing AREF at the first positive CLK edge following the HIGH to LOW transition of CKE.
9. First possible valid command after tXSC. During tXSC only NOP or DESEL commands are allowed.
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Publication Release Date : April 12, 2013
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W641GG2KB
1-Gbit GDDR3 Graphics SDRAM
H
H
H
No Operation
NOP
Mode Register Set
MRS
H
H
L
Extended Mode Register Set
EMRS
H
H
L
Extended Mode Register Set 2 EMRS2
Bank Activate
ACT
Read
RD
Read w/ Autoprecharge
RD/A
Write
WR
Write w/ Autoprecharge
WR/A
Precharge
PRE
Precharge All
Auto Refresh
Power Down Mode Entry
PREALL
AREF
L
X
Note
H
A2-7 A9-11
H
DTERDIS
A8
H
Data Terminator Disable
BA2
L
H X
H
BA1
H
BA0
H
WE#
H
DESEL
CAS#
CS1#
Ranks
CS0#
Device Deselect
Code
CKE
n-1
CKE
Operation
RAS#
6.3.2 Command Overview for 2-CS mode
X
X
H
X
L
H
X
X
X
X
X
1
H
L
H
X
X
X
X
X
H
H
H
X
X
X
X
X
X
L
L
L
0
0
0
OPCODE
X
L
L
L
1
0
0
1
X
L
1,2
OPCODE
H
H
L
X
L
L
L
MemBlock 1
H
H
L
H
L
H
H
BA BA BA Row Address
MemBlock 2
H
H
H
L
L
H
H
BA BA BA Row Address
MemBlock 1
H
H
L
H
H
L
H
BA BA BA
L
Col.
MemBlock 2
H
H
H
L
H
L
H
BA BA BA
L
Col.
MemBlock 1
H
H
L
H
H
L
H
BA BA BA
H
Col.
MemBlock 2
H
H
H
L
H
L
H
BA BA BA
H
Col.
MemBlock 1
H
H
L
H
H
L
L
BA BA BA
L
Col.
MemBlock 2
H
H
H
L
H
L
L
BA BA BA
L
Col.
MemBlock 1
H
H
L
H
H
L
L
BA BA BA
H
Col.
MemBlock 2
H
H
H
L
H
L
L
BA BA BA
H
Col.
MemBlock 1
H
H
L
H
L
H
L
BA BA BA
L
X
MemBlock 2
H
H
H
L
L
H
L
BA BA BA
L
X
Both
H
H
L
L
L
H
L
BA BA BA
L
X
MemBlock 1
H
H
L
H
L
H
L
X
X
X
H
X
MemBlock 2
H
H
H
L
L
H
L
X
X
X
H
X
Both
H
H
L
L
L
H
L
X
X
X
H
X
MemBlock 1
H
H
L
H
L
L
H
X
X
X
X
X
MemBlock 2
H
H
H
L
L
L
H
X
X
X
X
X
Both
H
H
L
L
L
L
H
X
X
X
X
X
H
L
H
L
X
X
H
X
H
X
X
X
X
X
1,6
PWDNEN
H
X
L
X
H
0
OPCODE
1,3
1,4
1,4
1,4
1,4
1
1
1,5
Power Down Mode Exit
PWDNEX
L
H
X
X
X
X
X
X
X
X
X
X
1,7
Self Refresh Entry
SREFEN
H
L
L
L
L
L
H
X
X
X
X
X
1,8
Self Refresh Exit
SREFEX
L
H
X
X
X
X
X
X
X
X
X
X
1,9
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Publication Release Date : April 12, 2013
Revision : A01-001
W641GG2KB
1-Gbit GDDR3 Graphics SDRAM
Notes:
1. X represents ―Don‘t Care‖.
2. This command is invoked when a Read is issued on another DRAM rank placed on the same command bus. Cannot be in power-down or selfrefresh state. The Read command will cause the data termination to be disabled. Refer to Figure (Self Calibration of PMOS and NMOS legs) for
timing.
3. BA0 - BA2 provide bank address, A0 - A11, A12 provide the row address.
4. BA0 - BA2 provide bank address, A2 - A7, A9 provide the column address, A8/AP controls Auto Precharge.
5. Auto Refresh and Self Refresh Entry differ only by the state of CKE.
6. PWDNEN is selected by issuing a DESEL or NOP at the first positive CLK edge following the HIGH to LOW transition of CKE.
7. First possible valid command after tXPN. During tXPN only NOP or DESEL commands are allowed.
8. Self Refresh is selected by issuing AREF at the first positive CLK edge following the HIGH to LOW transition of CKE.
9. First possible valid command after tXSC. During tXSC only NOP or DESEL commands are allowed.
6.3.3 Description of Command
Command
DESEL
NOP
Description
The DESEL function prevents new commands from being executed by the Graphics SDRAM. The Graphics
SDRAM is effectively deselected. Operations in progress are not affected.
The NOP command is used to perform a no operation to the Graphics SDRAM, which is selected
(corresponding CS is LOW). This prevents unwanted commands from being registered during idle or wait
states. Operations already in progress are not affected.
MRS
The Mode Register is loaded via address inputs A0 - A11. For more details see “Mode Register Set
Command (MRS)‖ . The MRS command can only be issued when all banks are idle and no bursts are in
progress. A subsequent executable command cannot be issued until tMRD is met.
EMRS
The Extended Mode Register is loaded via address inputs A0 - A11. For more details see section Extended
Mode Register Commands EMRS1-3 . The EMRS commands can only be issued when all banks are idle and
no bursts are in progress. A subsequent executable command cannot be issued until tMRD is met.
ACT
The ACT command is used to open (or activate) a row in a particular bank for a subsequent access. The value
on the BA0 - BA2 inputs selects the bank, and the address provided in inputs A0 - A11/A12 selects the row.
This row remains active (or open) for accesses until a precharge (PRE, RD/A, or WR/A command) is issued to
that bank. A precharge must be issued before opening a different row in the same bank.
RD
The RD command is used to initiate a burst read access to an active row. The value on the BA0 - BA2 inputs
selects the bank, and the address provided on inputs A2-A7, A9 selects the column location. The row will
remain open for subsequent accesses. For RD commands the value on A8 is set LOW.
RD/A
The RD/A command is used to initiate a burst read access to an active row. The value on the BA0 - BA2 inputs
selects the bank, and the address provided on inputs A2-A7, A9 selects the column location. The value on input
A8 is set HIGH. The row being accessed will be precharged at the end of the read burst. The same individualbank precharge function is performed like it is described for the PRE command. Auto precharge ensures that
the precharge is initiated at the earliest valid stage within the burst. The user must not issue a new ACT
command to the same bank until the precharge time (tRP) is completed. This time is determined as if an explicit
PRE command was issued at the earliest possible time as described in section ―Reads (RD)‖.
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Publication Release Date : April 12, 2013
Revision : A01-001
W641GG2KB
1-Gbit GDDR3 Graphics SDRAM
The WR command is used to initiate a burst write access to an active row. The value on the BA0 - BA2 inputs
selects the bank, and the address provided on inputs A2-A7, A9 selects the column location. The row will
remain open for subsequent accesses. For WR commands the value on A8 is set LOW.
WR
WR/A
PRE
Input data appearing on the DQs is written to the memory array depending on the value on the DM input
appearing coincident with the data. If a given DM signal is registered LOW, the corresponding data will be
written to the memory; if the DM signal is registered HIGH, the corresponding data inputs will be ignored, and
a write will not be executed for that byte / column location.
The WR/A command is used to initiate a burst write access to an active row. The value on the BA0, BA1and
BA2 inputs selects the bank, and the address provided on inputs A2-A7, A9 selects the column location. The
value on input A8 is set HIGH. The row being accessed will be precharged at the end of the write burst. The
same individual-bank precharge function is performed which is described for the PRE command. Auto
precharge ensures that the precharge is initiated at the earliest valid stage within the burst. The user is not
allowed to issue a new ACT to the same bank until the precharge time (tRP) is completed. This time is
determined as if an explicit PRE command was issued at the earliest possible time as described in section
―Writes (WR)‖.
Input data appearing on the DQs is written to the memory array depending on the DM input logic level
appearing coincident with the data. If a given DM signal is registered LOW, the corresponding data will be
written to the memory; if the DM signal is registered HIGH, the corresponding data inputs will be ignored, and
a write will not be executed to that byte / column location.
The PRE command is used to deactivate the open row in a particular bank. The bank will be available for a
subsequent row access a specified time (tRP) after the PRE command is issued. Inputs BA0 - BA2 select the
bank to be precharged. A8/AP is set to LOW. Once a bank has been precharged, it is in the idle state and must
be activated again prior to any RD or WR commands being issued to that bank. A PRE command will be treated
as a NOP if there is no open row in that bank, or if the previously open row is already in the process of
precharging.
PREALL
The PREALL command is used to deactivate all open rows in the memory device. The banks will be available
for a subsequent row access a specified time (tRP) after the PREALL command is issued. Once the banks have
been precharged, they are in the idle state and must be activated prior to any read or write commands being
issued. The PREALL command will be treated as a NOP for those banks where there is no open row, or if a
previously open row is already in the process of precharging. PREALL is issued by a PRE command with A8/AP
set to HIGH.
AREF
The AREF is used during normal operation of the GDDR3 Graphics RAM to refresh the memory content. The
refresh addressing is generated by the internal refresh controller. This makes the address bits ―Don‘t Care‖
during an AREF command. The GDDR3 GRAPHICS SDRAM requires AREF cycles at an average periodic
interval of tREFI(max). To improve efficiency a maximum number of eight AREF commands can be posted to
one memory device (with tRFC from AREF to AREF) as described in section ―Auto Refresh Command
(AREF)‖. This means that the maximum absolute interval between any AREF command is 8 x tREFI(max). This
maximum absolute interval is to allow the GDDR3 Graphics RAM output drivers and internal terminators to
recalibrate, compensating for voltage and temperature changes. All banks must be in the idle state before
issuing the AREF command. They will be simultaneously refreshed and return to the idle state after AREF is
completed. tRFC is the minimum required time between an AREF command and a following ACT/AREF
command.
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Publication Release Date : April 12, 2013
Revision : A01-001
W641GG2KB
1-Gbit GDDR3 Graphics SDRAM
The Self Refresh function can be used to retain data in the GDDR3 Graphics RAM even if the rest of the system
is powered down. When entering the Self Refresh mode by issuing the SREFEN command, the GDDR3
SREFEN
SREFEX
Graphics RAM retains data without external clocking. The SREFEN command is initiated like an AREF
command except CKE is disabled (LOW). The DLL is automatically disabled upon entering Self Refresh mode
and automatically enabled and reset upon exiting Self Refresh. (1000 cycles must then occur before a RD or
DTERDIS command can be issued) The active terminations remain enabled during Self Refresh. Input signals
except CKE are ―Don‘t Care‖. If two GDDR3 Graphics RAMs share the same Command and Address bus, Self
Refresh may be entered only for the two devices at the same time. In 2-CS mode, both memories may only
enter Self-Refresh, in parallel.
The SREFEX command is used to exit the Self Refresh mode. The DLL is automatically enabled and reset
upon exiting. The procedure for exiting Self Refresh requires a sequence of commands. First CLK and CLK#
must be stable prior to CKE going from LOW to HIGH. Once CKE is HIGH, the GDDR3 Graphics RAM must
receive only NOP/DESEL commands until tXSC is satisfied. This time is required for the completion of any
internal refresh in progress. A simple algorithm for meeting both refresh, DLL requirements and output
calibration is to apply NOPs for 1000 cycles before applying any other command to allow the DLL to lock and
the output drivers to recalibrate.
The PWDNEN command enables the power down mode. It is entered when CKE is set low together with a
NOP/DESEL. The CKE signal is sampled at the rising edge of the clock. Once the power down mode is
initiated, all of the receiver circuits except CLK and CKE are gated off to reduce power consumption. The DLL
remains active (unless disabled before with EMRS). All banks can be set to idle state or stay active. During
PWDNEN
Power Down Mode, refresh operations cannot be performed; therefore the refresh conditions of the chip have
to be considered and if necessary Power Down state has to be left to perform an Auto Refresh cycle. If two
GDDR3 Graphics RAMs share the same Command and Address bus, Power down may be entered only for the
two devices at the same time.
PWDNEX
A CKE HIGH value sampled at a low to high transition of CLK is required to exit power down mode. Once CKE
is HIGH, the GDDR3 Graphics RAM must receive only NOP/DESEL commands until tXPN is satisfied. After tXPN
any command can be issued, but it has to comply with the state in which the power down mode was entered.
DTERDIS
Data Termination Disable (Bus snooping for RD commands): The Data Termination Disable Command is
detected by the device by snooping the bus for RD commands excluding CS. The GDDR3 Graphics RAM will
disable its Data terminators when a RD command is detected. The terminators are disabled starting at CL - 1
clocks after the RD command is detected and the duration is 4 clocks. In a 2CS system, both DRAM devices
will snoop the bus for RD commands to either device and both will disable their terminators if a RD command
is detected. The command and address terminators are always enabled. See Figure (ODT Disable Timing
during a READ command) for an example of when the data terminators are disabled during a RD command.
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Publication Release Date : April 12, 2013
Revision : A01-001
W641GG2KB
1-Gbit GDDR3 Graphics SDRAM
6.3.4 Minimum delay from RD/A and WR/A to any other command (to another bank) with concurrent AP
From Command
To Command
WR/A
RD/A
Minimum delay to another bank (with concurrent
auto precharge)
RD or RD/A
(WL + 2) × tCK + tWTR
WR or WR/A
2 × tCK
PRE
ACT
tCK
tCK
RD or RD/A
2 × tCK
WR or WR/A
(CL + 4 - WL) × tCK
PRE
tCK
tCK
ACT
Note
6.4 Boundary Scan
6.4.1 General Description
The 1-Gbit GDDR3 incorporates a modified boundary scan test mode. This mode doesn‘t operate in accordance with IEEE
Standard 1149.1-1990. To save the current GDDR3 ball-out, this mode will scan the parallel data input and output the scanned data
through the WDQS0 pin controlled by SEN.
Note: Both pads CS1# and A12 will be activated and could be accessed during Boundary Scan.
6.4.2 Disabling the scan feature
It is possible to operate the GDDR3 without using the boundary scan feature. SEN (at U-4 of 136- ball package) should be tied
LOW(VSS) to prevent the device from entering the boundary scan mode. The other pins which are used for scan mode, RES, MF,
WDQS0 and CS will be operating at normal GDDR3 functionalities when SEN is deasserted.
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Publication Release Date : April 12, 2013
Revision : A01-001
W641GG2KB
1-Gbit GDDR3 Graphics SDRAM
6.4.2.1 Internal Block Diagram (Reference only)
Dedicated Scan D FF
Per signal under test
Tie to logic 0
D
DM0
DQ
CK
Pins under test
D
DQ5
DQ
CK
D
DQ4
DQ
CK
The following lists the rest of the signals on the scan chain:
DQ[3:0],DQ[31:6],RDQS[3:1],DM[3:1],
CAS#,WE#,CKE,BA[2:0],A[11:0],CK, CK# and ZQ
Two RFU‘s (J-2 and J-3 on 136-ball package) will be on
The scan chain and will read as a logic ―0‖
D
RDQS0
DQ
RES (SSH,Scan Shift)
The following lists the signals not on the scan chain:
VDD,VSS,VDDQ,VSSQ,VDDA,VSSA and VREF
CK
CS# (SCK,Scan Clock)
WDQS0 (SOUT,Scan Out)
Puts device into scan mode and re-maps pins to scan functionality
SEN, Scn Enable
MF (SOE#, Output Enable)
6.4.2.2 Boundary Scan Exit Order
BIT#
BALL
BIT#
BALL
BIT#
BALL
BIT#
BALL
BIT#
BALL
BIT#
BALL
1
D-3
13
E-10
25
K-11
37
R-10
49
L-3
61
G-4
2
C-2
14
F-10
26
K-10
38
T-11
50
M-2
62
F-4
3
C-3
15
E-11
27
K-9
39
T-10
51
M-4
63
F-2
4
B-2
16
G-10
28
M-9
40
T-3
52
K-4
64
G-3
5
B-3
17
F-11
29
M-11
41
T-2
53
K-3
65
E-2
6
A-4
18
G-9
30
L-10
42
R-3
54
K-2
66
F-3
7
B-10
19
H-9
31
N-11
43
R-2
55
L-4
67
E-3
8
B-11
20
H-10
32
M-10
44
P-3
56
J-3
9
C-10
21
H-11
33
N-10
45
P-2
57
J-2
10
C-11
22
J-11
34
P-11
46
N-3
58
H-2
11
D-10
23
J-10
35
P-10
47
M-3
59
H-3
12
D-11
24
L-9
36
R-11
48
N-2
60
H-4
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Publication Release Date : April 12, 2013
Revision : A01-001
W641GG2KB
1-Gbit GDDR3 Graphics SDRAM
Notes:
1. When the device is in scan mode, the mirror function will be disabled and none of the pins are remapped.
2. Since the other input of the MUX for DM0 tied to GND, the device will output the continuous zeros after scanning a bit #67, if the
chip stays in scan shift mode.
3. An unconnected CS1# and A12 on the board will be read as undefined.
6.4.2.3 Scan Pin Description
PACKAGE
BALL
SYMBOL
NORMAL
FUNCTION
TYPE
V-9
SSH
RES
Input
Scan Shift: Capture the data input from the pad at logic LOW and shift the
data on the chain at logic HIGH.
F-9
SCK
CS
Input
Scan Clock: Not a true clock, could be a single pulse or series of pulses.
All scan inputs will be referenced to rising edge of the scan clock
D-2
SOUT
WDQS0
V-4
SEN
SEN
A-9
SOE
MF
DESCRIPTION
Output Scan Output
Input
Scan Enable: Logic HIGH enables the device into scan mode and will be
disabled at logic LOW. Must be tied to GND when not in use.
Input
Scan Output Enable: Enables (registered LOW) and disables (registered
HIGH) SOUT data. This pin will be tied to VDD or GND through a resistor
(typically 1 KΩ for normal operation). Tester needs to overdrive this pin to
guarantee the required input logic level in scan mode.
Notes:
1. When SEN is asserted, no commands are to be executed by the GDDR3. This applies both to user commands and
manufacturing commands which may exist while RES is deasserted.
2. The Scan Function can be used right after bringing up VDD / VDDQ of the device. No initialization sequence of the device is
required. After leaving the Scan Function it is required to run through the complete initialization sequence.
3. In Scan Mode all terminations for CMD/ADD and DQ, DM, RDQS and WDQS are switched off.
4. In a double-load clam-shell configuration, SEN will be asserted to both devices. Separate two SOE‘s should be provided to top and
bottom devices to access the scanned output. When either of the devices is in scan mode, SOE for the other device which is not in a
scan will be disabled.
6.4.2.4 Scan DC Electrical Characteristics and Operating Condition
PARAMETER/CONDITION
Symbol
Min.
Max.
Units
Note
Input High (Logic 1) Voltage
VIH(DC)
VREF+0.15
—
1,2
Input Low (Logic 0) Voltage -
VIL(DC)
—
VREF-0.15 V
1,2
Notes:
1. The parameter applies only when SEN is asserted.
2. All voltages referenced to GND.
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Publication Release Date : April 12, 2013
Revision : A01-001
W641GG2KB
1-Gbit GDDR3 Graphics SDRAM
6.4.2.5 Scan Capture Timing
SCK
tSES
SEN
SSH
Low
tSCS
SOE#
tSDS
Pins
Under
Test
tSDH
VALID
Don‘t care
6.4.2.6 Scan Shift Timing
SCK
SEN
tSES
tSCS
SSH
tSCS
SOE#
SOUT
Scan Out
Bit 0
tSAC
Scan Out
Bit 1
Scan Out
Bit 2
Scan Out
Bit 3
tSOH
Don’t care
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Publication Release Date : April 12, 2013
Revision : A01-001
W641GG2KB
1-Gbit GDDR3 Graphics SDRAM
6.4.2.7 Scan AC Electrical Characteristic
Parameter/Condition
Symbol
Min.
Max.
Units
Note
tSCK
40
—
ns
1
Scan enable setup time
tSES
20
—
ns
1,2
Scan enable hold time
tSEH
20
—
ns
2
Scan command setup time for SSH, SOE and SOUT
tSCS
tSCH
14
—
ns
1
14
—
ns
1
tSDS
tSDH
10
—
ns
1
10
—
ns
1
—
10
ns
1
1.5
—
ns
1
Clock
Clock cycle time
Scan Command Time
Scan command hold time for SSH, SOE and SOUT
Scan Capture Time
Scan capture setup time
Scan capture hold time
Scan Shift Time
tSAC
tSOH
Scan clock to valid scan output
Scan clock to scan output hold
Notes:
1. The parameter applies only when SEN is asserted.
2. Scan Enable should be issued earlier than other Scan Commands by 6 ns.
6.4.3 Scan Initialization
The Initialization sequence for the boundary scan functionality depends on the intended SGRAM operation mode. There are two
modes to distinguish. The first mode is the Stand-Alone mode. In the Stand-Alone mode the SGRAM is supposed to support the
Boundary Scan functionality only, the user does not intend to operate the DRAM in its ordinary functionality after or prior to the
entering of the Boundary Scan functionality. The purpose of the Stand-Alone mode could be a connectivity test at the
manufacturing site.
The second mode is the regular SGRAM functionality. With this common mode the boundary scan functionality can be enabled after
the SGRAM has been initialized by the regular power-up and SGRAM Initialization sequence. When the boundary scan functionality
is left the regular SGRAM initialization sequence has to be re-iterated.
6.4.3.1 Scan Initialization for Stand-Alone Mode
The SGRAM needs to follow the given sequence to support the boundary scan functionality in the Stand-Alone mode.
There is no external clock for the whole sequence needed.
Sequence Flow:
1. External Voltages (VDD/VDDQ/VREF) need to be stable for 200μs, SEN has to be kept low.
2. Bring SEN up to high state to enter boundary scan functionality.
3. Operate boundary scan functionality according to the scan features given in Chapter.
4. Boundary scan can be exited by bringing SEN low or simply by switching power off.
The Scan initialization sequence for the Stand-Alone Mode is shown in Figure.
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Publication Release Date : April 12, 2013
Revision : A01-001
W641GG2KB
1-Gbit GDDR3 Graphics SDRAM
6.4.3.2 Scan Initialization for Stand-Alone mode
VDD
VDDQ
VREF
tSDS tSDH
CLK/
CLK#
VALID
tSCS
tSCH
SSH
[RES]
tSCS tSCH
SEN
tSES
SCK[CS#]
SOE[MF]
tSCS
tSCS
SOUT[WDQS]
tSDS tSDH
ScanOut Bit 0
Pins
Under
Test
VALID
T = 200 us
Boundary Scan Mode
Power-up :
Don‘t care
VDD / VDDQ / VREF stable
6.4.4 Scan Initialization in regular SGRAM operation
The Initialization sequence of the boundary scan functionality in regular SGRAM operation has to follow the given sequence.
Sequence Flow:
1. External Voltages (VDD/VDDQ/VREF) need to be stable for 200 μs, RES has to be kept low, external clock has to be stable prior to
RES goes high
2. Bring RES high and keep clock stable for 700tcks, CKE will be latched by rising RES edge, keep tATH/tATS
3. Bring SEN up to high state to enter boundary scan functionality
4. Operate boundary scan functionality accordingly to the scan features given in Chapter
5. Boundary scan can be exited by bringing SEN low
6. Wait tSN for bringing up RES, prior to bringing RES to high state external has to be stable
7. After RES is at high state wait 700tck
8. Continue with regular Initialization sequence (PRE-ALL, EMRS, MRS).
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Publication Release Date : April 12, 2013
Revision : A01-001
W641GG2KB
1-Gbit GDDR3 Graphics SDRAM
The steps 1 and 2 are necessary to enable the termination for the command/address pins. They are part of the regular SGRAM
Initialization. They are required if the user wants to issue commands between to entering of the boundary scan functionality and the
power-up sequence. The entering of the boundary scan mode is resetting the command/address termination values and all
EMRS/MRS settings. Therefore they have to be initialized again after the boundary scan functionary has been left. Figure
(Boundary Scan Exit Sequence) shows the scan initialization sequence for regular SGRAM operation.
6.4.4.1 Scan Initialization Sequence within regular SGRAM Mode
VDD
VDDQ
VREF
tSDS tSDH
VALID
CLK/CLK#
tSCS
tSCH
SSH [RES]
tSCS
tATS tATH
tSDS tSDH
CKE
tSCH
VALID
SEN
tSES
SCK[CS#]
SOE[MF]
tSCS
SOUT[WDQS]
tSCS
tSDS tSDH
ScanOut Bit 0
Pins
Under
Test
VALID
T = 200 us
Power-up :
VDD stable
700 tCK
RESET at power - up
Boundary Scan Mode
Don‘t care
6.4.5 Scan Exit Sequence
Figure shows the Scan exit Sequence. This figure show the exiting of the boundary scan functionality in conjugation with the
appended regular SGRAM initialization sequence to bring the SGRAM again in a well defined state.
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Publication Release Date : April 12, 2013
Revision : A01-001
W641GG2KB
1-Gbit GDDR3 Graphics SDRAM
6.4.5.1 Boundary Scan Exit Sequence
Stable clock
CLK/
CLK#
tRESL
RES
tATS tATH
Standard Power up sequence
Starting with PRE ALL
CKE
tSN
SEN
SOUT
invalid
700 tCK
6.4.5.2 Scan AC Electrical Parameter
Limit Values
Parameter
tRESL
tSN
Symbol
Unit
tRESL
tSN
- 35 -
Min
Max.
20
-
20
-
Note
ns
ns
Publication Release Date : April 12, 2013
Revision : A01-001
W641GG2KB
1-Gbit GDDR3 Graphics SDRAM
6.5 Programmable impedance output drivers and active terminations
6.5.1 GDDR3 IO Driver and Termination
The GDDR3 GRAPHICS SDRAM is equipped with programmable impedance output buffers and active terminations. This allows
the user to match the driver impedance to the system impedance.
To adjust the impedance of DQ[0:31] and RDQS[0:3], an external precision resistor (ZQ) is connected between the ZQ pin and
VSS. The value of the resistor must be six times the value of the desired impedance. For example, a 240 Ω resistor is required for
an output impedance of 40 Ω. The range of ZQ is 210 Ω to 270 Ω, giving an output impedance range of 35 Ω to 45 Ω (one sixth
the value of ZQ within 10%).
The value of ZQ is used to calibrate the internal DQ termination resistors of DQ[0:31], WDQS[0:3] and DM[0:3]. The two termination
values that are selectable using EMRS[3:2] are ZQ / 4 and ZQ / 2.
The value of ZQ is also used to calibrate the internal address command termination resistors. The inputs terminated in this manner
are A[0:11], A[12],CKE#, CS0#, CS1#, RAS#, CAS#, WE#. The two termination values that are selectable upon power up (CKE
latched LOW to HIGH transition of RES) are ZQ / 4 and ZQ / 2. RES, MF , CLK and CLK# are not internally terminated.
If no resistance is connected to ZQ, an internal default value of 240 Ω will be used. In this case, no calibration will be performed.
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Publication Release Date : April 12, 2013
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W641GG2KB
1-Gbit GDDR3 Graphics SDRAM
6.5.1.1 Output Driver simplified schematic
VDDQ
Read to other Rank
Output Data
Read to other Enable
DQ
VSSQ
6.5.1.2 Range of external resistance ZQ
Parameter
Symbol
Min.
Nom.
Max.
Units
External resistance value
ZQ
210
240
270
Ω
Note
6.5.1.3 Termination Types and Activation
Ball
Termination type
CLK, CLK#, RDQS[0:3], ZQ, RES, MF
Termination activation
No termination
CKE, CS0#, CS1#, RAS#, CAS#, WE#, BA0 - BA2 , A[0:11], A[12]
Add / CMDs
Always ON
DM[0:3], WDQS[0:3]
DQ
Always ON
DQ[0:31]
DQ
CMD bus snooping
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W641GG2KB
1-Gbit GDDR3 Graphics SDRAM
6.5.2 Self Calibration for Driver and Termination
The output impedance is updated during all AREF commands. These updates are used to compensate for variations in supply
voltage and temperature. Impedance updates do not affect device operation. No activity on the Address, command and data bus is
allowed during a minimum Keep Out time tKO after the Auto refresh command has been issued.
6.5.2.1 Termination update Keep Out time after Auto refresh command
CLK#
CLK
Com.
NOP
ARF
Add.
DQ
tKO
ARF : Autorefresh
Don’t care
Keep Out time
To guarantee optimum driver impedance after power-up, the GDDR3 GRAPHICS SDRAM needs 700 cycles after the clock is
applied and stable to calibrate the impedance upon power-up. The user can operate the part with fewer than 700 cycles, but
optimal output impedance will not be guaranteed.
The GDDR3 Graphics RAM proceeds in the following manner for Self Calibration:
The PMOS device is calibrated against the external ZQ resistor value. First one PMOS leg is calibrated against ZQ. The number of
legs used for the terminators (DQ and ADD/CMD) and the PMOS driver is represented in Table. Next, one NMOS leg is calibrated
against the already calibrated PMOS leg. The NMOS driver uses 6 NMOS legs.
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W641GG2KB
1-Gbit GDDR3 Graphics SDRAM
6.5.2.2 Number of Legs used for Terminator and Driver Self Calibration
CKE (at RES)
Termination
Number of Legs
0
ZQ/2
2
1
ZQ
1
ADD / CMD
EMRS[3:2]
Terminator
00
Disabled
0
10
ZQ/4
4
11
ZQ/2
2
PMOS
ZQ/6
6
NMOS
ZQ/6
6
DQ
Driver
Note
1
Note:
1. EMRS[3:2] = 00 disables the ADD and CMD terminations as well.
Figure represents a simplified schematic of the calibration circuits. First, the strength control bits are adjusted in such a way that the
VDDQ voltage is divided equally between the PMOS device and the ZQ resistor. The best bit pattern will cause the comparator to
switch the PMOS Match signal output value. In a second step, the NFET is calibrated against the already calibrated PFET. In the
same manner, the best control bit combination will cause the comparator to switch the NMOS Match signal output value.
6.5.2.3 Self Calibration of PMOS and NMOS Legs
VDDQ
VDDQ
NMOS
Calibration
VSSQ
Strength Control
[2:0]
PMOS
Calibration
VDDQ / 2
ZQ
Match
Strength Control
[2:0]
VDDQ / 2
VSSQ
VSSQ
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Publication Release Date : April 12, 2013
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W641GG2KB
1-Gbit GDDR3 Graphics SDRAM
6.5.3 Dynamic Switching of DQ terminations
The GDDR3 Graphics RAM will disable its data terminators when a READ or DTERDIS command is detected. The terminators are
disabled starting at CL - 1 Clocks after the READ / DTERDIS command is detected and the duration is 4 clocks. In a two rank
system, both devices will snoop the bus for a READ / DTERDIS command to either device and both will disable their terminators if
a READ / DTERDIS command is detected. The address and command terminators are always enabled.
6.5.3.1 ODT Disable Timing during a READ command
0
1
2
3
4
5
6
7
8
9
RD
N/D
N/D
N/D
N/D
N/D
N/D
N/D
N/D
N/D
CLK#
CLK
Com.
Add.
B/C
CAS Iatency = 5
RDQS
DQ
D0
DQ
Termination
D1
D2
D3
Data Terminations are disabled
Dx : Data from B / C
Com. : Command
Addr. : Address B / C
B / C : Bank / Column address
RD : READ
N / D : NOP or Deselect
Don‘t care
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1-Gbit GDDR3 Graphics SDRAM
6.5.4 Output impedance and Termination DC Electrical Characteristics
The Driver and Termination impedances are determined by applying VDDQ/2 nominal at the corresponding input/output and by
measuring the current flowing into or out of the device. VDDQ is set to the nominal value.
IOH is the current flowing out of DQ when the Pull-Up transistor is activated and the DQ termination disabled. IOL is the current
flowing into DQ when the Pull-Down transistor is activated and the DQ termination disabled. ITCAH(ZQ) is the current flowing out of the
Termination of Commands and Addresses for a ZQ termination value.
6.5.4.1 DC Electrical Characteristic
Limit Values
Parameter
ZQ Value
240
Min.
Max.
Unit
Note
IOH
ZQ/6
20.5
25.0
mA
1,2
IOL
ZQ/6
20.5
25.0
mA
1,2
ITCAH(ZQ)
ZQ
3.4
4.2
mA
1,2
Notes:
1. Measurement performed with VDDQ (nominal) and by applying VDDQ/2 at the corresponding Input / Output. 0° C ≤ Tc ≤70° C
2. for 1.8 V VDD/VDDQ power supply
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1-Gbit GDDR3 Graphics SDRAM
6.6 Mode Register Set Command (MRS)
The Mode Register stores the data for controlling the operation modes of the memory. It programs CAS latency, test mode, DLL
Reset, the value of the Write Latency and the Burst length. The Mode Register must be written after power up to operate the
SGRAM. During a Mode Register Set command the address inputs are sampled and stored in the Mode Register. The mode
Register content can only be set or changed when the chip is in idle state. For non-READ commands following a Mode Register Set
a delay of tMRD must be met.
To apply an MRS command, CS0 has to be used.
6.6.1 Mode Register Set Command
CLK#
CLK
CKE
(High)
CS#
RAS#
CAS#
WE#
A0-A11
COD
BA0
0
BA1, BA2
0
COD: Code to be loaded
into the register.
= Don't Care
6.6.2 Mode Registers
Three Mode Registers MRS, EMRS1 and EMRS2 define the specific mode of operation. All Mode Registers are initialized upon
power-up as indicated below.
All functions controlled by Mode Register EMRS3 and some high-speed options in the other registers as outlined below shall be
deactivated or deleted such that programming of the respective register bits has no effect.
6.6.2.1 Mode Register (MRS)
The Mode Register controls operating modes such as Burst Length, Burst Type, CAS latency, Write Latency, DLL Reset and Test
Mode as shown in Figure. The register is programmed via the MODE REGISTER SET command with BA0=0, BA1=0 and BA2=0.
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Publication Release Date : April 12, 2013
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W641GG2KB
1-Gbit GDDR3 Graphics SDRAM
6.6.2.2 Mode Register (MRS)
BA2
BA1
BA0
0
0
0
A11
A10
A9
WL
A8
A7
DLL
TM
A6
A5
A4
CAS Latency
A3
A2
BT
mode
A0
BL
Test Mode
Write Latency
A1
Burst Length
A1
A10
A9
WL
A7
A2
A1
A0
BL
0
1
1
3*
0
Normal*
0
1
0
4*
1
0
0
4
1
Test mode
0
1
1
1
0
1
5
1
1
0
6
1
1
1
7
8
All others
CAS Latency
DLL Reset
Burst Type
A8
DLL Reset
A6
A5
A4
Latency
A3
BT
0
No*
0
0
0
8*
0
Sequential*
1
Yes
0
0
1
9
1
RFU
0
1
0
10
0
1
1
11
1
0
0
12
1
0
1
13
1
1
0
14
1
1
1
7
Note: The DLL Reset bit is self-clearing
RFU
* Default value at power-up
6.6.2.3 Mode Register Set Timing
CLK#
CLK
Command
PA
NOP
tRP
MRS
NOP
NOP
NOP
A.C.
RD
tMRD
tMRDR
MRS : MRS command
PA : PREALL command
A.C. : Any other command as READ
RD
: READ command
Don't Care
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Publication Release Date : April 12, 2013
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W641GG2KB
1-Gbit GDDR3 Graphics SDRAM
6.6.3 Burst Length and Burst Type
6.6.3.1 Burst Length
Read and write accesses to the GDDR3 GRAPHICS SDRAM are burst-oriented, with a burst length of 4 or 8 as programmed in bits
A0-A2.
When a READ or WRITE command is issued, a block of columns equal to the burst length is effectively selected.
All accesses for that burst take place within this block, meaning that the burst will wrap within the block if a boundary is reached.
The block is uniquely selected by address bits A2-A7, A9.
The access order within a burst is fixed, and address bits A0 and A1 are ignored as shown in Table.
The only supported burst type is sequential.
6.6.3.2 Burst type
Accesses within a given bank must be programmed to be sequential. This is done using the Mode Register Set command (A3). This
device does not support the burst interleave mode.
6.6.3.2.1 Burst Definition
Burst Length
4
8
Column Address
Order of Accesses within a Burst
A2
A1
A0
—
X
X
0-1-2-3
0
X
X
0-1-2-3-4-5-6-7
1
X
X
4-5-6-7-0-1-2-3
The value applied at the balls A0 and A1 for the column address is ―Don‘t care‖.
6.6.4 CAS Latency
The READ latency, or CAS latency, is the delay between the registration of a READ command and the availability of the first piece
of output data. The latency is set using bits A4-A6.
If a READ command is registered at clock edge n, and the latency is m clocks, the data will be available nominally coincident with
clock edge n + m.
The high-speed option for CAS latencies of 13 to 20 shall be deleted or deactivated.
6.6.5 Write Latency
The WRITE latency (WL) is the delay, in clock cycles, between the registration of a WRITE command and the availability of the first
bit of input data. The latency is set using bits A9-A11.
If a WRITE command is registered at clock edge n, and the latency is m clocks, the data will be available nominally coincident with
clock edge n + m.
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Publication Release Date : April 12, 2013
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W641GG2KB
1-Gbit GDDR3 Graphics SDRAM
6.6.6 DLL Reset
The normal operating mode is selected by issuing a MODE REGISTER SET command with bit A8 set to zero, and bits A0-A7 and
A9-A11 set to the desired values. A DLL reset is initiated by issuing a MODE REGISTER SET command with bit A8 set to one, and
bits A0-A7 and A9-A12 set to the desired values. The register bit is self clearing meaning that it returns back to the value ‗0‘ after
the DLL reset function has been issued.
6.6.7 Test mode
The normal operating mode is selected by issuing a MODE REGISTER SET command with bit A7 set to ‗0‘, and bitsA0-A6 and A8A11 set to the desired values. Programming bit A7 to ‗1‘ places the device into a test mode that is only to be used by the DRAM
manufacturer. No functional operation is specified with test mode enabled.
6.7 Extended Mode Register Set Command (EMRS1)
The Extended Mode Register is used to control multiple operation modes of the device. The most important one is the
organization as a 1-CS or a 2-CS device. Furthermore, it is used to set the output driver impedance value, the
termination impedance value, the Write Recovery time value for Write with Autoprecharge. It is used as well to
enable/disable the DLL, to issue the Vendor ID. There is no default value for the Extended Mode Register. Therefore it
must be written after power up to operate the GDDR3 Graphics RAM. The Extended Mode Register can be
programmed by performing a normal Mode Register Set operation and setting the BA0 bit to HIGH. All other bits of the
EMR register are reserved and should be set to LOW. The Extended Mode Register must be loaded when all banks
are idle and no burst are in progress. The controller must wait the specified time tMRD before initiating any subsequent
operation (Figure: Extended Mode Register 1).
The timing of the EMRS command operation is equivalent to the timing of the MRS command operation. To apply an
EMRS command, CS0 has to be used.
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Publication Release Date : April 12, 2013
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W641GG2KB
1-Gbit GDDR3 Graphics SDRAM
6.7.1 Extended Mode Register Set Command
CLK#
CLK
CKE
(High)
CS#
RAS#
CAS#
WE#
A0-A11
COD
BA0
1
BA1
0
BA2
Mode
COD: Code to be loaded
into the register.
= Don't Care
6.7.2 Extended Mode Register 1 (EMRS1)
The Extended Mode Register 1 controls operating modes such as output driver impedance, data termination, address/command
termination, DLL on/off, Write recovery and Vendor ID as shown in Figure. It also selects between 1-CS mode and 2-CS mode
configuration. The register is programmed via the MODE REGISTER SET command with BA0=1, BA1=0 and BA2 set to the
desired configuration.
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Publication Release Date : April 12, 2013
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W641GG2KB
1-Gbit GDDR3 Graphics SDRAM
6.7.2.1 Extended Mode Register 1 (EMRS1)
BA2
BA1
BA0
A11
A10
Mode
0
1
RFU
Vendor
ID
A8
A7
A6
ADD/CMD
Ternination
WR
DLL
A9
A5
A4
Write
Recovery
A3
A2
A1
Data
Termination
A0
OCD
Impedance
BA2
Chip Select
Mode
A10
Vendor ID
A6
DLL
A1
A0
OCD
Impedance
0
1
1-CS
2-CS
0
1
Off (*)
On
0
1
On (*)
Off
0
0
1
1
0
1
0
1
Autocal (*)
35 ohms
40 ohms
45 ohms
A9
A8
ADD/CMD
Ternination
0
0
1
1
0
1
0
1
ZQ/4
ZQ/2
ZQ/2 (*)
ZQ
(*) = Default value at power-up
A7
A5
A4
Write
Recovery
0
0
0
0
1
1
1
1
0
0
1
1
0
0
1
1
0
1
0
1
0
1
0
1
11
4
5
6
7
8
9
10 (*)
A3
A2
Data
Termination
0
0
1
1
0
1
0
1
disabled
RFU
ZQ/4
ZQ/2 (*)
Notes:
1. Default termination values at Power Up.
2. The ODT disable function disables all terminators on the device.
3. If the user activates bits in the extended mode register in an optional field, either the optional field is activated (if option
implemented in the device) or no action is taken by the device (if option not implemented).
4. WR (write recovery time for auto precharge) in clock cycles is calculated by dividing tWR (in ns) and rounding up to the next
integer (WR[cycles] = tWR[ns] / tCK[ns]). The mode register must be programmed to this value.
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Publication Release Date : April 12, 2013
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W641GG2KB
1-Gbit GDDR3 Graphics SDRAM
6.7.2.2 Extended Mode Register Set Timing
CLK#
CLK
Command
PA
EMRS
NOP
NOP
NOP
tRP
A.C.
tMRD
EMRS : Extended MRS command
PA
: PREALL command
A.C.
: Any command
Don't Care
6.7.3 Chip Select Mode
Mode
EMRS1[BA2]
EMRS2[A5]
Pin for CS1#
Pin for A12
1-CS Mode, non-merged
0
0
NA
J-2
0
1
1
0
J-3
NA
1
1
NA
J-3
2-CS Mode
1-CS Mode, merged
6.7.4 DLL
The DLL is enabled by default. If DLL-off operation is desired, the DLL must be disabled by setting bit A6 to '1'. Once enabled, the
DLL requires 1000 cycles to lock.
6.7.5 Write Recovery
The programmed WR value is used for the auto precharge feature along with tRP to determine tDAL. WR must be programmed
with a value greater than or equal to [RU{ tWR / tCK }], where RU stands for round up, tWR is the analog value and tCK is the
operating clock cycle time.
The high-speed option for Write Recovery values of 11 to 20 shall be deleted or deactivated.
6.7.6 Termination Rtt
The data termination, Rtt, is used to set the value of the internal termination resistors. The GDDR3 DRAM supports ZQ / 4 and ZQ /
2 termination values. The termination may also be disabled for testing and other purposes. Data -, address - and command
- termination are disabled in parallel. The Termination Rtt are controlled independently from the Output Driver Impedance
values.
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Publication Release Date : April 12, 2013
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W641GG2KB
1-Gbit GDDR3 Graphics SDRAM
6.7.7 Impedance Autocalibration of Output Buffer and Active Terminator
GDDR3 GRAPHICS SDRAMs offer autocalibrating impedance output buffers and on-die terminations (ODT). This enables a user to
match the driver impedance and terminations to the system within a given range. To adjust the impedance, an external precision
resistor shall be connected between the ZQ pin and VSSQ. A nominal resistor value of 240 is equivalent to 40 Pull down, 40 Pull-up
and 60 ODT nominal impedances. If no resistance is connected to the ZQ pin, a default value of 240 is assumed and no calibration
is performed.
The output driver and on-die termination impedances are updated during all REFRESH commands to compensate for variations in
supply voltage and temperature. The impedance updates are transparent to the system.
Table provides an overview of the ODT settings controlled by EMRS1.
6.7.7.1 Impedance Options
Signal
ODT Activation
EMRS1 Control Bits
No ODT
-
CKE,CS0#,CS1#,RAS#,CAS#,WE#,BA0BA2,A0-A12
Always on
A8-A9
DM0-DM3,WDQS0-WDQS3
Always on
A2-A3
Always on except for Reads
(bus snooping)
A2-A3
No ODT
-
CLK,CLK#,RES,MF,SEN
DQ0-DQ31
RDQS0-RDQS3
6.7.7.2 Timing of Vendor Code and Revision ID Generation on DQ[7:0]
0
1
2
3
4
5
6
7
8
9
10
N/D
N/D
N/D
N/D
N/D
EMRS
N/D
N/D
N/D
N/D
CLK#
CLK
Com.
A[9:0],A11
EMRS
Add
Add
A10
tRIDon
tRIDoff
RDQS
DQ[7:0]
Vender Code and Revision ID
EMRS : Extended Mode Register Set Command
Add : Address
N / D : NOP or Deselect
Don‘t care
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1-Gbit GDDR3 Graphics SDRAM
6.7.8 Output Driver Impedance
Bits A0 and A1 define the driver strength. The Auto Calibration setting enables the Auto-Calibration functionality for the Pull down,
Pull-up and Termination over process, temperature and voltage changes. The 35Ω, 40Ω and 4Ω5 options enable factory settings
for the Pull down, Pull-up driver strength and termination.
With any of those options enabled, driver strength and termination are expected to change with process, voltage and temperature.
AC timings are only guaranteed with Auto Calibration.
6.7.9 Data Termination
Bits A2 and A3 define the data termination value for the on-die termination (ODT) for the DQ pins in combination with
the driver strength setting. The termination can be set to a value of ZQ/4 or ZQ/2; it may also be turned off.
6.7.10 Address command termination
Bits A8 and A9 define the address/command termination. The termination can be set to a value of ZQ/4, ZQ/2 or ZQ. The setting
overwrites the value defined upon power-up initialization.
6.8 Extended Mode Register 2 Set Command (EMRS2)
The Extended Mode Register 2 is used to control OCD/ODT impedance offsets. It can be programmed by performing a normal
Mode Register Set operation and setting the BA1 bit to HIGH and BA0, BA2 bits to LOW. The Extended Mode Register 2 must be
loaded when all banks are idle and no burst is in progress. The controller must wait the specified time tMRD before initiating any
subsequent operation. The timing of the EMRS2 command operation is equivalent to the timing of the MRS command operation.
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Publication Release Date : April 12, 2013
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W641GG2KB
1-Gbit GDDR3 Graphics SDRAM
6.8.1 Extended Mode Register 2 Set Command
CLK#
CLK
CKE
CS#
RAS#
CAS#
WE#
A0-A11
BA1
COD
1
COD : Code to be loaded into
the register
BA0,2
0
Don‘t care
6.8.2 Extended Mode Register 2 (EMRS2)
The Extended Mode Register 2 controls output driver and termination offsets and Merged Mode as shown in Figure. The register is
programmed via the MODE REGISTER SET command with BA0=0, BA1=1 and BA2=0.
The Application Mode function (mid range vs. high speed) on bit A0 and the temperature sensor self refresh function on bit A1 shall
be deleted or deactivated.
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Publication Release Date : April 12, 2013
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W641GG2KB
1-Gbit GDDR3 Graphics SDRAM
6.8.2.1 Extended Mode Register 2 (EMRS2)
A11
A10
A9
A8
BA1
BA0
0
1
0
A11
A10
A9
OCD PD
Offset
A8
A7
A6
ODT PU
Offset
0
0
0
0
1
1
1
1
0
0
1
1
0
0
1
1
0
1
0
1
0
1
0
1
0 (*)
+1
+2
+3
RFU
-3
-2
-1
0
0
0
0
1
1
1
1
0
0
1
1
0
0
1
1
0
1
0
1
0
1
0
1
0 (*)
+1
+2
+3
RFU
-3
-2
-1
OCD Pulldown
Offset
A7
A6
BA2
ODT Pullup
Offset
A5
A4
Merged
Mode
A3
A2
A1
A0
Reserved
A5
Merged Mode
0
1
Non-Merged (*)
Merged
(*) = Default value at power-up
6.8.2.2 Impedance Offsets
The driver and termination impedances may be offset individually for output driver and data termination. The offset impedance step
values correspond to a nominal value of TBD. With negative offset steps the drive strengths will be decreased and Ron will be
increased. With positive offset steps the drive strengths will be increased and Ron will be decreased.
6.8.2.3 Merged Mode
Merged Mode combines the specific pins of 1-CS Mode (A12) and 2-CS Mode (CS1#) on a single physical pin (J-3).
6.8.3 OCD Pull Down Offset
The 1G GDDR3 add the ability to add an offset to the Output impedance driver set using the bit A[1:0] of the EMRS. A range from
-3 to +3 can be chosen using A[11:9]. Each step corresponds to an approximate change of 1 Ohms. The offset will be applied also
on Autocal value if selected. The offset will be applied also on Autocal value if selected. With negative offset steps the Driver
Strength will be decreased and the Ron will be increased. With positive offset steps the Driver Strength will be increased and Ron
will be decreased.
6.8.4 ODT Pull Up Offset
The 1G GDDR3 add the ability to add an offset to the ODT set using the bit A[3:2] of the EMRS. A range from -3 to +3 can be
chosen using A[8:6]. Each step corresponds to an approximate change of 1.5 Ohms. With negative offset steps the Termination value
will be increased. With positive offset steps the Termination value will be decreased.
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Publication Release Date : April 12, 2013
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W641GG2KB
1-Gbit GDDR3 Graphics SDRAM
6.9 Extended Mode Register 3 (EMRS3)
All functions originally controlled by EMRS3 like alternate CL/WR, RDBI, WDBI and Multi-Cycle Preamble (MPR) shall be deleted or
deactivated, or shall be permanently set (autocal enabled, nominal VINT).
6.10 Vendor Code and Revision ID
When the Vendor Code function is enabled by bit A10, the GDDR3 GRAPHICS SDRAM will provide the vendor code on DQ[3:0]
and the revision identification on DQ[7:4] as shown in Table.
The Revision ID shall be made programmable on a single metal layer (TBD).
6.10.1 Vendor ID Code
Default Revision ID (DQ7-DQ4)
Manufacturer ID (DQ3-DQ0)
0000
1000
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Publication Release Date : April 12, 2013
Revision : A01-001
W641GG2KB
1-Gbit GDDR3 Graphics SDRAM
6.11 Bank / Row Activation (ACT)
Before a READ or WRITE command can be issued to a bank, a row in that bank must be opened. This is accomplished via the ACT
command, which selects both the bank and the row to be activated. After opening a row by issuing an ACT command, a READ
command may be issued after tRCDRD to that row or a WRITE command after tRCDWR.
A subsequent ACT command to a different row in the same bank can only be issued after the previous active row has been closed
(precharged). The minimum time interval between successive ACT commands to the same bank is defined by tRC.
A subsequent ACT command to another bank can be issued while the first bank is being accessed, which results in a reduction of
total row-access overhead. The minimum time interval between successive ACT commands to ACT commands to banks in the
same rank is defined by tRRD, and to banks in different ranks by tRRD_RR (see Figure:Bank Activation Timing on different rank in
2-CS mode).There is a minimum time tRAS between opening and closing a row.
For the 1-CS Mode (1Gb) an additional address bit is available (A12). Internally this additional address bit is converted into a
selection signal for one or the other internal rank representing the first or the second half of the 512 Mb. Subsequent column
accesses to the activated bank are steered to the internal rank as selected by A12 during activation of the bank.
6.11.1 Activating a specific row
CLK#
CLK
CKE
CS#
RAS#
CAS#
WE#
A0-A11
BA0-BA2
RA
RA : Row address
BA : Bank Address
Don‘t care
BA
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Publication Release Date : April 12, 2013
Revision : A01-001
W641GG2KB
1-Gbit GDDR3 Graphics SDRAM
6.11.2 Bank Activation Timing
CLK#
CLK
Com.
ACT
R/W
PRE
ACT
ACT
A0-A11
Row
Col
A8
Row
Row
BA0,BA1
B.Y
B.Y
B.Y
B.Y
B.X
Row: Row Address
Col: Column Address
B.X: Bank X
B.Y: Bank Y
R/W: READ or WRITE command
PRE: PRECHARGE command
ACT: ACTIVATE command
tRCD
tRAS
tRC
Don‘t care
tRRD
6.11.3 Bank Activation Timing on different rank in 2-CS mode
CLK#
CLK
Com.
ACT
R/W
PRE
ACT_0
ACT_1
A0-A11
Row
Col
A8
Row
Row
BA0,BA1
B.Y
B.Y
B.Y
B.Y
B.X
tRCD
tRAS
Row: Row Address
Col: Column Address
B.X: Bank X
B.Y: Bank Y
R/W: READ or WRITE command
PRE: PRECHARGE command
ACT_0: ACTIVATE command Rank 0
ACT_1: ACTIVATE command Rank 1
tRRD_RR=1
tRC
Don‘t care
For eight bank GDDR3 devices, there may be a need to limit the number of activates in a rolling window to ensure that the
instantaneous current supplying capability of the devices is not exceeded. To reflect the true capability of the DRAM instantaneous
current supply, the parameter tFAW (four activate window) is defined. No more than 4 banks may be activated in a rolling tFAW
window. Converting to clocks is done by dividing tFAW (ns) by tCK (ns) and rounding up the next integer value. As an example of the
rolling window, if (tFAW / tCK) rounds up to 10 clocks, and an activate command is issued in clock n, no more than three further
activate commands may be issued in clocks n+1 through n+9. tFAW is only valid within one rank. There is no further restriction
between ranks.
6.11.4 Four Window Active tFAW
CLK#
CLK
CMD
ACT
ACT
tRRD
ACT
ACT
ACT
tRRD
tRRD
ACT
tRRD
ACT
tRRD
ACT
tRRD
tFAW
tFAW+3*tRRD
ACT:ACTIVATE command
Don‘t care
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Publication Release Date : April 12, 2013
Revision : A01-001
W641GG2KB
1-Gbit GDDR3 Graphics SDRAM
6.11.5 Clock, CKE and command / Address Timings
tCK
tCH
tCL
CLK#
CLK
tIPW
CMD,
ADDR,
CKE
tIS
tIH
Don‘t care
Setup and Hold Timing for CKE is equal to CMD and ADDR Setup and Hold Timing.
6.12 Bank Activations with REFRESH
6.12.1 Bank Activations with REFRESH Command
Operating
Mode
1-CS Mode
2-CS Mode
2X REF Mode
Bank Refreshed per REF Command
Effective tRET
off
4 even or 4 odd banks in all 4 quedrants
32ms
on
All 8 banks in all 4 quadrants
16ms
off
4 even or 4 odd banks in selected rank (rank 0 or rank 1) or in
both ranks
32ms
on
All 8 banks in selected rank (rank 0 or rank 1) or in both ranks
16ms
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Publication Release Date : April 12, 2013
Revision : A01-001
W641GG2KB
1-Gbit GDDR3 Graphics SDRAM
6.13 Writes (WR)
6.13.1 Write - Basic Information
Write bursts are initiated with a WR command, as shown in Figure. The column and bank addresses are provided with the WR
command, and Auto Precharge is either enabled or disabled for that access. The length of the burst initiated with a WR command is
four or eight depending on the mode register setting. There is no interruption of WR bursts. The two least significant address bits A0
and A1 are ―Don‘t Care‖.
For WR commands with Autoprecharge the row being accessed is precharged tWR/A after the completion of the burst. If
tRAS(min) is violated the begin of the internal Autoprecharge will be performed one cycle after tRAS(min) is met. WR, the write
recovery time for write with Autoprecharge can be programmed in the Mode Register. Choosing high values for WR will prevent the
chip to delay the internal Autoprecharge in order to meet tRAS(min).
During WR bursts data will be registered with the edges of WDQS. The write latency can be programmed during Extended Mode
Register Set. The first valid data is registered with the first valid rising edge of WDQS following the WR command. The externally
provided WDQS must switch from HIGH to LOW at the beginning of the preamble. There is also a post amble requirement before
the WDQS returns to HIGH. The WDQS signal can only transition when data is applied at the chip input and during pre- and post
ambles. tDQSS is the time between WR command and first valid rising edge of WDQS. Nominal case is when WDQS edges are
aligned with edges of external CLK. Minimum and maximum values of tDQSS define early and late WDQS operation. Any input data
will be ignored before the first valid rising WDQS transition.
tDQSL and tDQSH define the width of low and high phase of WDQS. The sum of tDQSL and tDQSH has to be tCK. Back to back WR
commands are possible and produce a continuous flow of input data.
For back to back WR, tCCD has to be met. Any WR burst may be followed by a subsequent RD command. Figure (Write followed by
Read) shows the timing requirements for a WR followed by a RD. In this case the delay between the WR command and the
following RD may be zero for access across the two 8 bank segments (tWTR_RR = 1 tCK) as shown in Figure (Write followed by
Read on different ranks in 2-CS mode).
A WR may also be followed by a PRE command to the same bank. tWR has to be met as shown in Figure (Write followed by
Precharge on same bank).
Setup and hold time for incoming DQs and DMs relative to the WDQS edges are specified as tDS and tDH. DQ and DM input pulse
width for each input is defined as tDIPW. The input data is masked if the corresponding DM signal is high.
All timing parameters are defined with graphics DRAM terminations on.
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Publication Release Date : April 12, 2013
Revision : A01-001
W641GG2KB
1-Gbit GDDR3 Graphics SDRAM
6.13.1.1 Write Command
CLK#
CLK
CKE
CS#
RAS#
CAS#
WE#
A2-A7,A9
CA
A0,A1
A10-A11
A8
BA0,BA1
AP
CA : Colimn address
BA : Bank Address
Don‘t care
BA
6.13.1.2 Mapping of WDQS and DM Signals
WDQS
Data mask signal
Controlled DQs
WDQS0
DM0
DQ0 - DQ7
WDQS1
DM1
DQ8 - DQ15
WDQS2
DM2
DQ16 - DQ23
WDQS3
DM3
DQ24 - DQ31
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Publication Release Date : April 12, 2013
Revision : A01-001
W641GG2KB
1-Gbit GDDR3 Graphics SDRAM
6.13.1.3 Basic Write Burst / DM Timing
CLK#
CLK
nominal WDQS
tDQSS
tDQSH
tWPRE
tDQSS nominal
Preamble
tDS
tDQSL
tDQSH
tDH
tWPST
tDS
tDH
Postamble
WDQS
tDIPW
D0
DQ
D1
tDS
D3
tDH
DMx
early WDQS
D2
tDIPW
Data masked
min(tDQSS)
Data masked
WDQS
late WDQS
max(tDQSS)
WDQS
Don‘t care
DMx:Represents one DM line
Note: WDQS can only transition when data is applied at the chip input and during pre- and postambles.
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Publication Release Date : April 12, 2013
Revision : A01-001
W641GG2KB
1-Gbit GDDR3 Graphics SDRAM
6.14 Write - Basic Sequence
CLK#
CLK
0
Com.
WR
Addr.
B/C
1
2
3
4
5
6
7
8
N/D
DES
DES
DES
DES
DES
DES
DES
NOP
NOP
NOP
WL = 3
WDQS
D0 D1 D2 D3
DQ
WL = 4
WDQS
D0
DQ
Com.
WR
Addr.
B/C
N/D
NOP
NOP
D1 D2 D3
NOP
NOP
WL = 3
WDQS
DQ
D0
D1
D2 D3
WL = 4
WDQS
D0 D1 D2 D3
DQ
B / C: Bank / Column address
WR : WRITE
NOP : No Operation
DES : Deselect
N/D : NOP or DES
Com. : Command
Addr. : Address B / C
D# : Data to B / C
WL : Write Latency
Don’t care
Notes:
1. Shown with nominal value of tDQSS.
2. WDQS can only transition when data is applied at the chip input and during pre- and postambles.
3. When NOPs are applied on the command bus, the WDQS and the DQ busses remain stable High.
4. When DESs are applied on the command bus, the status of the WDQS and DQ busses is unknown.
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Publication Release Date : April 12, 2013
Revision : A01-001
W641GG2KB
1-Gbit GDDR3 Graphics SDRAM
6.15 Write - Consecutive Bursts
6.15.1Gapless Bursts
6.15.1.1 Gapless Write Bursts
0
1
2
3
4
5
6
7
8
9
Com.
WR
N/D
WR
N/D
DES
DES
DES
DES
DES
DES
Addr.
B/Cx
CLK#
CLK
B/Cy
WL = 3
WDQS
DQ
Dx0 Dx1 Dx2 Dx3 Dy0 Dy1 Dy2 Dy3
WL = 4
WDQS
DQ
Dx0 Dx1 Dx2 Dx3 Dy0 Dy1 Dy2 Dy3
WR : WRITE
DES : Deselect
N/D : NOP or DES
B / Cx: Bank / Column address
B / Cy: Bank / Column address
WL : Write Latency
Don‘t care
Dx# : Data to B / Cx
Dy# : Data to B / Cy
Com. : Command
Addr. : Address B / C
Notes:
1. Shown with nominal value of tDQSS.
2. The second WR command may be either for the same bank or another bank.
3. WDQS can only transition when data is applied at the chip input and during pre- and postambles.
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Publication Release Date : April 12, 2013
Revision : A01-001
W641GG2KB
1-Gbit GDDR3 Graphics SDRAM
6.15.2 Bursts with Gaps
6.15.2.1 Consecutive Write Bursts with Gaps
0
1
2
3
4
5
6
7
8
9
10
WR
N/D
N/D
WR
N/D
DES
DES
DES
DES
DES
DES
CLK#
CLK
Com.
Addr.
B/Cx
B/Cy
WL = 3
WDQS
Dx0 Dx1 Dx2
DQ
Dy0 Dy1 Dy2
Dx3
Dy3
WL = 4
WDQS
DQ
Dx0 Dx1 Dx2
Dx3
Com. : Command
Addr. : Address B / C
DES : Deselect
N/D : NOP or DES
WL : Write Latency
WR : WRITE
Dy0
Dy1 Dy2 Dy3
B / Cx: Bank / Column address
B / Cy: Bank / Column address
Don’t care
Dx# : Data to B / Cx
Dy# : Data to B / Cy
Notes:
1. Shown with nominal value of tDQSS.
2. The second WR command may be either for the same bank or another bank.
3. WDQS can only transition when data is applied at the chip input and during pre- and postambles.
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Publication Release Date : April 12, 2013
Revision : A01-001
W641GG2KB
1-Gbit GDDR3 Graphics SDRAM
6.15.3 Write with Autoprecharge
0
1
2
3
4
5
6
7
8
9
WR/A
N/D
DES
DES
DES
DES
DES
DES
DES
DES
10
CLK#
CLK
Com.
A9,
A7-A2
DES
B/C
A8
WL = 3
tWR/A=3
WDQS
tRP
DQ
D0
D1
D2
D3
tRASMIN
satisifed
WL = 4
Begin of
Autoprecharge
tWR/A=3
WDQS
tRP
DQ
D0
D1
D2
D3
tRASMIN
satisifed
Com. : Command
Addr. : Address B / C
WL : Write Latency
Don‘t care
Begin of
Autoprecharge
B / C: Bank / Column address
WR/A : WRITE with auto-precharge
D# : Data to B / C
DES : Deselect
N/D : NOP or DES
Notes:
1. Shown with nominal value of tDQSS.
2. tWR/A starts at the first rising edge of CLK after the last valid edge of WDQS.
3. tRP starts after tWR/A has been expired.
4. When issuing a WR/A command please consider that the tRAS requirement also must be met at the beginning of tRP.
5. tWR/A ≥ tWR.
6. WDQS can only transition when data is applied at the chip input and during pre- and postambles.
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Publication Release Date : April 12, 2013
Revision : A01-001
W641GG2KB
1-Gbit GDDR3 Graphics SDRAM
6.15.4 Write followed by Read
0
1
2
3
4
DES
DES
5
6
DES
DES
7
8
9
DES
RD
N/D
CLK#
CLK
Com.
WR
Addr.
B/C
DES
N/D
B/C
WL = 3
tWTR
WDQS
DQ
D0
Com.
WR
Addr.
B/C
N/D
DES
DES
D1
D2
D3
DES
DES
DES
DES
DES
RD
B/C
WL = 4
tWTR
WDQS
DQ
D0
D1
D2
D3
D# : Data to B / C
Com. : Command
Addr. : Address B / C
WL : Write Latency
Don‘t care
B / C: Bank / Column address
WR : WRITE
RD : READ
DES : Deselect
N/D : NOP or DES
Notes:
1. Shown with nominal value of tDQSS.
2. The RD command may be either for the same bank or another bank.
3. WDQS can only transition when data is applied at the chip input and during pre- and postambles.
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Publication Release Date : April 12, 2013
Revision : A01-001
W641GG2KB
1-Gbit GDDR3 Graphics SDRAM
6.15.5 Write followed by Read on different ranks in 2-CS mode
0
1
2
3
4
5
6
7
11
12
13
14
15
DES
WR_0
RD_1
N/D
DES
DES
DES
DES
DES
DES
DES
DES
DES
DES
DES
CLK#
CLK
Com.
CL = 9
tWTR_RR=1
Addr.
B/C
B/C
WL = 3
WDQS
RDQS
DQ
Com.
D0
DES
WR
RD
N/D
B/C
D2
D3
DES
D0
DES
DES
DES
D1
DES
D2
D3
DES
CL = 9
tWTR_RR=1
Addr.
DES
D1
B/C
WL = 4
WDQS
RDQS
DQ
D0
D1
D2
D0
D3
D# : Data to B / C
Com. : Command
Addr. : Address B / C
WL : Write Latency
D1
D2
D3
B / C: Bank / Column address
WR_0 : WRITE on Rank 0
Don‘t care
RD_1 : READ on Rank 1
DES : Deselect
N/D : NOP or DES
Notes:
1. tWTR_RR is defined between write and read command on different rank.
2. Shown with nominal value of tDQSS.
3. The RD command may be either for the same bank or another bank.
4. WDQS can only transition when data is applied at the chip input and during pre- and postamble.
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Publication Release Date : April 12, 2013
Revision : A01-001
W641GG2KB
1-Gbit GDDR3 Graphics SDRAM
6.15.6 Write followed by DTERDIS
0
1
2
3
4
5
6
7
8
9
10
DES
DES
DES
DES
DES
DES
DES
DES
DES
DES
DES
DES
DES
DES
DES
CLK#
CLK
Com.
WR
Addr.
B/C
DTD
CL = 7
WL = 3
WDQS
DQ
Com.
Addr.
D0
WR
N/D
DTD
DES
D1
D2
D3
DES
B/C
CL = 7
WL = 4
WDQS
DQ
D0
D1
D2
D3
B / C: Bank / Column address
WR : WRITE
DTD : DTERDIS
D# : Data to B / C
Com. : Command
Addr. : Address B / C
WL : Write Latency
CL : CAS Latency
DES : Deselect
N/D : NOP or Deselect
Don‘t care
Data Termination off
Notes:
1. Shown with nominal value of tDQSS.
2. WDQS can only transition when data is applied at the chip input and during pre- and postambles.
3. A margin of one clock has been introduced in order to make sure that the data termination is still on when the last Write data
reaches the memory.
4. The minimum distance between Write and DTERDIS is one clock.
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Publication Release Date : April 12, 2013
Revision : A01-001
W641GG2KB
1-Gbit GDDR3 Graphics SDRAM
6.15.7 Write with Autoprecharge followed by Read / Read with Autoprecharge on another bank
0
1
2
3
WR/A
N/D
DES
DES
5
4
6
7
8
9
DES
RD
RD/A
DES
CLK#
CLK
Com.
A9,
A2-A7
DES
DES
DES
B/C
B/C
A8
tWTR
tWTR
tRP
tWR/A
WL = 3
WDQS
DQ
Com.
A9,
A2-A7
D0
WR/A
N/D
DES
D1
DES
D2
D3
Begin of Autoprecharge
DES
DES
DES
DES
DES
B/C
RD
RD/A
B/C
A8
tWTR
tRP
tWR/A
WL = 4
WDQS
DQ
D0
D1
D2
D3
Begin of Autoprecharge
Com. : Command
Addr. : Address B / C
WL : Write Latency
Don‘t care
0 : RD, 1 : RD/A
B / C: Bank / Column address
WR/A : WRITE with Autoprecharge
RD RD/A : READ or
READ with Autoprecharge
D# : Data to B / C
DES : Deselect
N/D : NOP or Deselect
Notes:
1. Shown with nominal value of tDQSS.
2. The RD command is only allowed for another activated bank.
3. tWR/A is set to 4 in this example.
4. WDQS can only transition when data is applied at the chip input and during pre- and postambles.
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Publication Release Date : April 12, 2013
Revision : A01-001
W641GG2KB
1-Gbit GDDR3 Graphics SDRAM
6.15.8 Write followed by Precharge on same bank
0
1
2
Com.
WR
N/D
DES
Addr.
B/C
3
4
5
6
7
8
9
DES
DES
DES
DES
DES
DES
PRE
10
CLK#
CLK
DES
B
WL = 3
tRP
tWTR
WDQS
DQ
D0
Com.
WR
Addr.
B/C
N/D
DES
DES
D1
D2
D3
DES
DES
DES
DES
DES
DES
PRE
B
WL = 4
tWTR
tRP
WDQS
DQ
D0
D1
D2
D3
N/D : NOP or Deselect
DES : Deselect
Com. : Command
Addr. : Address B / C
WL : Write Latency
Don‘t care
B / C: Bank / Column address
WR : WRITE
PRE : PRECHARGE
Dx# : Data to B / Cx
Dy# : Data to B / Cy
Notes:
1. Shown with nominal value of tDQSS.
2. WR and PRE commands are to same bank.
3. tRAS requirement must also be met before issuing PRE command.
4. WDQS can only transition when data is applied at the chip input and during pre- and postambles.
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Publication Release Date : April 12, 2013
Revision : A01-001
W641GG2KB
1-Gbit GDDR3 Graphics SDRAM
6.16 Reads (RD)
6.16.1 Read - Basic Information
Read bursts are initiated with a RD command, as shown in Figure (Basic Read Burst Timing). The column and bank addresses
are provided with the RD command and Autoprecharge is either enabled or disabled for that access. The length of the burst initiated
with a RD command is 4 or 8. There is no interruption of RD bursts. The two least significant start address bits are ―Don‘t Care‖.
If Autoprecharge is enabled, the row being accessed will start internal precharge at the latter of either the completion of bits prefetch
or one cycle after tRAS(min) is met.
During RD bursts the memory device drives the read data edge aligned with the RDQS signal which is also driven by the memory.
After a programmable CAS latency of 7, 8, 9 or 10 the data is driven to the controller. RDQS leaves HIGH state one cycle before its
first rising edge (RD preamble tRPRE). After the last falling edge of RDQS a postamble of tRPST is performed. tAC is the time between
the positive edge of CLK and the appearance of the corresponding driven read data. The skew between RDQS and the crossing
point of CLK/CLK# is specified as tDQSCK. tAC and tDQSCK are defined relatively to the positive edge of CLK. tDQSQ is the skew between
a RDQS edge and the last valid data edge belonging to the RDQS edge. tDQSQ is derived at each RDQS edge and begins with
RDQS transition and ends with the last valid transition of DQs. tQHS is the data hold skew factor and tQH is the time from the first valid
rising edge of RDQS to the first conforming DQ going non-valid and it depends on tHP and tQHS. tHP is the minimum of tCL and
tCH. tQHS is effectively the time from the first data transition (before RDQS) to the RDQS transition. The data valid window is derived
for each RDQS transition and is defined as tQH minus tDQSQ.
After completion of a burst, assuming no other commands have been initiated, data will go HIGH and RDQS will go HIGH. Back to
back RD commands are possible producing a continuous flow of output data. For back to back RD, tCCD has to be met.
Any RD burst may be followed by a subsequent WR command. The minimum required number of NOP commands between the RD
command and the WR command (tRTW) depends on the programmed CAS latency and the programmed Write latency tRTW(min)=
(CL+4-WL) , the timing requirements for RD followed by a WR with some combinations of CL and WL. A RD may also be followed
by a PRE command. Since no interruption of bursts is allowed the minimum time between a RD command and a PRE is two clock
cycles.
All timing parameters are defined with controller terminations on.
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Publication Release Date : April 12, 2013
Revision : A01-001
W641GG2KB
1-Gbit GDDR3 Graphics SDRAM
6.16.1.1 Read Command
CLK#
CLK
CKE
CS#
RAS#
CAS#
WE#
A2-A7,A9
CA
A0,A1
A10-A11
A8
BA0-BA2
AP
AP : AutoPrecharge
CA : Row address
BA : Bank Address
Don‘t care
BA
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Publication Release Date : April 12, 2013
Revision : A01-001
W641GG2KB
1-Gbit GDDR3 Graphics SDRAM
6.16.1.2 Basic Read Burst Timing
tCH
tCL
tCK
tHP
CLK#
CLK
tDQSCK
RDQS
Preamble
Postamble
tRPRE
tRPST
DQ (first data valid)
D0
DQ (last data valid)
D1
D0
D2
D3
D2
D1
D3
tAC
D0
All DQs collectively
D1
tDQSQ
tQH
tQHS
tLZ
D2
Data
Valid
window
D3
tDQSQ
Don‘t care
Hi-Z : Not driven
By DDRⅢ SGRAM
tHZ
Notes:
1. The GDDR3 GRAPHICS SDRAM switches off the DQ terminations one cycle before data appears on the bus and drives the data
bus HIGH.
2. The GDDR3 GRAPHICS SDRAM drives the data bus HIGH one cycle after the last data driven on the bus before switching the
termination on again.
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1-Gbit GDDR3 Graphics SDRAM
6.16.2 Read - Basic Sequence
6.16.2.1 Read Burst
0
1
2
3
6
7
8
9
10
11
RD
N/D
N/D
N/D
N/D
N/D
N/D
N/D
N/D
N/D
CLK#
CLK
Com.
Addr.
B/C
CAS latency = 5
RDQS
DQ
D0
D1
D2
D3
D0
D1
CAS latency = 6
RDQS
DQ
B / C: Bank / Column address
Dx : Data from B / C
Com. : Command
Addr. : Address B / C
D2
D3
RD : READ
N/D : NOP or Deselect
Don‘t care
DQs : Terminations off
RDQS : Not driven
Notes:
1. Shown with nominal tAC and tDQSQ.
2. RDQS will start driving high 1/2 cycle prior to the first falling edge and stop 1/2 cycle after the last rising edge of RDQS.
3. The DQ terminations are switched off 1 cycle before the first Read Data and on again 1 cycle after the last Read data.
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6.16.3 Consecutive Read Bursts
6.16.3.1 Gapless Bursts
6.16.3.1.1 Gapless Consecutive Read Bursts
0
1
2
3
6
7
8
9
10
11
12
13
Com.
RD
N/D
RD
N/D
N/D
N/D
N/D
N/D
N/D
N/D
N/D
N/D
Addr.
B/Cx
CLK#
CLK
B/Cy
CAS latency = 5
RDQS
DQ
Dx0 Dx1 Dx2 Dx3 Dy0 Dy1 Dy2 Dy3
CAS latency = 6
RDQS
DQ
Dx0 Dx1 Dx2 Dx3 Dy0 Dy1 Dy2 Dy3
B / Cx: Bank / Column address
B / Cy: Bank / Column address
Dx# : Data from B / Cx
Dy# : Data from B / Cy
Com. : Command
Addr. : Address B / C
RD : READ
N/D : NOP or Deselect
Don‘t care
DQs : Terminations off
RDQS : Not driven
Notes:
1. The second RD command may be either for the same bank or another bank.
2. Shown with nominal tAC and tDQSQ.
3. Example applies only when READ commands are issued to same device.
4. RDQS will start driving high 1/2 cycle prior to the first falling edge and stop 1/2 cycle after the last rising edge of RDQS.
5. The DQ terminations are switched off 1 cycle before the first Read Data and on again 1 cycle after the last Read data.
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1-Gbit GDDR3 Graphics SDRAM
6.16.4 Bursts with Gaps
6.16.4.1 Consecutive Read Bursts with Gaps
0
1
2
3
6
7
8
9
10
11
12
Com.
RD
N/D
N/D
RD
N/D
N/D
N/D
N/D
N/D
N/D
N/D
Addr.
B/Cx
CLK#
CLK
B/Cy
CAS latency = 5
RDQS
DQ
Dx0
Dx1 Dx2
Dx3
Dy0
Dy1 Dy2
Dy3
CAS latency = 6
RDQS
DQ
Dx0
Dx1 Dx2
Dx3
B / Cx: Bank / Column address x
B / Cy: Bank / Column address y
RD : READ
Dx# : Data from B / Cx
Dy# : Data from B / Cy
Com. : Command
Addr. : Address B / C
Dy0
Dy1 Dy2
Don‘t care
DQs : Terminations off
RDQS : Not driven
Notes:
1. The second RD command may be either for the same bank or another bank.
2. RDQS will start driving high 1/2 cycle prior to the first falling edge and stop 1/2 cycle after the last rising edge of RDQS.
3. The DQ terminations are switched off 1 cycle before the first Read Data and on again 1 cycle after the last Read data.
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1-Gbit GDDR3 Graphics SDRAM
6.16.5 Read followed by DTERDIS
Notes:
1. At least BL/2+1 NOPs are required between a READ command and a DTERDIS command in order to avoid contention on the
RDQS bus in a 2 memories system.
2. CAS Latency 7 is used as an example.
3. The DQ terminations are switched off (CL-1) clock periods after the DTERDIS command for a duration of BL/2+2 clocks.
4. The dashed lines (RDQS bus) describe the RDQS behavior in the case where the DTERDIS command corresponds to a Read
command applied to the second Graphics DRAM in a 2 memories system. In this case, RDQS would be driven by the second
Graphics DRAM.
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1-Gbit GDDR3 Graphics SDRAM
6.16.6 Read with Autoprecharge
Notes:
1. When issuing a RD/A command, the tRAS requirement must be met at the beginning of Autoprecharge.
2. Shown with nominal tAC and tDQSQ.
3. RDQS will start driving high 1/2 cycle prior to the first falling edge and stop 1/2 cycle after the last rising edge of RDQS.
4. The DQ terminations are switched off 1 cycle before the first Read Data and on again 1 cycle after the last Read data.
5. tRAS Lockout support.
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1-Gbit GDDR3 Graphics SDRAM
6.16.7 Read followed by Write
Notes:
1. Shown with nominal tAC, tDQSQ and tDQSS.
2. RDQS will start driving high 1/2 cycle prior to the first falling edge and stop 1/2 cycle after the last rising edge of RDQS.
3. The DQ terminations are switched off 1 cycle before the first Read Data and on again 1 cycle after the last Read data.
4. WDQS can only transition when data is applied at the chip input and during pre- and postambles.
5. The Write command may be either on the same bank or on another bank.
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6.16.8 Read followed by Precharge on the same Bank
Notes:
1. tRAS requirement must also be met before issuing PRE command.
2. RD and PRE commands are applied to the same bank.
3. Shown with nominal tAC and tDQSQ.
4. RDQS will start driving high 1/2 cycle prior to the first falling edge and stop 1/2 cycle after the last rising edge of RDQS.
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1-Gbit GDDR3 Graphics SDRAM
6.17 Data Termination Disable (DTERDIS)
The Data Temination Disable command is detected by the device by snooping the bus for Read commands when CS is high. The
terminators are disabled starting at CL - 1 clocks after the DTERDIS command is detected and the duration is 4 clocks. The
command and address terminators are always enabled.
DTERDIS may only be applied to the GDDR3 Graphics memory if it is not in the Power Down or in the Self Refresh state.
The timing relationship between DTERDIS and other commands is defined by the constraint to avoid contention on the RDQS bus
(i.e Read to DTERDIS transition) or the necessity to have a defined termination on the data bus during Write (i.e. Write to DTERDIS
transition). ACT and PRE/PREALL may be applied at any time before or after a DTERDIS command.
6.17.1 Data Terminal Disable Command
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1-Gbit GDDR3 Graphics SDRAM
6.17.1.1 DTERDIS Timing
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1-Gbit GDDR3 Graphics SDRAM
6.17.2 DTERDIS followed by DTERDIS
Notes:
1. At least 1NOP is required between 2 DTERDIS commands. This corresponds to a Read to Read transition on the other memory
in a 2 memories system.
2. CAS Latency 7 is used as an example.
3. The DQ terminations are switched off (CL-1) clock periods after the DTERDIS command for duration of 4 clocks.
4. The dashed lines (RDQS bus) describe the RDQS behavior in the case where the DTERDIS command corresponds to a Read
command applied to the second Graphics DRAM in a 2 memories system. In this case, RDQS would be driven by the second
Graphics DRAM.
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1-Gbit GDDR3 Graphics SDRAM
6.17.3 DTERDIS followed by READ
Notes:
1. At least BL/2+1 NOPs are required between a DTERDIS command and a READ command in order to avoid contention on the
RDQS bus in a 2 memories system.
2. CAS Latency 7 is used as an example.
3. The DQ terminations are switched off (CL-1) clock periods after the DTERDIS command for duration of 4 clocks.
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1-Gbit GDDR3 Graphics SDRAM
6.17.4 DTERDIS followed by Write
Notes:
1. Write shown with nominal value of tDQSS.
2. WDQS can only transition when data is applied at the chip input and during preambles and postambles.
3. The minimum distance between DTERDIS and Write is (CL - WL + BL/2 +2) clocks.
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1-Gbit GDDR3 Graphics SDRAM
6.18 Precharge (PRE/PREALL)
The Precharge command is used to deactivate the open row in a particular bank (PRE) or the open rows in all banks (PREALL).
The bank(s) will enter the idle state and be available again for a new row access after the time tRP. A8/AP sampled with the PRE
command determines whether one or all banks are to be precharged. For PRE commands BA0, BA1 and BA2 select the bank. For
PREALL inputs BA0, BA1 and BA2 are ―Don‘t Care‖. The PRE/PREALL command may not be given unless the tRAS requirement is
met for the selected bank (PRE), or for all banks within one rank (PREALL).
6.18.1 Precharge Command
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1-Gbit GDDR3 Graphics SDRAM
6.18.2 BA2, BA1 and BA0 precharge bank selection within one rank
A8 / AP
BA2
BA1
BA0
Precharged bank(s)
0
0
0
0
Bank 0 only
0
0
0
1
Bank 1 only
0
0
1
0
Bank 2 only
0
0
1
1
Bank 3 only
0
1
0
0
Bank 4 only
0
1
0
1
Bank 5 only
0
1
1
0
Bank 6 only
0
1
1
1
Bank 7 only
1
X
X
X
All banks within one rank
6.18.3 Precharge Timing
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1-Gbit GDDR3 Graphics SDRAM
6.19 Auto Refresh Command (AREF)
AREF is used to do a refresh cycle on one row in each bank. The addresses are generated by an internal refresh controller; external
address pins are ―DON‘T CARE‖. All banks within the ranks must be idle before the AREF command can be applied. The delay
between the AREF command and the next ACT or subsequent AREF must be at least tRFC(min). The refresh period starts when the
AREF command is entered and ends tRFC later at which time all banks will be in the idle state.
Within a period of tREF the whole memory has to be refreshed. The average periodic interval time from AREF to AREF is then tREFI.
To improve efficiency bursts of AREF commands can be used. Such bursts may consist of maximum 8 AREF commands. tRFC(min)
is the minimum required time between two AREF commands inside of one AREF burst. According to the number of AREF commands
in one burst the average required time from one AREF burst to the next can be increased. Example: If the AREF bursts consists of
8 AREF commands, the average time from one AREF burst to the next is 8 * tREFI.
The AREF command generates an update of the OCD output impedance and of the addresses, commands and DQ terminations.
The timing parameter tKO .
AREF affects one rank, only. Therefore, accesses to the other rank in the 2-CS-mode are allowed after tKO has expired.
6.19.1 Auto Refresh Command
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1-Gbit GDDR3 Graphics SDRAM
6.19.2 Auto Refresh Cycle
6.20 Self-Refresh
6.20.1 Self-Refresh Entry (SREFEN)
The Self-Refresh mode can be used to retain data in the GDDR3 Graphics RAM even if the rest of the system is powered down.
When in the Self-Refresh mode, the GDDR3 Graphics RAM retains data without external clocking. The Self-Refresh command is
initiated like an Auto-Refresh command except CKE is disabled (LOW). Self Refresh Entry is only possible if all banks are
precharged and tRP is met. The GDDR3 Graphics RAM has a build-in timer to accommodate Self-Refresh operation. The SelfRefresh command is defined by having CS#, RAS#, CAS# and CKE held low with WE# high at the rising edge of the clock. Once
the command is registered, CKE must be held LOW to keep the device in Self- Refresh mode. When the GDDR3 Graphics RAM has
entered the Self-Refresh mode, all external control signals, except CKE are disabled. For power saving, the DLL and the clock are
internally disable; and the address and command terminators are turned off. But the Data terminators remain on. The user may halt
the external clock while the device is in Self-Refresh mode the next clock after Self-Refresh entry, however the clock must be
restarted before the device can exit Self-Refresh operation.
In 2-CS-mode, SR may only be entered for both ranks in parallel. Therefore CS0# and CS1# will have to be set to Low Level.
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1-Gbit GDDR3 Graphics SDRAM
6.20.1.1 Self-Refresh Entry Command
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1-Gbit GDDR3 Graphics SDRAM
6.20.1.2 Self Refresh Entry
6.21 Self-Refresh Exit (SREFEX)
To exit the Self Refresh Mode, a stable external clock is needed before setting CKE high asynchronously. Once the Self-Refresh
Exit command is registered, a delay equal or longer than tXSRD must be satisfied before a read command can be applied. During
this time, the DLL is automatically enabled, reset and calibrated.
CKE must remain HIGH for the entire Self-Refresh exit period and commands must be gated off with CS# held HIGH. Alternately,
NOP commands may be registered on each positive clock edge during the Self Refresh exit interval.
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1-Gbit GDDR3 Graphics SDRAM
6.21.1 Self Refresh Exit Command
6.21.2 Self Refresh Exit
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1-Gbit GDDR3 Graphics SDRAM
6.22 Power-Down
The GDDR3 requires CKE to be active at all times an access is in progress: From the issuing of a READ or WRITE command until
completion of the burst. For READs, a burst completion is defined after the rising edge of the Read Postamble. For Writes, a burst
completion is defined one clock after the rising edge of the Write Postamble.
For Read with Autoprecharge and Write with Autoprecharge, the internal Autoprecharge must be completed before entering PowerDown.
Power-Down is entered when CKE is registered LOW. (No access can be in progress. "Access" means as well READ or WRITE to a
second memory sharing the data bus in a dual rank system.) If Power-Down occurs when all banks are idle, this mode is referred to
as Precharge Power-Down; if Power- Down occurs when there is a row active in any bank, this mode is referred to as Active PowerDown. Entering power- down deactivates the input and output buffers, excluding CLK, CLK# and CKE. For maximum power saving,
the user has the option of disabling the DLL prior to entering power- down. In that case the DLL must be enabled and reset after
exiting power-down, and 1000 cycles must occur before a READ command can be issued.
In Power-Down mode, CKE low and a stable clock signal must be maintained at the inputs of the GDDR3 Graphics RAM, all the
other input signals are ―Don‘t Care‖. Power down duration is limited by the refresh requirements of the device.
The Power-Down state is synchronously exited when CKE is registered HIGH (along with a NOP or DESEL command). A valid
executable command may be applied tXPN later.
6.22.1 Power Down Command
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1-Gbit GDDR3 Graphics SDRAM
6.22.2 Power-Down Mode
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7 ELECTRICAL CHARACTERISTICS
7.1 Absolute Maximum Ratings and Operation Conditions
7.1.1 Absolute Maximum Rating
Rating
Parameter
Symbol
Unit
Min.
Max.
Power Supply Voltage
VDD
-0.5
2.5
V
Power Supply Voltage for Output Buffer
-0.5
2.5
V
Input Voltage
VDDQ
VIN
-0.5
2.5
V
Output Voltage
VOUT
-0.5
2.5
V
Storage Temperature
TSTG
TJ
-55
+150
°C
—
+125
°C
Tcase
0
+70
°C
IOUT
—
50
mA
Junction Temperature
Case Temperature
Short Circuit Output Current
Attention: Stresses above the max. Values listed here may cause permanent damage to the device. Exposure to absolute maximum
rating conditions for extended periods may affect device reliability. Maximum ratings are absolute ratings; exceeding only
one of these values may cause irreversible damage to the integrated circuit.
7.2 DC Operation Conditions
7.2.1 Recommended Power & DC Operation Conditions
7.2.1.1 Power & DC Operation Conditions (0 °C ≤ Tc ≤ 70 °C)
Limit Values
Parameter
Symbol
Unit
Note
1.9
V
1,2,3
—
0.71*VDDQ
V
4
—
—
0.8
V
3
IIL
–5.0
—
+5.0
μΑ
5
CLK Input leakage current
IILC
–5.0
—
+5.0
μΑ
Output leakage current
IOL
–5.0
—
+5.0
μΑ
Min.
Typ.
Max.
VDD / VDDQ
1.7
1.8
Reference Voltage
VREF
0.69*VDDQ
Output Low Voltage
VOL(DC)
Input leakage current
Power Supply Voltage
5
Notes:
1. Under all conditions VDDQ must be less than or equal to VDD.
2. VDDQ tracks with VDD. AC parameters are measured with VDD and VDDQ tied together.
3. for 1.8 V VDD/VDDQ power supply.
4. VREF is expected to equal 70% of VDDQ for the transmitting device and to track variations in the DC level of the same. Peak-to-peak noise on VREF
may not exceed ±2% VREF (DC). Thus, from 70% of VDDQ,
VREF
is allowed ± 19mV for DC error and an additional ± 27mV for AC noise.
5. IIL and IOL are measured with ODT disabled.
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1-Gbit GDDR3 Graphics SDRAM
7.3 DC & AC Logic Input Levels
7.3.1 DC & AC Logic Input Levels (0 °C ≤ Tc ≤ 70 °C)
Limit Values
Parameter
Symbol
Min.
Max.
Unit
Note
Input logic high voltage, DC
VIH(DC)
VREF + 0.15
—
V
1,2
Input logic low voltage, DC
VIL(DC)
—
VREF -0.15
V
1,2
Input logic high voltage, AC
VIH(AC)
VREF + 0.25
—
V
1,3,4
Input logic low voltage, AC
VIL(AC)
VIHR(DC)
VILR(DC)
VIHMF(DC)
VILMF(DC)
—
V
1,3,4
VDD
VREF - 0.25
VDDQ + 0.3
0.35 × VDDQ
VDD + 0.3
–0.3
0
V
Input logic high, DC, RESET pin
Input logic low, DC, RESET pin
Input Logic High, DC, MF pin
Input Logic Low, DC, MF pin
0.65 × VDDQ
-0.3
V
V
V
5
Notes:
1. for 1.8 V VDD/VDDQ power supply.
2. The DC values define where the input slew rate requirements are imposed, and the input signal must not violate these levels in order to maintain a
valid level.
3. Input slew rate = 3 V/ns. If the input slew rate is less than 3 V/ns, input timing may be compromised. All slew rates are measured between
and VIH(AC).
VIL(AC)
4. VIH overshoot: VIH(max) = VDDQ+0.5V for a pulse width ≤ 500ps and the pulse width cannot be greater than 1/3 of the cycle rate. VIL undershoot:
VIL(min) = 0 V for a pulse width ≤ 500ps and the pulse width cannot be greater than 1/3 of the cycle rate.
5. The MF pin must be hard-wired on board to either VDD or VSS.
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1-Gbit GDDR3 Graphics SDRAM
7.4 Differential Clock DC and AC Levels
7.4.1 Differential Clock DC and AC Input conditions (0 °C ≤ Tc ≤ 70°C)
Limit Values
Parameter
Symbol
Min.
Max.
Unit
Note
Clock Input Mid-Point Voltage, CLK and CLK#
VMP(DC)
0.7 × VDDQ – 0.10
0.7 × VDDQ + 0.10
V
1
Clock Input Voltage Level, CLK and CLK#
VIN(DC)
0.42
VDDQ + 0.3
V
1,2
Clock DC Input Differential Voltage, CLK and CLK#
VID(DC)
0.3
VDDQ
V
1
Clock AC Input Differential Voltage, CLK and CLK#
VID(AC)
0.5
VDDQ + 0.5
V
1,2,3
AC Differential Crossing Point Input Voltage
VIX(AC)
0.7 × VDDQ – 0.15
0.7 × VDDQ + 0.15
V
1,2,4
Notes:
1. All voltages referenced to VSS.
2. for 1.8 V VDD/VDDQ power supply.
3. VID is the magnitude of the difference between the input level on CLK and the input level on CLK#.
4. The value of VIX is expected to equal 0.7 × VDDQ of the transmitting device and must track variations in the DC level of the same.
7.5 Output Test Conditions
VDDQ
60 ohm
DQ
DQS
Test point
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1-Gbit GDDR3 Graphics SDRAM
7.6 Pin Capacitances
7.6.1 Pin Capacitances (VDDQ = 1.8 V, TA = 25°C, f = 1 MHz)
Parameter
Input capacitance:
A0-A11,A12, , BA0-2, CKE, CS#, CAS#, RAS#, WE#,
CKE, RES,CLK,CLK#
Symbol
Min.
Max.
Unit
CI,CCK
1.0
2.5
pF
CIO
2.0
3.0
pF
Input capacitance:
DQ0-DQ31, RDQS0-RDQS3, WDQS0-WDQS3, DM0-DM3
Note
7.7 Driver current characteristics
7.7.1 Driver IV characteristics at 40 Ohms
Figure represents the driver Pull-Down and Pull-Up IV characteristics under process, voltage and temperature best and worst
case conditions. The actual Driver Pull-Down and Pull-Up current must lie between these two bounding curves. The value of the
external ZQ resistor is 240 Ω, setting the nominal driver output impedance to 40 Ω.
7.7.1.1 40 Ohm Driver Pull-Down and Pull-up Characteristics
Pull-Up Characterstics
0.0
50
45
40
35
30
25
20
15
10
5
0
0.5
1.0
1.5
2.0
0
-5
IOUT (mA)
IOUT (mA)
Pull-Down Characterstics
0.0
0.5
1.0
1.5
2.0
-10
-15
-20
-25
-30
-35
-40
-45
-50
VDDQ - VOUT (V)
VOUT (V)
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1-Gbit GDDR3 Graphics SDRAM
Table lists the numerical values of the minimum and maximum allowed values of the output driver Pull-Down and Pull-Up IV
characteristics.
7.7.1.2 Programmed Driver IV Characteristics at 40 Ohm
Pull-Down Current (mA)
Pull-Up Current (mA)
Voltage (V)
Minimum
Maximum
Minimum
Maximum
0.1
2.32
3.04
-2.44
-3.27
0.2
4.56
5.98
-4.79
-6.42
0.3
6.69
8.82
-7.03
-9.45
0.4
8.74
11.56
-9.18
-12.37
0.5
10.70
14.19
-11.23
-15.17
0.6
12.56
16.72
-13.17
-17.83
0.7
14.34
19.14
-15.01
-20.37
0.8
16.01
21.44
-16.74
-22.78
0.9
17.61
23.61
-18.37
-25.04
1.0
19.11
26.10
-19.90
-27.17
1.1
20.53
28.45
.21.34
-29.17
1.2
21.92
30.45
-22.72
-31.25
1.3
23.29
32.73
-24.07
-33.00
1.4
24.65
34.95
-25.40
-35.00
1.5
26.00
37.10
-26.73
-37.00
1.6
27.35
39.15
-28.06
-39.14
1.7
28.70
41.01
-29.37
-41.25
1.8
30.08
42.53
-30.66
-43.29
1.9
—
43.71
—
-45.23
2.0
—
44.89
—
-47.07
7.8 Termination current characteristics
7.8.1 Termination IV Characteristic at 60 Ohms
Figure represents the DQ termination Pull-Up IV characteristic under process, voltage and temperature best and worst case
conditions. The actual DQ termination Pull-Up current must lie between these two bounding curves. The value of the external ZQ
resistor is 240 Ω, setting the nominal DQ termination impedance to 60 Ω. (Extended Mode Register programmed to ZQ/4).
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Publication Release Date : April 12, 2013
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W641GG2KB
1-Gbit GDDR3 Graphics SDRAM
7.8.1.1 60 Ohm Active Termination Characteristic
60 Ohm Termination Characteristic
0.0
0.5
1.0
1.5
2.0
0
-5
IOUT (mA)
-10
-15
-20
-25
-30
-35
VDDQ - VOUT (V)
Table lists the numerical values of the minimum and maximum allowed values of the output driver termination IV characteristic.
7.8.1.2 Programmed Terminator Characteristics at 60 Ohm
Terminator Pull-Up Current (mA)
Terminator Pull-Up Current (mA)
Voltage (V)
Voltage (V)
Minimum
Maximum
Minimum
Maximum
0.1
-1.63
-2.18
1.1
-14.23
-19.45
0.2
-3.19
-4.28
1.2
-15.14
-20.83
0.3
0.4
-4.69
-6.30
1.3
-16.04
-22.00
-6.12
-8.25
1.4
-16.94
-23.33
0.5
-7.49
-10.11
1.5
-17.82
-24.67
0.6
-8.78
-11.89
1.6
-18.70
-26.09
0.7
-10.01
-13.58
1.7
-19.58
-27.50
0.8
-11.16
-15.19
1.8
-20.44
-28.86
0.9
-12.25
-16.69
1.9
—
-30.15
1.0
-13.27
-18.11
2.0
—
-31.38
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Publication Release Date : April 12, 2013
Revision : A01-001
W641GG2KB
1-Gbit GDDR3 Graphics SDRAM
7.8.2 Termination IV Characteristic at 120 Ohms
Figure represents the DQ or ADD/CMD termination Pull-Up IV characteristic under process, voltage and temperature best and worst
case conditions. The actual termination Pull-Up current must lie between these two bounding curves. The value of the external ZQ
resistor is 240 Ω, setting the nominal termination impedance to 120 Ω. (Extended Mode Register programmed to ZQ/2 for DQ
terminations or CKE = 0 at the RES transition during Power-Up for ADD/CMD terminations).
7.8.2.1 120 Ohm Active Termination Characteristic
120 Ohm Termination Characteristic
0.0
0.5
1.0
1.5
2.0
0
-2
-4
IOUT (mA)
-6
-8
-10
-12
-14
-16
VDDQ - VOUT (V)
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Publication Release Date : April 12, 2013
Revision : A01-001
W641GG2KB
1-Gbit GDDR3 Graphics SDRAM
Table lists the numerical values of the minimum and maximum allowed values of the termination IV characteristic.
7.8.2.2 Programmed Terminator Characteristics of 120 Ohm
Terminator Pull-Up Current (mA)
Terminator Pull-Up Current (mA)
Voltage (V)
Voltage (V)
Minimum
Maximum
Minimum
Maximum
0.1
-0.81
-1.09
1.1
-7.11
-9.72
0.2
-1.60
0.3
-2.34
-2.14
1.2
-7.57
-10.42
-3.15
1.3
-8.02
-11.00
0.4
0.5
-3.06
-4.12
1.4
-8.47
-11.67
-3.74
-5.06
1.5
-8.91
-12.33
0.6
-4.39
-5.94
1.6
-9.35
-13.05
0.7
-5.00
-6.79
1.7
-9.79
-13.75
0.8
-5.58
-7.59
1.8
-10.22
-14.43
0.9
-6.12
-8.35
1.9
—
-15.08
1.0
-6.63
-9.06
2.0
—
-15.69
7.8.3 Termination IV Characteristic at 240 Ohms
Figure represents the ADD/CMD termination Pull-Up IV characteristic under process, voltage and temperature best and worst
case conditions. The actual ADD/CMD termination Pull-Up current must lie between these two bounding curves. The value of the
external ZQ resistor is 240 Ω, setting the nominal termination impedance to 240 Ω. (CKE = 1at the RES transition during Power-Up
for ADD/CMD terminations).
7.8.3.1 240 Ohm Active Termination Characteristic
240 Ohm Termination Characteristic
0.0
0.5
1.0
1.5
2.0
0
-1.0
-2.0
IOUT (mA)
-3.0
-4.0
-5.0
-6.0
-7.0
-8.0
VDDQ - VOUT (V)
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Publication Release Date : April 12, 2013
Revision : A01-001
W641GG2KB
1-Gbit GDDR3 Graphics SDRAM
Table lists the numerical values of the minimum and maximum allowed values of the ADD/CMD termination IV characteristic.
7.8.3.2 Programmed Terminator Characteristics at 240 Ohm
Terminator Pull-Up Current (mA)
Terminator Pull-Up Current (mA)
Voltage (V)
Voltage (V)
Minimum
Maximum
Minimum
Maximum
0.1
-0.41
-0.55
1.1
-3.56
-4.86
0.2
-0.80
0.3
-1.17
-1.07
1.2
-3.79
-5.21
-1.58
1.3
-4.01
-5.50
0.4
-1.53
-2.06
1.4
-4.23
-5.83
0.5
-1.87
-2.53
1.5
-4.46
-6.17
0.6
-2.20
-2.97
1.6
-4.68
-6.52
0.7
-2.50
-3.40
1.7
-4.90
-6.88
0.8
-2.79
-3.80
1.8
-5.11
-7.21
0.9
-3.06
-4.17
1.9
—
-7.54
1.0
-3.32
-4.53
2.0
—
-7.85
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Revision : A01-001
W641GG2KB
1-Gbit GDDR3 Graphics SDRAM
7.9 Operating Current Ratings
TYP.
SYM.
IDD0
IDD1
IDD2P
IDD2N
IDD3N
IDD4R
IDD4W
IDD5D
IDD6
PARAMETER/CONDITION
UNIT
One Bank Activate Precharge Current: tCK = tCK(min); tRC =
tRC(min); CKE = HIGH; data bus inputs are
SWITCHING; address and command inputs are SWITCHING; /CS is
HIGH between valid commands
One Bank Activate Read Precharge Current: tCK= tCK(min); tRC =
tRC(min); CKE = HIGH; 1 bank activated;
single read burst with data bus SWITCHING, address and command
inputs are SWITCHING; /CS is High between
valid commands; Iout = 0mA
Precharge Power-Down Current: tCK = tCK(min); all banks idle; CKE =
LOW; all other inputs are HIGH
Precharge Standby Current in Non Power-down mode.
Active Standby Current: tCK = tCK(min); 1 bank active; CKE = HIGH;
all other inputs are HIGH
Burst Read Current: tCK = tCK(min); CKE = HIGH; continuous read
burst across banks with data bus SWITCHING;
address and command inputs are SWITCHING; Iout = 0 mA
Write Burst Current: tCK = tCK(min); CKE = HIGH; continuous write
burst across banks with data bus SWITCHING;
address and command inputs are SWITCHING
Auto Refresh current at tREFI.
Self Refresh Current: CKE = LOW; all other inputs are HIGH
650
700
800
320
335
360
mA
330
345
380
mA
140
150
160
mA
190
200
220
mA
285
300
330
mA
495
520
550
mA
495
520
550
mA
380
400
435
mA
40
40
40
NOTES
2
2
mA
Notes:
1. IDD specifications are tested after the device is properly initialized.
2. Measured with open outputs and ODT off.
3. LOW is defined as inputs stable at VIL(max).
HIGH is defined as inputs stable at VIH(min).
SWITCHING is defined as inputs changing between HIGH and LOW every clock cycle for address and command inputs, and inputs changing with
50% of each data transfer for DQ.
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Publication Release Date : April 12, 2013
Revision : A01-001
W641GG2KB
1-Gbit GDDR3 Graphics SDRAM
7.10 AC Timings
Limit Values
Parameter
CAS latency
Symbol
650
min
Unit
700
max
800
min
max
min
max
MHz
Note
Clock and Clock Enable
System frequency
CL =11
fCK11
—
—
450
700
—
—
MHz
1
CL =10
fCK10
—
—
450
700
450
800
MHz
1
CL = 9
fCK9
450
650
—
—
—
—
MHz
1
0.06
Clock high level width
tJIT(cc)
tCH
0.45
—
0.45
—
0.45
—
tCK
tCK
Clock low level width
tCL
0.45
—
0.45
—
0.45
—
tCK
2,3,4
Minimum clock half period
tHP
0.45
—
0.45
—
0.45
—
tCK
3
Clock cycle to cycle period jitter
0.06
0.06
2,3
2,3,4
Command and Address Setup and Hold Timing
Address/Command input setup time
tIS
0.35
—
0.35
—
0.35
—
ns
5,6
Address/Command input hold time
tIH
0.35
—
0.35
—
0.35
—
ns
5,6
tIPW
0.7
—
0.7
—
0.7
—
tCK
4
tCK
tCK
7,8
Address/Command input pulse width
Mode Register Set Timing
tMRD
tMRDR
Mode Register Set cycle time
Mode Register Set to READ timing
6
—
6
—
6
—
12
—
12
—
12
—
—
—
tCK
tCK
7
Row Timing
Row Cycle Time
Row Active Time
tRC
tRAS
37
—
37
—
27
—
27
—
37
27
tRRD
7
—
7
—
8
—
tCK
tRRD_RR
tRP
1
—
1
—
—
12
—
12
—
1
14
—
tCK
tCK
Row to Column Delay Time for Reads
tRCDRD
11
—
11
—
13
—
tCK
Row to Column Delay Time for Writes
tRCDWR
tFAW
9
—
9
—
—
35
—
35
—
9
35
tCK
tCK
ACT(a) to ACT(b) Command period
ACT(a) to ACT(b) Command period (different rank)
Row Precharge Time
Four Active Windows within Rank
—
9
12
Column Timing
CAS(a) to CAS(b) Command period
Internal write to Read Command Delay
Write to Read Command Delay (different rank)
Write to Write Command Delay (different rank)
Read to Write command delay
Read to Read Command Delay (different rank)
tCCD
tWTR
BL/2
—
BL/2
—
BL/2
—
6
—
6
—
6
—
tWTR_RR
tWTW_RR
tRTW
tRTR_RR
1
—
1
—
1
—
2
—
2
—
2
—
tRTW(min) = CL + BL/2+ 2 - WL
—
2
—
2
2
—
tCK
tCK
tCK
tCK
tCK
tCK
10
11
10
10
14
10
Write Cycle Timing Parameters for Data and Data Strobe
Write command to first WDQS latching transition
tDQSS
WL–0.25
WL+0.25 WL–0.25
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WL+0.25 WL–0.25
WL+0.25
tCK
Publication Release Date : April 12, 2013
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W641GG2KB
1-Gbit GDDR3 Graphics SDRAM
Limit Values
Parameter
CAS latency
Symbol
650
Unit
700
800
min
max
min
max
min
max
MHz
Note
Data-in and Data Mask to WDQS Setup Time
tDS
0.18
—
0.18
—
0.18
—
ns
5,13
Data-in and Data Mask to WDQS Hold Time
tDH
0.18
—
0.18
—
0.18
—
ns
5,13
Data-in and DM input pulse width (each input)
tDIPW
0.40
—
0.40
—
0.40
—
tCK
DQS input low pulse width
0.40
—
0.40
—
0.40
—
DQS input high pulse width
tDQSL
tDQSH
0.40
—
0.40
—
0.40
—
tCK
tCK
DQS Write Preamble Time
tWPRE
0.75
1.25
0.75
1.25
0.75
1.25
tCK
DQS Write Postamble Time
tWPST
tWR
0.75
1.25
0.75
1.25
0.75
1.25
10
—
10
—
10
—
tCK
tCK
Write Recovery Time
11
Read Cycle Timing Parameters for Data and Data Strobe
tAC
tRPRE
–0.25
0.25
–0.25
0.25
–0.25
0.25
ns
Read Preamble
0.75
1.25
0.75
1.25
0.75
1.25
tCK
Read Postamble
tRPST
0.75
1.25
0.75
1.25
0.75
1.25
tCK
tHZ
tLZ
tACmin
tACmin
tACmax
tACmax
tACmin
tACmin
tACmax
tACmax
tACmin
tACmin
tACmax
tACmax
ns
DQS edge to Clock edge skew
tDQSCK
–0.25
0.25
–0.25
0.25
–0.25
0.25
ns
DQS edge to output data edge skew
tDQSQ
tQHS
—
0.16
—
0.16
—
0.16
ns
—
0.16
—
0.16
—
0.16
ns
Data Access Time from Clock
Data-out high impedance time from CLK
Data-out low impedance time from CLK
Data hold skew factor
Data output hold time from DQS
tHP–tQHS
tQH
4
ns
15
ns
Refresh/Power Down Timing
Refresh Period (8192 cycles)
tREF
Average periodic Auto Refresh interval
tREFI
Delay from AREF to next ACT/ AREF
Self Refresh Exit time
tRFC
tXSC
Power Down Exit time
tXPN
—
32
—
32
—
59
—
59
—
59
—
ns
1000
6
—
1000
—
1000
—
tCK
—
6
—
6
—
tCK
3.9
3.9
32
3.9
ms
µs
Other Timing Parameters
RES to CKE setup timing
tATS
10
—
10
—
10
—
ns
RES to CKE hold timing
tATH
tKO
tRIDon
tRIDoff
10
—
10
—
10
—
ns
10
—
10
—
10
—
ns
—
20
—
20
—
20
ns
—
20
—
20
—
20
ns
Termination update Keep Out timing
Rev. ID EMRS to DQ on timing
REV. ID EMRS to DQ off timing
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Publication Release Date : April 12, 2013
Revision : A01-001
W641GG2KB
1-Gbit GDDR3 Graphics SDRAM
1. fCK(min), fCK(max) for DLL on mode.
2. CLK and CLK# input slew rate must be greater than 3 V/ns.
3. tHP is the lesser of tCL minimum and tCH minimum actually applied to the device CLK,CLK# inputs.
4. Timing is calculated for a clock frequency of 700 MHz.
5. The input reference level for signals other than CLK and CLK# is VREF.
6. Command/Address input slew rate = 3 V/ns. If the slew rate is less than 3 V/ns, timing is no longer referenced to the midpoint but to the
maximum and ViH(AC) minimum points .
Vil(AC)
7. This value of tMRD applies only to the case where the "DLL reset"‘ bit is not activated.
8. tMRD is defined from MRS to any other command then READ.
9. tRAS,max is 8*tREFi.
10. tCCD is either for gapless consecutive reads or gapless consecutive writes.
11. WTR and tWR start at the first rising edge of CLK after the last valid (falling) WDQS edge of the slowest WDQS signal.
12. This parameter is defined for commands issued to rank m following rank n where m ≠ n. For all other type of access, standard
timing parameters do apply.
13. DQ and DM input slew rates must not deviate from WDQS by more than 10 percent. If the DQ/DM/WDQS slew rate is less than 3
V/ns, timing is no longer referenced to the midpoint but to the Vil(AC) maximum and ViH(AC) minimum points.
14. Please round up tRTW to the next integer of tCK.
15. This parameter is defined per byte.
16. Input slew rate = 1.21V/ns. If tIS/tIH higher than 700ps.
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Publication Release Date : April 12, 2013
Revision : A01-001
W641GG2KB
1-Gbit GDDR3 Graphics SDRAM
8. PACKAGE SPECIFICATION
Package Outline WBGA 136 (10x14 mm2, ball pitch: 0.8mm, Ø =0.45mm)
Note:
1. Ball land:0.5mm, Ball opening:0.4mm, PCB Ball land suggested
<= 0.4mm
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Publication Release Date : April 12, 2013
Revision : A01-001
W641GG2KB
1-Gbit GDDR3 Graphics SDRAM
9. ORDERING INFORMATION
PART NUMBER
DESCRIPTION
W641GG2KB-14
1Gb GDDR3 SDRAM 700MHZ.
W641GG2KB-12
1Gb GDDR3 SDRAM 800MHZ.
Note: For pad information of KGD, please contact sales representative.
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Publication Release Date : April 12, 2013
Revision : A01-001
W641GG2KB
1-Gbit GDDR3 Graphics SDRAM
10. REVISION HISTORY
VERSION
DATE
PAGE
A01-001
04/12/2013
All
DESCRIPTION
Product datasheet for customer.
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Publication Release Date : April 12, 2013
Revision : A01-001
W641GG2KB
1-Gbit GDDR3 Graphics SDRAM
Important Notice
Winbond products are not designed, intended, authorized or warranted for use as components in systems or
equipment intended for surgical implantation, atomic energy control instruments, airplane or spaceship
instruments, transportation instruments, traffic signal instruments, combustion control instruments, or for
other applications intended to support or sustain life. Furthermore, Winbond products are not intended for
applications wherein failure of Winbond products could result or lead to a situation wherein personal injury,
death or severe property or environmental damage could occur.
Winbond customers using or selling these products for use in such applications do so at their own risk and
agree to fully indemnify Winbond for any damages resulting from such improper use or sales.
------------------------------------------------------------------------------------------------------------------------------------------------Please note that all data and specifications are subject to change without notice.
All the trademarks of products and companies mentioned in the datasheet belong to their respective owners.
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Publication Release Date : April 12, 2013
Revision : A01-001