HYS72D128321HBR-6-C,PDF,HYS72D128321HBR-6-C PDF资料,Datasheet,下载HYS72D128321HBR-6-C技术资料

Aug. 2006

HYS72D64301HBR–[5/6]–C

HYS72D128x00HBR–[5/6]–C

HYS72D128321HBR–[5/6]–C

HYS72D256x20HBR–[5/6]–C

184-Pin Registered Double-Data-Rate SDRAM Module

RDIMM

DDR SDRAM

RoHS Compliant

Internet Data Sheet

Rev. 1.21

Internet Data Sheet

HYS72D[64/128/256]xxxHBR–[5/6]–C

Registered Double-Data-Rate SDRAM Module

HYS72D64301HBR–[5/6]–C, HYS72D128x00HBR–[5/6]–C, HYS72D128321HBR–[5/6]–C, HYS72D256x20HBR–[5/6]–C

Revision History: 2006-08, Rev. 1.21

Page

All

Subjects (major changes since last revision)

Qimonda update

All

Adapted Internet Edition

Previous Revision: 2006-03, Rev. 1.2

Page

Subjects (major changes since last revision)

Added product types to PC2700R

8

Previous Revision: 2005-12, Rev. 1.1

We Listen to Your Comments

Any information within this document that you feel is wrong, unclear or missing at all?

Your feedback will help us to continuously improve the quality of this document.

Please send your proposal (including a reference to this document) to:

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qag_techdoc_rev400 / 3.2 QAG / 2006-08-01

03292006-6N25-8R3I

2

Internet Data Sheet

HYS72D[64/128/256]xxxHBR–[5/6]–C

Registered Double-Data-Rate SDRAM Module

1

Overview

1.1

Features

•

184-Pin Registered 8-Byte Dual-In-Line DDR SDRAM Module for PC, Workstation and Server main memory applications

One rank 64M ×72, 128M ×72 organization , and two ranks 256M ×72 organization

Standard Double Data Rate Synchronous DRAMs (DDR SDRAM) with a single + 2.5 V (± 0.2 V) power supply and +2.6

(± 0.1 V) power supply for DDR400

•

Built with DDR SDRAMs in FBGA 60 package

Programmable CAS Latency, Burst Length, and Wrap Sequence (Sequential & Interleave)

Auto Refresh (CBR) and Self Refresh

RAS-lockout supported t_RAP= t_RCD

All inputs and outputs SSTL_2 compatible

Re-drive for all input signals using register and PLL devices.

Serial Presence Detect with E²PROM

Low Profile Modules form factor: 133.35 mm × 28.58 mm (1.1”) × 4.00 mm and 133.35 mm × 30.48 mm (1.2”)

Standard reference card layout Raw Card A, B, C and F

Gold plated contacts

RoHS Compliant Product¹⁾

TABLE 1

Performance

Part Number Speed Code

–5

–6

Unit

Speed Grade

Component

Module

@CL3

DDR400B

PC3200–3033

200

DDR333B

PC2700–2533

166

—

max. Clock Frequency

f_CK3

MHz

@CL2.5

@CL2

f_CK2.5

f_CK2

166

133

1) RoHS Compliant Product: Restriction of the use of certain hazardous substances (RoHS) in electrical and electronic equipment as defined

in the directive 2002/95/EC issued by the European Parliament and of the Council of 27 January 2003. These substances include mercury,

lead, cadmium, hexavalent chromium, polybrominated biphenyls and polybrominated biphenyl ethers.

Rev. 1.21, 2006-08

3

03292006-6N25-8R3I

Internet Data Sheet

HYS72D[64/128/256]xxxHBR–[5/6]–C

Registered Double-Data-Rate SDRAM Module

1.2

Description

The HYS72D[64/128/256]xxxHBR–[5/6]–C are low-profile

versions of the standard Registered DIMM modules with 1.1-

inch (28.58 mm) and 1.2-inch (30.40 mm) height for Server

Applications. The low-profile DIMM versions are available as

64M ×72, 128M ×72 (1 GB), and 256M ×72 (2 GB). The

memory array is designed with Double-Data-Rate

Synchronous DRAMs for ECC applications. All control and

address signals are re-driven on the DIMM using register

devices and a PLL for the clock distribution. This reduces

capacitive loading to the system bus, but adds one cycle to

the SDRAM timing. A variety of decoupling capacitors are

mounted on the PC board. The DIMMs feature serial

presence detect based on a serial E²PROM device using the

2-pin I²C protocol. The first 128 bytes contain factory

programmed configuration data and the second 128 bytes

are made available to the customer.

TABLE 2

Ordering Information

Product Type¹⁾

Compliance Code²⁾

Description

SDRAM Technology

PC3200 (CL=3)

HYS72D64301HBR–5–C

HYS72D128300HBR–5–C

HYS72D128321HBR–5–C

HYS72D256320HBR–5–C

PC2700 (CL=2.5)

PC3200R–30331–A0

PC3200R–30331–C0

PC3200R–30331–B0

PC3200R–30331–F0

one rank 512 MByte Reg. ECC DIMM

one rank 1 GByte Reg. ECC DIMM

two ranks 1 GByte Reg. ECC DIMM

two ranks 2 GByte Reg. ECC DIMM

512 MBit (×8)

512 MBit (×4)

512 MBit (×8)

512 MBit (×4)

HYS72D64301HBR–6–C

HYS72D128300HBR–6–C

HYS72D128900HBR–6–C

HYS72D128321HBR–6–C

HYS72D256320HBR–6–C

HYS72D256920HBR–6–C

PC2700R–25331–A0

PC2700R–25331–C0

PC2700R–25331–B0

PC2700R–25331–F0

one rank 512 MByte Reg. ECC DIMM

one rank 1 GByte Reg. ECC DIMM

two ranks 1 GByte Reg. ECC DIMM

two ranks 2 GByte Reg. ECC DIMM

512 MBit (×8)

512 MBit (×4)

512 MBit (×8)

512 MBit (×4)

1) All product types end with a place code designating the silicon-die revision. Reference information available on request. Example:

HYS72D256320HBR–5–C, indicating Rev.C die are used for SDRAM components.

2) The Compliance Code is printed on the module labels and describes the speed sort (for example “PC2700R”), the latencies (for example

“25331” means CAS latency of 2.5 clocks, Row-Column-Delay (RCD) latency of 3 clocks and Row Precharge latency of 3 clocks), SPD

code definition version 1, and the Raw Card used for this module.

TABLE 3

Address Format

Density Organization

Memory

Ranks

SDRAMs

# of

SDRAMs

# of row/bank/

column bits

Refresh

Period Interval

512 MB 64M ×72

1

2

64M ×8

128M ×4

64M ×8

128M ×4

9

13/2/12

13/2/11

13/2/12

8K

64 ms

7.8 ms

1 GB

2 GB

128M ×72

256M ×72

18

36

Rev. 1.21, 2006-08

4

03292006-6N25-8R3I

Internet Data Sheet

HYS72D[64/128/256]xxxHBR–[5/6]–C

Registered Double-Data-Rate SDRAM Module

2

Pin Configuration

The pin configuration of the Registered DDR SDRAM DIMM is listed by function in Table 4 (184 pins). The abbreviations used

in columns Pin and Buffer Type are explained in Table 5 and Table 6 respectively. The pin numbering is depicted in Chapter 1.

Pin Name

#

Type Type

Buffer Function

TABLE 4

Pin Configuration of RDIMM

37

32

A4

A5

I

SSTL

Address Bus 11:0

Pin Name

#

Buffer Function

Type Type

125 A6

29 A7

122 A8

27 A9

Clock Signals

137 CK0

I

SSTL

Clock Signal

138 CK0

Complement Clock

Clock Enable Rank 0

21

CKE0

141 A10

AP

111 CKE1

Clock Enable Rank 1

2-rank module

118 A11

115 A12

NC

SSTL

Note: 1-rank module

Address Signal 12

Control Signals

Note: Module based on

256 Mbit or larger

dies

157 S0

158 S1

I

SSTL

Chip Select of Rank 0

Chip Select of Rank 1

Note: 2-ranks module

Note: 1-rank module

Row Address Strobe

Column Address Strobe

Write Enable

NC

I

–

Note: 128 Mbit based

module

NC

–

167 A13

SSTL

Address Signal 13

154 RAS

I

SSTL

Note: 1 Gbit based

module

65

63

10

CAS

WE

NC

–

Note: Module based on

512 Mbit or smaller

dies

RESET

LV-

CMOS

Register Reset

Address Signals

Data Signals

59

52

48

43

41

BA0

BA1

A0

I

SSTL

Bank Address Bus 1:0

Address Bus 11:0

2

DQ0

DQ1

DQ2

DQ3

DQ4

DQ5

DQ6

DQ7

DQ8

DQ9

DQ10

DQ11

I/O

SSTL

Data Bus 63:0

4

6

A1

8

A2

94

95

98

99

12

13

19

20

130 A3

105 DQ12

Rev. 1.21, 2006-08

5

03292006-6N25-8R3I

Internet Data Sheet

HYS72D[64/128/256]xxxHBR–[5/6]–C

Registered Double-Data-Rate SDRAM Module

Pin Name

#

Type Type

Buffer Function

Pin Name

#

Type Type

Buffer Function

106 DQ13

109 DQ14

110 DQ15

I/O

SSTL

Data Bus 63:0

166 DQ53

170 DQ54

171 DQ55

I/O

I

SSTL

Data Bus 63:0

23

24

28

31

DQ16

DQ17

DQ18

DQ19

83

84

87

88

DQ56

DQ57

DQ58

DQ59

114 DQ20

117 DQ21

121 DQ22

123 DQ23

174 DQ60

175 DQ61

178 DQ62

179 DQ63

33

35

39

40

DQ24

DQ25

DQ26

DQ27

44

45

49

51

CB0

CB1

CB2

CB3

Check Bits 7:0

126 DQ28

127 DQ29

131 DQ30

133 DQ31

134 CB4

135 CB5

142 CB6

144 CB7

53

55

57

60

DQ32

DQ33

DQ34

DQ35

5

DQS0

Data Strobes 8:0

14

25

36

56

67

78

86

47

97

DQS1

DQS2

DQS3

DQS4

DQS5

DQS6

DQS7

DQS8

DM0

146 DQ36

147 DQ37

150 DQ38

151 DQ39

61

64

68

69

DQ40

DQ41

DQ42

DQ43

Data Mask 0

Note: ×8 based module

Data Strobe 9

DQS9

I/O

I

SSTL

Note: ×4 based module

Data Mask 1

153 DQ44

155 DQ45

161 DQ46

162 DQ47

107 DM1

Note: ×8 based module

Data Strobe 10

DQS10 I/O

Note: ×4 based module

Data Mask 2

72

73

79

80

DQ48

DQ49

DQ50

DQ51

119 DM2

I

Note: ×8 based module

Data Strobe 11

DQS11 I/O

Note: ×4 based module

165 DQ52

Rev. 1.21, 2006-08

6

03292006-6N25-8R3I

Internet Data Sheet

HYS72D[64/128/256]xxxHBR–[5/6]–C

Registered Double-Data-Rate SDRAM Module

Pin Name

#

Type Type

Buffer Function

Pin Name

#

Type Type

Buffer Function

129 DM3

I

SSTL

Data Mask 3

15, V_DDQ

22,

30,

54,

62,

PWR

–

I/O Driver Power Supply

Note: ×8 based module

Data Strobe 12

DQS12 I/O

Note: ×4 based module

Data Mask 4

149 DM4

I

77,

96,

Note: ×8 based module

Data Strobe 13

104,

112,

128,

136,

143,

156,

164,

172,

180

DQS13 I/O

Note: ×4 based module

Data Mask 5

159 DM5

I

Note: ×8 based module

Data Strobe 14

DQS14 I/O

Note: ×4 based module

Data Mask 6

169 DM6

I

Note: ×8 based module

Data Strobe 15

7,

V_DD

PWR

–

Power Supply

DQS15 I/O

38,

46,

70,

85,

108,

120,

148,

168

Note: ×4 based module

Data Mask 7

177 DM7

I

Note: ×8 based module

Data Strobe 16

DQS16 I/O

Note: ×4 based module

Data Mask 8

140 DM8

I

3

V_SS

GND

–

Ground Plane

Note: ×8 based module

Data Strobe 17

11

18

26

34

42

50

58

66

74

81

89

93

100

DQS17 I/O

Note: ×4 based module

EEPROM

92

91

SCL

SDA

I

CMOS Serial Bus Clock

OD Serial Bus Data

I/O

181 SA0

182 SA1

183 SA2

I

CMOS Slave Address Select

Bus 2:0

CMOS

Power Supplies

V_REFAI

1

–

I/O Reference Voltage

EEPROM Power Supply

184 V_DDSPDPWR

Rev. 1.21, 2006-08

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03292006-6N25-8R3I

Internet Data Sheet

HYS72D[64/128/256]xxxHBR–[5/6]–C

Registered Double-Data-Rate SDRAM Module

Pin Name

#

Type Type

Buffer Function

TABLE 5

Abbreviations for Pin Type

116 V_SS

124

GND

–

Ground Plane

Abbreviation Description

I

Standard input-only pin. Digital levels.

Output. Digital levels.

132

O

139

I/O

AI

I/O is a bidirectional input/output signal.

Input. Analog levels.

145

152

PWR

GND

NU

NC

Power

160

Ground

176

Not Usable (JEDEC Standard)

Not Connected (JEDEC Standard)

Other Pins

82

V_DDID

NC

O

OD

–

V_DDIdentification

Not connected

9,

NC

16,

TABLE 6

17,

71,

75,

76,

Abbreviations for Buffer Type

Abbreviation Description

90,

SSTL

Serial Stub Terminalted Logic (SSTL2)

101,

102,

103,

113,

163,

173

LV-CMOS

CMOS

OD

Low Voltage CMOS

CMOS Levels

Open Drain. The corresponding pin has 2

operational states, active low and tristate,

and allows multiple devices to share as a

wire-OR.

Rev. 1.21, 2006-08

8

03292006-6N25-8R3I

Internet Data Sheet

HYS72D[64/128/256]xxxHBR–[5/6]–C

Registered Double-Data-Rate SDRAM Module

FIGURE 1

Pin Configuration 184 Pins, Registered

V_SS

Pin 093 -

Pin 094 - DQ04

Pin 095 - DQ05

V

_REF- Pin 001

- Pin 003

DQ00 - Pin 002

DQ01 - Pin 004

DQ02 - Pin 006

DQ03 - Pin 008

RESET - Pin 010

DQ08 - Pin 012

DQS1 - Pin 014

NC - Pin 016

V

SS

V

Pin 096 -

DDQ

DQS0 - Pin 005

Pin 097 - DQ00/DQS9

Pin 099 - DQ07

Pin 101 - NC

Pin 098 - DQ06

V

_DD- Pin 007

V

Pin 100 -

SS

NC - Pin 009

Pin 102 - NC

V

_SS- Pin 011

Pin 103 - NC

V

Pin 104 -

DDQ

DQ09 - Pin 013

Pin 105 - DQ15

Pin 107 - DM1/DQS10

Pin 109 - DQ14

Pin 111 - CKE1/NC

Pin 113 - NC

Pin 106 - DQ13

V

_DDQ- Pin 015

V

Pin 108 -

DD

NC - Pin 017

DQ10 - Pin 019

CKE0 - Pin 021

DQ16 - Pin 023

DQS2 - Pin 025

A9 - Pin 027

V

_SS- Pin 018

Pin 110 - DQ15

V

DQ11 - Pin 020

Pin 112 -

Pin 114 - DQ20

V_SS

DDQ

V

_DDQ- Pin 022

Pin 115 - A12/NC

Pin 117 - DQ21

Pin 119 - DM2/DQS11

Pin 121 - DQ22

Pin 123 - DQ23

Pin 125 - A6

DQ17 - Pin 024

Pin 116 -

Pin 118 - A11

V

_SS- Pin 026

V

DQ18 - Pin 028

Pin 120 -

Pin 122 - A8

DD

A7 - Pin 029

V

_DDQ- Pin 030

DQ19 - Pin 031

DQ24 - Pin 033

DQ25 - Pin 035

A4 - Pin 037

V_SS

A5 - Pin 032

Pin 124 -

V

_SS- Pin 034

Pin 126 - DQ28

Pin 127 - DQ29

Pin 129 - DM3/DQS12

Pin 131 - DQ30

Pin 133 - DQ31

Pin 135 - CB5

V_DDQ

DQS3 - Pin 036

Pin 128 -

Pin 130 - A3

V

_DD- Pin 038

DQ26 - Pin 039

A2 - Pin 041

V

DQ27 - Pin 040

Pin 132 -

Pin 134 - DQ04

V_DDQ

Pin 136 -

SS

V

_SS- Pin 042

A1 - Pin 043

CB00 - Pin 044

CB01 - Pin 045

DQS8 - Pin 047

CB02 - Pin 049

CB03 - Pin 051

Pin 137 - CK0

V

_DD- Pin 046

Pin 138 - CK0

Pin 139 - V_SS

A0 - Pin 048

Pin 140 - DM8/DQS17

Pin 142 - CB06

Pin 144 - CB07

Pin 141 - A10/AP

V

_SS- Pin 050

V

Pin 143 -

DDQ

BA1 - Pin 052

V

-

DQ32 Pin 053

Pin 145

SS

-

Pin 146 DQ36

V

_DDQ- Pin 054

-

DQ33 Pin 055

Pin 147 DQ37

-

Pin 148

V

DD

DQS4

V_SS

- Pin 056

- Pin 058

- Pin 060

-

Pin 149 DM4/DQS13

-

DQ34 Pin 057

-

Pin 150 DQ38

-

Pin 151 DQ39

-

BA0 Pin 059

-

Pin 152 V_SS

DQ35

V

-

Pin 153 DQ44

-

DQ40 Pin 061

-

Pin 154 RAS

_DDQ- Pin 062

-

Pin 155 DQ45

-

WE Pin 063

-

Pin 156 V_DDQ

DQ41

- Pin 064

-

Pin 157 S0

-

CAS Pin 065

-

Pin 158 S1/NC

V

_SS- Pin 066

-

Pin 159 DM5/DQS14

-

DQS5 Pin 067

-

Pin 160

V

SS

DQ42

V_DD

- Pin 068

- Pin 070

- Pin 072

-

Pin 161 DQ46

-

DQ43 Pin 069

-

Pin 162 DQ47

-

Pin 163 NC

-

NC Pin 071

-

Pin 164 V_DDQ

DQ48

V

-

Pin 165 DQ52

-

DQ49 Pin 073

-

Pin 166 DQ53

_SS- Pin 074

-

Pin 167 A13/NC

-

NC Pin 075

-

Pin 168

V

DD

NC

- Pin 076

- Pin 078

- Pin 080

- Pin 082

- Pin 084

- Pin 086

- Pin 088

- Pin 090

- Pin 092

V

-

Pin 169 DM6/DQS15

-

Pin 077

DDQ

-

Pin 170 DQ54

DQS6

-

Pin 171 DQ55

-

DQ50 Pin 079

-

Pin 172

V

DDQ

DQ51

V_DDID

V_SS

-

Pin 173 NC

-

Pin 081

-

Pin 174 DQ60

-

Pin 175 DQ61

-

DQ56 Pin 083

-

Pin 176 V_SS

DQ57

DQS7

DQ59

NC

V_DD

-

Pin 177 DM7/DQS16

-

Pin 085

-

Pin 178 DQ62

-

Pin 179 DQ63

-

DQ58 Pin 087

-

Pin 180

V

DDQ

V

-

Pin 181 SA0

-

Pin 089

SS

-

Pin 182 SA1

-

Pin 183 SA2

-

SDA Pin 091

-

Pin 184

V

DDSPD

SCL

MPPD0020

Rev. 1.21, 2006-08

03292006-6N25-8R3I

9

Internet Data Sheet

HYS72D[64/128/256]xxxHBR–[5/6]–C

Registered Double-Data-Rate SDRAM Module

3

Electrical Characteristics

3.1

Operating Conditions

TABLE 7

Absolute Maximum Ratings

Parameter

Symbol

Values

Unit Note/ Test

Condition

min.

typ. max.

Voltage on I/O pins relative to V_SS

Voltage on inputs relative to V_SS

Voltage on V_DDsupply relative to V_SS

Voltage on V_DDQsupply relative to V_SS

Operating temperature (ambient)

Storage temperature (plastic)

V_IN, V_OUT

V_IN

–0.5

–1

0

–

V

_DDQ+ 0.5

V

–

+3.6

+70

+150

–

V

V_DD

–

V

V_DDQ

T_A

–

V

–

°C

W

mA

T_STG

PD

-55

–

Power dissipation (per SDRAM component)

Short circuit output current

1

I_OUT

–

50

–

Attention: Permanent damage to the device may occur if “Absolute Maximum Ratings” are exceeded. This is a stress

rating only, and functional operation should be restricted to recommended operation conditions. Exposure

to absolute maximum rating conditions for extended periods of time may affect device reliability and

exceeding only one of the values may cause irreversible damage to the integrated circuit.

Rev. 1.21, 2006-08

10

03292006-6N25-8R3I

Internet Data Sheet

HYS72D[64/128/256]xxxHBR–[5/6]–C

Registered Double-Data-Rate SDRAM Module

TABLE 8

Electrical Characteristics and DC Operating Conditions

Parameter

Symbol

Values

Unit Note/Test Condition¹⁾

Min.

Typ.

Max.

Device Supply Voltage

Output Supply Voltage

EEPROM supply voltage

V_DD

2.3

2.5

2.3

2.5

2.3

0

2.5

2.6

2.5

2.6

2.5

2.7

3.6

0

V

f_CK≤ 166 MHz

f

_CK> 166 MHz ²⁾

f_CK≤ 166 MHz ³⁾

V_DD

V_DDQ

V_DDSPD

f_CK> 166 MHz ²⁾³⁾

—

Supply Voltage, I/O Supply V_SS, V_SSQ

Voltage

4)

5)

Input Reference Voltage

V_REF

V_TT

0.49 × V_DDQ0.5 × V_DDQ0.51 × V_DDQ

V

I/O Termination Voltage

(System)

V_REF– 0.04

V_REF+ 0.04

6)

Input High (Logic1) Voltage V_IH(DC)

Input Low (Logic0) Voltage V_IL(DC)

V_REF+ 0.15

–0.3

V_DDQ+ 0.3

V_REF– 0.15

V_DDQ+ 0.3

V

Input Voltage Level, CK and V_IN(DC)

–0.3

CK Inputs

6)7)

8)

Input Differential Voltage,

CK and CK Inputs

V_ID(DC)

0.36

0.71

–2

V_DDQ+ 0.6

V

VI-Matching Pull-up Current VI_Ratio

to Pull-down Current

1.4

2

—

µA

Input Leakage Current

Output Leakage Current

I_I

Any input 0 V ≤ V_IN≤ V_DD; All

other pins not under test = 0 V⁹⁾

I_OZ

–5

5

DQs are disabled; 0 V ≤ V_OUT

V_DDQ

≤

9)

Output High Current, Normal I_OH

Strength Driver

—

–16.2

—

mA V_OUT

=

1.95 V

Output Low Current, Normal I_OL

16.2

mA V_OUT= 0.35 V

Strength Driver

1) 0 °C ≤ T_A≤ 70 °C; V_DDQ= 2.5 V ± 0.2 V, V_DD= +2.5 V ± 0.2 V;

2) DDR400 conditions apply for all clock frequencies above 166 MHz

3) Under all conditions, V_DDQmust be less than or equal to V_DD

4) Peak to peak AC noise on V_REFmay not exceed ± 2% V_REF.DC. V_REFis also expected to track noise variations in V_DDQ

5) V_TTis not applied directly to the device. V_TTis a system supply for signal termination resistors, is expected to be set equal to V_REF, and

must track variations in the DC level of V_REF

6) Inputs are not recognized as valid until V_REFstabilizes.

7) _IDis the magnitude of the difference between the input level on CK and the input level on CK.

.

V

8) The ratio of the pull-up current to the pull-down current is specified for the same temperature and voltage, over the entire temperature and

voltage range, for device drain to source voltage from 0.25 to 1.0 V. For a given output, it represents the maximum difference between

pull-up and pull-down drivers due to process variation.

9) Values are shown per pin.

Rev. 1.21, 2006-08

11

03292006-6N25-8R3I

Internet Data Sheet

HYS72D[64/128/256]xxxHBR–[5/6]–C

Registered Double-Data-Rate SDRAM Module

TABLE 9

_DDConditions

I

Parameter

Symbol

Operating Current 0

I_DD0

one bank; active/ precharge; DQ, DM, and DQS inputs changing once per clock cycle;

address and control inputs changing once every two clock cycles.

Operating Current 1

I_DD1

one bank; active/read/precharge; Burst Length = 4; see component data sheet.

Precharge Power-Down Standby Current

all banks idle; power-down mode; CKE ≤ V_IL,MAX

I_DD2P

I_DD2F

Precharge Floating Standby Current

CS ≥ V_IH,,MIN, all banks idle; CKE ≥ V_IH,MIN

;

address and other control inputs changing once per clock cycle; V_IN= V_REFfor DQ, DQS and DM.

Precharge Quiet Standby Current

I_DD2Q

CS ≥ V_IHMIN, all banks idle; CKE ≥ V_IH,MIN; V_IN= V_REFfor DQ, DQS and DM;

address and other control inputs stable at ≥ V_IH,MINor ≤ V_IL,MAX

.

Active Power-Down Standby Current

one bank active; power-down mode; CKE ≤ V_ILMAX; V_IN= V_REFfor DQ, DQS and DM.

I_DD3P

I_DD3N

Active Standby Current

one bank active; CS ≥ V_IH,MIN; CKE ≥ V_IH,MIN; t_RC= t_RAS,MAX

DQ, DM and DQS inputs changing twice per clock cycle;

address and control inputs changing once per clock cycle.

;

Operating Current Read

I_DD4R

one bank active; Burst Length = 2; reads; continuous burst;

address and control inputs changing once per clock cycle;

50% of data outputs changing on every clock edge;

CL = 2 for DDR266(A), CL = 3 for DDR333 and DDR400B; I_OUT= 0 mA

Operating Current Write

I_DD4W

one bank active; Burst Length = 2; writes; continuous burst;

address and control inputs changing once per clock cycle;

50% of data outputs changing on every clock edge;

CL = 2 for DDR266(A), CL = 3 for DDR333 and DDR400B

Auto-Refresh Current

I_DD5

I_DD6

I_DD7

t

_RC= t_RFCMIN, burst refresh

Self-Refresh Current

CKE ≤ 0.2 V; external clock on

Operating Current 7

four bank interleaving with Burst Length = 4; see component data sheet.

Rev. 1.21, 2006-08

12

03292006-6N25-8R3I

Internet Data Sheet

HYS72D[64/128/256]xxxHBR–[5/6]–C

Registered Double-Data-Rate SDRAM Module

TABLE 10

_DDSpecification for HYS72D[64/128/256]xxxHBR–5–C

I

Product Type

Unit

Note ¹⁾²⁾

Organization

512 MB

×72

1 GB

×72

1 GB

×72

2 GB

×72

1 Rank

–5

1 Rank

–5

2 Ranks

–5

2 Ranks

–5

Symbol

Typ.

Max.

Typ.

Max.

Typ.

Max.

Typ.

Max.

3)

I_DD0

1050

1270

360

1240

1470

440

1890

2200

670

2210

2530

780

1660

1880

670

1910

2140

780

3120

3430

1290

2410

1870

1670

2770

3610

3700

4510

1270

5680

3570

3890

1460

2650

2140

1850

3090

3980

4070

5490

1430

6500

mA

3)4)

5)

I_DD1

I_DD2P

I_DD2F

I_DD2Q

I_DD3P

I_DD3N

I_DD4R

I_DD4W

I_DD5

5)

830

940

1360

960

1510

1120

970

1360

960

1510

1120

970

5)

510

600

5)

460

530

860

870

5)

920

1050

1510

1560

2120

390

1540

2380

2470

3280

640

1730

2620

2710

4130

740

1540

1970

2020

2290

640

1730

2190

2240

2800

740

3)4)

3)

1360

1400

1670

330

3)

5)

I_DD6

3)4)

I_DD7

2390

2770

4450

5140

3010

3450

1) Module I_DDis calculated on the basis of component I_DDand includes Register and PLL currents

2) Test condition for maximum values: V_DD= 2.7 V, T_A= 10 °C

3) The module I_DDxvalues are calculated from the component I_DDxdata sheet values as: m × I_DDx[component] + n × I_DD3N[component] with m

and n number of components of rank 1 and 2; n=0 for 1 rank modules

4) DQ I/O (I_DDQ) currents are not included into calculations: module I_DDvalues will be measured differently depending on load conditions

5) The module I_DDxvalues are calculated from the corrponent I_DDxdata sheet values as: (m + n) × I_DDx[component]

Rev. 1.21, 2006-08

13

03292006-6N25-8R3I

Internet Data Sheet

HYS72D[64/128/256]xxxHBR–[5/6]–C

Registered Double-Data-Rate SDRAM Module

TABLE 11

_DDSpecification for HYS72D[64/128/256]xxxHBR–6–C

I

Product Type

Unit

Note¹⁾²⁾

Organization

512 MB

×72

1 GB

×72

1 GB

×72

2 GB

×72

1 Rank

–6

1 Rank

–6

2 Ranks

–6

2 Ranks

–6

Symbol

Typ.

Max.

Typ.

Max.

Typ.

Max.

Typ.

Max.

3)

I_DD0

1000

1160

340

1140

1360

410

1790

2000

600

2020

2330

700

1530

1700

600

1720

1940

700

2860

3060

1120

2060

1630

1460

2440

3150

3240

4000

1110

5040

3180

3490

1280

2260

1890

1640

2690

3580

3670

4940

1270

5750

mA

3)4)

5)

I_DD1

I_DD2P

I_DD2F

I_DD2Q

I_DD3P

I_DD3N

I_DD4R

I_DD4W

I_DD5

5)

740

840

1180

860

1310

1000

880

1180

860

1310

1000

880

5)

470

560

5)

430

500

770

5)

830

940

1370

2090

2180

2930

580

1520

2420

2510

3780

680

1370

1740

1790

2040

580

1520

1990

2030

2530

680

3)4)

3)

1210

1250

1510

320

1410

1450

1950

390

3)

5)

I_DD6

3)4)

I_DD7

2150

2490

3980

4580

2690

3070

1) Module I_DDis calculated on the basis of component I_DDand includes Register and PLL currents

2) Test condition for maximum values: V_DD= 2.7 V, T_A= 10 °C

3) The module I_DDxvalues are calculated from the component I_DDxdata sheet values as: m × I_DDx[component] + n × I_DD3N[component] with m

and n number of components of rank 1 and 2; n=0 for 1 rank modules

4) DQ I/O (I_DDQ) currents are not included into calculations: module I_DDvalues will be measured differently depending on load conditions

5) The module I_DDxvalues are calculated from the corrponent I_DDxdata sheet values as: (m + n) × I_DDx[component]

Rev. 1.21, 2006-08

14

03292006-6N25-8R3I

Internet Data Sheet

HYS72D[64/128/256]xxxHBR–[5/6]–C

Registered Double-Data-Rate SDRAM Module

3.2

A.C. Timing Parameters

TABLE 12

AC Timing - Absolute Specifications for PC3200 and PC2700

Parameter

Symbol –5

–6

Unit Note/ Test

Condition ¹⁾

DDR400B

DDR333

Min.

Max.

Min.

Max.

2)3)4)5)

DQ output access time from

CK/CK

t_AC

–0.5

+0.5

–0.7

+0.7

ns

2)3)4)5)

CK high-level width

Clock cycle time

t_CH

t_CK

0.45

0.55

8

0.45

6

0.55

12

t_CK

5

ns

t_CK

CL = 3.0 ^2)3)4)5)

CL = 2.5 ^2)3)4)5)

CL = 2.0 ^2)3)4)5)

6

12

6

12

7.5

12

7.5

0.45

12

2)3)4)5)

CK low-level width

t_CL

0.45

0.55

2)3)4)5)6)

Auto precharge write recovery + t_DAL

precharge time

(t_WR/t_CK)+(t_RP/t_CK

)

2)3)4)5)

DQ and DM input hold time

t_DH

0.4

—

0.45

1.75

—

ns

2)3)4)5)6)

DQ and DM input pulse width

(each input)

t_DIPW

1.75

2)3)4)5)

DQS output access time from

CK/CK

t_DQSCK

–0.6

0.35

—

+0.6

—

–0.6

0.35

—

+0.6

—

ns

t_CK

ns

t_CK

DQS input low (high) pulse width t_DQSL,H

(write cycle)

DQS-DQ skew (DQS and

associated DQ signals)

Write command to 1^stDQS

latching transition

t_DQSQ

t_DQSS

t_DS

+0.40

1.25

+0.40

1.25

TFBGA

2)3)4)5)

0.72

0.75

2)3)4)5)

DQ and DM input setup time

0.4

0.2

—

0.45

0.2

—

ns

DQS falling edge hold time from t_DSH

CK (write cycle)

t_CK

2)3)4)5)

DQS falling edge to CK setup

time (write cycle)

t_DSS

0.2

—

0.2

—

t_CK

2)3)4)5)

Clock Half Period

t_HP

t_HZ

min. (t_CL, t_CH

)

—

min. (t_CL, t_CH

–0.7

)

—

ns

2)3)4)5)7)

Data-out high-impedance time

from CK/CK

—

+0.7

Address and control input hold

time

t_IH

0.6

0.7

2.2

—

0.75

0.8

—

ns

fast slew rate

3)4)5)6)8)

slow slew rate

3)4)5)6)8)

2)3)4)5)9)

Control and Addr. input pulse

width (each input)

t_IPW

2.2

Rev. 1.21, 2006-08

15

03292006-6N25-8R3I

Internet Data Sheet

HYS72D[64/128/256]xxxHBR–[5/6]–C

Registered Double-Data-Rate SDRAM Module

Parameter

Symbol –5

DDR400B

–6

Unit Note/ Test

Condition ¹⁾

DDR333

Min.

Max.

Min.

Max.

Address and control input setup t_IS

time

0.6

—

0.75

—

ns

t_CK

fast slew rate

3)4)5)6)8)

0.7

–0.7

2

—

0.8

–0.7

2

—

slow slew rate

3)4)5)6)8)

2)3)4)5)7)

2)3)4)5)

Data-out low-impedance time

from CK/CK

t_LZ

+0.7

—

+0.7

—

Mode register set command

cycle time

t_MRD

DQ/DQS output hold time

Data hold skew factor

t_QH

t_HP–t_QHS

—

t_HP–t_QHS

—

ns

t_QHS

t_RAP

t_RAS

t_RC

+0.50

—

+0.50

—

TFBGA ^2)3)4)5)

2)3)4)5)

Active to Autoprecharge delay

Active to Precharge command

t_RCD

40

t_RCD

42

2)3)4)5)

70E+3

—

70E+3 ns

Active to Active/Auto-refresh

command period

55

60

—

ns

2)3)4)5)

Active to Read or Write delay

t_RCD

t_REFI

15

—

18

—

ns

2)3)4)5)10)

Average Periodic Refresh

Interval

7.8

µs

2)3)4)5)

Auto-refresh to Active/Auto-

refresh command period

t_RFC

65

—

72

—

ns

2)3)4)5)

Precharge command period

Read preamble

t_RP

15

—

18

—

ns

t_CK

ns

t_RPRE

t_RPST

t_RRD

0.9

0.40

10

1.1

0.60

—

0.9

0.40

12

1.1

0.60

—

Read postamble

Active bank A to Active bank B

command

2)3)4)5)

Write preamble

t_WPRE

t_WPRES

t_WPST

t_WR

0.25

0

—

0.25

0

—

t_CK

ns

2)3)4)5)11)

2)3)4)5)12)

2)3)4)5)

Write preamble setup time

Write postamble

—

0.40

15

0.60

—

0.40

15

0.60

—

t_CK

ns

Write recovery time

2)3)4)5)

Internal write to read command t_WTR

delay

2

—

1

—

t_CK

2)3)4)5)

Exit self-refresh to non-read

command

t_XSNR

75

—

75

—

ns

Exit self-refresh to read

command

t_XSRD

200

t_CK

1) 0 °C ≤ T_A≤ 70 °C; V_DDQ= 2.5 V ± 0.2 V, V_DD= +2.5 V ± 0.2 V (DDR333); _DDQ= 2.6 V ± 0.1 V, _DD= +2.6 V ± 0.1 V (DDR400)

2) Input slew rate ≥ 1 V/ns for DDR400, DDR333

3) The CK/CK input reference level (for timing reference to CK/CK) is the point at which CK and CK cross: the input reference level for signals

other than CK/CK, is V_REF. CK/CK slew rate are ≥ 1.0 V/ns.

4) Inputs are not recognized as valid until V_REFstabilizes.

5) The Output timing reference level, as measured at the timing reference point indicated in AC Characteristics (note 3) is V_TT

6) For each of the terms, if not already an integer, round to the next highest integer. t_CKis equal to the actual system clock cycle time.

7) _HZand t_LZtransitions occur in the same access time windows as valid data transitions. These parameters are not referred to a specific

voltage level, but specify when the device is no longer driving (HZ), or begins driving (LZ).

.

t

Rev. 1.21, 2006-08

16

03292006-6N25-8R3I

Internet Data Sheet

HYS72D[64/128/256]xxxHBR–[5/6]–C

Registered Double-Data-Rate SDRAM Module

8) Fast slew rate ≥ 1.0 V/ns , slow slew rate ≥ 0.5 V/ns and < 1 V/ns for command/address and CK & CK slew rate > 1.0 V/ns, measured

between V_IH(ac)and V_IL(ac)

.

9) These parameters guarantee device timing, but they are not necessarily tested on each device.

10) A maximun of eight Autorefresh commands can be posted to any given DDR SDRAM device

11) The specific requirement is that DQS be valid (HIGH,LOW, or some point on a valid transition) on or before this CK edge. A valid transition

is defined as monotonic and meeting the input slew rate specificationsof the device. When no writes were previously in progress on the

bus, DQS will be transitioning from Hi-Z to logic LOW. If a previous write was in progress, DQS could be HIGH, LOW at this time, depending

on t_DQSS

.

12) The maximum limit for this parameter is not a device limit. The device operates with a greater value for this parameter, but system

performance (bus turnaround) degrades accordingly.

Rev. 1.21, 2006-08

17

03292006-6N25-8R3I

Internet Data Sheet

HYS72D[64/128/256]xxxHBR–[5/6]–C

Registered Double-Data-Rate SDRAM Module

4

SPD Codes

TABLE 13

SPD Codes for HYS72D[64/128/256]3[00/01/20/21]HBR–5–C

Product Type

Organization

Label Code

512 MB

1 GByte

×72

1 GByte

×72

2 GByte

×72

1 Rank (×8)

2 Ranks (×8)

1 Rank (×4)

2 Ranks (×4)

PC3200R–

30331

PC3200R–30331 PC3200R–

30331

PC3200R–

30331

JEDEC SPD Revision

Rev 1.0

HEX

Rev 1.0

HEX

Rev 1.0

HEX

Rev 1.0

HEX

Byte#

Description

0

Programmed SPD Bytes in E2PROM

Total number of Bytes in E2PROM

Memory Type (DDR = 07h)

Number of Row Addresses

Number of Column Addresses

Number of DIMM Ranks

Data Width (LSB)

80

08

07

0D

0B

01

48

00

04

50

70

02

82

08

01

0E

04

80

08

07

0D

0B

02

48

00

04

50

70

02

82

08

01

0E

04

80

08

07

0D

0C

01

48

00

04

50

70

02

82

04

01

0E

04

80

08

07

0D

0C

02

48

00

04

50

70

02

82

04

01

0E

04

1

2

3

4

5

6

7

Data Width (MSB)

8

Interface Voltage Levels

t_CK@ CL_max(Byte 18) [ns]

t_ACSDRAM @ CL_max(Byte 18) [ns]

Error Correction Support

Refresh Rate

9

10

11

12

13

14

15

16

17

Primary SDRAM Width

Error Checking SDRAM Width

t

_CCD[cycles]

Burst Length Supported

Number of Banks on SDRAM Device

Rev. 1.21, 2006-08

18

03292006-6N25-8R3I

Internet Data Sheet

HYS72D[64/128/256]xxxHBR–[5/6]–C

Registered Double-Data-Rate SDRAM Module

Product Type

Organization

Label Code

512 MB

×72

1 GByte

×72

1 GByte

×72

2 GByte

×72

1 Rank (×8)

2 Ranks (×8)

1 Rank (×4)

2 Ranks (×4)

PC3200R–

30331

PC3200R–30331 PC3200R–

30331

PC3200R–

30331

JEDEC SPD Revision

Rev 1.0

HEX

Rev 1.0

HEX

Rev 1.0

HEX

Rev 1.0

HEX

Byte#

Description

18

19

20

21

22

23

24

25

26

27

28

29

30

31

32

33

34

35

CAS Latency

1C

01

02

26

C1

60

70

75

70

3C

28

3C

28

80

60

40

00

37

41

28

50

00

01

1C

01

02

26

C1

60

70

75

70

3C

28

3C

28

80

60

40

00

37

41

28

50

00

01

1C

01

02

26

C1

60

70

75

70

3C

28

3C

28

01

60

40

00

37

41

28

50

00

01

1C

01

02

26

C1

60

70

75

70

3C

28

3C

28

01

60

40

00

37

41

28

50

00

01

CS Latency

Write Latency

DIMM Attributes

Component Attributes

t

_CK@ CL_max-0.5 (Byte 18) [ns]

t_ACSDRAM @ CL_max-0.5 [ns]

t

_CK@ CL_max-1 (Byte 18) [ns]

_ACSDRAM @ CL_max-1 [ns]

t_RPmin[ns]

t

_RRDmin[ns]

_RCDmin[ns]

t_RASmin[ns]

Module Density per Rank

t

_AS,t_CS[ns]

t_AH,t_CH[ns]

t

_DS[ns]

_DH[ns]

36 - 40 not used

41

42

43

44

45

46

47

t_RCmin[ns]

_RFCmin[ns]

t_CKmax[ns]

t

_DQSQmax[ns]

_QHSmax[ns]

not used

DIMM PCB Height

Rev. 1.21, 2006-08

19

03292006-6N25-8R3I

Internet Data Sheet

HYS72D[64/128/256]xxxHBR–[5/6]–C

Registered Double-Data-Rate SDRAM Module

Product Type

Organization

Label Code

512 MB

×72

1 GByte

×72

1 GByte

×72

2 GByte

×72

1 Rank (×8)

2 Ranks (×8)

1 Rank (×4)

2 Ranks (×4)

PC3200R–

30331

PC3200R–30331 PC3200R–

30331

PC3200R–

30331

JEDEC SPD Revision

Rev 1.0

HEX

Rev 1.0

HEX

Rev 1.0

HEX

Rev 1.0

HEX

Byte#

48 - 61 not used

SPD Revision

Description

00

10

C7

7F

51

00

xx

00

10

C8

7F

51

00

xx

00

10

41

7F

51

00

xx

00

10

42

7F

51

00

xx

62

63

64

65

66

67

68

69

70

71

72

73

74

75

76

77

78

79

80

81

82

83

84

85

86

Checksum of Byte 0-62

Manufacturer’s JEDEC ID Code (1)

Manufacturer’s JEDEC ID Code (2)

Manufacturer’s JEDEC ID Code (3)

Manufacturer’s JEDEC ID Code (4)

Manufacturer’s JEDEC ID Code (5)

Manufacturer’s JEDEC ID Code (6)

Manufacturer’s JEDEC ID Code (7)

Manufacturer’s JEDEC ID Code (8)

Module Manufacturer Location

Part Number, Char 1

37

32

44

36

34

33

30

31

48

42

52

35

43

20

37

32

44

31

32

38

33

32

31

48

42

52

35

43

37

32

44

31

32

38

33

30

48

42

52

35

43

37

32

44

32

35

36

33

32

30

48

42

52

35

43

Part Number, Char 2

Part Number, Char 3

Part Number, Char 4

Part Number, Char 5

Part Number, Char 6

Part Number, Char 7

Part Number, Char 8

Part Number, Char 9

Part Number, Char 10

Part Number, Char 11

Part Number, Char 12

Part Number, Char 13

Part Number, Char 14

Rev. 1.21, 2006-08

20

03292006-6N25-8R3I

Internet Data Sheet

HYS72D[64/128/256]xxxHBR–[5/6]–C

Registered Double-Data-Rate SDRAM Module

Product Type

Organization

Label Code

512 MB

×72

1 GByte

×72

1 GByte

×72

2 GByte

×72

1 Rank (×8)

2 Ranks (×8)

1 Rank (×4)

2 Ranks (×4)

PC3200R–

30331

PC3200R–30331 PC3200R–

30331

PC3200R–

30331

JEDEC SPD Revision

Rev 1.0

HEX

Rev 1.0

HEX

Rev 1.0

HEX

Rev 1.0

HEX

Byte#

Description

87

88

89

90

91

92

93

94

Part Number, Char 15

20

1x

xx

00

20

1x

xx

00

20

1x

xx

00

20

1x

xx

00

Part Number, Char 16

Part Number, Char 17

Part Number, Char 18

Module Revision Code

Test Program Revision Code

Module Manufacturing Date Year

Module Manufacturing Date Week

95 - 98 Module Serial Number (1 - 4)

99 - 127 not used

Rev. 1.21, 2006-08

21

03292006-6N25-8R3I

Internet Data Sheet

HYS72D[64/128/256]xxxHBR–[5/6]–C

Registered Double-Data-Rate SDRAM Module

TABLE 14

SPD Codes for HYS72D[64/128/256]3[00/01/20/21]HBR–6–C

Product Type

Organization

Label Code

512 MB

×72

1 GByte

×72

1 GByte

×72

2 GByte

×72

1 Rank (×8)

2 Ranks (×8)

1 Rank (×4)

2 Ranks (×4)

PC2700R–

25331

PC2700R–

25331

PC2700R–

25331

PC2700R–

25331

JEDEC SPD Revision

Rev 1.0

HEX

Rev 1.0

HEX

Rev 1.0

HEX

Rev 1.0

HEX

Byte#

Description

0

Programmed SPD Bytes in E2PROM

Total number of Bytes in E2PROM

Memory Type (DDR = 07h)

Number of Row Addresses

Number of Column Addresses

Number of DIMM Ranks

80

08

07

0D

0B

01

48

00

04

60

70

02

82

08

01

0E

04

0C

01

02

26

C1

80

08

07

0D

0B

02

48

00

04

60

70

02

82

08

01

0E

04

0C

01

02

26

C1

80

08

07

0D

0C

01

48

00

04

60

70

02

82

04

01

0E

04

0C

01

02

26

C1

80

08

07

0D

0C

02

48

00

04

60

70

02

82

04

01

0E

04

0C

01

02

26

C1

1

2

3

4

5

6

Data Width (LSB)

7

Data Width (MSB)

8

Interface Voltage Levels

9

t_CK@ CL_max(Byte 18) [ns]

10

11

12

13

14

15

16

17

18

19

20

21

22

t_ACSDRAM @ CL_max(Byte 18) [ns]

Error Correction Support

Refresh Rate

Primary SDRAM Width

Error Checking SDRAM Width

t_CCD[cycles]

Burst Length Supported

Number of Banks on SDRAM Device

CAS Latency

CS Latency

Write Latency

DIMM Attributes

Component Attributes

Rev. 1.21, 2006-08

22

03292006-6N25-8R3I

Internet Data Sheet

HYS72D[64/128/256]xxxHBR–[5/6]–C

Registered Double-Data-Rate SDRAM Module

Product Type

Organization

Label Code

512 MB

×72

1 GByte

×72

1 GByte

×72

2 GByte

×72

1 Rank (×8)

2 Ranks (×8)

1 Rank (×4)

2 Ranks (×4)

PC2700R–

25331

PC2700R–

25331

PC2700R–

25331

PC2700R–

25331

JEDEC SPD Revision

Rev 1.0

HEX

Rev 1.0

HEX

Rev 1.0

HEX

Rev 1.0

HEX

Byte#

Description

23

24

25

26

27

28

29

30

31

32

33

34

35

t_CK@ CL_max-0.5 (Byte 18) [ns]

75

70

00

48

30

48

2A

80

75

45

00

3C

48

30

28

50

00

01

00

10

61

7F

75

70

00

48

30

48

2A

80

75

45

00

3C

48

30

28

50

00

01

00

10

62

7F

75

70

00

48

30

48

2A

01

75

45

00

3C

48

30

28

50

00

01

00

10

DB

7F

75

70

00

48

30

48

2A

01

75

45

00

3C

48

30

28

50

00

01

00

10

DC

7F

t

_ACSDRAM @ CL_max-0.5 [ns]

_CK@ CL_max-1 (Byte 18) [ns]

t

t_ACSDRAM @ CL_max-1 [ns]

t_RPmin[ns]

t_RRDmin[ns]

t_RCDmin[ns]

_RASmin[ns]

t

Module Density per Rank

t_AS,t_CS[ns]

t

_AH,t_CH[ns]

_DS[ns]

t

t_DH[ns]

36 - 40 not used

41

42

43

44

45

46

47

t_RCmin[ns]

t_RFCmin[ns]

t_CKmax[ns]

t_DQSQmax[ns]

t_QHSmax[ns]

not used

DIMM PCB Height

48 - 61 not used

62

63

64

65

SPD Revision

Checksum of Byte 0-62

Manufacturer’s JEDEC ID Code (1)

Manufacturer’s JEDEC ID Code (2)

Rev. 1.21, 2006-08

23

03292006-6N25-8R3I

Internet Data Sheet

HYS72D[64/128/256]xxxHBR–[5/6]–C

Registered Double-Data-Rate SDRAM Module

Product Type

Organization

Label Code

512 MB

×72

1 GByte

×72

1 GByte

×72

2 GByte

×72

1 Rank (×8)

2 Ranks (×8)

1 Rank (×4)

2 Ranks (×4)

PC2700R–

25331

PC2700R–

25331

PC2700R–

25331

PC2700R–

25331

JEDEC SPD Revision

Rev 1.0

HEX

Rev 1.0

HEX

Rev 1.0

HEX

Rev 1.0

HEX

Byte#

Description

66

67

68

69

70

71

72

73

74

75

76

77

78

79

80

81

82

83

84

85

86

87

88

89

90

91

Manufacturer’s JEDEC ID Code (3)

Manufacturer’s JEDEC ID Code (4)

Manufacturer’s JEDEC ID Code (5)

Manufacturer’s JEDEC ID Code (6)

Manufacturer’s JEDEC ID Code (7)

Manufacturer’s JEDEC ID Code (8)

Module Manufacturer Location

Part Number, Char 1

7F

51

00

xx

7F

51

00

xx

7F

51

00

xx

7F

51

00

xx

37

32

44

36

34

33

30

31

48

42

52

36

43

20

1x

37

32

44

31

32

38

33

32

31

48

42

52

36

43

20

1x

37

32

44

31

32

38

33

30

48

42

52

36

43

20

1x

37

32

44

32

35

36

33

32

30

48

42

52

36

43

20

1x

Part Number, Char 2

Part Number, Char 3

Part Number, Char 4

Part Number, Char 5

Part Number, Char 6

Part Number, Char 7

Part Number, Char 8

Part Number, Char 9

Part Number, Char 10

Part Number, Char 11

Part Number, Char 12

Part Number, Char 13

Part Number, Char 14

Part Number, Char 15

Part Number, Char 16

Part Number, Char 17

Part Number, Char 18

Module Revision Code

Rev. 1.21, 2006-08

24

03292006-6N25-8R3I

Internet Data Sheet

HYS72D[64/128/256]xxxHBR–[5/6]–C

Registered Double-Data-Rate SDRAM Module

Product Type

Organization

Label Code

512 MB

×72

1 GByte

×72

1 GByte

×72

2 GByte

×72

1 Rank (×8)

2 Ranks (×8)

1 Rank (×4)

2 Ranks (×4)

PC2700R–

25331

PC2700R–

25331

PC2700R–

25331

PC2700R–

25331

JEDEC SPD Revision

Rev 1.0

HEX

Rev 1.0

HEX

Rev 1.0

HEX

Rev 1.0

HEX

Byte#

Description

92

93

94

Test Program Revision Code

xx

00

xx

00

xx

00

xx

00

Module Manufacturing Date Year

Module Manufacturing Date Week

95 - 98 Module Serial Number (1 - 4)

99 - 127 not used

Rev. 1.21, 2006-08

25

03292006-6N25-8R3I

Internet Data Sheet

HYS72D[64/128/256]xxxHBR–[5/6]–C

Registered Double-Data-Rate SDRAM Module

TABLE 15

SPD Codes for HYS72D[128/256]90x0HBR–6–C

Product Type

Organization

Label Code

1 GByte

×72

2 GByte

×72

1 Rank (×4)

PC2700R–25331

Rev 1.0

2 Ranks (×4)

PC2700R–25331

Rev 1.0

JEDEC SPD Revision

Byte#

Description

HEX

0

Programmed SPD Bytes in E2PROM

Total number of Bytes in E2PROM

Memory Type (DDR = 07h)

Number of Row Addresses

Number of Column Addresses

Number of DIMM Ranks

80

08

07

0D

0C

01

48

00

04

60

70

02

82

04

01

0E

04

0C

01

02

26

C1

75

80

08

07

0D

0C

02

48

00

04

60

70

02

82

04

01

0E

04

0C

01

02

26

C1

75

1

2

3

4

5

6

Data Width (LSB)

7

Data Width (MSB)

8

Interface Voltage Levels

9

t_CK@ CL_max(Byte 18) [ns]

10

11

12

13

14

15

16

17

18

19

20

21

22

23

t_ACSDRAM @ CL_max(Byte 18) [ns]

Error Correction Support

Refresh Rate

Primary SDRAM Width

Error Checking SDRAM Width

t_CCD[cycles]

Burst Length Supported

Number of Banks on SDRAM Device

CAS Latency

CS Latency

Write Latency

DIMM Attributes

Component Attributes

t_CK@ CL_max-0.5 (Byte 18) [ns]

Rev. 1.21, 2006-08

26

03292006-6N25-8R3I

Internet Data Sheet

HYS72D[64/128/256]xxxHBR–[5/6]–C

Registered Double-Data-Rate SDRAM Module

Product Type

Organization

Label Code

1 GByte

2 GByte

×72

1 Rank (×4)

PC2700R–25331

Rev 1.0

2 Ranks (×4)

PC2700R–25331

Rev 1.0

JEDEC SPD Revision

Byte#

Description

HEX

24

t_ACSDRAM @ CL_max-0.5 [ns]

70

00

48

30

48

2A

01

75

45

00

3C

48

30

28

50

00

01

00

10

DB

7F

70

00

48

30

48

2A

01

75

45

00

3C

48

30

28

50

00

01

00

10

DC

7F

25

t

_CK@ CL_max-1 (Byte 18) [ns]

_ACSDRAM @ CL_max-1 [ns]

26

t

27

t_RPmin[ns]

28

t

_RRDmin[ns]

_RCDmin[ns]

29

t

30

t_RASmin[ns]

31

Module Density per Rank

32

t_AS,t_CS[ns]

33

t_AH,t_CH[ns]

34

t

_DS[ns]

_DH[ns]

35

t

36 - 40

41

not used

t_RCmin[ns]

42

t_RFCmin[ns]

43

t_CKmax[ns]

44

t

_DQSQmax[ns]

_QHSmax[ns]

45

t

46

not used

47

DIMM PCB Height

48 - 61

62

not used

SPD Revision

63

Checksum of Byte 0-62

Manufacturer’s JEDEC ID Code (1)

Manufacturer’s JEDEC ID Code (2)

Manufacturer’s JEDEC ID Code (3)

64

65

66

Rev. 1.21, 2006-08

27

03292006-6N25-8R3I

Internet Data Sheet

HYS72D[64/128/256]xxxHBR–[5/6]–C

Registered Double-Data-Rate SDRAM Module

Product Type

Organization

Label Code

1 GByte

2 GByte

×72

1 Rank (×4)

PC2700R–25331

Rev 1.0

2 Ranks (×4)

PC2700R–25331

Rev 1.0

JEDEC SPD Revision

Byte#

Description

HEX

67

68

69

70

71

72

73

74

75

76

77

78

79

80

81

82

83

84

85

86

87

88

89

90

91

92

Manufacturer’s JEDEC ID Code (4)

Manufacturer’s JEDEC ID Code (5)

Manufacturer’s JEDEC ID Code (6)

Manufacturer’s JEDEC ID Code (7)

Manufacturer’s JEDEC ID Code (8)

Module Manufacturer Location

Part Number, Char 1

7F

51

00

xx

7F

51

00

xx

37

32

44

31

32

38

39

30

48

42

52

36

43

20

1x

xx

37

32

44

32

35

36

39

32

30

48

42

52

36

43

20

1x

xx

Part Number, Char 2

Part Number, Char 3

Part Number, Char 4

Part Number, Char 5

Part Number, Char 6

Part Number, Char 7

Part Number, Char 8

Part Number, Char 9

Part Number, Char 10

Part Number, Char 11

Part Number, Char 12

Part Number, Char 13

Part Number, Char 14

Part Number, Char 15

Part Number, Char 16

Part Number, Char 17

Part Number, Char 18

Module Revision Code

Test Program Revision Code

Rev. 1.21, 2006-08

28

03292006-6N25-8R3I

Internet Data Sheet

HYS72D[64/128/256]xxxHBR–[5/6]–C

Registered Double-Data-Rate SDRAM Module

Product Type

Organization

Label Code

1 GByte

2 GByte

×72

1 Rank (×4)

PC2700R–25331

Rev 1.0

2 Ranks (×4)

PC2700R–25331

Rev 1.0

JEDEC SPD Revision

Byte#

Description

HEX

93

Module Manufacturing Date Year

Module Manufacturing Date Week

Module Serial Number (1 - 4)

not used

xx

00

xx

00

94

95 - 98

99 - 127

Rev. 1.21, 2006-08

29

03292006-6N25-8R3I

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HYS72D[64/128/256]xxxHBR–[5/6]–C

Registered Double-Data-Rate SDRAM Module

5

Package Outlines

FIGURE 2

Package Outline Raw Card A - L-DIM-184-21-3

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Rev. 1.21, 2006-08

30

03292006-6N25-8R3I

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HYS72D[64/128/256]xxxHBR–[5/6]–C

Registered Double-Data-Rate SDRAM Module

FIGURE 3

Package Outline Raw Card C - L-DIM-184-22-2

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Rev. 1.21, 2006-08

31

03292006-6N25-8R3I

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Internet Data Sheet

HYS72D[64/128/256]xxxHBR–[5/6]–C

Registered Double-Data-Rate SDRAM Module

FIGURE 4

Package Outline Raw Card B - L-DIM-184-23-2

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Rev. 1.21, 2006-08

32

03292006-6N25-8R3I

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Internet Data Sheet

HYS72D[64/128/256]xxxHBR–[5/6]–C

Registered Double-Data-Rate SDRAM Module

FIGURE 5

Package Outline Raw Card F – L-DIM-184-25

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Notes

1. General tolerances +/- 0.15

2. Drawing according to ISO 8015

Rev. 1.21, 2006-08

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Internet Data Sheet

HYS72D[64/128/256]xxxHBR–[5/6]–C

Registered Double-Data-Rate SDRAM Module

6

Application Note

Power Up and Power Management on DDR Registered DIMMs

(according to JEDEC ballot JC-42.5 Item 1173)

184-pin Double Data Rate (DDR) Registered DIMMs include two new features to facilitate controlled power-up and to minimize

power consumption during low power mode. One feature is externally controlled via a system-generated RESET signal; the

second is based on module detection of the input clocks. These enhancements permit the modules to power up with SDRAM

outputs in a High-Z state (eliminating risk of high current dissipations and/or dotted I/Os), and result in the powering-down of

module support devices (registers and Phase-Locked Loop) when the memory is in Self-Refresh mode.

The new RESET pin controls power dissipation on the module’s registers and ensures that CKE and other SDRAM inputs are

maintained at a valid ‘low’ level during power-up and self refresh. When RESET is at a low level, all the register outputs are

forced to a low level, and all differential register input receivers are powered down, resulting in very low register power

consumption. The RESET pin, located on DIMM tab #10, is driven from the system as an asynchronous signal according to

the attached details. Using this function also permits the system and DIMM clocks to be stopped during memory Self Refresh

operation, while ensuring that the SDRAMs stay in Self Refresh mode.

TABLE 16

Function for RESET

Register Inputs

Register Outputs¹⁾

RESET

CK

Data in (D)

Data out (Q)

H

L

Rising

L or H

High Z

X or Hi-Z

Falling

L or H

High Z

X or Hi-Z

H

L

X

Qo

X

Illegal input conditions

L

X or Hi-Z

1) X : Don’t care, Hi-Z : High Impedance, Qo: Data latched at the previous of CK risning and CK falling

As described in the table above, a low on the RESET input ensures that the Clock Enable (CKE) signal(s) are maintained low

at the SDRAM pins (CKE being one of the 'Q' signals at the register output). Holding CKE low maintains a high impedance

state on the SDRAM DQ, DQS and DM outputs — where they will remain until activated by a valid ‘read’ cycle. CKE low also

maintains SDRAMs in Self Refresh mode when applicable.

The DDR PLL devices automatically detect clock activity above 20MHz. When an input clock frequency of 20MHz or greater

is detected, the PLL begins operation and initiates clock frequency lock (the minimum operating frequency at which all

specifications will be met is 95MHz). If the clock input frequency drops below 20MHz (actual detect frequency will vary by

vendor), the PLL VCO (Voltage Controlled Oscillator) is stopped, outputs are made High-Z, and the differential inputs are

powered down — resulting in a total PLL current consumption of less than 1mA. Use of this low power PLL function makes the

use of the PLL RESET (or G pin) unnecessary, and it is tied inactive on the DIMM.

This application note describes the required and optional system sequences associated with the DDR Registered DIMM

'RESET' function. It is important to note that all references to CKE refer to both CKE0 and CKE1 for a 2-bank DIMM. Because

RESET applies to all DIMM register devices, it is therefore not possible to uniquely control CKE to one physical DIMM bank

through the use of the RESET pin.

Rev. 1.21, 2006-08

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03292006-6N25-8R3I

Internet Data Sheet

HYS72D[64/128/256]xxxHBR–[5/6]–C

Registered Double-Data-Rate SDRAM Module

Power-Up Sequence with RESET — Required

1. The system sets RESET at a valid low level. This is the preferred default state during power-up. This input condition forces

all register outputs to a low state independent of the condition on the register inputs (data and clock), ensuring that CKE is

at a stable low-level at the DDR SDRAMs.

2. The power supplies should be initialized according to the JEDEC-approved initialization sequence for DDR SDRAMs.

3. Stabilization of Clocks to the SDRAM The system must drive clocks to the application frequency (PLL operation is not

assured until the input clock reaches 20MHz). Stability of clocks at the SDRAMs will be affected by all applicable system

clock devices, and time must be allotted to permit all clock devices to settle. Once a stable clock is received at the DIMM

PLL, the required PLL stabilization time (assuming power to the DIMM is stable) is 100 microseconds. When a stable clock

is present at the SDRAM input (driven from the PLL), the DDR SDRAM requires 200 µsec prior to SDRAM operation.

4. The system applies valid logic levels to the data inputs of the register (address and controls at the DIMM connector). CKE

must be maintained low and all other inputs should be driven to a known state. In general these commands can be

determined by the system designer. One option is to apply an SDRAM ‘NOP’ command (with CKE low), as this is the first

command defined by the JEDEC initialization sequence (ideally this would be a ‘NOP Deselect’ command). A second option

is to apply low levels on all of the register inputs to be consistent with the state of the register outputs.

5. The system switches RESET to a logic ‘high’ level. The SDRAM is now functional and prepared to receive commands.

Since the RESET signal is asynchronous, setting the RESET timing in relation to a specific clock edge is not required

(during this period, register inputs must remain stable).

6. The system must maintain stable register inputs until normal register operation is attained. The registers have an activation

time that allows their clock receivers, data input receivers, and output drivers sufficient time to be turned on and become

stable. During this time the system must maintain the valid logic levels described in step 5. It is also a functional requirement

that the registers maintain a low state at the CKE outputs to guarantee that the DDR SDRAMs continue to receive a low

level on CKE. Register activation time (t (ACT) ), from asynchronous switching of RESET from low to high until the registers

are stable and ready to accept an input signal, is specified in the register and DIMM do-umentation.

7. The system can begin the JEDEC-defined DDR SDRAM power-up sequence (according to the JEDEC-pproved

initialization sequence).

Self Refresh Entry (RESET low, clocks powered off) — Optional

Self Refresh can be used to retain data in DDR SDRAM DIMMs even if the rest of the system is powered down and the clocks

are off. This mode allows the DDR SDRAMs on the DIMM to retain data without external clocking. Self Refresh mode is an

ideal time to utilize the RESET pin, as this can reduce register power consumption (RESET low deactivates register CK and

CK, data input receivers, and data output drivers).

•

The system applies Self Refresh entry command. (CKEÆLow, CSÆLow, RAS Æ Low, CASÆ Low, WEÆ High)

Note: The commands reach the DDR SDRAM one clock later due to the additional register pipelining on a Registered DIMM.

After this command is issued to the SDRAM, all of the address and control and clock input conditions to the SDRAM are

Don’t Cares— with the exception of CKE.

•

The system sets RESET at a valid low level. This input condition forces all register outputs to a low state, independent of

the condition on the registerm inputs (data and clock), and ensures that CKE, and all other control and address signals, are

a stable low-level at the DDR SDRAMs. Since the RESET signal is asynchronous, setting the RESET timing in relation to a

specific clock edge is not required.

•

The system turns off clock inputs to the DIMM. (Optional) a. In order to reduce DIMM PLL current, the clock inputs to the

DIMM are turned off, resulting in High-Z clock inputs to both the SDRAMs and the registers. This must be done after the

RESET deactivate time of the register (t (INACT) ). The deactivate time defines the time in which the clocks and the control

and address signals must maintain valid levels after RESET low has been applied and is specified in the register and DIMM

documentation. b. The system may release DIMM address and control inputs to High-Z. This can be done after the RESET

deactivate time of the register. The deactivate time defines the time in which the clocks and the control and the address

signals must maintain valid levels after RESET low has been applied. It is highly recommended that CKE continue to remain

low during this operation.

Rev. 1.21, 2006-08

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Internet Data Sheet

HYS72D[64/128/256]xxxHBR–[5/6]–C

Registered Double-Data-Rate SDRAM Module

•

The DIMM is in lowest power Self Refresh mode.

Self Refresh Exit (RESET low, clocks powered off) — Optional

1. Stabilization of Clocks to the SDRAM. The system must drive clocks to the application frequency (PLL operation is not

assured until the input clock reaches ~20MHz). Stability of clocks at the SDRAMs will be affected by all applicable system

clock devices, and time must be allotted to permit all clock devices to settle. Once a stable clock is received at the DIMM

PLL, the required PLL stabilization time (assuming power to the DIMM is stable) is 100 microseconds.

2. The system applies valid logic levels to the data inputs of the register (address and controls at the DIMM connector). CKE

must be maintained low and all other inputs should be driven to a known state. In general these commands can be

determined by the system designer. One option is to apply an SDRAM ‘NOP’ command (with CKE low), as this is the first

command defined by the JEDEC Self Refresh Exit sequence (ideally this would be a ‘NOP Deselect’ command). A second

option is to apply low levels on all of the register inputs, to be consistent with the state of the register outputs.

3. The system switches RESET to a logic ‘high’ level. The SDRAM is now functional and prepared to receive commands.

Since the RESET signal is asynchronous, RESET timing relationship to a specific clock edge is not required (during this

period, register inputs must remain stable).

4. The system must maintain stable register inputs until normal register operation is attained. The registers have an activation

time that allows the clock receivers, input receivers, and output drivers sufficient time to be turned on and become stable.

During this time the system must maintain the valid logic levels described in Step 2. It is also a functional requirement that

the registers maintain a low state at the CKE outputs to guarantee that the DDR SDRAMs continue to receive a low level

on CKE. Register activation time (t (ACT) ), from asynchronous switching of RESET from low to high until the registers are

stable and ready to accept an input signal, is specified in the register and DIMM do-umentation.

5. System can begin the JEDEC-defined DDR SDRAM Self Refresh Exit Procedure.

Self Refresh Entry (RESET low, clocks running) — Optional

Although keeping the clocks running increases power consumption from the on-DIMM PLL during self refresh, this is an

alternate operating mode for these DIMMs.

1. System enters Self Refresh entry command. (CKEÆ Low, CSÆ Low, RASÆ Low, CASÆ Low, WEÆ High)

Note: The commands reach the DDR SDRAM one clock later due to the additional register pipelining on a Registered DIMM.

After this command is issued to the SDRAM, all of the address and control and clock input conditions to the SDRAM are

Don’t Cares — with the exception of CKE.

•

The system sets RESET at a valid low level. This input condition forces all register outputs to a low state, independent of

the condition on the data and clock register inputs, and ensures that CKE is a stable low-level at the DDR SDRAMs.

The system may release DIMM address and control inputs to High-Z. This can be done after the RESET deactivate time of

the register (t (INACT) ). The deactivate time describes the time in which the clocks and the control and the address signals

must maintain valid levels after RESET low has been applied. It is highly recommended that CKE continue to remain low

during the operation.

•

The DIMM is in a low power, Self Refresh mode.

Self Refresh Exit (RESET low, clocks running) — Optional

1. The system applies valid logic levels to the data inputs of the register (address and controls at the DIMM connector). CKE

must be maintained low and all other inputs should be driven to a known state. In general these commands can be

determined by the system designer. One option is to apply an SDRAM ‘NOP’ command (with CKE low), as this is the first

command defined by the Self Refresh Exit sequence (ideally this would be a ‘NOP Deselect’ command). A second option

is to apply low levels on all of the register inputs to be consistent with the state of the register outputs.

Rev. 1.21, 2006-08

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03292006-6N25-8R3I

Internet Data Sheet

HYS72D[64/128/256]xxxHBR–[5/6]–C

Registered Double-Data-Rate SDRAM Module

2. The system switches RESET to a logic 'high' level. The SDRAM is now functional and prepared to receive commands.

Since the RESET signal is asynchronous, it does not need to be tied to a particular clock edge (during this period, register

inputs must continue to remain stable).

3. The system must maintain stable register inputs until normal register operation is attained. The registers have an activation

time that allows the clock receivers, input receivers, and output drivers sufficient time to be turned on and become stable.

During this time the system must maintain the valid logic levels described in Step 1. It is also a functional requirement that

the registers maintain a low state at the CKE outputs in order to guarantee that the DDR SDRAMs continue to receive a

low level on CKE. This activation time, from asynchronous switching of RESET from low to high, until the registers are

stable and ready to accept an input signal, is t (ACT ) as specified in the register and DIMM documentation.

4. The system can begin JEDEC defined DDR SDRAM Self Refresh Exit Procedure.

Self Refresh Entry/Exit (RESET high, clocks running) — Optional

As this sequence does not involve the use of the RESET function, the JEDEC standard SDRAM specification

explains in detail the method for entering and exiting Self Refresh for this case.

Self Refresh Entry (RESET high, clocks powered off) — Not Permissible

In order to maintain a valid low level on the register output, it is required that either the clocks be running and the system drive

a low level on CKE, or the clocks are powered off and RESET is asserted low according to the sequence defined in this

application note. In the case where RESET remains high and the clocks are powered off, the PLL drives a High-Z clock input

into the register clock input. Without the low level on RESET an unknown DIMM state will result.

Rev. 1.21, 2006-08

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03292006-6N25-8R3I

Internet Data Sheet

HYS72D[64/128/256]xxxHBR–[5/6]–C

Registered Double-Data-Rate SDRAM Module

Table of Contents

1

1.1

1.2

Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3

Features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3

Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4

2

Pin Configuration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5

3

Electrical Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10

3.1

A.C. Timing Parameters . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15

4

5

6

SPD Codes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 18

Package Outlines . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 30

Application Note . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 34

Table of Contents . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 42

Rev. 1.21, 2006-08

38

03292006-6N25-8R3I

Internet Data Sheet

Edition 2006-08

Published by Qimonda AG

Gustav-Heinemann-Ring 212

D-81739 München, Germany

Legal Disclaimer

The information given in this Internet Data Sheet shall in no event be regarded as a guarantee of conditions or characteristics

(“Beschaffenheitsgarantie”). With respect to any examples or hints given herein, any typical values stated herein and/or any

information regarding the application of the device, Qimonda hereby disclaims any and all warranties and liabilities of any kind,

including without limitation warranties of non-infringement of intellectual property rights of any third party.

Information

For further information on technology, delivery terms and conditions and prices please contact your nearest Qimonda Office.

Warnings

Due to technical requirements components may contain dangerous substances. For information on the types in question please

contact your nearest Qimonda Office.

Qimonda Components may only be used in life-support devices or systems with the express written approval of Qimonda, if a

failure of such components can reasonably be expected to cause the failure of that life-support device or system, or to affect

the safety or effectiveness of that device or system. Life support devices or systems are intended to be implanted in the human

body, or to support and/or maintain and sustain and/or protect human life. If they fail, it is reasonable to assume that the health

of the user or other persons may be endangered.

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