ETC HYS72V32600GR-7.5-C2

HYS 72Vxx5/6x0GR-7.5
Low Profile PC133 Registered SDRAM-Modules
3.3 V Low Profile 168-pin PC133 Registered
SDRAM Modules for 1U Server Applications
PC133 128 MByte Module
PC133 256 MByte module
PC133 512 MByte Module
PC133 1024 MByte Module
• 168-pin Registered 8 Byte Dual-In-Line
SDRAM Module for Workstation and Server
main memory applications with 1,2” inch
(30,40 mm) height
• Programmable CAS Latency, Burst Length,
and Wrap Sequence (Sequential &
Interleave)
• All inputs and outputs are LVTTL compatible
• One bank 16M × 72, 32M x 72 and 64M × 72
and two bank 128Mx72 organization
• Utilizes SDRAMs in TSOPII-54 packages
with on-board registers and PLL.
• Optimized for ECC applications with very low
input capacitances
• Card Sizes :
RawCard “F” and “G” 133.35 mm x 30,40 with
gold contact pads
• JEDEC standard Synchronous DRAMs
(SDRAM) with 128Mb, 256Mb and
512Mb memory density. Stacked
components for two bank modules
• These modules all fully compatible with the
current industry standard PC133
specifications and fully backward compatible
to PC100 applications
• Single + 3.3 V (± 0.3 V) power supply
• Auto Refresh (CBR) and Self Refresh
• Serial Presence Detect with E 2PROM
• Performance:
-7.5
Unit
fCK3
Clock Frequency (max.) @ CL = 3
133
MHz
tAC3
Clock Access Time (min.)@ CL = 3
5.4
ns
fCK2
Clock Frequency (max.) @ CL = 2
100
MHz
tAC2
Clock Access Time (min.)@ CL = 2
6
ns
The HYS 72Vxx5/6x0GR-7.5 are industry standard 168-pin 8-byte Dual in-line Memory Modules (DIMMs)
organized as 16M × 72, 32M x 72, 64M × 72 and 128M x 72 high speed memory arrays designed with x4 or x8
organised Synchronous DRAMs (SDRAMs) for ECC applications. All control and address signals are registered
on-DIMM and the design incorporates a PLL circuit for the Clock inputs. Use of an on-board register reduces
capacitive loading on the input signals but are delayed by one cycle in arriving at the SDRAM devices. Decoupling
capacitors are mounted on the PC board. The DIMMs use a serial presence detects scheme implemented via a
serial E2PROM using the 2-pin I2C protocol. The first 128 bytes are utilized by the DIMM manufacturer and the
second 128 bytes are available to the end user. All Infineon 168-pin DIMMs provide a high performance, flexible
8-byte interface in a 133.35 mm long footprint. This module family is designed with 30,40 mm (1.2 inch) maximum
height for 1U Server Applications b ased on JEDEC standard RawCards “F” and “G”.
INFINEON Technologies
1
1.02
HYS 72Vxx5/6x0GR-7.5
Low Profile PC133 Registered SDRAM-Modules
Ordering Information
Type
Compliance Code
Description
SDRAM
Technology
HYS 72V16600GR-7.5
PC133R-333-542-F
one bank 128 MB Reg. DIMM
128 MBit (x8)
HYS 72V32501GR-7.5
PC133R-333-542-G
one bank 256 MB Reg. DIMM
128 MBit (x4)
HYS 72V32600GR-7.5
PC133R-333-542-F
one bank 256 MB Reg. DIMM
256 Mbit (x8)
HYS 72V64500GR-7.5
PC133R-333-542-G
one bank 512 MB Reg. DIMM
256 Mbit (x4)
HYS 72V64601GR-7.5
PC133R-333-542-F
1.2” height:
HYS 72V128520GR-7.5 PC133R-333-542-G
Note:
one bank 512 MB Reg. DIMM
512 MBit (x8)
two banks 1024 MB Reg.
DIMM
256 Mbit (x4)
stacked
All part numbers end with a place code (not shown), designating the die revision. Consult factory for
current revision. Example: HYS 64V16600GR-7.5-C2, indicating Rev.C2 dies are used for SDRAM
components.
INFINEON Technologies
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1.02
HYS 72Vxx5/6x0GR-7.5
Low Profile PC133 Registered SDRAM-Modules
Pin Definitions and Functions
A0 - A11, A12 Address Inputs
DQMB0 - DQMB7 Data Mask
(A12 is used for 256Mbit and 512Mbit
based modules only)
BA0, BA1
Bank Selects
CS0 - CS3
DQ0 - DQ63
Data Input/Output
REGE *)
Chip Select
Register Enable
“H” or N.C = registered mode
“L” = buffered mode
CB0 - CB7
Check Bits
VDD
Power (+ 3.3 V)
RAS
Row Address Strobe
VSS
Ground
CAS
Column Address Strobe
SCL
Clock for Presence Detect
WE
Read/Write Input
SDA
Serial Data Out
CKE0
Clock Enable
N.C.
No Connection
–
–
CLK0 - CLK3 Clock Input
*) note : To confirm to this specification, motherboards must pull this pin to high state or no connect.
Address Format
Density Organization Memory SDRAMs
Banks
# of
# of row/bank/ Refresh Period Interval
SDRAMs columns bits
128 MB 16M × 72
1
16M x 8
9
12/2/10
4k
64 ms 15.6 µs
256 MB 32M x 72
1
32M x 4
18
12/2/11
4k
64 ms 15.6 µs
64 ms 7.8 µs
256 MB 32M x 72
1
32M x 8
9
13/2/10
8k
512 MB 64M × 72
1
64M × 4
18
13/2/11
8k
64 ms 7.8 µs
512 MB 64M × 72
1
64M × 8
9
13/2/12
8k
64 ms 7.8 µs
1 GB
2
64M × 4
36
13/2/11
8k
64 ms 7.8 µs
128M x 72
INFINEON Technologies
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1.02
HYS 72Vxx5/6x0GR-7.5
Low Profile PC133 Registered SDRAM-Modules
Pin Configuration
PIN#
Symbol
PIN#
Symbol
PIN#
Symbol
1
PIN# Symbol
VSS
43
VSS
85
VSS
127
VSS
2
3
DQ0
DQ1
44
45
DU
CS2
86
87
DQ32
DQ33
128
129
CKE0
CS3
4
DQ2
46
DQMB2
88
DQ34
130
DQMB6
5
DQ3
47
DQMB3
89
DQ35
131
DQMB7
6
7
VDD
DQ4
48
49
DU
VDD
90
91
VDD
DQ36
132
133
N.C.
VDD
8
DQ5
50
N.C.
92
DQ37
134
N.C.
9
DQ6
51
N.C.
93
DQ38
135
N.C.
10
11
DQ7
DQ8
52
53
CB2
CB3
94
95
DQ39
DQ40
136
137
CB6
CB7
12
VSS
54
VSS
96
VSS
138
VSS
13
DQ9
55
DQ16
97
DQ41
139
DQ48
14
15
DQ10
DQ11
56
57
DQ17
DQ18
98
99
DQ42
DQ43
140
141
DQ49
DQ50
16
DQ12
58
DQ19
100
DQ44
142
DQ51
17
DQ13
59
VDD
101
DQ45
143
VDD
18
19
VDD
DQ14
60
61
DQ20
N.C.
102
103
VDD
DQ46
144
145
DQ52
N.C.
20
DQ15
62
DU
104
DQ47
146
DU
21
CB0
63
N.C.
105
CB4
147
REGE
22
23
CB1
VSS
64
65
VSS
DQ21
106
107
CB5
VSS
148
149
VSS
DQ53
24
N.C.
66
DQ22
108
N.C.
150
DQ54
25
N.C.
67
DQ23
109
N.C.
151
DQ55
26
27
VDD
WE
68
69
VSS
DQ24
110
111
VDD
CAS
152
153
VSS
DQ56
28
DQMB0
70
DQ25
112
DQMB4
154
DQ57
29
DQMB1
71
DQ26
113
DQMB5
155
DQ58
30
31
CS0
DU
72
73
DQ27
VDD
114
115
CS1
RAS
156
157
DQ59
VDD
32
VSS
74
DQ28
116
VSS
158
DQ60
33
A0
75
DQ29
117
A1
159
DQ61
34
35
A2
A4
76
77
DQ30
DQ31
118
119
A3
A5
160
161
DQ62
DQ63
36
A6
78
VSS
120
A7
162
VSS
37
A8
79
CLK2
121
A9
163
CLK3
38
39
A10 (AP)
BA1
80
81
N.C.
WP
122
123
BA0
A11
164
165
N.C.
SA0
40
VDD
82
SDA
124
VDD
166
SA1
41
VDD
83
SCL
125
CLK1
167
SA2
42
CLK0
84
VDD
126
A12
168
VDD
INFINEON Technologies
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1.02
HYS 72Vxx5/6x0GR-7.5
Low Profile PC133 Registered SDRAM-Modules
RCS0
RDQMB0
DQ0-DQ7
CS
DQM
DQ0-DQ7
D0
RDQMB4
DQ32-DQ39
CS
DQM
DQ0-DQ7
D4
RDQMB1
DQ8-DQ15
CS
DQM
DQ0-DQ7
D1
RDQMB5
DQ40-DQ47
CS
DQM
DQ0-DQ7
D5
CS WE
DQM
DQ0-DQ7
D8
RCB0-RCB7
RCS2
RDQMB2
DQ16-DQ23
CS
DQM
DQ0-DQ7
D2
RDQMB4
DQ48-DQ55
CS
DQM
DQ0-DQ7
D6
RDQMB3
DQ24-DQ31
CS
DQM
DQ0-DQ7
D3
RDQMB7
DQ56-DQ63
CS
DQM
DQ0-DQ7
D7
VC C
E 2 PROM
(256 word x 8 Bit)
SA0
SA0
SA1
SA1 SDA
SA2
SA2
WP
SCL
SCL
D0-D8, Reg., DLL
C
VS S
D0-D8, Reg., DLL
CLK0
PLL
47 k Ω
SDRAMs D0-D8
12 pF
Notes:
DQ wirding may differ from that
decribed in this drawing;
however DQ/DQB relationship
must be maintained as shown
2)
All resistors are 10 Ω unless
otherwise noted
* ) A12 is only for 32 M x 72 & 64Mx72
organisation
Register
1)
CS0/CS2
DQMB0-7
BA0, BA1
A0-A11,12* )
RAS
CAS
CKE0
WE
RCS0/RCS2
RDQMB0-7
RBA0, RBA1
RA0-11,12
RRAS
RCAS
RCKE0
RWE
SDRAMs
SDRAMs
SDRAMs
SDRAMs
SDRAMs
SDRAMs
D0-D8
D0-D8
D0-D8
D0-D8
D0-D8
D0-D8
CLK1, CLK2, CLK3
REGE
10 kΩ
VC C
12 pF
reg_1U_1
Block Diagram: One Bank 16M x72, 32M x 72 and 64M × 72 Modules
HYS72V16600, HYS72V32600 & HYS72V64601GR using x8 organized SDRAMs (RawCard F)
INFINEON Technologies
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1.02
HYS 72Vxx5/6x0GR-7.5
Low Profile PC133 Registered SDRAM-Modules
RCS0
RDQMB0
RDQMB4
DQ0-DQ3
DQM
CS
DQ0-DQ3
D0
DQ32-DQ35
DQM
CS
DQ0-DQ3
D8
DQ4-DQ7
DQM
CS
DQ0-DQ3
D1
DQ36-DQ39
DQM
CS
DQ0-DQ3
D9
RDQMB1
RDQMB5
DQM
DQ0-DQ3
DQ40-DQ43
DQM
CS
DQ0-DQ3
D10
DQ12-DQ15
CS
DQM
DQ0-DQ3
D3
DQ44-DQ47
CS
DQM
DQ0-DQ3
D11
CB0-CB3
DQM
CS
DQ0-DQ3
D16
CB4-CB7
DQM
CS
DQ0-DQ3
D17
DQ8-DQ11
D2
RCS2
RDQMB2
RDQMB6
DQ16-DQ19
DQM
CS
DQ0-DQ3
D4
DQ48-DQ51
DQM
CS
DQ0-DQ3
D12
DQ20-DQ23
CS
DQM
DQ0-DQ3
D5
DQ52-DQ55
CS
DQM
DQ0-DQ3
D13
RDQMB3
RDQMB7
DQ24-DQ27
CS
DQM
DQ0-DQ3
D6
DQ56-DQ59
CS
DQM
DQ0-DQ3
D14
DQ28-DQ31
CS
DQM
DQ0-DQ3
D7
DQ60-DQ63
CS
DQM
DQ0-DQ3
D15
CLK0
PLL
CS0/CS2
DQMB0-7
BA0, BA1
A0-A11, A12
RAS
CAS
CKE0
WE
Register
12 pF
SDRAMs D0-D17
CLK1, CLK2, CLK3
RCS0/RCS2
RDQMB0-7
RBA0, RBA1
RA0-RA11, RA12
RRAS
RCAS
RCKE0
RWE
12 pF
SDRAMs D0-D17
SDRAMs D0-D17
SDRAMs D0-D17
SDRAMs D0-D17
SDRAMs D0-D17
SDRAMs D0-D17
REGE
10 k Ω
SA0
SA1
SA2
SCL
E 2PROM
(256 word x 8 Bit)
SA0
SA1 SDA
WP
SA2
SCL
V CC
47 k Ω
D0-D17, Reg., DLL
C
V SS
D0-D17, Reg., DLL
1)
DQ wirding may differ from that decribed
in this drawing; however DQ/DQB relationship
must be maintained as shown
2)
All resistors are 10 Ω unless otherwise noted
V CC
SPB04135
Block Diagram: One Bank 32M x 72 and 64M x 72 Modules
HYS72V32501GR and HYS72V64500GR with x4 components (RawCard G)
INFINEON Technologies
6
1.02
HYS 72Vxx5/6x0GR-7.5
Low Profile PC133 Registered SDRAM-Modules
RCS0
RCS1
RDQMB0
RDQMB4
DQ0-DQ3
CS
DQM
DQ0-DQ3
D0
CS
DQM
DQ0-DQ3
D0
DQ32-DQ35
DQM CS
DQ0-DQ3
D8
CS
DQM
DQ0-DQ3
D8
DQ4-DQ7
DQM
CS
DQ0-DQ3
D1
DQM
CS
DQ0-DQ3
D1
DQ36-DQ39
DQM CS
DQ0-DQ3
D9
DQM
CS
DQ0-DQ3
D9
DQ8-DQ11
DQM
CS
DQ0-DQ3
D2
DQM
CS
DQ0-DQ3
D2
DQ40-DQ43
DQM CS
DQ0-DQ3
D10
DQM
CS
DQ0-DQ3
D10
DQ12-DQ15
CS
DQM
DQ0-DQ3
D3
CS
DQM
DQ0-DQ3
D3
DQ44-DQ47
DQM CS
DQ0-DQ3
D11
CS
DQM
DQ0-DQ3
D11
CB0-CB3
CS
DQM
DQ0-DQ3
D16
CS
DQM
DQ0-DQ3
D16
CB4-CB7
DQM CS
DQ0-DQ3
D17
DQM
CS
DQ0-DQ3
D17
DQ16-DQ19
DQM
CS
DQ0-DQ3
D4
DQM
CS
DQ0-DQ3
D4
DQ48-DQ51
DQM CS
DQ0-DQ3
D12
DQM
CS
DQ0-DQ3
D12
DQ20-DQ23
DQM
CS
DQ0-DQ3
D5
DQM
CS
DQ0-DQ3
D5
DQ52-DQ55
DQM CS
DQ0-DQ3
D13
CS
DQM
DQ0-DQ3
D13
DQ24-DQ27
DQM
CS
DQ0-DQ3
D6
DQM
CS
DQ0-DQ3
D6
DQ56-DQ59
DQM CS
DQ0-DQ3
D14
CS
DQM
DQ0-DQ3
D14
DQ28-DQ31
DQM
CS
DQ0-DQ3
D7
DQM
CS
DQ0-DQ3
D7
DQ61-DQ63
DQM CS
DQ0-DQ3
D15
DQM
CS
DQ0-DQ3
D15
RDQMB1
RDQMB5
RCS2
RCS3
RDQMB2
RDQMB6
RDQMB3
CLK0
RDQMB7
PLL
Stacked SDRAMs D0-D17
CLK1, CLK2, CLK3
CS0-CS3
DQMB0-7
BA0, BA1
A0-A11, A12* )
RAS
CAS
CKE0
WE
REGE
10 k Ω
V CC
Register
12 pF
RCS0-RCS3
RDQMB0-7
RBA0, RBA1
RA0-RA11
RRAS
RCAS
RCKE0
RWE
*)
12 pF
Stacked SDRAMs D0-D17
Stacked SDRAMs D0-D17
Stacked SDRAMs D0-D17
Stacked SDRAMs D0-D17
Stacked SDRAMs D0-D17
Stacked SDRAMs D0-D17
E 2PROM
(256 word x 8 Bit)
SA0
SA0
SA1
SA1 SDA
SA2
SA2
WP
SCL
SCL
V CC
47 k Ω
D0-D17, Reg. DLL
C
V SS
D0-D17, Reg. DLL
1.)
DQ wirding may differ from that decribed
in this drawing; however DQ/DQB relationship
must be maintained as shown
2.) All resistors are 10 Ω unless otherwise noted
A12 is only used for
128 M x 72 organisation
SPB04136
Block Diagram: Two Bank 128M x 72 Modules HYS72V128520GR with x4 components
(RawCard G)
INFINEON Technologies
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1.02
HYS 72Vxx5/6x0GR-7.5
Low Profile PC133 Registered SDRAM-Modules
Absolute Maximum Ratings
Parameter
Symbol
Limit Values
Unit
min.
max.
Input / Output voltage relative to VSS
VIN, VOUT
– 1.0
4.6
V
Power supply voltage on V DD
VDD
– 1.0
4.6
V
Storage temperature range
TSTG
-55
+150
o
Power dissipation (per SDRAM component)
PD
–
1
W
Data out current (short circuit)
IOS
–
50
mA
C
Permanent device damage may occur if “Absolute Maximum Ratings” are exceeded.
Functional operation should be restricted to recommended operation conditions.
Exposure to higher than recommended voltage for extended periods of time affect device reliability
DC Characteristics
TA = 0 to 70 °C 1); VSS = 0 V; VDD = 3.3 V ± 0.3 V
Parameter
Symbol
Limit Values
min.
Unit
max.
Input High Voltage
VIH
2.0
VDD + 0.3
V
Input Low Voltage
VIL
– 0.5
0.8
V
Output High Voltage (I OUT = – 4.0 mA)
VOH
2.4
–
V
Output Low Voltage (IOUT = 4.0 mA)
VOL
–
0.4
V
Input Leakage Current, any input
(0 V < VIN < 3.6 V, all other inputs = 0 V)
II(L)
– 10
10
µA
Output Leakage Current
IO(L)
– 10
10
µA
(DQ is disabled, 0 V < VOUT < VDD)
Capacitance
TA = 0 to 70 °C 1); VDD = 3.3 V ± 0.3 V, f = 1 MHz
Parameter
Symbol
Limit Values
Unit
One Bank Two Bank
Modules Modules
Input Capacitance
(all inputs except CLK and CKE)
CIN
10
20
pF
Input Capacitance (CLK)
CCLK
30
30
pF
Input Capacitance (CKE)
CCKE
17
30
pF
Input/Output Capacitance
(DQ0 - DQ63, CB0 - CB7)
CIO
10
17
pF
Input Capacitance (SCL, SA0 - 2)
CSC
8
8
pF
Input/Output Capacitance (SDA)
CSD
8
8
pF
INFINEON Technologies
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1.02
HYS 72Vxx5/6x0GR-7.5
Low Profile PC133 Registered SDRAM-Modules
Operating Currents per SDRAM Component
TA = 0 to 70 °C 1), VDD = 3.3 V ± 0.3 V
(Recommended Operating Conditions unless otherwise noted)
Parameter
Test Condition Symbol 128Mb 256Mb 512 Mb Unit Note
max.
Operating current
2)
–
tRC = tRC(MIN.), tCK = tCK(MIN.)
ICC1
160
230
270
mA
tCK = min.
ICC2P
1.5
2
4
mA
2)
tCK = min.
ICC2N
40
40
36
mA
2)
CKE ≥ V IH(MIN.)
ICC3N
50
50
35
mA
2)
CKE ≤ V IL(MAX.)
ICC3P
10
10
11
mA
2)
–
ICC4
100
150
255
mA
Outputs open, Burst Length = 4,
CL = 3. All banks operated in
random access, all banks
operated in ping-pong manner
to maximize gapless data
access
Precharge stand-by current
in Power Down Mode
CS = V IH(MIN.), CKE ≤ VIL(MAX.)
Precharge Stand-by Current
in Non-Power Down Mode
CS = V IH (MIN.), CKE ≥ V IH(MIN.)
No operating current
tCK = min., CS = VIH(MIN.),
active state (max. 4 banks)
Burst operating current
tCK = min.,
Read command cycling
2), 3)
–
Auto refresh current
tCK = min.,
Auto Refresh command cycling
ICC5
230
240
440
mA
2)
Self refresh current
–
Self Refresh Mode,CKE = 0.2 V
ICC6
1.5
3
4
mA
2)
INFINEON Technologies
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1.02
HYS 72Vxx5/6x0GR-7.5
Low Profile PC133 Registered SDRAM-Modules
AC Characteristics (SDRAM Device Specification) 4), 5)
TA = 0 to 70 °C 1); VSS = 0 V; VDD = 3.3 V ± 0.3 V, tT = 1 ns
Parameter
Symbol
Limit Values
Unit
Note
-7.5
min.
max.
Clock and Access Time
tCK
Clock Cycle Time
CAS Latency = 3
CAS Latency = 2
–
7.5
10
–
–
ns
ns
–
–
133
100
MHz
MHz
–
–
5.4
6
ns
ns
–
ns
–
fCK
Clock Frequency
CAS Latency = 3
CAS Latency = 2
–
tAC
Access Time from Clock
CAS Latency = 3
CAS Latency = 2
–
Clock High Pulse Width
tCH
2.5
Clock Low Pulse Width
tCL
2.5
–
ns
–
Transition Time
tT
0.5
10
ns
–
Input Setup Time
tIS
1.5
–
ns
–
Input Hold Time
tIH
0.8
–
ns
–
Power Down Mode Entry Time
tSB
–
1
CLK
–
Power Down Mode Exit Setup Time
tPDE
1
–
CLK
–
Mode Register Setup Time
tRCS
2
–
CLK
–
Row to Column Delay Time
tRCD
20
–
ns
–
Row Precharge Time
tRP
20
–
ns
–
Row Active Time
tRAS
45
100k
ns
–
Row Cycle Time
tRC
67.5
–
ns
–
Setup and Hold Parameters
Common Parameters
Activate (a) to Activate (b) Command Period
tRRD
2
–
CLK
–
CAS(a) to CAS(b) Command Period
tCCD
1
–
CLK
–
INFINEON Technologies
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HYS 72Vxx5/6x0GR-7.5
Low Profile PC133 Registered SDRAM-Modules
AC Characteristics (SDRAM Device Specification) (cont’d)
4), 5)
TA = 0 to 70 °C 1); VSS = 0 V; VDD = 3.3 V ± 0.3 V, tT = 1 ns
Parameter
Symbol
Limit Values
Unit
Note
-7.5
min.
max.
Refresh Cycle
tREF
Refresh Period
128MBit SDRAM Based Modules
256 & 512MBit SDRAM Based Modules
–
µs
µs
–
–
15.6
7.8
tSREX
1
–
CLK
6)
Data Out Hold Time
tOH
3
–
ns
–
Data Out to Low Impedance Time
tLZ
0
–
ns
7)
Data Out to High Impedance Time
tHZ
3
7
ns
7)
DQM Data Out Disable Latency
tDQZ
–
2
CLK
–
Data Input to Precharge
(write recovery)
tWR
2
–
CLK
–
DQM Write Mask Latency
tDQW
0
–
CLK
–
INFINEON Technologies
11
Self Refresh Exit Time
Read Cycle
Write Cycle
1.02
HYS 72Vxx5/6x0GR-7.5
Low Profile PC133 Registered SDRAM-Modules
Notes
1. The registered DIMM modules are designed to operate under system operating conditions
between 0-55 deg C ambient, maximum sustained bandwidth and 0 LFM airflow. Operating at
higher ambient temperatures needs sufficient air flow to limit the case temperature of the
SDRAM components do not exceed 85oC.
2. These parameters depend on the cycle rate. All values are measured at 133 MHz operation
frequency. Input signals are changed once during tck excepts for Icc6 and for standby currents
when tck = infinity.
3. These parameters are measured with continous data stream during read access and all DQ
toggling. CL=3 and BL=4 is assumed and the data-out current is excluded.
4. An initial pause of 100 µ s is required after power-up. Then a Precharge All Banks command must
be given followed by eight Auto Refresh (CBR) cycles before the Mode Register Set Operation
can begin. Also the on-DIMM PLL must be given enough clock cycles to stabilize (tSTAB ) before
any operation can be guaranteed.
5. AC timing tests have VIL = 0.8 V and VIH = 2.0 V with the timing referenced to the 1.4 V crossover
point. The transition time is measured between V IH and VIL. All AC measurements assume
tT = 1 ns with the AC output load circuit shown. Specified tAC and tOH parameters are measured
with a 50 pF only, without any resistive termination and with a input signal of 1 V/ns edge rate
between 0.8 V and 2.0 V.
6. Self Refresh Exit is a synchronous operation and begins on the second positive clock edge after
CKE returns high. Self Refresh Exit is not complete until a time period equal to tRC is satisfied
after the Self Refresh Exit command is registered.
7. Referenced to the time at which the output achieves the open circuit condition, not to output
voltage levels.
t CH
2.4 V
0.4 V
CLOCK
t CL
t SETUP
tT
t HOLD
1.4 V
INPUT
t AC
t LZ
t AC
I/O
t OH
50 pF
OUTPUT
1.4 V
Measurement conditions for
tAC and tOH
t HZ
SPT03404
Serial Presence Detect
A serial presence detect storage device - E 2PROM 34C02 - is assembled onto the module.
Information about the module configuration, speed, etc. is written into the E2PROM device during
module production using a serial presence detect protocol (I2C synchronous 2-wire bus).
INFINEON Technologies
12
1.02
HYS 72Vxx5/6x0GR-7.5
Low Profile PC133 Registered SDRAM-Modules
SPD-Table for -7.5 Registered DIMM Modules
2
Memory Type
SDRAM
3
4
5
Number of Row Addresses )
Number of Column Addresses
Number of DIMM Banks
12/13
10/11/12
1,2
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
Module Data Width
Module Data Width (cont’d)
Module Interface Levels
Cycle Time at CL = 3
Access Time from Clock at CL = 3
DIMM Config (Error Det/Corr.)
Refresh Rate/Type
SDRAM Width, Primary
Error Checking SDRAM Data Width
Minimum tCCD
Burst Length Supported
Number of SDRAM Banks
SDRAM Supported CAS Latencies
SDRAM CS Latencies
SDRAM WE Latencies
SDRAM DIMM Module Attributes
22
SDRAM Device Attributes
23
24
Min. Clock Cycle Time at CL = 2
Max. Access Time from Clock for
CL = 2
Min. Clock Cycle Time at CL = 1
72
0
LVTTL
7.5 ns
5.4 ns
ECC
15.6/7.8 µs
x4, x8
x4, x8
1 CLK
1, 2, 4, 8
4
2&3
0
0
Registered
with PLL
VDD tol +/–
10%
10 ns
6.0
25
26
27
28
29
30
31
Max. Access Time from Clock at
CL = 1
SDRAM Minimum tRP
SDRAM Minimum tRRD
SDRAM Minimum tRCD
SDRAM Minimum tRAS
Module Bank Density (per bank)
32
33
34
SDRAM Input Setup Time
SDRAM Input Hold Time
SDRAM Data Input Setup Time
INFINEON Technologies
0D
0A
02
0D
0C
0D
0B
01
02
82
08
08
82
08
08
82
04
04
512 MB
2 Banks
512 MB
1 Bank*)
256 MB
1 Bank2)
128
256
1 GB
2 Banks
Number of SPD Bytes
Total Bytes in Serial PD
512 MB
1 Bank**)
0
1
Hex
256 MB
1 Bank1)
SPD
Entry
Value
128 MB
1 Bank
Byte# Description
80
08
0C
0A
01
80
08
08
0C
0B
01
80
04
04
0D
0A
01
82
08
08
13
48
00
01
75
54
02
82
04
04
01
0F
04
06
01
01
1F
0E
A0
60
not
supported
not supp.
20 ns
15 ns
20 ns
45 ns
128 M/
256M/
512 MB
1.5 ns
0.8 ns
1.5 ns
04
0D
0B
01
00
00
20
40
40
14
0F
14
2D
80
40
80
80
15
08
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1.02
HYS 72Vxx5/6x0GR-7.5
Low Profile PC133 Registered SDRAM-Modules
SPD-Table for -7.5 Registered DIMM Modules (cont’d)
0.8 ns
–
JEDEC 2
–
512 MB
2 Banks
512 MB
1 Bank*)
256 MB
1 Bank2)
256 MB
1 Bank1)
1 GB
2 Banks
62
63
64
65-71
72
73-90
91-92
93-94
95-98
99-125
126
SDRAM Data Input Hold Time
Superset Information(may be used in
future)
SPD Revision
Checksum for Bytes 0 - 62
Manufacturers JEDEC ID Code
Manufacturer
Module Assembly Location
Module Part Number
Module Revision Code
Module Manufacturing Date
Module Serial Number
Hex
512 MB
1 Bank**)
35
36-61
SPD
Entry
Value
128 MB
1 Bank
Byte# Description
BD
BD
08
00
60
79
12
BC
84
C1
INFINEO(N)
83
Frequency Specification
–
64
127
Details of Clocks
–
8F
128255
Open for Customer Use
–
Note: 1) HYS72V32501GR-7.5 (128Mbit x4 based), 2) HYS72V32600GR-7.5 (256Mbit x8 based)
*) HYS72V64500GR-7.5 (256Mbit based) **) HYS72V64601GR-7.5 (512Mbit based)
INFINEON Technologies
14
1.02
HYS 72Vxx5/6x0GR-7.5
Low Profile PC133 Registered SDRAM-Modules
Package Outlines Raw Card F
Module Package
JEDEC MO-161
Registered DIMM Modules (Raw Card F) L-DIM168-51
128MB, 256MB & 512MB modules based on x8 SDRAM components
133.35 ± 0.15
30,4 max.
1,2" max.
127.35
Register
PLL
Register
3
1
10
11
6.35
3
1.27
40
41
6.35
84
42.18
66.68
3.125
2
94
95
124
125
168
4 ±0.1
17.78
85
non-stacked:
stacked:
4 max.
6.8 max.
2.55
0.2
Detail of Contacts
+0.5
1
1.27 ± 0.1
1.27± 0.1
1.27
note: all outline dimensions and tolerances are in accordance with the JEDEC standard
INFINEON Technologies
15
1.02
HYS 72Vxx5/6x0GR-7.5
Low Profile PC133 Registered SDRAM-Modules
Package Outlines Raw Card G
Module Package
JEDEC MO-161
Registered DIMM Modules (Raw Card G) L-DIM168-52
133.35 ± 0.15
30,4 max.
1,2" max.
127.35
Register
Register
3
1
10
11
6.35
3
1.27
40
41
6.35
84
42.18
2
85
94
95
124
17.78
3.125
66.68
125
168
Register
4 ± 0.1
PLL
non-stacked:
stacked:
4 max.
6.8 max.
2.55
0.2
Detail of Contacts
+0.5
1
1.27 ± 0.1
1.27± 0.1
1.27
L-DIM-168-52
note: all outline dimensions and tolerances are in accordance with the JEDEC standard
INFINEON Technologies
16
1.02
HYS 72Vxx5/6x0GR-7.5
Low Profile PC133 Registered SDRAM-Modules
Functional Description
All these PC133 168-pin Registered DIMMs conform to a compatible set of timing and operation
characteristics intended to comply with the 133 MHz standards. The Registered DIMMs achieve
high speed data transfer rate up to 133 MHz, when in “registered mode”. The “registered mode” is
achieved when the REGE input signal is in “high” state or the pin is not connected. Operation in
“buffered mode” (REGE = “low”) needs careful system design to compensate all input signals for the
extra delay time of the register components when in “buffered mode”. “Buffered mode” is limited to
66 Mhz operation and is beyond the scope of this datasheet.
Registered Mode:
All control and address signals are synchronized with the positive edge of externally supplied clocks
and are registered on-DIMM and hence delayed by one clock cycle in arriving at the SDRAM
devices. The use of the on-board register reduces the capacitive loading of the DIMM on input
control and address signals. The SDRAM device data lines (DQ) are connected directly to the DIMM
tabs through 10 Ohm series resistors. All the following timing diagrams and explanations show
DIMM operation at the tabs, not SDRAM operation.
The picture below depicts an overview of the effect of the Registered Mode on the data outputs
(DQs) for a Read operation. Without the registers, the data is delayed according to the device CAS
latency, in the case two clocks. With the register, the data is delayed according to the device CAS
latency plus an additional clock cycle. This is known as the DIMM CAS latency, and in this example
is four three. The data path can be thought of as a pipeline in which the register effectively lengthens
the pipe by one clock cycle.
Registered DIMM Burst Read Operation (BL = 4)
T0
T1
T2
T3
T4
T5
T6
Read A
NOP
NOP
NOP
NOP
NOP
NOP
CLK
Command
Device
CAS latency = 2
t CK2 , DQ’s
DIMM
CAS latency = 3
t CK3 , DQ’s
DOUT A0 DOUT A1 DOUT A2 DOUT A3
DOUT A0 DOUT A1 DOUT A2 DOUT A3
Added for on-DIMM pipeline register
One Clock Reg-DIMM Latency = 1
SPT03968
In case of a Burst Write Command the data-in is delayed one clock due the op-DIMM pipeline
register also. Therefore, data for the first Burst Write cycle must be applied on the DQ pins on the
next clock cycle after the Write command is issued. the remaining data inputs must be supplied on
INFINEON Technologies
17
1.02
HYS 72Vxx5/6x0GR-7.5
Low Profile PC133 Registered SDRAM-Modules
each subsequent rising clock edge until the burst length is completed. When the burst has finished,
any additional data supplied to the DQ pins will be ignored.
T0
T1
T2
T3
T4
T5
T6
T7
T8
NOP
Write A
NOP
NOP
NOP
NOP
NOP
NOP
NOP
DIN A0
DIN A1
DIN A2
DIN A3
don’t care
CLK
Command
DQ’s
The first data element and the Write
are registered on the next clock edge
Reg-DIMM Latency = 1 CLK
Extra data is ignored after
termination of a Burst.
SPT03969
Registered DIMM Burst Write Operation (BL = 4)
INFINEON Technologies
18
1.02
HYS 72Vxx5/6x0GR-7.5
Low Profile PC133 Registered SDRAM-Modules
INFINEON Technologies
19
1.02
HYS 72Vxx5/6x0GR-7.5
Low Profile PC133 Registered SDRAM-Modules
Change List
12.00
18.1.2001
23.1.2001
Rev. 0.1
Rev. 0.1
Rev. 0.1
12.02.2001
19.02.2001
27.02.2001
04.04.2001
11.04.2001
Rev.0.2
Rev. 0.3
Rev. 0.4
Rev. 0.5
Rev. 0.5b
29.05.2001
21.06.2001
28.06.2001
Rev. 0.6
Rev. 0.7
Rev. 0.8
06.09.2001
17.12.2001
Rev. 0.9
Final 1.0
INFINEON Technologies
First revision
Clarification of “buffered mode”operation (not tested)
Height reduced from 1.2” (nominal) to 1.155” (max) according to the
lastest IBM drawings for RawCard F
PM decided to stay with 1.2” inch height
New PCB L-DIM-168-56 with 1.125” height
Both Gerber Files (1,125” and 1.2”) are now in the target datasheet
x4 based modules on L-DIM-168-52 added
Info from Mr. Pammer AIT Rgb: L-DIM-168-51 is based on Raw Card A and
L-DIM-168-52 is based on Raw Card B
Block Diagram for stacked x8 module changed for use of x8 stacks with one
CKE and two CS
HYS72V32501GR-7.5 (128Mbit x4 based 256MByte) added
Outline Drawings changed to L-DIM-168-51,52 & 56
Product Marketing Decision : Remove all 1,125” inch modules
Datasheet changed from “target” to “preliminary”
RawCards and therefore the Compliance Code changed according to
JEDEC naming conventions, RawCard F for x8 and RawCard G for x4 (nonstackd and stacked)
SCR: Thickness of modules changed from 4 to 4 max and 6.4 to 6.8 max
SCR-028-2001-11-12 PC133 / TPCR_08 / JC42.5 Item 1138.5 :
JEDEC changed Byte 62h (SPD Revision) from 02h to 12h
Checksum changed therefore also
20
1.02