240pin Fully Buffered DDR2 SDRAM DIMMs based on 512 Mb F-ver. This Hynix's Fully Buffered DIMM is a high-bandwidth & large capacity channel solution that has a narrow host interface. Hynix's FB-DIMM features novel architecture including the Advanced Memory Buffer that isolates the DDR2 SDRAMs from the channel. This single component located in the front side center of each DIMM, acts as a repeater and buffer for all signals and commands which are exchanged between the host controller and the DDR2 SDRAMs including data in and output. The AMB communicates with the host controller and adjacent DIMMs on a system board using an industry standard Differential Point to Point Link Interface at 1.5V power. The AMB also allows buffering of memory traffic to support large memory capacities. All memory control for the DDR2 SDRAM devices resides in the host, including memory request initiation, timing, refresh, scrubbing, sparing, configuration access and power management. The AMB interface is responsible for handling channel and memory requests to and from the local FBDIMM and for forwarding request to other FBDIMMs on the memory channel. FEATURES * 240 pin Fully Buffered ECC dual In-Line DDR2 SDRAM Module * JEDEC standard Double Data Rate2 Synchronous DRAMs (DDR2 SDRAMs) with 1.8V +/- 0.1V Power Supply * All inputs and outputs are compatible with SSTL_1.8 interface * Built with 512Mb DDR2 SDRAMs in 60ball FBGA * Host interface and AMB component industry standard compliant * MBIST & IBIST test functions * 4 Bank architecture * OCD (Off-Chip Driver Impedance Adjustment) * ODT (On-Die Termination) * Fully differential clock operations (CK & CK) * Programmable Burst Length 4 / 8 with both sequential and interleave mode * Auto refresh and self refresh supported * 8192 refresh cycles / 64ms * Serial presence detect with EEPROM * 133.35 x 30.35 mm form factor * RoHS compliant * Full Module Heat Spreader This document is a general product description and is subject to change without notice. Hynix Semiconductor does not assume any responsibility for use of circuits described. No patent licenses are implied. Rev 1.2 / Feb. 2009 1 1240pin Fully Buffered DDR2 SDRAM DIMMs ORDERING INFORMATION Part Name Density HMP564F7FFP8C-C4/Y5N3 HMP564F7FFP8C-C4/Y5/S5/S6D3 Org. # of # of DRAMs ranks 512MB 64Mx72 9 1 1GB 128Mx72 18 2 2GB 256Mx72 36 2 HMP512F7FFP8C-C4/Y5N3 HMP512F7FFP8C-C4/Y5/S5/S6D3 HMP525F7FFP4C-C4/Y5N3 HMP525F7FFP4C-C4/Y5D3 AMB H. S type Height Full Module 30.35mm Vendor Version Intel D1 IDT C1 Intel D1 IDT C1 Intel D1 IDT C1 Note: *: The 16th and 17th digits stand for AMB vendor and revision. SPEED GRADE & KEY PARAMETERS Speed Grade C4 Y5 S5/6 DDR2 533 4-4-4 DDR2 667 5-5-5 DDR2 800 5-5-5 / 6-6-6 PC2 4200 PC2 5300 PC2 6400 FB-DIMM Peak Channel Throughput 6.4 8.0 9.6 GByte/S FB-DIMM Link Transfer Rate 3.2 4.0 4.8 GT/s DDR2 DRAM Speed Grade FB-DIMM Speed Grade Unit ADDRESS TABLE Density Org. Ranks SDRAMs # of DRAMs 512MB 64M x 72 1 64Mbx8 9 14(A0~A13)/2(BA0~BA1)/10(A0~A9) 8K / 64ms 1GB 128M x 72 2 64Mbx8 18 14(A0~A13)/2(BA0~BA1)/10(A0~A9) 8K / 64ms 2GB 256M x 72 2 128Mbx4 36 14(A0~A13)/2(BA0~BA1) 11(A0~A9,A11) 8K / 64ms Rev 1.2 / Feb. 2009 # of row/bank/column Address Refresh Method 2 1240pin Fully Buffered DDR2 SDRAM DIMMs Input/Output Functional Description Pin Name type Polarity SCK Input Positive System clock input 1 SCK Input Negative System clock input 1 PN[13:0] Output Positive Primary Northbound Data 14 PN[13:0] Output Negative Primary Northbound Data 14 PS[9:0] Input Positive Primary Southbound Data 10 PS[9:0] Input Negative Primary Southbound Data 10 SN[13:0] Output Positive Secondary Northbound Data 14 SN[13:0] Output Negative Secondary Northbound Data 14 SS[9:0] Input Positive Secondary Southbound Data 10 SS[9:0] Input Negative Secondary Southbound Data 10 SCL Input - Serial Presence Detect (SPD) Clock Input 1 SDA Input / Output - SPD Data Input / Output 1 SA[2:0] Input - SPD Address inputs, also used to select the DIMM number in the AMB 3 VID[1:0] Input - Voltage ID: These pins must be unconnected for DDR2-based Fully buffered DIMMs 2 RESET Input Active Low AMB reset signal 1 RFU - - Reserved for Future Use 16 VCC Supply +1.5V AMB Core Power and AMB channel Interface Power(1.5volt) 8 VDD Supply +1.8V DRAM Power and AMB DRAM I/O Power 24 VTT Supply +0.9V DRAM Address/Command/Clock Termination Power(VDD/2) 4 VDDSPD Supply +3.3V SPD Power 1 VSS Supply Ground 80 The DNU/M_Test pin provides an external connection on R/Cs A-D for testing the margin of Vref which is produced by a voltage divider on the module. It is not intended to be used in normal system operation and must not be connected(DNU) in a system. This test pin may have other features on future card designs and if it does, will be included in this specification at that time. 1 Total 240 DNU/ M_Test - / Analog Rev 1.2 / Feb. 2009 - / 0.9V Function Description Count 3 1240pin Fully Buffered DDR2 SDRAM DIMMs PIN ASSIGNMENT Pin Name Pin Name Pin Name Pin Name Pin Name Pin Name 1 VDD 41 PN13 81 VSS 121 VDD 161 SN13 201 VSS 2 VDD 42 VSS 82 PS4 122 VDD 162 VSS 202 SS4 3 VDD 43 VSS 83 PS4 123 VDD 163 VSS 203 SS4 4 VSS 44 RFU* 84 VSS 124 VSS 164 RFU* 204 VSS 5 VDD 45 RFU* 85 VSS 125 VDD 165 RFU* 205 VSS 6 VDD 46 VSS 86 RFU* 126 VDD 166 VSS 206 RFU* 7 VDD 47 VSS 87 RFU* 127 VDD 167 VSS 207 RFU* 8 VSS 48 PN12 88 VSS 128 VSS 168 SN12 208 VSS 9 VCC 49 PN12 89 VSS 129 VCC 169 SN12 209 VSS 10 VCC 50 VSS 90 PS9 130 VCC 170 VSS 210 SS9 11 VSS 51 PN6 91 PS9 131 VSS 171 SN6 211 SS9 VSS 12 VTT 52 PN6 92 VSS 132 VCC 172 SN6 212 13 VCC 53 VSS 93 PS5 133 VCC 173 VSS 213 SS5 14 VSS 54 PN7 94 PS5 134 VSS 174 SN7 214 SS5 15 VTT 55 PN7 95 VSS 135 VTT 175 SN7 215 VSS 16 VID1 56 VSS 96 PS6 136 VID0 176 VSS 216 SS6 17 RESET 57 PN8 97 PS6 137 DNU/M_Test 177 SN8 217 SS6 18 VSS 58 PN8 98 VSS 138 VSS 178 SN8 218 VSS 19 RFU** 59 VSS 99 PS7 139 RFU** 179 VSS 219 SS7 20 RFU** 60 PN9 100 PS7 140 RFU** 180 SN9 220 SS7 21 VSS 61 PN9 101 VSS 141 VSS 181 SN9 221 VSS 22 PN0 62 VSS 102 PS8 142 SN0 182 VSS 222 SS8 23 PN0 63 PN10 103 PS8 143 SN0 183 SN10 223 SS8 24 VSS 64 PN10 104 VSS 144 VSS 184 SN10 224 VSS 25 PN1 65 VSS 105 RFU** 145 SN1 185 VSS 225 RFU* 26 PN1 66 PN11 106 RFU** 146 SN1 186 SN11 226 RFU* 27 VSS 67 PN11 107 VSS 147 VSS 187 SN11 227 VSS 28 PN2 68 VSS 108 VDD 148 SN2 188 VSS 228 SCK 29 PN2 109 VDD 149 SN2 229 SCK 30 VSS 69 VSS 110 VSS 150 VSS 189 VSS 230 VSS 31 PN3 70 PS0 111 VDD 151 SN3 190 SS0 231 VDD Key Key 32 PN3 71 PS0 112 VDD 152 SN3 191 SS0 232 VDD 33 VSS 72 VSS 113 VDD 153 VSS 192 VSS 233 VDD 34 PN4 73 PS1 114 VSS 154 SN4 193 SS1 234 VSS 35 PN4 74 PS1 115 VDD 155 SN4 194 SS1 235 VDD VDD 36 VSS 75 VSS 116 VDD 156 VSS 195 VSS 236 37 PN5 76 PS2 117 VTT 157 SN5 196 SS2 237 VTT 38 PN5 77 PS2 118 SA2 158 SN5 197 SS2 238 VDDSPD 39 VSS 78 VSS 119 SDA 159 VSS 198 VSS 239 SA0 40 PN13 79 PS3 120 SCL 160 SN13 199 SS3 240 SA1 80 PS3 200 SS3 NC= No Connect, RFU= Reserved for Future Use. Note: *: These pin positions are reserved for forwarded clocks to be used in future module implementations **: These pin positions are reserved for future architecture flexibility 1) The following signals are CRC bits and thus appear out of the normal sequence: PN12/ PN12, SN12 / SN12, PN13 / PN13, SN13 / SN13,PS9 / PS9, SS9 / SS9 Rev 1.2 / Feb. 2009 4 1240pin Fully Buffered DDR2 SDRAM DIMMs FUNCTIONAL BLOCK DIAGRAM 512MB(64Mbx72) ECC FB-DIMM /S0 DQS4 /DQS4 DQS13 DQS0 /DQS0 DQS9 DM NU /CS RDQS /RDQS I/O 0 I/O 1 I/O 2 DQ0 DQ1 DQ2 DQ3 DQ4 DQ5 DQ6 DQ7 I/O I/O I/O I/O I/O 3 4 5 6 7 DQS /DQS DQ32 DQ33 DQ34 DQ35 DQ36 DQ37 DQ38 DQ39 D0 DM NU /CS RDQS /RDQS I/O 0 I/O 1 I/O 2 I/O I/O I/O I/O I/O 3 4 5 6 7 DQS /DQS DQ40 DQ41 DQ42 DQ43 DQ44 DQ45 DQ46 DQ47 D1 DM NU /CS RDQS /RDQS I/O 0 I/O 1 I/O 2 I/O I/O I/O I/O I/O 3 4 5 6 7 DQS /DQS DQ48 DQ49 DQ50 DQ51 DQ52 DQ53 DQ54 DQ55 D2 DM NU /CS RDQS /RDQS I/O 0 I/O 1 I/O 2 I/O I/O I/O I/O I/O 3 4 5 6 7 DQS /DQS DQ56 DQ57 DQ58 DQ59 DQ60 DQ61 DQ62 DQ63 D3 All address/command/control/clock V TT DM NU /CS RDQS /RDQS I/O 0 I/O 1 I/O 2 I/O I/O I/O I/O I/O 3 4 5 6 7 WP SDA U0 A0 A1 SA0 SA1 DQS /DQS DQS /DQS DQS /DQS D5 DM NU /CS RDQS /RDQS I/O 0 I/O 1 I/O 2 I/O I/O I/O I/O I/O 3 4 5 6 7 D6 DM NU /CS RDQS /RDQS I/O 0 I/O 1 I/O 2 I/O I/O I/O I/O I/O 3 4 5 6 7 D7 DM NU /CS RDQS /RDQS I/O 0 I/O 1 I/O 2 I/O I/O I/O I/O I/O 3 4 5 6 7 D8 Serial PD SCL /DQS DQS8 /DQS8 DQS17 CB0 CB1 CB2 CB3 CB4 CB5 CB6 CB7 SCL DQS D4 DQS7 /DQS7 DQS16 DQS3 /DQS3 DQS12 DQ24 DQ25 DQ26 DQ27 DQ28 DQ29 DQ30 DQ31 3 4 5 6 7 /DQS DQS6 /DQS6 DQS15 DQS2 /DQS2 DQS11 DQ16 DQ17 DQ18 DQ19 DQ20 DQ21 DQ22 DQ23 I/O I/O I/O I/O I/O DQS DQS5 /DQS5 DQS14 DQS1 /DQS1 DQS10 DQ8 DQ9 DQ10 DQ11 DQ12 DQ13 DQ14 DQ15 DM NU /CS RDQS /RDQS I/O 0 I/O 1 I/O 2 A2 SA2 SDA VTT Terminators VCC AMB VDD SPD Serial PD,AMB VDD DO-D8, AMB VREF DO-D8 VSS DO-D8,SPD, AMB PN0-PN13 /PN0-/PN13 PS0-PS9 /PS0-/PS9 DQ0-DQ63 CB0-CB7 DQS0-DQS17 /DQS0-/DQS8 SCL SDA SA0-SA2 /RESET SCK/ /SCK A M B SN0-SN13 /SN0-/SN13 SS0-SS9 /SS0-/SS9 /S0-/CS(all SDRAMs) CKE0 -> CKE ODT -> ODT BA0-BA2 A0-A15 /RAS /CAS /WE CK/ /CK Notes : 1. DQ-to-I/O wiring may be changed within a byte. 2. There are two physical copies of each address/command/control/clock. Rev 1.2 / Feb. 2009 5 1240pin Fully Buffered DDR2 SDRAM DIMMs FUNCTIONAL BLOCK DIAGRAM 1GB(128Mbx72) ECC FB-DIMM /S 1 /S 0 DQS /D Q S DQS9 DQS5 /D Q S 5 D Q S14 DM N U /C S R D Q S /R D Q S I/O 0 I/O 1 I/O 2 DQ0 DQ1 DQ2 DQ3 DQ4 DQ5 DQ6 DQ7 DQS1 /D Q S 1 D Q S 10 I/O I/ O I/O I/O I/O D Q S /D Q S D0 3 4 5 6 7 DM N U /C S R D Q S /R D Q S I/ O 0 I/ O 1 I/ O 2 I/ O I/O I/ O I/ O I/ O 3 4 5 6 7 D Q S /D Q S D Q 40 D Q 41 D Q 42 D Q 43 D Q 44 D Q 45 D Q 46 DQ 47 D9 DM N U /C S R D Q S /R D Q S I/O 0 I/O 1 I/O 2 I/O I/O I/O I/O I/O 3 4 5 6 7 D Q S /D Q S D5 DM N U /C S R D Q S /R D Q S I/O 0 I/O 1 I/O 2 I/O I/O I/O I/O I/O 3 4 5 6 7 D Q S /D Q S D 14 DQ S6 /D Q S 6 DQ S15 DM N U /C S R D Q S /R D Q S I/O 0 I/O 1 I/O 2 DQ8 DQ 9 D Q 10 D Q 11 D Q 12 D Q 13 D Q 14 DQ 15 I/O I/ O I/O I/O I/O D Q S /D Q S D1 3 4 5 6 7 DM N U /C S R D Q S /R D Q S I/ O 0 I/ O 1 I/ O 2 I/ O I/O I/ O I/ O I/ O 3 4 5 6 7 D Q S /D Q S DQ48 DQ49 DQ50 DQ51 DQ52 DQ53 DQ54 D Q 55 D1 0 z DM N U /C S R D Q S /R D Q S I/O 0 I/O 1 I/O 2 I/O I/O I/O I/O I/O 3 4 5 6 7 D Q S /D Q S D6 DM N U /C S R D Q S /R D Q S I/O 0 I/O 1 I/O 2 I/O I/O I/O I/O I/O 3 4 5 6 7 D Q S /D Q S D 15 DQS7 /D Q S 7 DQ S16 DQS2 /D Q S 2 DQ S11 DM N U /C S R D Q S /R D Q S I/ O 0 I/ O 1 I/ O 2 D Q16 D Q17 D Q18 D Q19 D Q20 D Q21 D Q22 D Q 23 I/ O I/O I/ O I/ O I/ O D Q S /D Q S D2 3 4 5 6 7 DM N U /C S R D Q S /R D Q S I/O 0 I/O 1 I/O 2 I/O I/O I/O I/O I/O D Q S /D Q S D Q 56 D Q 57 D Q 58 D Q 59 D Q 60 D Q 61 D Q 62 D Q 63 D1 1 3 4 5 6 7 DM N U /C S R D Q S /R D Q S I/O 0 I/O 1 I/O 2 I/O I/O I/O I/O I/O 3 4 5 6 7 D Q S /D Q S D7 DM N U /C S R D Q S /R D Q S I/ O 0 I/ O 1 I/ O 2 I/ O I/O I/ O I/ O I/ O 3 4 5 6 7 D Q S /D Q S D 16 DQS8 /D Q S 8 D Q S17 DQS3 /D Q S 3 D Q S12 DM N U /C S R D Q S /R D Q S I/ O 0 I/ O 1 I/ O 2 D Q24 D Q25 D Q26 D Q27 D Q28 D Q29 D Q30 D Q 31 I/ O I/O I/ O I/ O I/ O D Q S /D Q S D3 3 4 5 6 7 DM N U /C S R D Q S /R D Q S I/O 0 I/O 1 I/O 2 I/O I/O I/O I/O I/O D Q S /D Q S C B0 C B1 C B2 C B3 C B4 C B5 C B6 C B7 D1 2 3 4 5 6 7 DM N U /C S R D Q S /R D Q S I/O 0 I/O 1 I/O 2 I/O I/O I/O I/O I/O 3 4 5 6 7 D Q S /D Q S D8 DM N U /C S R D Q S /R D Q S I/ O 0 I/ O 1 I/ O 2 I/ O I/O I/ O I/ O I/ O 3 4 5 6 7 D Q S /D Q S D 17 DQS4 /D Q S 4 D Q S 13 DM N U /C S R D Q S /R D Q S I/O 0 I/O 1 I/O 2 D Q32 D Q33 D Q34 D Q35 D Q36 D Q37 D Q38 DQ 39 I/O I/ O I/O I/O I/O D Q S /D Q S D4 3 4 5 6 7 DM N U /C S R D Q S /R D Q S I/ O 0 I/ O 1 I/ O 2 I/ O I/O I/ O I/ O I/ O 3 4 5 6 7 A ll a d d re s s/ c o m m a n d /c o n tro l/c lo c k S e ria l P D SCL SCL WP SDA U0 A0 A1 A2 SA0 SA1 SA2 SDA D Q S /D Q S D 13 P N 0 -P N 1 3 /P N 0 -/P N 1 3 P S 0 -P S 9 /P S 0 -/P S 9 V TT VTT T e rm in a to rs VCC AMB VDD SPD S e ria l P D ,A M B VDD D O -D 1 7 , A M B VREF D O -D 1 7 VSS D Q 0 -D Q 6 3 C B 0 -C B 7 D Q S 0 -D Q S 1 7 /D Q S 0 -/D Q S 8 D O -D 1 7 ,S P D , A M B SCL SDA S A 0 -S A 2 /R ES ET S C K , /S C K A M B S N 0 -S N 1 3 /S N 0 -/S N 1 3 S S 0 -S S 9 /S S 0 -/S S 9 /S 0 -/ C S (D 0 -D 8 ) C K E 0 -> C K E (D 0 -D 8 ) /S 1 -/ C S (D 9 -D 1 7 ) C K E 1 -> C K E (D 9 -D 1 7 ) O D T -> O D T (a ll S D R A M s ) B A 0 -B A 2 (a ll S D R A M s ) A 0 -A 1 5 (a ll S D R A M s ) /R A S (a ll S D R A M s ) /C A S (a ll S D R A M s ) /W E (a ll S D R A M s ) C K , /C K (a ll S D R A M s ) Notes : 1. DQ-to-I/O wiring may be changed within a byte. 2. There are two physical copies of each address/command/control/clock. Rev 1.2 / Feb. 2009 6 1240pin Fully Buffered DDR2 SDRAM DIMMs FUNCTIONAL BLOCK DIAGRAM 2GB(256Mbx72) ECC FB-DIMM VSS /S1 /S0 /DQS9 DQS9 /DQS0 DQS0 DQ0 DQ1 DQ2 DQ3 /DQS1 DQS1 DQ 8 DQ 9 DQ 10 DQ 11 /DQS2 DQS2 DQ 16 DQ 17 DQ 18 DQ 19 /DQS3 DQS3 DQ 24 DQ 25 DQ 26 DQ27 /DQS4 DQS4 DQ 32 DQ 33 DQ 34 DQ 35 /DQS5 DQS5 DQ 40 DQ 41 DQ 42 DQ43 /DQS6 DQS6 DQ 48 DQ 49 DQ 50 DQ51 /DQS7 DQS7 DQ 56 DQ 57 DQ 58 DQ59 /DQS8 DQS8 CB0 CB1 CB2 CB3 DQS /DQS /CS I/O 0 I/O 1 D0 I/O 2 I/O 3 DM DQS /DQS /CS I/O 0 I/O 1 I/O 2 D18 I/O 3 DM DQS /DQS /CS I/O 0 I/O 1 D1 I/O 2 I/O 3 DM DQS /DQS /CS I/O 0 I/O 1 I/O 2 D19 I/O 3 DM DQS /DQS /CS I/O 0 I/O 1 D2 I/O 2 I/O 3 DM DQS /DQS /CS I/O 0 I/O 1 D20 I/O 2 I/O 3 DM DQS /DQS /CS I/O 0 I/O 1 D3 I/O 2 I/O 3 DM DQS /DQS /CS I/O 0 I/O 1 D21 I/O 2 I/O 3 DM DQS /DQS /CS I/O 0 I/O 1 D4 I/O 2 I/O 3 DM DQS /DQS /CS I/O 0 I/O 1 D22 I/O 2 I/O 3 DM DQS /DQS /CS I/O 0 I/O 1 D5 I/O 2 I/O 3 DM DQS /DQS /CS I/O 0 I/O 1 D23 I/O 2 I/O 3 DM DQS /DQS /CS I/O 0 I/O 1 D6 I/O 2 I/O 3 DM DQS /DQS /CS I/O 0 I/O 1 I/O 2 D24 I/O 3 DM DQS /DQS /CS I/O 0 I/O 1 D7 I/O 2 I/O 3 DM DQS /DQS /CS I/O 0 I/O 1 D25 I/O 2 I/O 3 DM DQS /DQS /CS I/O 0 I/O 1 D8 I/O 2 I/O 3 DM DQS /DQS /CS I/O 0 I/O 1 I/O 2 D26 I/O 3 DM All address/command/control/clock Serial PD SCL SCL WP U0 A0 A1 SDA A2 SA0 SA1 SA2 SDA DQ4 DQ5 DQ6 DQ7 /DQS10 DQS10 DQ20 DQ21 DQ22 DQ23 /DQS11 DQS11 DQ36 DQ37 DQ38 DQ39 /DQS12 DQS12 DQ44 DQ45 DQ46 DQ47 /DQS13 DQS13 DQ52 DQ53 DQ54 DQ55 /DQS14 DQS14 DQ60 DQ61 DQ62 DQ63 /DQS15 DQS15 DQ64 DQ65 DQ66 DQ67 /DQS16 DQS16 DQ60 DQ61 DQ62 DQ63 /DQS17 DQS17 CB4 CB5 CB6 CB7 V TT VTT Terminators VCC AMB DQS /DQS /CS I/O 0 I/O 1 D9 I/O 2 I/O 3 DM DQS /DQS /CS I/O 0 I/O 1 D27 I/O 2 I/O 3 DM DQS /DQS /CS I/O 0 I/O 1 D10 I/O 2 I/O 3 DM DQS /DQS /CS I/O 0 I/O 1 D28 I/O 2 I/O 3 DM DQS /DQS /CS I/O 0 I/O 1 D11 I/O 2 I/O 3 DM DQS /DQS /CS I/O 0 I/O 1 D29 I/O 2 I/O 3 DM DQS /DQS /CS I/O 0 I/O 1 D12 I/O 2 I/O 3 DM DQS /DQS /CS I/O 0 I/O 1 D30 I/O 2 I/O 3 DM DQS /DQS /CS I/O 0 I/O 1 D13 I/O 2 I/O 3 DM DQS /DQS /CS I/O 0 I/O 1 D31 I/O 2 I/O 3 DM DQS /DQS /CS I/O 0 I/O 1 D14 I/O 2 I/O 3 DM DQS /DQS /CS I/O 0 I/O 1 D32 I/O 2 I/O 3 DM DQS /DQS /CS I/O 0 I/O 1 D15 I/O 2 I/O 3 DM DQS /DQS /CS I/O 0 I/O 1 D33 I/O 2 I/O 3 DM DQS /DQS /CS I/O 0 I/O 1 D16 I/O 2 I/O 3 DM DQS /DQS /CS I/O 0 I/O 1 D34 I/O 2 I/O 3 DM DQS /DQS /CS I/O 0 I/O 1 D17 I/O 2 I/O 3 DM DQS /DQS /CS I/O 0 I/O 1 D35 I/O 2 I/O 3 DM PN0-PN13 /PN0-/PN13 PS0-PS9 /PS0-/PS9 VDD DQ0-DQ63 Serial PD,AMB CB0-CB7 DQS0-DQS17 DO-D35, AMB /DQS0-/DQS17 VREF DO-D35 VDD SPD VSS DO-D35,SPD, AMB SCL SDA SA0-SA2 /RESET SCK, /SCK A M B SN0-SN13 /SN0-/SN13 SS0-SS9 /SS0-/SS9 /S0-/CS (all SDRAMs) CKE0 -> CKE (all SDRAMs) ODT -> ODT (all SDRAMs) BA0-BA2 (all SDRAMs) A0-A15 (all SDRAMs) /RAS (all SDRAMs) /CAS (all SDRAMs) /W E (all SDRAMs) CK, /CK (all SDRAMs) Notes : 1. DQ-to-I/O wiring may be changed within a byte. 2. There are two physical copies of each address/command/control/clock. Rev 1.2 / Feb. 2009 7 1240pin Fully Buffered DDR2 SDRAM DIMMs Architecture Advanced Memory Buffer Pin Description Pin Name Pin Description FB-DIMM Channel Signals Count 99 SCK System Clock Input, positive line 1 SCK System Clock Input, negative line 1 PN[13:0] Primary Northbound Data, positive lines 14 PN[13:0] Primary Northbound Data, negative lines 14 PS[9:0] Primary Southbound Data, positive lines 10 PS[9:0] Primary Southbound Data, negative lines 10 SN[13:0] Secondary Northbound Data, positive lines 14 SN[13:0] Secondary Northbound Data, negative lines 14 SS[9:0] Secondary Southbound Data, positive lines 10 SS[9:0] Secondary Southbound Data, negative lines 10 FBDRES To an external precision calibration resistor connected to Vcc 1 DDR2 Interface Signals DQS[8:0] 175 Data Strobes, positive lines 9 DQS[8:0] Data Strobes, negative lines 9 DQS[17:9]/DM[8:0] Data Strobes(x4 DRAM only), positive lines. These signals are driven low to x8 DRAM on writes. 9 DQS[17:9] Data Strobes(x4 DRAM only), negative lines 9 DQ[63:0] Data 64 CB[7:0] Checkbits 8 A[15:0]A,A[15:0]B Addresses. A10 is part of the pre-charge command 32 BA[2:0]A,BA[2:0]B Bank Addresses 6 RASA,RASB Part of command, with CAS, WE and CS[1:0] 2 CASA,CASB Part of command, with RAS, WE and CS[1:0] 2 WEA,WEB Part of command, with RAS, WE and CS[1:0] 2 ODTA,ODTB On-die Termination Enable 2 CKE[1:0]A,CKE[1:0]B Clock Enable(one per rank) 4 CS[1:0]A,CS[1:0]B Chip Select(One per rank) 4 CLK[3:0] CLK[1:0] used on 9 and 18 device DIMMs, CLK[3:0] used on 36 device DIMMs. CLK[3:2] should be output disabled when not in use. 4 CLK[3:0] Negative lines for CLK[3:0] 4 DDRC_C14 DDR Compensation: Common return pin for DDRC_B18 and DDRC_C18 1 DDRC_B18 DDR Compensation: Resistor connected to common return pin DDRC_C14 1 DDRC_C18 DDR Compensation: Resistor connected to common return pin DDRC_C14 1 DDRC_B12 DDR Compensation: Resistor connected to VSS 1 DDRC_C12 DDR Compensation: Resistor connected to VDD 1 Rev 1.2 / Feb. 2009 8 1240pin Fully Buffered DDR2 SDRAM DIMMs Advanced Memory Buffer Pin Description Pin Name Pin Description Count SPD Bus Interface Signals 5 SCL Serial Presence Detect (SPD) Clock Input 1 SDA SPD Data Input / Output 1 SA{2:0] SPD Address Inputs, also used to select the DIMM number in the AMB 3 Miscellaneous Signals 163 PLLTSTO PLL Clock Observability Output 1 VCCAPLL Analog VCC for the PLL. Tied with low pass filter to VCC. 1 VSSAPLL Analog VSS for the PLL. Tied to 1 TEST_pin# Leave floating on the DIMM 6 TESTLO_pin# Tie to ground on the DIMM2 5 BFUNC Tie to ground to set functionality as "buffer on DIMM." 1 RESET AMB reset signal 1 NC No connect. Many NC are connected to VDD on the DIMM, to lower the impedance of the VDD power islands. 129 RFU Reserved for Future Use 18 Power/Ground Signals 213 VCC AMB Core Power(1.5 Volt) 24 VCCFBD AMB Channel I/O Power(1.5 Volt) 8 VDD AMB DRAM I/O Power (1.8 Volt) 24 VDDSPD SPD Power (3.3 Volt) 1 VSS Ground 156 Total 655 Note: 1. System Clock Signals SCK and SCK switch at one half the DRAM CK/ CK frequency. 2. TESTLO_AB20 and TESTLO_AC20 should be configured for debug purposes on protype DIMMs: each pin should have a zero ohm resistor pull-down to ground, and an unpopulated resistor pull-up to VCC. These resistors can be replaced on production DIMMs with a direct connection to ground. Rev 1.2 / Feb. 2009 9 1240pin Fully Buffered DDR2 SDRAM DIMMs Pin Assignments for the Advanced Memory Buffer(AMB) (Top View) 655-Ball LFBGA 0.8 mm x 0.8 mm pitch Left Side 1 2 3 VDD A B 4 5 6 7 VSS DQ26 DQ12 DQS3 DQS3 VSS DQ14 DQS10 VDD 8 DQS10 DQ13 9 10 11 12 13 14 15 VDD DQS1 DQ10 VDD TEST VDD VDD VSS DQ11 DQS1 VSS DDRC TESTLO VDD VSS C VSS DQS2 DQ18 VSS DQ4 DQS9 VSS DQ15 DQ9 VSS DQ8 DDRC VSS D DQ19 DQS2 VSS DQ16 DQ24 VSS DQS9 DQ7 VSS DQ3 DQS0 VSS DQS8 E DQ21 VSS DQ17 DQ29 VSS DQ25 DQ6 VSS DQ5 DQ1 VSS DQ0 CB1 VSS CB2 F VSS DQ20 DQ23 VSS DQ31 DQ27 VSS TESTLO TEST VSS DQS0 DQ2 VDD CB0 CB3 G DQS11 DQS11 NC NC NC VSS H DQ22 VSS NC NC NC DQ28 DDRC DQS17 DQS8 VDD DQS12 DQS12 NC NC NC BFUNC RFU RFU RFU DQ30 VSS NC NC NC VSS VDD VSS VDD J VSS CLK2 NC NC NC BA1A VSS CKE1A NC NC NC VDD VSS VDD VSS K CLK2 CLK0 NC NC NC VSS WEA RASA NC NC NC VSS VCC VSS VCC L CLK0 VSS NC NC NC A0A CKE0A VSS NC NC NC VCC VSS VCC VSS M ODT0A RFU NC NC NC CASA VSS BA2A NC NC NC VSS VCC VSS VCC N CS1A CS0A NC NC NC VSS BA0A A10A NC NC NC VCC VSS VCC VSS P A6A VSS NC NC NC A2A A1A A3A NC NC NC VSS VCC VSS VCC R VSS A8A NC NC NC A11A VSS A5A NC NC NC VCC VSS VCC VSS T A4A A13A NC NC NC VSS A9A A7A NC NC NC VSS VCC VSS VCC U PN0 PN0 NC NC NC A15A A14A A12A NC NC NC RFU VCCFBD VSS VSS VSS RFUa RFUa VCCFBD VSS VSS VSS V PN1 PN1 VSS SN0 SN0 VCCFBD VSS VCCFBD W PN2 PN2 VSS SN1 SN1 SN3 SN4 SN5 SN13 SN12 SN6 SN7 SN8 SN9 SN10 Y PN3 PN3 VSS SN2 SN0 SN3 SN4 SN6 SN13 SN12 SN6 SN7 SN8 SN9 SN10 AA VSS PN4 PN4 VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS RESET PN5 PN13 RFUa PN12 PN6 PN7 PN8 PN9 VSSAPLL VCCAPLL PN10 PN11 a FBDRES PLLTSTO PN10 PN11 AB AC 1 2 VSS PN5 PN13 RFU PN12 PN6 PN7 PN8 PN9 3 4 5 6 7 8 9 10 11 12 13 14 15 NC= No Connect, RFU= Reserved for Future Use. Note: a. These pin positions are reserved for forwarded clocks to be used in future AMB implementations Rev 1.2 / Feb. 2009 10 1240pin Fully Buffered DDR2 SDRAM DIMMs Right Side A 16 17 18 19 20 21 22 23 24 25 26 27 VDD TEST VDD DQ52 DQS15 VDD DQ49 DQS6 VDD DQ48 DQ38 VDD 28 B VDD TEST DDRC VSS DQS15 DQ53 VSS DQS6 DQ50 VSS DQS13 DQS13 VSS C DQS17 VSS DDRC DQ54 VSS DQ55 DQ51 VSS DQS7 DQ56 VSS DQ46 DQS14 D CB6 CB7 VSS DQS16 DQ63 VSS DQ59 DQS7 VSS DQ36 DQ44 VSS E VSS CB5 DQS16 VSS DQ61 DQ57 VSS DQ58 DQ39 VSS DQ33 DQ45 29 VDD DQS14 DQ47 VSS DQ41 F CB4 VDD DQ62 DQ60 VSS TEST TEST VSS DQ37 DQ35 VSS DQS5 DQ43 VSS G TESTLO RFU RFU NC NC NC DQS4 DQS4 VSS NC NC NC DQS5 DQ40 H VSS VDD VSS NC NC NC VSS DQ34 DQ32 NC NC NC VSS DQ42 J VDD VSS VDD NC NC NC RASB VSS RFU NC NC NC CLK3 VSS K VSS VCC VSS NC NC NC ODT0B CS1B VSS NC NC NC CLK1 CLK3 L VCC VSS VCC NC NC NC VSS CASB WEB NC NC NC VSS CLK1 M VSS VCC VSS NC NC NC CS0B VSS BA1B NC NC NC CKE0B VSS N VCC VSS VCC NC NC NC A0B A2B VSS NC NC NC BA0B BA2B P VSS VCC VSS NC NC NC VSS A4B A1B NC NC NC VSS CKE1B R VCC VSS VCC NC NC NC A6B VSS A10B NC NC NC A3B VSS T VSS VCC VSS NC NC NC A11B A9B VSS NC NC NC A7B A5B U VSS VCCFBD RFU NC NC NC A8B A15B A14B SA0 SCL SDA PS8 PS8 VSS A13B A12B SA2 SA1 PS7 PS7 V VCCFBD VSS VCCFBD VSS VCCFBD RFU RFUa W VSS SS0 SS1 SS2 SS3 SS4 SS9 SS5 SS6 SS7 SS8 VSS PS6 PS6 Y VSS SS0 SS1 SS2 SS3 SS4 SS9 SS5 SS6 SS7 SS8 VSS PS5 PS5 AA VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS PS9 PS9 VSS PS4 RFUa VDDSPD VSS a AB AC VSS SN11 VSS SCK TESTLO a PS0 PS1 PS2 PS3 RFU SN11 VSS SCK TESTLO PS0 PS1 PS2 PS3 PS4 RFU 16 17 18 19 20 21 22 23 24 25 26 VSS 27 28 29 NC= No Connect, RFU= Reserved for Future Use. Note: a. These pin positions are reserved for forwarded clocks to be used in future AMB implementations Rev 1.2 / Feb. 2009 11 1240pin Fully Buffered DDR2 SDRAM DIMMs Advanced Memory Buffer(AMB) DRAM Interface Specifications Please refer to the AMB Specification for all technical requirements The following specifications for the AMB constitute the subset which is critical for proper operation of the DDR2 SDRAM interface. Note: This list is not complete, more information will follow in later revisions of this specification. Critical AMB Specifications Symbol Parameter Type VDDQ =1.8V +/-0.1V Min Max Units Notes tSU DQ to DQS, DQS setup time (read) Input 245 ps 1 tH DQ to DQS, DQS hold time (read) Input 245 ps 1 tDVBamb AMB Data Valid Before DQS Output 470 ps 1 tDVAamb AMB Data Valid After DQS Output 470 ps 1 tCVBamb C/A/CNTL Valid Before Clock Output 1030 ps 1 tCVAamb C/A/CNTL Valid After Clock Output 890 ps 1 tDQSCKamb DQS/DQS-to-CK/CK output skew Output -240 240 ps 1 CIN Input Capacitance(DQ/DQS/DQS) 2.0 2.5 pF 1 Note 1: The timing numbers are for example only. Design should be based on the latest component specifications Rev 1.2 / Feb. 2009 12 1240pin Fully Buffered DDR2 SDRAM DIMMs Basic Functionality 1. Advanced Memory Buffer Overview The Advanced Memory Buffer reference design complies with the JEDEC FB-DIMM Architecture and Protocol Specification. 2. Advanced Memory Buffer Functionality 2.1 Advanced Memory Buffer * * * * * * * * * * Supports channel initialization procedures as defined in the initialization chapter of the FB-DIMM Architecture and Protocol Specification to align the clocks and the frame boundaries verify channel connectivity and identify AMB DIMM position. Supports the forwarding of southbound and northbound frames, servicing requests directed to DIMM, as defined in the protocol chapter, and merging the return data into the northbound frames. If the AMB resides on the last DIMM in the channel, the AMB initializes northbound frames. Detects errors on the channel and reports them to the host memory controller. Acts as DRAM memory buffer for all read, write and configuration accesses addressed to the DIMM. Provides a read buffer FIFO and a write buffer FIFO. Supports an SMBus protocol interface for access to the AMB configuration registers. Provides logic to support MEMBIST and IBIST Design for Test functions. Provides a register interface for the thermal sensor and status indicator. Functions as a repeater to extend the maximum length of FBD Links. 2.2 Transparent Mode for DRAM Test Support In this mode, the Advanced Memory Buffer will provide lower speed tester access to DRAM pins through the FB-DIMM I/O pins. This allows the tester to send and arbitrary test pattern to the DRAMs. Transparent mode only supports a maximum DRAM frequency equivalent to DDR2 400. Transparent mode functionality: * * * Reconfigure FB-DIMM inputs from differential high speed link receivers to two single ended lower speed receivers(~200 Mhz) These inputs directly control DDR2 Command/Address and input data that is replicated to all DRAMs Used low speed direct drive FB-DIMM outputs to bypass high speed Parallel/Serial circuitry and provide test results back to tester 2.3 DDR2 SDRAM * * * Supports DDR2 at speeds of 533,667 and 800 MT/s Supports 512Mb devices in x4 and x8 configurations 72 bit DDR2 SDRAM memory array Rev 1.2 / Feb. 2009 13 1240pin Fully Buffered DDR2 SDRAM DIMMs 3. Advanced Memory Buffer Block Diagram 10x2 10x2 South bound Data in South bound Data out Data Merge Re-Time PLL Re-synch 1x2 Demux Ref Clock PISO I0*12 I0*12 MUX Reset# Link init SM & Control & CSRs Reset Control Init patterns IBIST - RX Command Decoder & CRC Check IBIST - RX Failover DRAM Cmd MUX LAI Logic Thermal Sensor DDR State Controller & CSRs Core Control & CSRs MUX 36 Deep Write Data FIFO External MEMBIST DDR Calibration & DDR IOBIST/DFX LAI Controller Data CRC Gen & Read FIFO Data Out DRAMclock 4 DRAMclock# 29 DRAM Address /CommandCopy1 29 DRAM Address /CommandCopy2 DDR IO's 72+18X2 DRAM Address Data/Strobe Data In NB LAI Buffer Sync & Idle Pattern Generator IBIST - TX Cmd Out 4 IBISt - RX MUX SMbus SMbus Controller Link init SM & Control & CSRs Failover 14*6*2 14*12 PISO Demux Re-synch Data Merge Northbound DataOut 14x2 Re-Time 14x2 Northbound DataIn Advanced Memory Buffer Block Diagram Rev 1.2 / Feb. 2009 14 1240pin Fully Buffered DDR2 SDRAM DIMMs 4. Interfaces Below Figure illustrates the AMB and all of its interfaces.They consists of two FB-DIMM links, one DDR2 channel and an SMBus interface. Each FB-DIMM link connects the AMB to a host memory controller or an adjacent FB-DIMM. The DDR2 channel supports direct connection to the DDR2 SDRAMs on a Fully Buffered DIMM. M e m o ry In te rfa ce SB FBD In L in k SB FBD O u t L in k AMB NB FBD O u t L in k NB FBD In L in k Secondary or to optional next FBD Primary or Host Direction DDR2 Channel SMBus A d v a n c e d M e m o ry B u ffe r In te rfa c e s 4.1 FBD High-Speed Differential Point-to-Point Link (at 1.5V) Interfaces The Advanced Memory Buffer supports one FBD channel consisting of two bidirectional link interfaces using high speed differential point-to-point electrical signaling. The southbound input link is 10 lanes wid and carries commands and write data from the host memory controller or the adjacent DIMM in the host direction. The southbound output link forwards this same data to the next FBD. The northbound input link is 13 to 14 lanes wide and carries read return data or status information from the next FB-DIMM in the chain back towards the host. The northbound output link forwards this information back towards the host and multiplexes in any read return data or status information that is generated internally. 4.2 DDR2 Channel The DDR2 channel on the Advanced Memory Buffer supports direct connection to DDR2 SDRAMs. The DDR2 channel supports two ranks of eight banks with 16 row/column request, 64 data signals, and eight check-bit signals. There are two copies of address and command signals to support DIMM routing and electrical requirements. Four transfer bursts are driven on the data and check-bit lines at 800 MHz. Propagation delays between read data/check-bit strobe lanes on a given channel can differ. Each strobe can be calibrated by hardware state machines using write/read trial and error. Hardware aligns the read data and check-bits to a single core clock. The Advanced Memory Buffer provides four copies of the command clock phase references(CLK[3:0]) and write data/check-bit strobes(DQSs) for each DRAM nibble. Rev 1.2 / Feb. 2009 15 1240pin Fully Buffered DDR2 SDRAM DIMMs 4.3 SMBus Slave Interface The Advanced Memory Buffer supports an SMBus interface to allow system access to configuration registers independent of the FB-DIMM link. The Advanced Memory Buffer will never be a master on the SMBus, only a slave. Serial SMBus data transfer is supported at 100 kHz. SMBus access to the Advanced Memory Buffer may be a requirement to boot and to set link strength, frequency and other parameters needed to insure robust configurations. It is also required for diagnostic support when the link is down. The SMBus address straps located on the DIMM connector are used by the unique ID. 4.4 FBD Channel Latency FB-DIMM channel latency is measured from the time a read request is driven on the FB-DIMM channel pins to the time when the first 16 bytes (2nd chunk) of read completion data is sampled by the memory controller. When not using the Variable Read Latency capability, the latency for a specific DIMM on a channel is always equal to the latency for any other DIMM on that channel. However, the latency for each DIMM in a specific configuration with some number of DIMMs installed. As more DIMMs are added to the channel, additional latency is required to read from each DIMM on the channel. Because the channel is based on the point to point interconnection of buffer components between DIMMs, memory requests are required to travel through N-1 buffers before reaching the Nth buffer. The result is that a 4 DIMM channel configuration will have greater idle read latency compared to a 1DIMM channel configuration.The Variable Read Latency capability can be used to reduce latency for DIMMs closer to the host. The idle latencies listed in this section are representative of what might be achieved in typical AMB designs. Actual implementations with latencies less than the values listed will have higher application performance and vice versa. 4.5 Peak Theoretical Throughput An FB-DIMM channel transfers read completion data on the FBD Northbound data connection. 144 bits of data are transferred for every FBD Northbound data frame. This matches the 18-byte data transfer of an ECC DDR DRAM in a single DRAM command clock. A DRAM burst of 8 from a single channel or a DRAM burst of four from two lock stepped channels provides a total of 72 bytes of data(64 bytes plus 8 bytes ECC) The FBD frame rate matches the DRAM command clock because of the fixed 6:1 ratio of the FBD channel clock to the DRAM command clock. Therefore, the Northbound data connection will exhibit the same peak theoretical throughput as a single DRAM channel. For example, when using DDR2 533 DRAMs, the peak theoretical throughput as a single DRAM channel.For example, when using DDR2 533 DRAMs, the peak theoretical bandwidth of the Northbound data connection is 4.276 GB/sec. Write data is transferred on the FBD Southbound command and data connection, via Command+Wdata frames. 72 bits of data are transferred for every FBD Command+Wdata frame. Two Command+Wdata frames match the 18-byte data transfer of and ECC DDR DRAM in a single DRAM command clock. A DRAM burst of 8 transfers from a single channel, or a burst of 4 from two lock-step channels provides a total of 72 bytes of data(64 bytes plus & bytes ECC) When the FBD frame rate matches the DRAM command clock, the Southbound command and data connection will exhibit one half the peak theoretical throughput of a single DRAM channel. For example, when using DDR2 533 DRAMs, the peak theoretical bandwidth of the Southbound command and data connection is 2.133 GB/sec. The total peak theoretical throughput for a single FBD channel is defined as the sum of the peak theoretical throughput of the Northbound data connection and the Southbound command and data connection. When the FBD frame rate matches the DRAM command clock, this is equal to 1.5 times the peak theoretical throughput of a single DRAM channel. For example, when using DDR2 533 DRAMs, the peak theoretical throughput of a DDR2 533 channel would be 4.267 GB/sec, while the peak theoretical throughput of and FBD -/+533 channel would be 6.4 GB/sec. Rev 1.2 / Feb. 2009 16 1240pin Fully Buffered DDR2 SDRAM DIMMs 5 Hot-add The FB-DIMM channel does not provide a mechanism to automatically detect and report the addition of a new DIMM south of the currently active last DIMM. It is assumed the system will be notified through some means of the addition of one or more new DIMMs so that specific commands can be sent to the host controller to initialize the newly added DIMM(s) and perform a Hot-add Reset to bring them into the channel timing domain. It should be noted that the power to the DIMM socket must be removed before a "hot-add" DIMM is inserted or removed. Applying or removing the power to a DIMM socket is a system platform function. 6 Hot-remove In order to accomplish removal of DIMMs the host must perform a Fast Reset sequence targeted at the last DIMM that will be retained on the channel. The Fast Reset re-establish the appropriate last DIMM so that the Southbound Tx outputs of the last DIMM and the Southbound and Northbound outputs of the DIMMs beyond the last active DIMM are disabled. Once the appropriate outputs are disabled the system can coordinate the procedure to remove power in preparation for physical removal of the DIMM if needed. It should be noted that the power to the DIMM socket must be removed before a "hot-add" DIMM is inserted or removed. Applying or removing the power to a DIMM socket is a system platform function. 7 Hot-replace Hot replace of DIMM is accomplished through combing th Hot-Remove and Hot-Add process. Rev 1.2 / Feb. 2009 17 1240pin Fully Buffered DDR2 SDRAM DIMMs Electrical Characteristics ABSOLUTE MAXIMUM RATINGS Parameter Symbol Value Unit Note VIN, VOUT - 0.3 V ~ 1.75 V V 1 Voltage on VCC relative to Vss VCC - 0.3 V ~ 1.75 V V 1 Voltage on VDD relative to Vss VDD - 0.5 V ~ 2.3 V V 1 Voltage on VTT relative to Vss VTT - 0.5 V ~ 2.3 V V 1 TSTG - 55 oC ~ 100 oC Voltage on any pins relative to Vss Storage Temperature range o 1 C Note: 1. Stress greater than those listed may cause permanent damage to the device. This is a stress rating only, and device functional operation at or above the conditions indicated is not implied. Exposure to absolute maximum rating conditions for extended periods may affect reliability. OPERATING TEMPERATURE RANGE Parameter AMB Component Case temperature Range DRAM Component Case Temperature Range Symbol TCASE Rating 0 ~ + 110 Units oC Notes TCASE 0 ~ + 95 oC 1,2 Note: 1. Within the DRAM component Case Temperature range all DRAM specification will be supported. 2. If the DRAM case temperature is Above 85oC, the Auto-Refresh command interval has to be reduced from 7.8us of tREFI to 3.9us. Supply Voltage Levels and DC Operating Conditions. Parameter Symbol Min Nom Max Unit AMB Supply Voltage VCC 1.455 1.5 1.575 V DRAM Supply Voltage VDD 1.7 1.8 1.9 V Termination Voltage EEPROM Supply Voltage VTT 0.50 x VDD 3.3 0.52 x VDD 3.6 V VDDSPD 0.48 x VDD 3.0 V Note DC Input Logic High(SPD) VIH(DC) 2.1 - VDDSPD V 1 DC Input Logic Low(SPD) VIL(DC) - - 0.8 V 1 DC Input Logic High(RESET) VIH(DC) 1.0 - - V 2 DC Input Logic Low(RESET) VIL(DC) - - +0.5 V 2 IL IL -90 -5 - +90 +5 uA uA 2 3 Leakage Current (RESET) Leakage Current (Link) Note: 1. Applies for SMB and SPD bus Signals. 2. Applies for AMB CMOS Signal RESET. 3. for all other AMB related DC parameters, please refer to the High Speed Differential Link Interface Specifications Rev 1.2 / Feb. 2009 18 1240pin Fully Buffered DDR2 SDRAM DIMMs Timing Parameters Parameter Symbol EI Assertion Pass-Thru Timing Min tEI Propagad EI Deassertion Pass-Thru Timing Typ Max Unit Note - 4 clks - bit lock clks - clks 1 tEID EI Assertion Duration tEI Bit Lock Interval Frame Lock Interval 100 tBitLock 119 frames 1 tFrameLock 154 frames 1 Note: 1. Defined in FB-DIMM Architecture and Protocol Spec. Environmental Parameters Symbol Parameter Rating Units Notes TOPR Operating temperature See Note HOPR Operating humidity(relative) 10 to 90 % 2 TSTG Storage temperature -50 to +100 oC 2 HSTG Storage humidity(without condensation) 5 to 95 % 2 PBAR Barometric pressure(operating) 3050 m 2 PBAR Barometric pressure (storage) 15240 m 2 1 Note: 1. The designer must meet the case temperature specifications for individual module components. 2. Stresses greater than those listed may cause permanent damage to the device. This is a stress rating only, and device functional operation at or above the conditions indicated is not implied. Exposure to absolute maximum rating conditions for extended periods Rev 1.2 / Feb. 2009 19 1240pin Fully Buffered DDR2 SDRAM DIMMs IDD Specification and Conditions IDD Measurement Conditions Symbol Conditions Idle_0 Idle Current, single or last DIMML0 state, idle (0 BW)Primary channel enabled, Secondary Channel Disabled CKE high. Command and address lines stable. DRAM clock active. Idle_1 Idle Current, first DIMML0 state, idle (0 BW)Primary and Secondary channels enabled CKE high. Command and address lines stable. DRAM clock active. Idle_2 Idle Current, DRAM power downL0 state, idle (0 BW)Primary and Secondary channels enabledCKE low. Command and address lines floated. DRAM clock active, ODT and CKE driven low. Active_1 Active PowerL0 state. 50% DRAM BW, 67% read, 33% write. Primary and Secondary channels enabled. DRAM clock active, CKE high. Active_2 Active Power, data pass throughL0 state. 50% DRAM BW to downstream DIMM, 67% read, 33% write. Primary and Secondary channels enabled CKE high. Command and address lines stable. DRAM clock active. L0s Channel Standby Average power over 42 frames where the channel enters and exits L0sDRAMs Idle (0 BW). CKE low. Command and address lines floated. Dram clocks active, ODE and CKE driven low. Training (for AMB spec, not in SPD) Training Primary and Secondary channels enabled.100% toggle on all channels lanes.DRAMs idle (0 BW).CKE high. Command and address lines stable.DRAM clock active. Rev 1.2 / Feb. 2009 20 1240pin Fully Buffered DDR2 SDRAM DIMMs IDD Power Supply Currents Specifications. SAC Timing Parameters by Speed Grade 512MB(HMP564F7FFP8C) Power Supply Intel IDT Y5 Icc_Idle_0 @1.5V 2400 IDT 1GB(HMP512F7FFP8C) Intel S5 2400 3000 IDT Y5 2400 IDT 2GB(HMP525F7FFP4C) Intel S5 2400 3000 IDT Unit 2400 mA Note1) Y5 2400 Idd_Idle_0 @1.8V 315 315 315 630 630 630 1260 1260 mA Idle_0 Total Power 4.167 4.167 5.067 4.734 4.734 5.634 5.868 5.868 W Icc_Idle_1 @1.5V 3100 3100 3875 3100 3100 3875 3100 3100 mA Idd_Idle_1 @1.8V 315 315 315 630 630 630 1260 1260 mA Idle_1 Total Power 5.217 5.217 6.380 5.784 5.784 6.947 6.918 6.918 W Icc_Active_1 @1.5V 3600 3600 4500 3600 3600 4500 3600 3600 mA Idd_Active_1 @1.8V 900 900 1035 1800 1800 2070 3600 3600 mA Active_1 Total Power 7.020 7.020 8.613 8.640 8.640 10.476 11.880 11.880 W Icc_Active_2 @1.5V 3300 3300 4125 3300 3300 4125 3300 3300 mA Idd_Active_2 @1.8V 900 900 1035 1800 1800 2070 3600 3600 mA Active_2 Total Power 6.570 6.570 8.051 8.190 8.190 9.914 11.430 11.430 W Icc_Training @1.5V 4000 4000 5000 4000 4000 5000 4000 4000 mA Idd_Training @1.8V 900 900 1035 1800 1800 2070 3600 3600 mA Training Total Power 7.620 7.620 9.363 9.240 9.240 11.226 11.480 11.480 W Note: 1) Assure that Primary channel Drive strength at 100% with De-emphasis at -6.5dB Secondary channel drive strength at 60% with De-emphasis at -3dB when enabled. Address and Data fields are pseudo-random, which provides a 50% toggle rate on DRAM data lines and link lanes when data is being transferred. Assuming 1 activate command and 1 read/write command per BL=4 transferBL=4.10 lanes southbound and 14 lanes northbound are enabled and active (12 lanes NB if non-ECC DIMM). SPD specific assumption:Number of devices on the specific DIMM assumed.Termination of command, address, and control is actual value used on the DIMM. ECC or non-ECC as per the specific DIMM. SPD specifies Delta TAMB power spec specific assumptions: Dual rank x8 ECC DIMM assumed (18 DRAM devices present on DIMM) Modeled with 27 ohm termination for command, address, and clocks, and 47 ohm termination for control. ECC DIMM assumed (72 bit data, 14 lanes northbound). AMB specification specifies current for each rail. Rev 1.2 / Feb. 2009 21 1240pin Fully Buffered DDR2 SDRAM DIMMs Termination Current Internal signals are terminated on the DIMM through resistors to an external power supply VTT = VDD / 2. Modeled with 30 Ohm termination for clocks, 39 ohm for command / address and 47 ohm for control. The VTT power supply must be able to source and sink these currents: VTT Currents table Description Symbol Typ Max Unit Idle Current, DRAM Power Down (Conditions TBD) ITT1 - 700 mA Active Power, 50% DRAM BW (conditions TBD) ITT2 - 700 mA Rev 1.2 / Feb. 2009 22 1240pin Fully Buffered DDR2 SDRAM DIMMs PACKAGE OUTLINE 64Mx72, 512MB Module (1 rank of x8 based DDR2 SDRAMs) HMP564F7FFP8C FRONT VIEW 4.0 0.1 133.35 0.15 30.35 AMB 67.00 51.00 5.00 BACK VIEW Chekbit FRONT VIEW WITH HEAT SPREADER Side 8.20 max 5.20 max BACK VIEW WITH HEAT SPREADER 3.0 max 1.270.10 Note 1: All dimensions are typical millimeter scale unless otherwise stated. Rev 1.2 / Feb. 2009 23 1240pin Fully Buffered DDR2 SDRAM DIMMs PACKAGE OUTLINE 128Mx72, 1GB Module (2 ranks of x8 based DDR2 SDRAMs) HMP512F7FFP8C FRONT VIEW 30.35 4.0 0.1 133.35 0.15 AMB 67.00 51.00 5.00 BACK VIEW Chekbit Chekbit FRONT VIEW WITH HEAT SPREADER Side 8.20 max 5.20 max BACK VIEW WITH HEAT SPREADER 3.0 max 1.270.10 Note 1: All dimensions are typical millimeter scale unless otherwise stated. Rev 1.2 / Feb. 2009 24 1240pin Fully Buffered DDR2 SDRAM DIMMs PACKAGE OUTLINE 256Mx72, 2GB Module (2 ranks of x4 based DDR2 SDRAMs) HMP525F7FFP4C FRONT VIEW 30.35 4.0 0.1 133.35 0.15 67.00 51.00 5.00 BACK VIEW FRONT VIEW WITH HEAT SPREADER Side 8.20 max 5.20 max BACK VIEW WITH HEAT SPREADER 3.0 max 1.270.10 Note 1: All dimensions are typical millimeter scale unless otherwise stated. Rev 1.2 / Feb. 2009 25 1240pin Fully Buffered DDR2 SDRAM DIMMs REVISION HISTORY Revision History Date 1.0 First Version Release July. 2008 1.1 Orddering Info. table revised Sep. 2008 1.2 IDD Power spec added Feb. 2009 Rev 1.2 / Feb. 2009 Remark 26