EDW2032BBBG-60-F - Elpida Memory, Inc.

DATA SHEET

Document No. E1864E10 (Ver. 1.0)

Date Published December 2011 (K) Japan

Printed in Japan

URL: http://www.elpida.com

Elpida Memory, Inc. 2011

Specifications

• Density: 2G bits

• Organization

— 4Mbit x 32 I/O x 16 banks

— 8Mbit x 16 I/O x 16 banks

• Package

— 170-ball FBGA

— Lead-free (RoHS compliant) and Halogen-free

• Power supply:

— VDD: 1.6V/1.5V ± 3% and 1.35V ± 3%

— VDDQ: 1.6V/1.5V ± 3% and 1.35V ± 3%

• Data rate: 7.0Gbps/6.0Gbps/5.0Gbps (max.)

• 16 internal banks

• Four bank groups for tCCDL = 3tCK

• 8n prefetch architecture: 256 bit per array Read or

Write access for x32; 128 bit for x16

• Burst length (BL): 8 only

• Programmable CAS latency: 6 to 20

• Programmable Write latency: 3 to 7

• Programmable CRC READ latency: 1 to 3

• Programmable CRC WRITE latency: 8 to 14

• Programmable EDC hold pattern for CDR

• Precharge: auto precharge option for each burst

access

• Refresh: auto-refresh, self-refresh

• Refresh cycles: 16384 cycles/32ms

• Interface: Pseudo open drain (POD-15)

• On-die termination (ODT): nom. values of 60Ω or 120Ω

• Pseudo open drain (POD-15) compatible outputs

— 40Ω pulldown

— 60Ω pullup

• ODT and output driver strength auto-calibration with

external resistor ZQ pin (120Ω)

• Programmable termination and driver strength offsets

• Selectable external or internal VREF for data inputs;

programmable offsets for internal VREF

• Separate external VREF for address / command inputs

• Operating case temperature range

— TC = 0°C to +95°C

Features

• x32/x16 mode configuration set at power-up with

EDC pin

• Single ended interface for data, address and command

• Quarter data-rate differential clock inputs CK, /CK for

address and commands

• Two half data-rate differential clock inputs WCK, /WCK,

each associated with two data bytes (DQ, /DBI, EDC)

• Double Data Rate (DDR) data (WCK)

• Single Data Rate (SDR) command (CK)

• Double Data Rate (DDR) addressing (CK)

• Write data mask function via address bus

(single/double byte mask)

• Data Bus Inversion (DBI) and Address Bus Inversion

(ABI)

• Input/output PLL on/off mode

• Duty cycle corrector (DCC) for data clock (WCK)

• Address training: address input monitoring via DQ pins

• WCK2CK clock training: phase information via EDC

pins

• Data read and write training via Read FIFO (FIFO

depth = 6)

• Read FIFO pattern preload by LDFF command

• Direct write data load to Read FIFO by WRTR

command

• Consecutive read of Read FIFO by RDTR command

• Read/Write data transmission integrity secured by

cyclic redundancy check (CRC–8)

• Read/Write EDC on/off mode

• DQ Preamble for Read on/off mode

• Low Power modes

• RDQS mode on EDC pin

• On-chip temperature sensor with read-out

• Automatic temperature sensor controlled self-refresh

rate

• Digital tRAS lockout

• Vendor ID, FIFO depth and Density info fields for

identification

• Mirror function with MF pin

• Boundary Scan function with SEN pin

2G bits GDDR5 SGRAM

EDW2032BBBG (64M words x 32 bits)

EDW2032BBBG

Data Sheet E1864E10 (Ver. 1.0)

Ordering Information

Part Number

Part number

Organization

(words x bits) VDD, VDDQ Max. Data Rate Package

EDW2032BBBG-40-F

EDW2032BBBG-50-F

EDW2032BBBG-60-F

EDW2032BBBG-70-F

64M x 32 1.5V / 1.35V

1.5V / 1.35V

1.6V / 1.35V

4.0Gbps / 3.2Gbps

5.0Gbps / 4.0Gbps

6.0Gbps / 4.0Gbps

7.0Gbps / 4.0Gbps

170-ball FBGA

Elpida Memory

Density/Bank

20: 2Gb/16-bank

Organization

32: x32

Power Supply, Interface

B: VDD = 1.5V

Product Family

W: GDDR5 SGRAM

Type

D: Packaged Device

E D W 20 32 B B B

- 60 - F

Revision

Package

BG: FBGA

Speed

40: 4.0Gbps

50: 5.0Gbps

60: 6.0Gbps

70: 7.0Gbps

Environment Code

F: Lead Free (RoHS compliant)

and Halogen Free

EDW2032BBBG

Data Sheet E1864E10 (Ver. 1.0)

Pin Configuration

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EDW2032BBBG

Data Sheet E1864E10 (Ver. 1.0)

Note: 1. /xxx indicates active low signal.

Signal Function Signal Function

CK, /CK Clock ZQ Impedance Reference

WCK01, /WCK01,

WCK23, /WCK23 Data Clocks /RESET Reset

/CKE Clock Enable MF Mirror Function

/CS Chip Select SEN Scan Enable

/RAS, /CAS, /WE Command inputs VREFC Reference voltage for command and address

BA0 - BA3 Bank Address inputs VREFD Reference voltage for DQ and /DBI

A0 - A12 Address inputs VDDQ I/O power

DQ0 - DQ31 Data Input/Output VSSQ I/O ground

/DBI0 - /DBI3 Data bus inversion VDD Power supply

EDC0 - EDC3 Error Detection Code VSS Ground

/ABI Address bus inversion NC Not connected

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EDW2032BBBG

Data Sheet E1864E10 (Ver. 1.0)

1. Configuration

The Elpida GDDR5 SGRAM is a high speed dynamic random-access memory designed for applications requiring

high bandwidth. It contains 2,147,483,648 bits and is internally configured as a 16-bank DRAM.

The GDDR5 SGRAM uses a 8n prefetch architecture and DDR interface to achieve high-speed operation. The

device can be configured to operate in x32 mode or x16 (clamshell) mode. The mode is detected during device

initialization. The GDDR5 interface transfers two 32 bit wide data words per WCK clock cycle to/from the I/O pins.

Corresponding to the 8n prefetch a single write or read access consists of a 256 bit wide, two CK clock cycle data

transfer at the internal memory core and eight corresponding 32 bit wide one-half WCK clock cycle data transfers

at the I/O pins.

The GDDR5 SGRAM operates from a differential clock CK and /CK. Commands are registered at every rising edge

of CK. Addresses are registered at every rising edge of CK and every rising edge of /CK.

GDDR5 replaces the pulsed strobes (WDQS & RDQS) used in previous DRAMs such as GDDR4 with a free running

differential forwarded clock (WCK, /WCK) with both input and output data registered and driven respectively at both

edges of the forwarded WCK.

Read and write accesses to the GDDR5 SGRAM are burst oriented; an access starts at a selected location and

continues for a total of eight data words. Accesses begin with the registration of an ACTIVE command, which is then

followed by a READ or WRITE command. The address bits registered coincident with the ACTIVE command and

the next rising /CK edge are used to select the bank and the row to be accessed. The address bits registered

coincident with the READ or WRITE command and the next rising /CK edge are used to select the bank and the

column location for the burst access.

EDW2032BBBG

Data Sheet E1864E10 (Ver. 1.0)

1.1 Signal Description

Table 1: Signal Description

Signal Type Detailed Function

CK, /CK Input

Clock: CK and /CK are differential clock inputs. Command inputs are latched on the rising edge

of CK. Address inputs are latched on the rising edge of CK and the rising edge of /CK. All

latencies are referenced to CK. CK and /CK are externally terminated.

WCK01, /WCK01,

WCK23, /WCK23 Input

Data Clocks: WCK and /WCK are differential clocks used for WRITE data capture and READ

data output. WCK01, /WCK01 is associated with DQ0-DQ15, /DBI0, /DBI1, EDC0 and EDC1.

WCK23, /WCK23 is associated with DQ16-DQ31, /DBI2, /DBI3, EDC2 and EDC3. WCK clocks

operate at nominally twice the CK clock frequency.

/CKE Input

Clock Enable: /CKE low activates and /CKE high deactivates internal clock, device input

buffers and output drivers. Taking /CKE high provides Precharge Power-Down and Self-

Refresh operations (all banks idle), or Active Power-Down (row active in any bank). /CKE is

synchronous for Power-Down entry and exit and for Self-Refresh entry. /CKE must be

maintained low throughout READ and WRITE accesses.

Input buffers excluding CK, /CK, /CKE, WCK01, /WCK01, WCK23, /WCK23 are disabled

during Power-Down. Input buffers excluding /CKE are disabled during Self-Refresh.

The value of /CKE latched at power-up with /RESET going high determines the termination

value of the address and command inputs.

/CS Input

Chip Select: /CS low enables, and /CS high disables the command decoder. All commands are

masked when /CS is registered high, but internal command execution continues. /CS provides

for individual device selection on memory channels with multiple memory devices. /CS is

considered part of the command code.

/RAS, /CAS, /WE Input Command inputs: /RAS, /CAS and /WE (along with /CS) define the command to be entered.

BA0 - BA3 Input

Bank Address inputs: BA0-BA3 define to which bank an ACTIVE, READ, WRITE or

PRECHARGE command is being applied. BA0-BA3 also determine which Mode Register is

accessed with a MODE REGISTER SET command. BA0-BA3 are sampled with the rising edge

of CK.

A0 - A12 Input

Address inputs: A0-A12 provide the row address for ACTIVE commands. A0-A5(A6) provide

the column address and A8 defines the auto precharge function for READ and WRITE

commands, to select one location out of the memory array in the respective bank. A8 sampled

during a PRECHARGE command determines whether the PRECHARGE applies to one bank

(A8 low, bank selected by BA0-BA3) or all banks (A8 high). The address inputs also provide

the op-code during an MODE REGISTER SET command, and the data bits during LDFF

commands. A8-A12 are sampled with the rising edge of CK and A0-A7 are sampled with the

rising edge of /CK.

DQ0 - DQ31 I/O Data Input/Output: 32 bit data bus

/DBI0 - /DBI3 I/O Data bus inversion: /DBI0 is associated with DQ0-DQ7, /DBI1 with DQ8-DQ15, /DBI2 with

DQ16-DQ23, and /DBI3 with DQ24-DQ31.

EDC0 - EDC3 Output

Error Detection Code: The calculated CRC data is transmitted on these pins. In addition these

pins drive a hold pattern when idle and can be used as an RDQS function. EDC0 is associated

with DQ0-DQ7, EDC1 with DQ8-DQ15, EDC2 with DQ16-DQ23, and EDC3 with DQ24-DQ31.

/ABI Input Address bus inversion

ZQ - Impedance Reference: external reference pin for auto-calibration

/RESET Input Reset: VDDQ CMOS input. A full chip reset may be performed at any time by pulling /RESET

low. With /RESET low all ODTs are disabled.

MF Input Mirror Function: VDDQ CMOS input. Must be tied to Power or Ground.

SEN Input Scan Enable: VDDQ CMOS input. Must be tied to Ground when not in use.

VREFC Supply Reference voltage for command and address inputs.

VREFD Supply Reference voltage for DQ and /DBI inputs.

VDDQ Supply Isolated power for the input and output buffers.

VSSQ Supply Isolated ground for the input and output buffers.

VDD Supply Power supply

VSS Supply Ground

NC - Not connected

EDW2032BBBG

Data Sheet E1864E10 (Ver. 1.0)

1.2 Mirror Function Mode

The GDDR5 SGRAM provides a mirror function (MF) pin to change the physical location of the command, address,

data and WCK pins assisting in routing devices back to back. The MF ball should be tied directly to VSSQ or VDDQ

depending on the control line orientation desired.

The pins affected by this Mirror Function mode are listed in Table 2.

Table 2: Ball Assignment with Mirror Function

Functions within the GDDR5 SGRAM that refer to external signals are transparent with respect to Mirror Function

mode, meaning that the signal names shown in the respective functional description apply both to mirrored (MF=1)

and non-mirrored (MF=0) modes. The referenced package pin is determined by the Mirror Function mode the

devices is configured to.

1.3 Clamshell Mode Detection

The GDDR5 SGRAM can operate in a x32 mode or a x16 mode to allow a clamshell configuration with a point to

point connection on the high speed data signals. The disabled pins in x16 mode will be in Hi-Z state, non-terminating.

The x16 mode is detected at power-up on the pin at location C-13 which is EDC1 when configured to MF=0 and

EDC2 when configured to MF=1. For x16 mode this pin is tied to VSSQ; the pin is part of the two bytes that are

disabled in this mode and therefore not needed for EDC functionality. For x32 mode this pin is active and always

terminated to VDDQ in the system or by the controller. The configuration is set with /RESET going high. Once the

configuration has been set, it cannot be changed during normal operation. Usually the configuration is fixed in the

system.

Table 3: Clamshell Mode and Mirror Function

Ball

Signal

Ball

Signal

Ball

Signal

Ball

Signal

MF=0 MF=1 MF=0 MF=1 MF=0 MF=1 MF=0 MF=1

A2 DQ1 DQ25 A4 DQ0 DQ24 K5 A11 A6 A9 A1 G12 /CS /WE

B2 DQ3 DQ27 B4 DQ2 DQ26 P5 /WCK23 /WCK01 L12 /WE /CS

C2 EDC0 EDC3 D4 WCK01 WCK23 H10 BA3 A3 BA1 A5 A13 DQ9 DQ17

D2 /DBI0 /DBI3 E4 DQ4 DQ28 K10 BA1 A5 BA3 A3 B13 DQ11 DQ19

E2 DQ5 DQ29 F4 DQ6 DQ30 A11 DQ8 DQ16 C13 EDC1 EDC2

F2 DQ7 DQ31 H4 A10 A0 A8 A7 B11 DQ10 DQ18 D13 /DBI1 /DBI2

M2 DQ31 DQ7 K4 A8 A7 A10 A0 E11 DQ12 DQ20 E13 DQ13 DQ21

N2 DQ29 DQ5 M4 DQ30 DQ6 F11 DQ14 DQ22 F13 DQ15 DQ23

P2 /DBI3 /DBI0 N4 DQ28 DQ4 H11 BA0 A2 BA2 A4 M13 DQ23 DQ15

R2 EDC3 EDC0 P4 WCK23 WCK01 K11 BA2 A4 BA0 A2 N13 DQ21 DQ13

T2 DQ27 DQ3 T4 DQ26 DQ2 M11 DQ22 DQ14 P13 /DBI2 /DBI1

U2 DQ25 DQ1 U4 DQ24 DQ0 N11 DQ20 DQ12 R13 EDC2 EDC1

G3 /RAS /CAS D5 /WCK01 /WCK23 T11 DQ18 DQ10 T13 DQ19 DQ11

L3 /CAS /RAS H5 A9 A1 A11 A6 U11 DQ16 DQ8 U13 DQ17 DQ9

Mode MF EDC1 (MF=0) or EDC2 (MF=1)

x16 non-mirrored VSSQ VSSQ

x32 non-mirrored VSSQ VDDQ (terminated by the system or controller)

x16 mirrored VDDQ VSSQ

x32 mirrored VDDQ VDDQ (terminated by the system or controller)

EDW2032BBBG

Data Sheet E1864E10 (Ver. 1.0)

Figure 1 shows examples of the board channels and topologies that are supported in GDDR5 in order to illustrate

the expected usage of x16 mode and the MF pin.

Figure 1: Example GDDR5 PCB Layout Topologies

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EDW2032BBBG

Data Sheet E1864E10 (Ver. 1.0)

1.4 Clocking

The GDDR5 SGRAM operates from a differential clock CK and /CK. Commands are registered at every rising edge

of CK. Addresses are registered at every rising edge of CK and every rising edge of /CK.

GDDR5 uses a double data rate data interface and an 8n-prefetch architecture. The data interface uses two

differential forwarded clocks (WCK, /WCK). DDR means that the data is registered at every rising edge of WCK and

rising edge of /WCK. WCK and /WCK are continuously running and operate at twice the frequency of the

command/address clock (CK, /CK).

Figure 2: GDDR5 Clocking and Interface Relationship

1.5 Addressing

The GDDR5 SGRAM uses a double data rate address scheme to reduce pins required on the GDDR5 SGRAM as

shown in Table 4. The addresses should be provided to the GDDR5 SGRAM in two parts; the first half is latched on

the rising edge of CK along with the command pins such as /RAS, /CAS and /WE; the second half is latched on the

rising edge of /CK.

The use of DDR addressing allows all address values to be latched in at the same rate as the SDR commands. All

addresses related to command access have been positioned for latching on the initial rising edge for faster

decoding.

Table 4: Address Pairs

Addressing schemes for x32 mode and x16 mode differ only in the number of valid column addresses, as shown in

Table 5.

Table 5: Addressing Scheme

Clock Edge Address Inputs

Rising CK BA3 BA2 BA1 BA0 A12 A11 A10 A9 A8

Rising /CK A3 A4 A5 A2 (RFU) A6 A0 A1 A7

64M x 32 128M x 16

Row Address A0-A12 A0-A12

Column address A0-A5 A0-A6

Bank address BA0-BA3 BA0-BA3

Autoprecharge A8 A8

Page size 2 KB 2 KB

Refresh 16K/32ms 16K/32ms

Refresh period 1.9 µs 1.9 µs

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EDW2032BBBG
Data Sheet E1864E10 (Ver. 1.0)
10
1.6 Commands
Table 6: Command Truth Table
Notes: 1. H = logic high level; L = logic low level; X = Don’t Care. Signal may be H or L, but not floating.
2. Addresses shown are logical addresses; physical addresses are inverted when address bus inversion (ABI) is 
activated and /ABI=L.
3. BA0-BA3 provide the Mode Register address (MRA), A0-A11 the opcode to be loaded.
4. BA0-BA3 provide the bank address (BA), A0-A12 provide the row address (RA).
5. BA0-BA3 provide the bank address, A0-A5 (A6) provide the column address (CA); no sub-word addressing within a 
burst of 8.
6. This command is REFRESH when /CKE(n) = L, and SELF-REFRESH ENTRY when /CKE(n) is H.
7. BA0-BA2 select burst location (BST) and A0-A9, BA3 provide the data.
8. DESELECT and NO OPERATION are functionally interchangeable.
9. In address training mode READ is decoded from the command pins only with /RAS = H, /CAS = L, /WE= H.
 Operation Code
/CKE
n-1
/CKE
n /CS /RAS /CAS /WE
BA3-
BA0 A11 A10 A8 
A6-A7,
A9,A12
A0-A5
 (A6) Note
DESELECT DESEL L X H X X X X XXXX X 2,8
NO OPERATION 
(NOP) NOP L X LH H H X XXXX X 2,8
MODE REGISTER 
SET MRS L L L L L L MRA OPCODE 2,3
ACTIVATE ACT L L L L H H BA RA 2,4
READ RD L L L H L H BA L L L X CA 2,5,9
READ with 
Autoprecharge RDA L L L H L H BA L L H X CA 2,5
LOAD FIFO LDFF L L L H L H BST H L L DATA 2,7
READ TRAINING RDTR L L L H L H X H H L X X 2
WRITE without Mask WR L L L H L L BA L L L X CA 2,5
WRITE without Mask 
with Autoprecharge WRA L L L H L L BA L L H X CA 2,5
WRITE with Single 
Byte Mask WSM L L L H L L BA L H L X CA 2,5
WRITE with 
Autoprecharge, Single 
Byte Mask
WSMAL L L H L L BAL HHX CA2,5
WRITE
 with Double 
Byte Mask WDM L L L H L L BA H L L X CA 2,5
WRITE with 
Autoprecharge, 
Double Byte Mask
WDMAL L L H L L BAHL HX CA2,5
WRITE TRAINING WRTR L L L H L L X H H L X X 2
PRECHARGE PRE L L L L H L BA X X L X X 2
PRECHARGE ALL PREALL L L L L H L X X X H X X 2
REFRESH REF L L LL L H X XXXX X 6
POWER-DOWN 
ENTRY PDE L H H X  X  X  X XXXX X
LH H H
POWER-DOWN 
EXIT PDX H L H X  X  X  X XXXX X
LH H H
SELF REFRESH 
ENTRY SRE L H L L L H X XXXX X 6
SELF REFRESH 
EXIT SRX H L H X  X  X  X XXXX X
LH H H

EDW2032BBBG

Data Sheet E1864E10 (Ver. 1.0)

2. Electrical Characteristics

Table 7: Absolute Maximum Ratings

Caution: Stresses greater than those listed under “Absolute Maximum Ratings” may cause permanent

damage of the device. This is a stress rating only, and functional operation of the device at these

or any other conditions above those indicated in the operational sections of these specification

is not implied. Exposure to absolute maximum rating conditions for extended periods may affect

device reliability.

Table 8: Operating Temperature Range

Notes: 1. Operating temperature TC is the case surface temperature on the center / top side of the DRAM. It specifies the

temperature where all DRAM specifications will be supported.

2. For measurement conditions, please refer to JEDEC document JESD51-2.

Parameter Symbol Min. Max. Unit

Voltage on VDD supply relative to VSS VDD -0.5 2.0 V

Voltage on VDDQ supply relative to VSSQ VDDQ -0.5 2.0 V

Voltage on VREF and inputs relative to VSS VIN -0.5 2.0 V

Voltage on I/O pins relative to VSS VOUT -0.5 2.0 V

Storage Temperature TSTG -55 +150 °C

Short Circuit output current IOUT — 50 mA

Parameter Symbol Min Max Unit

Operating temperature TC 0 +95 °C

EDW2032BBBG
Data Sheet E1864E10 (Ver. 1.0)
12
2.1 Operating Conditions
Table 9: DC Operating Conditions
Notes: 1. All voltages are measured at the package pins.
2. GDDR5 SGRAMs are designed to tolerate PCB designs with separate VDDQ and VDD power regulators.
3. AC noise in the system is estimated at 50 mV peak-to-peak for the purpose of DRAM design.
4. Source of reference voltage and control of Reference voltage for DQ and /DBI pins is determined by VREFD, Half 
VREFD and VREFD Offset Mode Registers.
5. VREFD Offsets are not supported with VREFD2.
6. External VREFC is to be provided by the controller as there is no alternative supply.
7. DB, /DBI input slew rate must be greater than or equal to 3V/ns for POD15 and 2.7V/ns for POD135. The slew rate is 
measured between VREFD crossing and VIHD(AC) or VILD(AC) or VREFD2 crossing and VIHD2(AC) or VILD2(AC).
8. ADR/CMD input slew rate must be greater than or equal to 3V/ns for POD15 and 2.7V/ns for POD135. The slew rate 
is measured between VREFC crossing and VIHA(AC) or VILA(AC).
9. VIHX and VILX define the input voltage levels for the receiver that detects x32 mode or x16 mode with /RESET going 
high.
10. IL is measured with ODT off. Any input 0V ≤ VIN ≤ VDDQ; all other pins not under test = 0V.
11. IOZ is measured with DQs disabled; 0V ≤ VOUT ≤ VDDQ.
Parameter Symbol
POD15 POD135
Unit Notemin. typ. max. min. typ. max.
Device supply voltage (-60, -70) VDD 1.552 1.6 1.648 1.3095 1.35 1.3905 V 2
Device supply voltage (-50, -40) VDD 1.455 1.5 1.545 1.3095 1.35 1.3905 V 2
I/O Supply voltage (-60, -70) VDDQ 1.552 1.6 1.648 1.3095 1.35 1.3905 V 2
I/O Supply voltage (-50, -40) VDDQ 1.455 1.5 1.545 1.3095 1.35 1.3905 V 2
Reference voltage for DQ and /DBI pins VREFD 0.69 * 
VDDQ —0.71 * 
VDDQ
0.69 * 
VDDQ —0.71 * 
VDDQ V3,4
Reference voltage for DQ and /DBI pins VREFD2 0.49 * 
VDDQ —0.51 * 
VDDQ
0.49 * 
VDDQ —0.51 * 
VDDQ V 3,4,5
External reference voltage for address and 
command VREFC 0.69 * 
VDDQ —0.71 * 
VDDQ
0.69 * 
VDDQ —0.71 * 
VDDQ V6
DC input logic high voltage for address and 
command inputs VIHA(DC) VREFC 
+ 0.15 ——
VREFC 
+ 0.135 ——V
DC input logic low voltage for address and 
command inputs VILA(DC) — — VREFC
- 0.15 ——
VREFC 
- 0.135 V
DC input logic high voltage for DQ, /DBI 
inputs with VREFD VIHD(DC) VREFD 
+ 0.10 ——
VREFD 
+ 0.09 ——V
DC input logic low voltage for DQ, /DBI 
inputs with VREFD VILD(DC) — — VREFD
- 0.10 ——
VREFD 
- 0.09 V
DC input logic high voltage for DQ, /DBI 
inputs with VREFD2 VIHD2(DC) VREFD2 
+ 0.30 ——
VREFD2 
+ 0.27 ——V
DC input logic low voltage for DQ, /DBI 
inputs with VREFD2 VILD2(DC) — — VREFD2 
- 0.30 ——
VREFD2 
- 0.27 V
Input logic high voltage for /RESET, SEN, 
MF VIHR VDDQ
- 0.5 ——
VDDQ
- 0.5 ——V
Input logic low voltage for /RESET, SEN, MF VILR — — 0.3 — — 0.3 V
Input logic high voltage for EDC1/2 
(x16 mode detect) VIHX VDDQ 
- 0.3 ——
VDDQ 
- 0.3 ——V9
Input logic low voltage for EDC1/2 
(x16 mode detect) VILX — — 0.3 — — 0.3 V 9
Input leakage current 
(any input 0V ≤ VIN ≤ VDDQ; all other pins 
not under test = 0V)
IL -5 — +5 -5 — +5 µA 10
Output leakage current 
(DQs are disabled; 0V ≤ VOUT ≤ VDDQ) IOZ -5 — +5 -5 — +5 µA 11
Output logic low voltage VOL(DC) — — 0.62 — — 0.56 V
External resistor value ZQ 115 120 125 115 120 125 Ω

EDW2032BBBG

Data Sheet E1864E10 (Ver. 1.0)

Table 10: AC Operating Conditions

Notes: 1. All voltages are measured at the package pins.

2. For optimum performance it is recommended that signal swings are larger than shown in the table.

Table 11: Clock Input Operating Conditions

Notes: 1. All voltages are measured at the package pins.

2. This provides a minimum of 0.9V to a maximum of 1.2V, and is nominally 70% of VDDQ with POD15. If POD135, this

provides a minimum of 0.845V to a maximum of 1.045V, and is nominally 70% of VDDQ. DRAM timings relative to CK

cannot be guaranteed if these limits are exceeded.

3. For AC operations, all DC clock requirements must be satisfied as well.

4. The value of VIXCK and VIXWCK is expected to equal 70% VDDQ for the transmitting device and must track variations

in the DC level of the same.

5. VIDCK is the magnitude of the difference between the input level in CK and the input level on /CK. The input reference

level for signals other than CK and /CK is VREFC.

6. VIDWCK is the magnitude of the difference between the input level in WCK and the input level on /WCK. The input

reference level for signals other than WCK and /WCK is either VREFD, VREFD2 or the internal VREFD.

7. The CK and /CK input reference level (for timing referenced to CK and /CK) is the point at which CK and /CK cross.

Please refer to the applicable timings in the AC timings table.

8. The WCK and /WCK input reference level (for timing referenced to WCK and /WCK) is the point at which WCK and

/WCK cross. Please refer to the applicable timings in the AC Timings table.

9. VREFD is either VREFD, VREFD2 or the internal VREFD.

10. The slew rate is measured between VREFC crossing and VIXCK(AC).

11. The slew rate is measured between VREFD crossing and VIXWCK(AC).

Parameter Symbol

POD15 POD135

Unit Notemin. typ. max. min. typ. max.

AC input logic high voltage for address and

command inputs VIHA(AC) VREFC

+ 0.20 ——

VREFC

+ 0.18 ——V

AC input logic low voltage for address and

command inputs VILA(AC) — — VREFC

- 0.20 ——

VREFC

- 0.18 V

AC input logic high voltage for DQ, /DBI

inputs with VREFD VIHD(AC) VREFD

+ 0.15 ——

VREFD

+ 0.135 ——V

AC input logic low voltage for DQ, /DBI

inputs with VREFD VILD(AC) — — VREFD

- 0.15 ——

VREFD

- 0.135 V

AC input logic high voltage for DQ, /DBI

inputs with VREFD2 VIHD2(AC) VREFD2

+ 0.40 ——

VREFD2

+ 0.36 ——V

AC input logic low voltage for DQ, /DBI

inputs with VREFD2 VILD2(AC) — — VREFD2

- 0.40 ——

VREFD2

- 0.36 V

Parameter Symbol

POD15 POD135

Unit Notemin. max. min. max.

Clock input mid-point voltage: CK, /CK VMP(DC) VREFC

- 0.1

VREFC

+ 0.1

VREFC

- 0.1

VREFC

+ 0.1 V2,7

Clock input differential voltage: CK, /CK VIDCK(DC) 0.22 — 0.198 — V 5,7

Clock input differential voltage: CK, /CK VIDCK(AC) 0.40 — 0.36 — V 3,5,7

Clock input differential voltage: WCK, /WCK VIDWCK(DC) 0.20 — 0.18 — V 6,8

Clock input differential voltage: WCK, /WCK VIDWCK(AC) 0.30 — 0.27 — V 3,6,8

Clock input voltage level for CK, /CK,

WCK, /WCK single ended inputs VIN -0.3 VDDQ

+ 0.3 -0.3 VDDQ

+ 0.3 V

CK, /CK single ended slew rate CKslew 3 — 2.7 — V/ns 10

WCK, /WCK single ended slew rate WCKSlew 3 — 2.7 — V/ns 11

Clock input crossing point voltage: CK, /CK VIXCK(AC) VREFC

- 0.12

VREFC

+ 0.12

VREFC

- 0.108

VREFC

+ 0.108 V 3,4,7

Clock input crossing point voltage:

WCK, /WCK VIXWCK(AC) VREFD

- 0.10

VREFD

+ 0.10

VREFD

- 0.09

VREFD

+ 0.09 V3,4,

8,9

EDW2032BBBG

Data Sheet E1864E10 (Ver. 1.0)

3. Package Drawing

170-ball FBGA

Solder ball: Lead free (Sn-Ag-Cu)

ECA-TS2-0327-02

Unit: mm

0.12 S

0.2 S

1.1 ± 0.1

0.35 ± 0.05

12.0 ± 0.1

INDEX MARK

14.0 ± 0.1

0.2 S A

INDEX MARK

170-

0.45 ± 0.05

0.8

0.15 MS

12.8

2.0

10.4

0.8

0.2 S B

EDW2032BBBG

Data Sheet E1864E10 (Ver. 1.0)

NOTES FOR CMOS DEVICES

1 PRECAUTION AGAINST ESD FOR MOS DEVICES

Exposing the MOS devices to a strong electric field can cause destruction of the gate

oxide and ultimately degrade the MOS devices operation. Steps must be taken to stop

generation of static electricity as much as possible, and quickly dissipate it, when once

it has occurred. Environmental control must be adequate. When it is dry, humidifier

should be used. It is recommended to avoid using insulators that easily build static

electricity. MOS devices must be stored and transported in an anti-static container,

static shielding bag or conductive material. All test and measurement tools including

work bench and floor should be grounded. The operator should be grounded using

wrist strap. MOS devices must not be touched with bare hands. Similar precautions

need to be taken for PW boards with semiconductor MOS devices on it.

2 HANDLING OF UNUSED INPUT PINS FOR CMOS DEVICES

No connection for CMOS devices input pins can be a cause of malfunction. If no

connection is provided to the input pins, it is possible that an internal input level may be

generated due to noise, etc., hence causing malfunction. CMOS devices behave

differently than Bipolar or NMOS devices. Input levels of CMOS devices must be fixed

high or low by using a pull-up or pull-down circuitry. Each unused pin should be connected

to VDD or GND with a resistor, if it is considered to have a possibility of being an output

pin. The unused pins must be handled in accordance with the related specifications.

3 STATUS BEFORE INITIALIZATION OF MOS DEVICES

Power-on does not necessarily define initial status of MOS devices. Production process

of MOS does not define the initial operation status of the device. Immediately after the

power source is turned ON, the MOS devices with reset function have not yet been

initialized. Hence, power-on does not guarantee output pin levels, I/O settings or

contents of registers. MOS devices are not initialized until the reset signal is received.

Reset operation must be executed immediately after power-on for MOS devices having

reset function.

CME0107

EDW2032BBBG

Data Sheet E1864E10 (Ver. 1.0)

M01E1007

No part of this document may be copied or reproduced in any form or by any means without the prior

written consent of Elpida Memory, Inc.

Elpida Memory, Inc. does not assume any liability for infringement of any intellectual property rights

(including but not limited to patents, copyrights, and circuit layout licenses) of Elpida Memory, Inc. or

third parties by or arising from the use of the products or information listed in this document. No license,

express, implied or otherwise, is granted under any patents, copyrights or other intellectual property

rights of Elpida Memory, Inc. or others.

Descriptions of circuits, software and other related information in this document are provided for

illustrative purposes in semiconductor product operation and application examples. The incorporation of

these circuits, software and information in the design of the customer's equipment shall be done under

the full responsibility of the customer. Elpida Memory, Inc. assumes no responsibility for any losses

incurred by customers or third parties arising from the use of these circuits, software and information.

[Product applications]

Be aware that this product is for use in typical electronic equipment for general-purpose applications.

Elpida Memory, Inc. makes every attempt to ensure that its products are of high quality and reliability.

However, this product is not intended for use in the product in aerospace, aeronautics, nuclear power,

combustion control, transportation, traffic, safety equipment, medical equipment for life support, or other

such application in which especially high quality and reliability is demanded or where its failure or

malfunction may directly threaten human life or cause risk of bodily injury. Customers are instructed to

contact Elpida Memory's sales office before using this product for such applications.

[Product usage]

Design your application so that the product is used within the ranges and conditions guaranteed by

Elpida Memory, Inc., including the maximum ratings, operating supply voltage range, heat radiation

characteristics, installation conditions and other related characteristics. Elpida Memory, Inc. bears no

responsibility for failure or damage when the product is used beyond the guaranteed ranges and

conditions. Even within the guaranteed ranges and conditions, consider normally foreseeable failure

rates or failure modes in semiconductor devices and employ systemic measures such as fail-safes, so

that the equipment incorporating Elpida Memory, Inc. products does not cause bodily injury, fire or other

consequential damage due to the operation of the Elpida Memory, Inc. product.

[Usage environment]

Usage in environments with special characteristics as listed below was not considered in the design.

Accordingly, our company assumes no responsibility for loss of a customer or a third party when used in

environments with the special characteristics listed below.

Example:

1) Usage in liquids, including water, oils, chemicals and organic solvents.

2) Usage in exposure to direct sunlight or the outdoors, or in dusty places.

3) Usage involving exposure to significant amounts of corrosive gas, including sea air, CL2, H2S, NH3,

SO2, and NOx.

4) Usage in environments with static electricity, or strong electromagnetic waves or radiation.

5) Usage in places where dew forms.

6) Usage in environments with mechanical vibration, impact, or stress.

7) Usage near heating elements, igniters, or flammable items.

If you export the products or technology described in this document that are controlled by the Foreign

Exchange and Foreign Trade Law of Japan, you must follow the necessary procedures in accordance

with the relevant laws and regulations of Japan. Also, if you export products/technology controlled by

U.S. export control regulations, or another country's export control laws or regulations, you must follow

the necessary procedures in accordance with such laws or regulations.

If these products/technology are sold, leased, or transferred to a third party, or a third party is granted

license to use these products, that third party must be made aware that they are responsible for

compliance with the relevant laws and regulations.

The information in this document is subject to change without notice. Before using this document, confirm that this is the latest version.

EDW2032BBBG

Data Sheet E1864E10 (Ver. 1.0)

Revision History

Ver. Date Description

1.0 Dec. 2011 Initial version