IS61DDB22M18A-250M3 datasheet, PDF

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IS61DDB22M18A-250M3: DescriptionDDR SRAM, 2MX18, 0.45ns, CMOS, PBGA165, 15 X 17 MM, 1.40 MM HEIGHT, LFBGA-165; Categorystorage storage; File Size453KB，29 Pages; ManufacturerIntegrated Silicon Solution ( ISSI )

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IS61DDB22M18A-250M3 Overview

DDR SRAM, 2MX18, 0.45ns, CMOS, PBGA165, 15 X 17 MM, 1.40 MM HEIGHT, LFBGA-165

IS61DDB22M18A-250M3 Parametric

Parameter Name	Attribute value
Maker	Integrated Silicon Solution ( ISSI )
Parts packaging code	BGA
package instruction	LBGA,
Contacts	165
Reach Compliance Code	compli
ECCN code	3A991.B.2.A
Maximum access time	0.45 ns
Other features	PIPELINED ARCHITECTURE
JESD-30 code	R-PBGA-B165
length	17 mm
memory density	37748736 bi
Memory IC Type	DDR SRAM
memory width	18
Number of functions	1
Number of terminals	165
word count	2097152 words
character code	2000000
Operating mode	SYNCHRONOUS
Maximum operating temperature	70 °C
Minimum operating temperature
organize	2MX18
Package body material	PLASTIC/EPOXY
encapsulated code	LBGA
Package shape	RECTANGULAR
Package form	GRID ARRAY, LOW PROFILE
Parallel/Serial	PARALLEL
Maximum seat height	1.4 mm
Maximum supply voltage (Vsup)	1.89 V
Minimum supply voltage (Vsup)	1.71 V
Nominal supply voltage (Vsup)	1.8 V
surface mount	YES
technology	CMOS
Temperature level	COMMERCIAL
Terminal form	BALL
Terminal pitch	1 mm
Terminal location	BOTTOM
width	15 mm

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IS61DDB22M18A

IS61DDB21M36A

2Mx18, 1Mx36

36Mb DDR-II (Burst 2) CIO SYNCHRONOUS SRAM

FEATURES



1Mx36 and 2Mx18 configuration available.

On-chip delay-locked loop (DLL) for wide data valid

window.

Common I/O read and write ports.

Synchronous pipeline read with self-timed late write

operation.

Double Data Rate (DDR) interface for read and

write input ports.

Fixed 2-bit burst for read and write operations.

Clock stop support.

Two input clocks (K and K#) for address and control

registering at rising edges only.

Two input clocks (C and C#) for data output control.

Two echo clocks (CQ and CQ#) that are delivered

simultaneously with data.

+1.8V core power supply and 1.5V to 1.8V VDDQ,

used with 0.75V to 0.9V VREF.

HSTL input and output interface.

Registered addresses, write and read controls, byte

writes, data in, and data outputs.

Full data coherency.

Boundary scan using limited set of JTAG 1149.1

functions.

Byte write capability.

Fine ball grid array (FBGA) package:

13mmx15mm and 15mmx17mm body size

165-ball (11 x 15) array

Programmable impedance output drivers via 5x

user-supplied precision resistor.

ADVANCED INFORMATION

JULY 2012

DESCRIPTION

The 36Mb IS61DDB21M36A and IS61DDB22M18A are

synchronous, high-performance CMOS static random access

memory (SRAM) devices. These SRAMs have a common I/O

bus. The rising edge of K clock initiates the read/write

operation, and all internal operations are self-timed. Refer to

the

Timing Reference Diagram for Truth Table

for a

description of the basic operations of these DDR-II (Burst of

2) CIO SRAMs.

Read and write addresses are registered on alternating rising

edges of the K clock. Reads and writes are performed in

double data rate.

The following are registered internally on the rising edge of

the K clock:



Read/write address

Read enable



Write enable



Byte writes for first burst address



Data-in for first burst address

The following are registered on the rising edge of the K#

clock:



Byte writes for second burst address



Data-in for second burst address

Byte writes can change with the corresponding data-in to

enable or disable writes on a per-byte basis. An internal write

buffer enables the data-ins to be registered one cycle after

the write address. The first data-in burst is clocked one cycle

later than the write command signal, and the second burst is

timed to the following rising edge of the K# clock.

During the burst read operation, the data-outs from the first

bursts are updated from output registers of the second rising

edge of the C# clock (starting one and half cycles later after

read command). The data-outs from the second bursts are

updated with the third rising edge of the C clock. The K and

K# clocks are used to time the data-outs whenever the C and

C# clocks are tied high.

The device is operated with a single +1.8V power supply and

is compatible with HSTL I/O interfaces.



without notice. ISSI assumes no liability arising out of the application or use of any information, products or services described herein. Customers are advised to

obtain the latest version of this device specification before relying on any published information and before placing orders for products.

Integrated Silicon Solution, Inc. does not recommend the use of any of its products in life support applications where the failure or malfunction of the product can

reasonably be expected to cause failure of the life support system or to significantly affect its safety or effectiveness. Products are not authorized for use in such

applications unless Integrated Silicon Solution, Inc. receives written assurance to its satisfaction, that:

a.) the risk of injury or damage has been minimized;

b.) the user assume all such risks; and

c.) potential liability of Integrated Silicon Solution, Inc is adequately protected under the circumstances

Integrated Silicon Solution, Inc.- www.issi.com

Rev. 00A

7/05/2012

IS61DDB22M18A

IS61DDB21M36A

Ball Descriptions

Symbol

K, K#

Type

Input

Description

Input clock: This input clock pair registers address and control inputs on the rising edge of K, and

registers data on the rising edge of K and the rising edge of K#. K# is ideally 180 degrees out of

phase with K. All synchronous inputs must meet setup and hold times around the clock rising

edges. These balls cannot remain VREF level.

Input clock for output data. C and C# are used to clock out the READ data. They can be used

together to deskew the flight times of various devices on the board back to the controller. See

application example for further details.

Synchronous echo clock outputs: The edges of these outputs are tightly matched to the

synchronous data outputs and can be used as a data valid indication. These signals are free

running clocks and do not stop when Q tri-states.

DLL disable and reset input : when low, this input causes the DLL to be bypassed and reset the

previous DLL information. When high, DLL will start operating and lock the frequency after tCK lock

time. The device behaves in one read latency mode when the DLL is turned off. In this mode, the

device can be operated at a frequency of up to 167 MHz.

Synchronous address inputs: These inputs are registered and must meet the setup and hold times

around the rising edge of K. These inputs are ignored when device is deselected.

Data input and output signals. Input data must meet setup and hold times around the rising edges of

K and K# during WRITE operations. These pins drive out the requested dta when the read

operation is active. Valid output data is synchronized to the respective C and C#, or to the

respective K and K# if C and /C are tied to high. When read access is deselected, DQ0 - DQn are

automatically tri-stated.

See BALL CONFIGURATION figures for ball site location of individual signals.

The x18 device uses DQ0~DQ17. DQ18~DQ35 should be treated as NC pin.

The x36 device uses DQ0~DQ35.

Synchronous Read or Write input. When LD# is low, this input designates the access type (read

when it is High, write when it is Low) for loaded address. R/W# must meet the setup and hold times

around edge of K.

Synchronous load. This input is brought Low when a bus cycle sequence is defined. This definition

includes address and read/write direction.

Synchronous byte writes: When low, these inputs cause their respective byte to be registered and

written during WRITE cycles. These signals are sampled on the same edge as the corresponding

data and must meet setup and hold times around the rising edges of K and #K for each of the two

rising edges comprising the WRITE cycle. See Write Truth Table for signal to data relationship.

HSTL input reference voltage: Nominally VDDQ/2, but may be adjusted to improve system noise

margin. Provides a reference voltage for the HSTL input buffers.

Power supply: 1.8 V nominal. See DC Characteristics and Operating Conditions for range.

Power supply: Isolated output buffer supply. Nominally 1.5 V. See DC Characteristics and Operating

Conditions for range.

Ground of the device

Output impedance matching input: This input is used to tune the device outputs to the system data

bus impedance. DQ and CQ output impedance are set to 0.2xRQ, where RQ is a resistor from this

ball to ground. This ball can be connected directly to VDDQ, which enables the minimum

impedance mode. This ball cannot be connected directly to VSS or left unconnected.

IEEE1149.1 input pins for JTAG.

IEEE1149.1 output pins for JTAG.

No connect: These signals should be left floating or connected to ground to improve package heat

dissipation.

C, C#

CQ, CQ#

Input

Output

Doff#

Input

DQ0 - DQn

Bidir

R/W#

LD#

REF

DDQ

TMS, TDI, TCK

TDO

Input

reference

Power

Ground

Input

Output

N/A

Integrated Silicon Solution, Inc.- www.issi.com

Rev. 00A

7/05/2012

IS61DDB22M18A

IS61DDB21M36A

The write data is provided in a ‘late write’ mode; that is, the data-in corresponding to the first address of the burst, is

presented one cycle later or at the rising edge of the following K clock. The data-in corresponding to the second write

burst address follows next, registered by the rising edge of K#.

The data-in provided for writing is initially kept in write buffers. The information on these buffers is written into the array

on the third write cycle. A read cycle to the last two write address produces data from the write buffers.

Similarly, a

read address followed by the same write address produces the latest write data.

The SRAM maintains data coherency.

During a write, the byte writes independently control which byte of any of the two burst addresses is written (see

X18/X36 Write Truth Tables

and

Timing Reference Diagram for Truth Table).

Whenever a write is disabled (R/W# is high at the rising edge of K), data is not written into the memory.

RQ Programmable Impedance

An external resistor, RQ, must be connected between the ZQ pin on the SRAM and V

to enable the SRAM to adjust

its output driver impedance. The value of RQ must be 5x the value of the intended line impedance driven by the

SRAM. For example, an RQ of 250Ω results in a driver impedance of 50Ω. The allowable range of RQ to guarantee

impedance matching is between 175Ω and 350Ω at V

DDQ

=1.5V. The RQ resistor should be placed less than two inches

away from the ZQ ball on the SRAM module. The capacitance of the loaded ZQ trace must be less than 7.5pF.

The ZQ pin can also be directly connected to V

DDQ

to obtain a minimum impedance setting. ZQ should not be

connected to V

Programmable Impedance and Power-Up Requirements

Periodic readjustment of the output driver impedance is necessary as the impedance is greatly affected by drifts in

supply voltage and temperature. During power-up, the driver impedance is in the middle of allowable impedances

values. The final impedance value is achieved within 1024clock cycles.

Clock Consideration

This device uses an internal DLL for maximum output data valid window. It can be placed in a stopped-clock mode to

minimize power and requires only 1024 cycles to restart. No clocks can be issued until V

reaches its allowable

operating range.

Single Clock Mode

This device can be also operated in single-clock mode. In this case, C and C# are both connected high at power-up

and must never change. Under this condition, K and K# control the output timings. Either clock pair must have both

polarities switching and must never connect to V

REF

, as they are not differential clocks.

Delay Locked Loop (DLL)

Delay Lock Loop (DLL) is a new system to align the output data coincident with clock rising or falling edge to enhance

the output valid timing characteristics. It is locked to the clock frequency and is constantly adjusted to match the clock

frequency. Therefore device can have stable output over the temperature and voltage variation.

DLL has a limitation of locking range and jitter adjustment which are specified as tKHKH and tKCvar respectively in the

AC timing characteristics. In order to turn this feature off, applying logic low to the Doff# pin will bypass this. In the DLL

off mode, the device behaves with one cycle latency and a longer access time which is known in DDR-I or legacy

QUAD mode.

The DLL can also be reset without power down by toggling Doff# pin low to high or stopping the input clocks K and K#

for a minimum of 30ns.(K and K# must be stayed either at higher than VIH or lower than VIL level. Remaining Vref is

not permitted.) DLL reset must be issued when power up or when clock frequency changes abruptly. After DLL being

reset, it gets locked after 2048 cycles of stable clock.

Integrated Silicon Solution, Inc.- www.issi.com

Rev. 00A

7/05/2012

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