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PRELIMINARY

32K x 8 Magnetic Nonvolatile CMOS RAM

CY9C62256

Cypress Semiconductor Corporation

3901 North First Street

San Jose

CA 95134

408-943-2600

Document #: 38-15001 Rev. *E

Revised November 15, 2004

Features

· 100% form, fit, function-compatible with 32K × 8

micropower SRAM (CY62256)
-- Fast Read and Write access: 70 ns
-- Voltage range: 4.5V5.5V operation
-- Low power: 330 mW Active; 495

µW standby

-- Easy memory expansion with CE and OE features
-- TTL-compatible inputs and outputs
-- Automatic power-down when deselected

· Replaces 32K × 8 Battery Backed (BB)SRAM, SRAM,

EEPROM, FeRAM or Flash memory

· Data is automatically Write protected during power loss
· Write Cycles Endurance: > 10

cycles

· Data Retention: > 10 Years
· Shielded from external magnetic fields
· Extra 64 Bytes for device identification and tracking
· Temperature ranges

-- Commercial: 0°C to 70°C
-- Industrial: 40°C to 85°C

· JEDEC STD 28-pin DIP (600-mil), 28-pin (300-mil) SOIC,

and 28-pin TSOP-1 packages. Also available in 450-mil

wide (300-mil body width) 28-pin narrow SOIC.

Functional Description

The CY9C62256 is a high-performance CMOS nonvolatile

RAM employing an advanced magnetic RAM (MRAM)

process. An MRAM is nonvolatile memory that operates as a

fast read and write RAM. It provides data retention for more

than ten years while eliminating the reliability concerns,

functional disadvantages and system design complexities of

battery-backed SRAM, EEPROM, Flash and FeRAM. Its fast

writes and high write cycle endurance makes it superior to

other types of nonvolatile memory.
The CY9C62256 operates very similarly to SRAM devices.

Memory read and write cycles require equal times. The MRAM

memory is nonvolatile due to its unique magnetic process.

Unlike BBSRAM, the CY9C62256 is truly a monolithic nonvol-

atile memory. It provides the same functional benefits of a fast

write without the serious disadvantages associated with

modules and batteries or hybrid memory solutions.
These capabilities make the CY9C62256 ideal for nonvolatile

memory applications requiring frequent or rapid writes in a

bytewide environment.
The CY9C62256 is offered in both commercial and industrial

temperature ranges.

Logic Block Diagram

Pin Configurations

COLUMN

DECODER

W DE

SE AM

INPUTBUFFER

I/O

1
2
3
4
5
6
7

8
9

10
11

20
19

24
23

Top View

SOIC/DIP

28
27

GND

I/O

512x512

ARRAY

I/O

22
23
24
25
26

27
28
1
2

15
14
13
12

19
18
17

I/O

GND

I/O

TSOP I

Top View

(not to scale)

Silicon Sig.

POWER

DOWN &
WRITE
PROTECT

PRELIMINARY

CY9C62256

Document #: 38-15001 Rev. *E

Page 2 of 11

Overview

The CY9C62256 is a byte wide MRAM memory. The memory

array is logically organized as 32,768 x 8 and is accessed

using an industry standard parallel asynchronous SRAM-like

interface. The CY9C62256 is inherently nonvolatile and offers

write protect during sudden power loss. Functional operation

of the MRAM is similar to SRAM-type devices, otherwise.

Memory Architecture
Users access 32,768 memory locations each with eight data

bits through a parallel interface. Internally, the memory array

is organized into eight blocks of 512 rows x 64 columns each.
The access and cycle time are the same for read and write

memory operations. Unlike an EEPROM or Flash, it is not

necessary to poll the device for a ready condition since writes

occur at bus speed.

Memory Operation
The CY9C62256 is designed to operate in a manner similar to

other bytewide memory products. For users familiar with

BBSRAM, the MRAM performance is superior. For users

familiar with EEPROM, Flash and FeRAM, the obvious differ-

ences result from higher write performance of MRAM

technology and much higher write endurance.
All memory array bits are set to logic "1" at the time of

shipment.

Read Operation
A read cycle begins whenever WE (Write Enable bar) is

inactive (HIGH) and CE (Chip Enable bar) and OE (Output

Enable bar) are active LOW. The unique address specified by

the 15 address inputs (A0A14) defines which of the 32,768

bytes of data is to be accessed. Valid data will be available at

the eight output pins within t

(access time) after the last

address input is stable, providing that CE and OE access times

are also satisfied. If CE and OE access times are not satisfied

then the data access must be measured from the

later-occurring signal (CE or OE) and the limiting parameter is

either t

ACE

for CE or t

DOE

for the OE rather than address

access.

Write Cycle
The CY9C62256 initiates a write cycle whenever the WE and

CE signals are active (LOW) after address inputs are stable.

The later occurring falling edge of CE or WE will determine the

start of the write cycle. The write cycle is terminated by the

earlier rising edge of CE or WE. All address inputs must be

kept valid throughout the write cycle. The OE control signal

should be kept inactive (HIGH) during write cycles to avoid bus

contention. However, if the output drivers are enabled (CE and

OE active) WE will disable the outputs in t

HZWE

from the WE

falling edge.
Unlike other nonvolatile memory technologies, there is no

write delay with MRAM. The entire memory operation occurs

in a single bus cycle. Therefore, any operation including read

or write can occur immediately following a write. Data Polling,

a technique used with EEPROMs to determine if the write is

complete is unnecessary. Page write, a technique used to

enhance EEPROM write performance is also unnecessary

because of inherently fast write cycle time for MRAM.
The total Write time for the entire 256K array is 2.3 ms.

Write Inhibit and Data Retention Mode
This feature protects against the inadvertent write. The

CY9C62256 provides full functional capability for V

greater

than 4.5V and write protects the device below 4.0V. Data is

maintained in the absence of V

. During the power-up,

normal operation can resume 20

µs after V

PFD

is reached.

Refer to page 8 for details.

Sudden Power Loss--"Brown Out"
The nonvolatile RAM constantly monitors V

. Should the

supply voltage decay below the operating range, the

CY9C62256 automatically write-protects itself, all inputs

become don't care, and all outputs become high-impedance.

Refer to page 8 for details.

Silicon Signature/Device ID
An extra 64 bytes of MRAM are available to the user for Device

ID. By raising A9 to V

+ 2.0V and by using address locations

00(Hex) to 3F(Hex) on address pins A7, A6, A14, A13, A12

and A0 (MSB to LSB) respectively, the additional Bytes may

be accessed in the same manner as the regular memory array,

with 140 ns access time. Dropping A9 from input high

+ 2.0V) to < V

returns the device to normal operation

after 140-ns delay.

All User Space bits above are set to logic "1" at the time of

shipment.

Magnetic Shielding
CY9C62256 is protected from external magnetic fields through

the application of a "magnetic shield" that covers the entire

memory array.

Applications

Battery-Backed SRAM (BB SRAM) Replacement
CY9C62256 is designed to replace (plug and play) existing

BBSRAM while eliminating the need for battery and V

monitor IC, reducing cost and board space and improving

system reliability.
The cost associated with multiple components and assemblies

and manufacturing overhead associated with battery-backed

SRAM is eliminated by using monolithic MRAM. CY9C62256

eliminates multiple assemblies, connectors, modules, field

maintenance and environmental issues common with BB

SRAM. MRAM is a true nonvolatile RAM with high perfor-

mance, high endurance, and data retention.
Battery-backed SRAMs are forced to monitor V

in order to

switch to the backup battery. Users that are modifying existing

designs to use MRAM in place of BB SRAM, can eliminate the

controller IC along with the battery. MRAM performs this

function on chip.
Cost: The cost of both the component and manufacturing

overhead of battery-backed SRAM is high. In addition, there is

a built in rework step required for battery attachment in case

Address (MSB to LSB)

A7 A6 A14 A13 A12 A0

Description

00h

Manufacturer ID

34h

01h

Device ID

40h

02h 3Fh

User Space

62 Bytes

PRELIMINARY

CY9C62256

Document #: 38-15001 Rev. *E

Page 3 of 11

of surface mount assembly. This can be eliminated with

MRAM. In case of DIP battery backed modules, the assembly

techniques are constrained to through-hole assembly and

board wash using no water.
System Reliability: Battery-backed SRAM is inherently

vulnerable to shock and vibration. In addition, a negative

voltage, even a momentary undershoot, on any pin of a

battery-backed SRAM can cause data loss. The negative

voltage causes current to be drawn directly from the battery,

weakens the battery, and reduces its capacity over time. In

general, there is no way to monitor the lost battery capacity.

MRAM guarantees reliable operation across the voltage range

with inherent nonvolatility.
Space: Battery-backed SRAM in DIP modules takes up board

space height and dictates through-hole assembly. MRAM is

offered in surface mount as well as DIP packages.
Field Maintenance: Batteries must eventually be replaced

and this creates an inherent maintenance problem. Despite

projections of long life, it is difficult to know how long a battery

will last, considering all the factors that degrade them.
Environmental: Lithium batteries are a potential disposal

burden and considered a fire hazard. MRAM eliminates all

such issues through a truly monolithic nonvolatile solution.
Users replacing battery-backed SRAMs with integrated Real

Time Clock (RTC) in the same package may need to move

RTC function to a different location within the system.

EEPROM Replacement
CY9C62256 can also replace EEPROM in current applica-

tions. CY9C62256 is pinout and functionally compatible to

bytewide EEPROM, however it does not need data-bar polling,

page write and hardware write protect due to its fast write and

inadvertent write protect features.
Users replacing EEPROMs with MRAM can eliminate the

page mode operation and simplify to standard asynchronous

write. Additionally, data-bar polling can be eliminated, since

every byte write is completed within same cycle. All writes are

completed within 70 ns.

FeRAM Replacement
FeRAM requires addresses to be latched on falling edge of

CE, which adds to system overhead in managing the CE and

latching function. MRAM eliminates this overhead by offering

a simple asynchronous SRAM interface.
Users replacing FeRAM can simplify their address decoding

since CE does not need to be driven active and then inactive

for each address. This overhead is eliminated when using

MRAM.
Secondly, MRAM read is nondestructive and no precharge

cycle is required like the one used with FeRAM.This has no

apparent impact to the design, however the read cycle time

can now see immediate improvement equal to the precharge

time.

Boot-up PROM (EPROM, PROM) Function Replacement
The CY9C62256 can be accessed like an EPROM or PROM.

When CE and OE are low and WE is high, the data stored at

the memory location determined by the address pins is

asserted on the outputs. MRAM may be used to accomplish

system boot up function using this condition.

PRELIMINARY

CY9C62256

Document #: 38-15001 Rev. *E

Page 4 of 11

Maximum Ratings

(Above which the useful life may be impaired. For user guide-

lines, not tested.)
Storage Temperature .................................65°C to +150°C
Ambient Temperature with

Power Applied...............................................40°C to +85°C
Supply Voltage to Ground Potential

(Pin 28 to Pin 14) ........................................... 0.5V to +7.0V
DC Voltage Applied to Outputs

in High-Z State

[1]

....................................0.5V to V

+ 0.5V

DC Input Voltage

[1]

.................................0.5V to V

+ 0.5V

except in case of Super Voltage pin (A9) while accessing 64

device ID and Silicon signature Bytes.........

-0.5V to V

+ 2.5V

Output Current into Outputs (LOW)............................. 20 mA
Static Discharge Voltage ........................................> 2001V

(per MIL-STD-883, Method 3015)
Latch-up Current..................................................... > 200 mA
Maximum Exposure to Magnetic Field

@ Device Package

[2,3]

............................................ < 20 Oe

Operating Range

Range

Ambient Temperature

Commercial

0°C to +70°C

± 10%

Industrial

40°C to +85°C

± 10%

Electrical Characteristics

Over the Operating Range

Parameter

Description

Test Conditions

CY9C62256-70

Unit

Min.

Typ.

[5]

Max.

Output HIGH Voltage

= Min., I

-1.0 mA

2.4

Output LOW Voltage

= Min., I

= 2.1 mA

0.4

Input HIGH Voltage

2.2

+ 0.5V

Input LOW Voltage

0.5

[1]

0.8

[4]

Input Leakage Current

GND < V

< V

0.5

+0.5

µA

Output Leakage Current

GND < V

< V

, Output Disabled

0.5

+0.5

µA

Operating Supply Current

= Max.,

OUT

= 0 mA,

f = f

MAX

= 1/t

SB1

Automatic CE

Power-down Current--

TTL Inputs

Max. V

, CE > V

> V

< V

, f = f

MAX

500

µA

SB2

Automatic CE

Power-down Current--

CMOS Inputs

Max. V

CE > V

- 0.3V

> V

- 0.3V

or V

< 0.3V, f = 0

µA

Capacitance

[6]

Parameter

Description

Test Conditions

Max.

Unit

Input Capacitance

= 25

°C, f = 1 MHz,

= 5.0V

OUT

Output Capacitance

Notes:

1. V

(min.) = 2.0V for pulse duration of 20 ns.

2. Magnetic field exposure is highly dependent on the distance from the magnetic field source. The magnetic field falls off as 1/R squared, where R is the distance

from the magnetic source.

3. Exposure beyond this level may cause loss of data.
4. I

during access to 64 device ID and silicon signature bytes with super voltage pin at V

+ 2.0V will be 100

A max.

5. Typical specifications are the mean values measured over a large sample size across normal production process variations and are taken at nominal conditions

= 25°C, V

). Parameters are guaranteed by design and characterization, and not 100% tested.

6. Tested initially and after any design or process changes that may affect these parameters.

PRELIMINARY

CY9C62256

Document #: 38-15001 Rev. *E

Page 5 of 11

AC Test Loads and Waveforms

Switching Characteristics

Over the Operating Range

[7]

Parameter

Description

CY9C62256-70

Unit

Min.

Max.

Read Cycle
t

Read Cycle Time

Address to Data Valid

OHA

Data Hold from Address Change

ACE

CE LOW to Data Valid

DOE

OE LOW to Data Valid

LZOE

OE LOW to Low Z

[8]

HZOE

OE HIGH to High Z

[8,9]

LZCE

CE LOW to Low Z

[8]

HZCE

CE HIGH to High Z

[8,9]

CE LOW to Power-up

CE HIGH to Power-down

Write Cycle

[10,11]

Write Cycle Time

SCE

CE LOW to Write End

Address Set-up to Write End

Address Hold from Write End

Address Set-up to Write Start

PWE

WE Pulse Width

Data Set-up to Write End

Data Hold from Write End

HZWE

WE LOW to High Z

[8, 9]

LZWE

WE HIGH to Low Z

[8]

Notes:

7. Test conditions assume signal transition time of 5 ns or less, timing reference levels of 1.5V, input pulse levels of 0 to 3.0V, and output loading of the specified

and 100-pF load capacitance.

8. At any given temperature and voltage condition, t

HZCE

is less than t

LZCE

, t

HZOE

is less than t

LZOE

, and t

HZWE

is less than t

LZWE

for any given device.

9. t

HZOE

, t

HZCE

, and t

HZWE

are specified with C

= 5 pF as in part (b) of AC Test Loads. Transition is measured

±500 mV from steady-state voltage.

10. The internal write time of the memory is defined by the overlap of CE LOW and WE LOW. Both signals must be LOW to initiate a write and either signal can

terminate a write by going HIGH. The data input set-up and hold timing should be referenced to the rising edge of the signal that terminates the write.

11. The minimum write pulse width for write cycle #3 (WE controlled, OE LOW) is the sum of t

HZWE

and t

3.0V

OUTPUT

R1 1800

990

100 pF

INCLUDING

JIG AND

SCOPE

GND

90%

10%

90%

10%

< 5 ns

OUTPUT

R1 1800

990

5 pF

INCLUDING

JIG AND

SCOPE

(a)

(b)

OUTPUT

1.77V

Equivalent to:

THEVENIN EQUIVALENT

ALL INPUT PULSES

639

PRELIMINARY

CY9C62256

Document #: 38-15001 Rev. *E

Page 8 of 11

Power-down/-up Mode AC Waveforms

Parameter

Description

Min.

Typ.

Max.

Unit

PFD

Power-fail Deselect Voltage

4.2

4.35

4.5

[18]

PFD

(max.) to V

PFD

(min.) V

Fall

Time

100

µs

PFD

(min.) to V

Fall Time

µs

to V

PFD

(max.) Rise Time

µs

Write Protect Time On V

= V

PFD

(typ)

µs

REC

PFD

(max.) to Inputs Recognized

500

µs

Vcc

PFD

(max)

PFD

(min)

REC

INPUTS

OUTPUTS

DON'T CARE

RECOGNIZED

VALID

HIGH-Z

PFD

(typ)

Ordering Information

Speed

(ns)

Ordering Code

Package

Name

Package Type

Operating

Range

CY9C62256

-70SC

S21

28-lead (300-mil) Molded SOIC

Commercial

CY9C62256-70SI

S21

28-lead (300-mil) Molded SOIC

Industrial

CY9C62256-70SNC

SN28

28-lead (300-mil) Narrow Body SOIC

Commercial

CY9C62256-70SNI

SN28

28-lead (300-mil) Narrow Body SOIC

Industrial

CY9C62256

-70ZC

Z28

28-lead Thin Small Outline Package

Commercial

CY9C62256

-70ZI

Z28

28-lead Thin Small Outline Package

Industrial

CY9C62256

-70PC

P15

28-lead (600-mil) Molded DIP

Commercial

CY9C62256-70PI

P15

28-lead (600-mil) Molded DIP

Industrial

Note:

18. V

PFD

(max.) to V

PFD

(min.) fall time of less than t

may result in deselection/ write protection not occurring until 20

s after V

passes V

PFD

(min.).

PRELIMINARY

CY9C62256

Document #: 38-15001 Rev. *E

Page 10 of 11

© Cypress Semiconductor Corporation, 2004. The information contained herein is subject to change without notice. Cypress Semiconductor Corporation assumes no responsibility for the use
of any circuitry other than circuitry embodied in a Cypress product. Nor does it convey or imply any license under patent or other rights. Cypress products are not warranted nor intended to be
used for medical, life support, life saving, critical control or safety applications, unless pursuant to an express written agreement with Cypress. Furthermore, Cypress does not authorize its
products for use as critical components in life-support systems where a malfunction or failure may reasonably be expected to result in significant injury to the user. The inclusion of Cypress
products in life-support systems application implies that the manufacturer assumes all risk of such use and in doing so indemnifies Cypress against all charges.

All product and company names mentioned in this document may be the trademarks of their respective holders.

Package Diagrams

(continued)

28-lead Thin Small Outline Package Type 1 (8 × 13.4 mm) Z28

51-85071-*G

DIMENSIONS IN INCHES

MIN.

MAX.

PIN 1 ID

0.291

0.300

0.463

0.477

0.050

TYP.

0.094

0.110

0.002

0.014

SEATING PLANE

0.008

0.012

0.702

0.710

0.020

0.042

0.004

0.014

0.020

0.015

0.032

0.026

OMEDATA

CSPI

DETAIL "A"

0.390

0.420

0.390

0.420

DETAIL "B"

450-mil Wide (300-mil Body Width) 28-pin Narrow SOIC (SN28)

51-85092-*B

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