MR25H256APDF - EVERSPIN TECHNOLOGIES

MR25H256 / MR25H256A

MR25H256A has been released for mass production and is recommended for all new designs.

MR25H256 remains in mass production but will be subject to eventual phase out and end of life

and is not recommended for new designs.Both versions have the same specications.

256Kb Serial SPI MRAM

FEATURES

• No write delays

• Unlimited write endurance

• Data retention greater than 20 years

• Automatic data protection on power loss

• Block write protection

• Fast, simple SPI interface with up to 40 MHz clock rate

• 2.7 to 3.6 Volt power supply range

• Low current sleep mode

• Industrial and Automotive Grade 1 and Grade 3 tempera-

tures

• Available in 8-DFN or 8-DFN Small Flag RoHS-compliant

package.

• Direct replacement for serial EEPROM, Flash, FeRAM

• Industrial Grade and AEC-Q100 Grade 1 and Grade 3 options

• Moisture Sensitivity MSL-3

Small Flag 8-DFN

RoHS

8-DFN

Product Versions and Options

MR25H256A Product Options

Grade Temperature Package

Industrial -40 to +85 C 8-DFN Small Flag

Automotive AEC-Q100 Grade 3 -40 to +85 C 8-DFN Small Flag

Automotive AEC-Q100 Grade 1 -40 to +125 C 8-DFN Small Flag

MR25H256 Product Options (Not recommended for new designs)

Grade Temperature Package

Industrial -40 to +85 C 8-DFN Small Flag

8-DFN

Automotive AEC-Q100 Grade 1 -40 to +125 C 8-DFN Small Flag

8-DFN

MR25H256 / MR25H256A

TABLE OF CONTENTS

OVERVIEW ............................................................................................................................................4

Figure 1 – Block Diagram ........................................................................................................................................... 4

System Conguration .....................................................................................................................4

Figure 2 – System Conguration ............................................................................................................................. 4

DEVICE PIN ASSIGNMENT ...................................................................................................................5

Figure 3 – Pin Diagram All 8-DFN Packages ........................................................................................................ 5

Table 1 – Pin Functions All 8-DFN Packages ....................................................................................................... 5

SPI COMMUNICATIONS PROTOCOL ...................................................................................................6

Table 2 – Command Codes ....................................................................................................................................... 6

Status Register and Block Write Protection ..................................................................................6

Table 3 – Status Register Bit Assignments ........................................................................................................... 6

Table 4 – Block Memory Write Protection ............................................................................................................ 7

Table 5 – Memory Protection Modes .................................................................................................................... 7

Read Status Register (RDSR) ...........................................................................................................7

Figure 4 – RDSR ............................................................................................................................................................. 7

Write Enable (WREN) .......................................................................................................................8

Figure 5 – WREN ............................................................................................................................................................ 8

Write Disable (WRDI) .......................................................................................................................8

Figure 6 – WRDI ............................................................................................................................................................. 8

Write Status Register (WRSR) .........................................................................................................9

Figure 7 – WRSR ............................................................................................................................................................. 9

Read Data Bytes (READ) ............................................................................................................... 10

Figure 8 – READ ...........................................................................................................................................................10

Write Data Bytes (WRITE) ............................................................................................................. 11

Figure 9 – WRITE ..........................................................................................................................................................11

Enter Sleep Mode (SLEEP) ............................................................................................................ 12

Figure 10 – SLEEP ........................................................................................................................................................12

MR25H256 / MR25H256A

Exit Sleep Mode (WAKE) ............................................................................................................... 12

Figure 11 – WAKE ........................................................................................................................................................12

ELECTRICAL SPECIFICATIONS ......................................................................................................... 13

Absolute Maximum Ratings ........................................................................................................ 13

Table 6 – Absolute Maximum Ratings .................................................................................................................13

Table 7 – Operating Conditions .............................................................................................................................14

Table 8 – DC Characteristics ....................................................................................................................................14

Table 9 – Power Supply Characteristics ..............................................................................................................14

TIMING SPECIFICATIONS ................................................................................................................. 15

Table 10 – Capacitance ............................................................................................................................................. 15

Table 11 – AC Measurement Conditions ............................................................................................................15

Figure 12 – Output Load for Impedance Parameter Measurements .......................................................15

Figure 13 – Output Load for All Other Parameter Measurements ............................................................ 15

Power-Up Timing .......................................................................................................................... 16

Table 12 – Power-Up ..................................................................................................................................................16

Figure 14 – Power-Up Timing ................................................................................................................................ 16

Synchronous Data Timing ............................................................................................................ 17

Table 13 – AC Timing Parameters .........................................................................................................................17

Figure 15 – Synchronous Data Timing ................................................................................................................19

Figure 16 – HOLD Timing ........................................................................................................................................ 19

ORDERING INFORMATION ............................................................................................................... 20

Table 14 – Ordering Part Number Decoder Table ...........................................................................................20

Table 15 – Ordering Part Numbers .......................................................................................................................20

PACKAGE OUTLINE DRAWINGS ....................................................................................................... 21

Figure 17 – 8-DFN Small Flag Package ................................................................................................................21

Figure 18 – 8-DFN Package .....................................................................................................................................22

REVISION HISTORY ........................................................................................................................... 23

HOW TO REACH US ........................................................................................................................... 24

Table of Contents - Continued

MR25H256 / MR25H256A

The MR25H256/MR25H256A is a serial MRAM with memory array logically organized as 32Kx8 using the four

pin interface of chip select (CS), serial input (SI), serial output (SO) and serial clock (SCK) of the serial periph-

eral interface (SPI) bus. Serial MRAM implements a subset of commands common to today’s SPI EEPROM

and Flash components allowing MRAM to replace these components in the same socket and interoperate

on a shared SPI bus. Serial MRAM oers superior write speed, unlimited endurance, low standby & operating

power, and more reliable data retention compared to available serial memory alternatives.

32KB

MRAM ARRAY

Instruction Decode

Clock Generator

Control Logic

Write Protect

HOLD

SCK

Instruction Register

Address Register

Counter

Data I/O Register

Nonvolatile Status

15 8

Figure 1 – Block Diagram

Single or multiple devices can be connected to the bus as shown in Figure 2. Pins SCK, SO and SI are com-

mon among devices. Each device requires CS and HOLD pins to be driven separately.

MOSI

MISO

MOSI = Master Out Slave In

MISO = Master In Slave Out

SCK

SCKSISO SCKSISO

HOLD

HOLD HOLDCS CS

SPI

Micro Controller EVERSPIN SPI MRAM 1 EVERSPIN SPI MRAM 2

Figure 2 – System Conguration

OVERVIEW

System Conguration

MR25H256 / MR25H256A

Signal Name Pin I/O Function Description

CS 1 Input Chip Select

An active low chip select for the serial MRAM. When chip select is high, the

memory is powered down to minimize standby power, inputs are ignored

and the serial output pin is Hi-Z. Multiple serial memories can share a com-

mon set of data pins by using a unique chip select for each memory.

SO 2 Output Serial Output

The data output pin is driven during a read operation and remains Hi-Z at

all other times. SO is Hi-Z when HOLD is low. Data transitions on the data

output occur on the falling edge of SCK.

WP 3 Input Write Protect A low on the write protect input prevents write operations to the Status

VSS 4 Supply Ground Power supply ground pin.

SI 5 Input Serial Input

All data is input to the device through this pin. This pin is sampled on the

rising edge of SCK and ignored at other times. SI can be tied to SO to create

a single bidirectional data bus if desired.

SCK 6 Input Serial Clock

Synchronizes the operation of the MRAM. The clock can operate up to 40

MHz to shift commands, address, and data into the memory. Inputs are

captured on the rising edge of clock. Data outputs from the MRAM occur

on the falling edge of clock. The serial MRAM supports both SPI Mode 0

(CPOL=0, CPHA=0) and Mode 3 (CPOL=1, CPHA=1). In Mode 0, the clock is

normally low. In Mode 3, the clock is normally high. Memory operation is

static so the clock can be stopped at any time.

HOLD 7 Input Hold

A low on the Hold pin interrupts a memory operation for another task.

When HOLD is low, the current operation is suspended. The device will

ignore transitions on the CS and SCK when HOLD is low. All transitions of

HOLD must occur while CS is low.

VDD 8 Supply Power Supply Power supply voltage from +2.7 to +3.6 volts.

HOLD

SCK

Table 1 – Pin Functions All 8-DFN Packages

Figure 3 – Pin Diagram All 8-DFN Packages

Top View

DEVICE PIN ASSIGNMENT

MR25H256 / MR25H256A

SPI COMMUNICATIONS PROTOCOL

Instruction Description Binary Code Hex Code Address Bytes Data Bytes

WREN Write Enable 0000 0110 06h 0 0

WRDI Write Disable 0000 0100 04h 0 0

RDSR Read Status Register 0000 0101 05h 0 1

WRSR Write Status Register 0000 0001 01h 0 1

READ Read Data Bytes 0000 0011 03h 2 1 to ∞

WRITE Write Data Bytes 0000 0010 02h 2 1 to ∞

SLEEP Enter Sleep Mode 1011 1001 B9h 0 0

WAKE Exit Sleep Mode 1010 1011 ABh 0 0

Table 2 – Command Codes

The status register consists of the 8 bits listed in table 2.2. Status register bits BP0 and BP1 dene the mem-

ory block arrays that are protected as described in table 2.3. The Status Register Write Disable bit (SRWD)

is used in conjunction with bit 1 (WEL) and the Write Protection pin (WP) as shown in table 2.4 to enable

writes to status register bits. The fast writing speed of MR25H256/MR25H256A does not require write status

bits. The state of bits 6,5,4, and 0 can be user modied and do not aect memory operation. All bits in the

status register are pre-set from the factory to the “0” state.

Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0

SRWD Don’t Care Don’t Care Don’t Care BP1 BP0 WEL Don’t Care

Table 3 – Status Register Bit Assignments

MR25H256/MR25H256A can be operated in either SPI Mode 0 (CPOL=0, CPHA =0) or SPI Mode 3 (CPOL=1,

CPHA=1). For both modes, inputs are captured on the rising edge of the clock and data outputs occur on

the falling edge of the clock. When not conveying data, SCK remains low for Mode 0; while in Mode 3, SCK

is high. The memory determines the mode of operation (Mode 0 or Mode 3) based upon the state of the

SCK when CS falls.

All memory transactions start when CS is brought low to the memory. The rst byte is a command code. De-

pending upon the command, subsequent bytes of address are input. Data is either input or output. There

is only one command performed per CS active period. CS must go inactive before another command can

be accepted. To ensure proper part operation according to specications, it is necessary to terminate each

access by raising CS at the end of a byte (a multiple of 8 clock cycles from CS dropping) to avoid partial or

aborted accesses.

Status Register and Block Write Protection

MR25H256 / MR25H256A

WEL SRWD WP Protected Blocks Unprotected Blocks Status

0 X X Protected Protected Protected

1 0 X Protected Writable Writable

1 1 Low Protected Writable Protected

1 1 High Protected Writable Writable

Status Register Memory Contents

BP1 BP0 Protected Area Unprotected Area

0 0 None All Memory

0 1 Upper Quarter Lower Three-Quarters

1 0 Upper Half Lower Half

1 1 All None

The Read Status Register (RDSR) command allows the Status Register to be read. The Status Register can be

read at any time to check the status of write enable latch bit, status register write protect bit, and block write

protect bits. For MR25H256/MR25H256A, the write in progress bit (bit 0) is not written by the memory be-

cause there is no write delay. The RDSR command is entered by driving CS low, sending the command code,

and then driving CS high.

Figure 4 – RDSR

When WEL is reset to 0, writes to all blocks and the status register are protected. When WEL is set to 1, BP0

and BP1 determine which memory blocks are protected. While SRWD is reset to 0 and WEL is set to 1, status

BP1.

SCK

Status Register Out

High Impedance High Z

Mode 3

Mode 0

10 2 3 4 5 6 7 0 1 2 3 4 5 6 7

00000101

MSB

76543210

Table 4 – Block Memory Write Protection

Table 5 – Memory Protection Modes

Read Status Register (RDSR)

MR25H256 / MR25H256A

The Write Enable (WREN) command sets the Write Enable Latch (WEL) bit in the status register to 1. The WEL

bit must be set prior to writing in the status register or the memory. The WREN command is entered by driv-

ing CS low, sending the command code, and then driving CS high.

The Write Disable (WRDI) command resets the WEL bit in the status register to 0. This prevents writes to

status register or memory. The WRDI command is entered by driving CS low, sending the command code,

and then driving CS high.

The WEL bit is reset to 0 on power-up or completion of WRDI.

Figure 6 – WRDI

Figure 5 – WREN

SCK

Instruction (06h)

High Impedance

Mode 3

Mode 0

Mode 3

Mode 0

10 234567

00000110

SCK

Instruction (04h)

High Impedance

Mode 3

Mode 0

Mode 3

Mode 0

10 234567

00000100

Write Enable (WREN)

Write Disable (WRDI)

MR25H256 / MR25H256A

Figure 7 – WRSR

SCK

Status Register In

High Impedance

Mode 3

Mode 0

Instruction (01h)

0000000176543210

MSB

0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15

The Write Status Register (WRSR) command allows new values to be written to the Status Register. The

WRSR command is not executed unless the Write Enable Latch (WEL) has been set to 1 by executing a WREN

command while pin WP and bit SRWD correspond to values that make the status register writable as seen in

table 2.4. Status Register bits are non-volatile with the exception of the WEL which is reset to 0 upon power

cycling.

The WRSR command is entered by driving CS low, sending the command code and status register write data

byte, and then driving CS high.

Write Status Register (WRSR)

MR25H256 / MR25H256A

The Read Data Bytes (READ) command allows data bytes to be read starting at an address specied by the

16-bit address. Only address bits 0-14 are decoded by the memory. The data bytes are read out sequentially

from memory until the read operation is terminated by bringing CS high The entire memory can be read in a

single command. The address counter will roll over to 0000h when the address reaches the top of memory.

The READ command is entered by driving CS low and sending the command code. The memory drives the

read data bytes on the SO pin. Reads continue as long as the memory is clocked. The command is terminat-

ed by bring CS high.

Figure 8 – READ

SCK

16-Bit Address

High Impedance

Instruction (03h)

Data Out 1 Data Out 2

00000011X 3

765432107

210

MSB

0 1 2 3 4 5 6 7 8 9 10 20 21 22 23 24 25 26 27 28 29 30 31

14 13

Read Data Bytes (READ)

MR25H256 / MR25H256A

The Write Data Bytes (WRITE) command allows data bytes to be written starting at an address specied by

the 16-bit address. Only address bits 0-14 are decoded by the memory. The data bytes are written sequen-

tially in memory until the write operation is terminated by bringing CS high. The entire memory can be

written in a single command. The address counter will roll over to 0000h when the address reaches the top

of memory.

Unlike EEPROM or Flash Memory, MRAM can write data bytes continuously at its maximum rated clock

speed without write delays or data polling. Back to back WRITE commands to any random location in mem-

ory can be executed without write delay. MRAM is a random access memory rather than a page, sector, or

block organized memory making it ideal for both program and data storage.

The WRITE command is entered by driving CS low, sending the command code, and then sequential write

data bytes. Writes continue as long as the memory is clocked. The command is terminated by bringing CS

high.

Figure 9 – WRITE

SCK

16-Bit Address

High Impedance

Instruction (02h)

00000010X 321076543210

MSB MSB

012345678910 20 21 22 23 24 25 26 27 28 29 30 31

14 13

SCK

Data Byte 3

High Impedance

Data Byte NData Byte 2

34 210 76543210

MSB

76543210765

MSB

32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 Mode 3

Mode 0

Write Data Bytes (WRITE)

MR25H256 / MR25H256A

The Enter Sleep Mode (SLEEP) command turns o all MRAM power regulators in order to reduce the overall

chip standby power to 3 μA typical. The SLEEP command is entered by driving CS low, sending the com-

mand code, and then driving CS high. The standby current is achieved after time, tDP. If power is removed

when the part is in sleep mode, upon power restoration, the part enters normal standby. The only valid

command following SLEEP mode entry is a WAKE command.

The Exit Sleep Mode (WAKE) command turns on internal MRAM power regulators to allow normal operation.

The WAKE command is entered by driving CS low, sending the command code, and then driving CS high.

The memory returns to standby mode after tRDP. The CS pin must remain high until the tRDP period is over.

Figure 10 – SLEEP

Figure 11 – WAKE

SCK

Standby CurrentActive Current

Mode 3

Mode 0

Sleep Mode Current

Instruction (B9h)

10111001

01234567

SCK

Sleep Mode Current

Mode 3

Mode 0

Standby Current

Instruction (ABh)

10101 011

01234567

RDP

Enter Sleep Mode (SLEEP)

Exit Sleep Mode (WAKE)

MR25H256 / MR25H256A

ELECTRICAL SPECIFICATIONS

This device contains circuitry to protect the inputs against damage caused by high static voltages or electric

elds; however, it is advised that normal precautions be taken to avoid application of any voltage greater

than maximum rated voltages to these high-impedance (Hi-Z) circuits.

The device also contains protection against external magnetic elds. Precautions should be taken to avoid

application of any magnetic eld more intense than the eld intensity specied in the maximum ratings.

Symbol Parameter Conditions Value 1Unit

VDD Supply voltage 2All -0.5 to 4.0 V

VIN Voltage on any pin 2All -0.5 to VDD + 0.5 V

IOUT Output current per pin All ±20 mA

PDPackage power dissipation 3All 0.600 W

TBIAS Temperature under bias

Industrial -45 to 95 °C

AEC-Q100 Grade 3 -45 to 95 °C

AEC-Q100 Grade 1 -45 to 135 °C

Tstg Storage Temperature All -55 to 150 °C

TLead

Lead temperature during solder (3

minute max) All 260 °C

Hmax_write Maximum magnetic eld (Write) During Write 12,000 A/m

Hmax_read

Maximum magnetic eld (Read or

Standby)

During Read or

Standby 12,000 A/m

Notes:

1. Permanent device damage may occur if absolute maximum ratings are exceeded. Functional opera-

tion should be restricted to recommended operating conditions. Exposure to excessive voltages or

magnetic elds could aect device reliability.

2. All voltages are referenced to VSS. The DC value of VIN must not exceed actual applied VDD by more

than 0.5V. The AC value of VIN must not exceed applied VDD by more than 2V for 10ns with IIN limited

to less than 20mA.

3. Power dissipation capability depends on package characteristics and use environment.

Table 6 – Absolute Maximum Ratings

Absolute Maximum Ratings

MR25H256 / MR25H256A

Symbol Parameter Grade Min Typical Max Unit

VDD Power supply voltage

Industrial 2.7 - 3.6 V

AEC-Q100 Grade 3 2.7 - 3.6 V

AEC-Q100 Grade1 3.0 - 3.6 V

VIH Input high voltage All 2.2 - VDD + 0.3 V

VIL Input low voltage All -0.5 - 0.8 V

TATemperature under bias

Industrial -40 - 85 °C

AEC-Q100 Grade 3 -40 - 85 °C

AEC-Q100 Grade 1 1-40 - 125 °C

1. AEC-Q100 Grade 1 temperature profile assumes 10 percent duty cycle at maximum temperature (2 years

out of 20-year life.)

Table 7 – Operating Conditions

Symbol Parameter Conditions Min Typical Max Unit

ILI Input leakage current All - - ±1 μA

ILO Output leakage current All - - ±1 μA

VOL Output low voltage

IOL = +4 mA - - 0.4 V

IOL = +100 μA - - VSS + 0.2v V

VOH Output high voltage

IOH = -4 mA 2.4 - - V

IOH = -100 μA VDD - 0.2 - - V

Table 8 – DC Characteristics

Table 9 – Power Supply Characteristics

Symbol Parameter Conditions Typical Max Unit

IDDR Active Read Current

@ 1 MHz 2.5 3 mA

@ 40 MHz 6 10 mA

IDDW Active Write Current

@ 1 MHz 8 13 mA

@ 40 MHz 23 27 mA

ISB Standby Current CS High 190 115 μA

IZZ Standby Sleep Mode Current CS High 7 30 μA

1. ISB current is specied with CS high and the SPI bus inactive.

MR25H256 / MR25H256A

TIMING SPECIFICATIONS

Table 10 – Capacitance

Symbol Parameter Typical Max 1Unit

CIn Control input capacitance - 6 pF

CI/O Input/Output capacitance - 8 pF

1. ƒ = 1.0 MHz, dV = 3.0 V, TA = 25 °C, periodically sampled rather than 100% tested.

Table 11 – AC Measurement Conditions

Figure 12 – Output Load for Impedance Parameter Measurements

Parameter Value Unit

Logic input timing measurement reference level 1.5 V

Logic output timing measurement reference level 1.5 V

Logic input pulse levels 0 or 3.0 V

Input rise/fall time 2 ns

Output load for low and high impedance parameters See Figure 4.1

Output load for all other timing parameters See Figure 4.2

Output

L= 1.5 V

RL= 50 Ω

ZD= 50 Ω

Output

435 Ω

590 Ω

30 pF

3.3 V

Figure 13 – Output Load for All Other Parameter Measurements

MR25H256 / MR25H256A

The MR25H256/MR25H256A is not accessible for a start-up time tPU = 400 μs after power up. Users must

wait this time from the time when VDD (min) is reached until the rst CS low to allow internal voltage refer-

ences to become stable. The CS signal should be pulled up to VDD so that the signal tracks the power supply

during power-up sequence.

Symbol Parameter Min Typical Max Unit

VWI Write Inhibit Voltage 2.2 - 2.7 V

tPU Startup Time 400 - - μs

Table 12 – Power-Up

VDD

(max)

VDD(min)

tPU

Time

Normal Operation

Chip Selection not allowed

Reset state

of the

device

Figure 14 – Power-Up Timing

Power-Up Timing

MR25H256 / MR25H256A

Over the Operating Temperature Range and CL = 30 pF

Symbol Parameter Min Max Unit

fSCK SCK Clock Frequency 0 40 MHz

tRI Input Rise Time - 50 ns

tRF Input Fall Time - 50 ns

tWH SCK High Time 11 - ns

tWL SCK Low Time 11 - ns

Synchronous Data Timing (See “Figure 15 – Synchronous Data Timing” on page 19

tCS CS High Time 40 - ns

tCSS CS Setup Time 10 - ns

tCSH CS Hold Time 10 - ns

tSU Data In Setup Time 5 - ns

tHData In Hold Time 5 - ns

tVOutput Valid

Industrial Grade

VDD = 2.7 to 3.6v. 0 10 ns

VDD = 3.0 to 3.6v. 0 9 ns

AEC Q-100 Grade 3

VDD = 2.7 to 3.6v. 0 10 ns

VDD = 3.0 to 3.6v. 0 9 ns

AEC Q-100 Grade 1 VDD = 3.0 to 3.6v. 0 10 ns

Table continues next page.

Table 13 – AC Timing Parameters

Synchronous Data Timing

MR25H256 / MR25H256A

Symbol Parameter Min Max Unit

tHO Output Hold Time 0 - ns

HOLD Timing

tHD HOLD Setup Time 10 - ns

tCD HOLD Hold Time 10 - ns

tLZ HOLD to Output Low Impedance - 20 ns

tHZ HOLD to Output High Impedance - 20 ns

Other Timing Specications (See “Figure 16 – HOLD Timing” on page 19)

tWPS WP Setup To CS Low 5 - ns

tWPH WP Hold From CS High 5 - ns

tDP Sleep Mode Entry Time 3 - μs

tRDP Sleep Mode Exit Time 400 - μs

tDIS Output Disable Time 12 - ns

AC Timing Parameters (Continued)

MR25H256 / MR25H256A

Figure 16 – HOLD Timing

SCK

HOLD

Figure 15 – Synchronous Data Timing

SCK

High Impedance

VIH

VIL

VIH

VIL

VIH

VIL

VIH

VIL

CSS

tWL

CSH

tDIS

MR25H256 / MR25H256A

ORDERING INFORMATION

Table 14 – Ordering Part Number Decoder Table

Table 15 – Ordering Part Numbers

Grade Temperature Package Shipping Container Order Part Number

Industrial -40 to +85 C 8-DFN Small Flag Trays MR25H256ACDF

Tape and Reel MR25H256ACDFR

AEC-Q100 Grade 3 -40 to +85 C 8-DFN Small Flag Trays MR25H256APDF

Tape and Reel MR25H256APDFR

AEC-Q100 Grade 1 -40 to +125 C 8-DFN Small Flag Trays MR25H256AMDF

Tape and Reel MR25H256AMDFR

Industrial -40 to +85 C 8-DFN Small Flag Trays MR25H256CDF 1

Tape and Reel MR25H256CDFR 1

Industrial -40 to +85 C 8-DFN Trays MR25H256CDC 1

Tape and Reel MR25H256CDCR 1

AEC-Q100 Grade 1 -40 to +125 C 8-DFN Small Flag Trays MR25H256MDF 1

Tape and Reel MR25H256MDFR 1

AEC-Q100 Grade 1 -40 to +125 C 8-DFN Trays MR25H256MDC 1

Tape and Reel MR25H256MDCR 1

Note:

1. Not recommended for new designs.

Memory Speed Voltage Density Revision Temp Package Grade

Example Ordering Part Number MR 25 H 256 A C DF

Everspin MRAM MR

40 MHz 25

3.0v. Vdd H

256 Kb 256

No Revision Blank

Revision A A

Revision B B

Industrial -40 to 85°C C

AEC Q-100 Grade 3 -40 to 85°C P

AEC-Q100 Grade 1 -40 to 125°C M

8-pin DFN DC

8-pin DFN Tape and Reel DCR

8-pin DFN (small ﬂag) in Tray DF

8-pin DFN (small ﬂag) Tape and Reel DFR

Engineering Samples ES

Customer Samples CS

Mass Producon Blank

MR25H256 / MR25H256A

Detail A

Pin 1 Index

0.10 C2X

NOTE:

1. All dimensions are in mm. Angles in degrees.

2. Coplanarity applies to the exposed pad as well as the terminals. Coplanarity shall be

within 0.08 mm.

3. Refer to JEDEC MO-229-E

PACKAGE OUTLINE DRAWINGS

Figure 17 – 8-DFN Small Flag Package

Exposed metal Pad. Do not con-

nect anything except VSS

Dimension A B C D E F G H I J K L M

Max 5.10 6.10 0.90 - 0.45 0.05 1.54 0.70 2.10 2.10 0.210 - -

Nominal 5.00 6.00 0.85

1.27

BSC

0.40 - 1.40 0.60 2.00 2.00 0.200 C0.45 R0.20

Min 4.90 5.90 0.80 - 0.35 0.00 1.26 0.50 1.90 1.90 0.190 - -

MR25H256 / MR25H256A

DAP Size

4.4 x 4.4

Detail A

Pin 1 Index

NOTE:

1. All dimensions are in mm. Angles in degrees.

2. Coplanarity applies to the exposed pad as well as the terminals. Coplanarity shall be

within 0.08 mm.

3. Warpage shall not exceed 0.10 mm.

4. Refer to JEDEC MO-229-E

Figure 18 – 8-DFN Package

Exposed metal Pad. Do not

connect anything except VSS

Dimension A B C D E F G H I J K L M N

Max.

Min.

5.10

4.90

6.10

5.90

1.00

0.90

1.27

BSC

0.45

0.35

0.05

0.00

0.35

Ref.

0.70

0.50

4.20

4.00

4.20

4.00

0.261

0.195

C0.35 R0.20

0.05

0.00

Not Recommended for New Designs

MR25H256 / MR25H256A

Revision Date Description of Change

0.1 June 1, 2015 First Draft

0.2 September 29,

2015 Added Grade 3 parameters to Table 4.4 and reformatted the table.

0.3 November 2, 2015 Revised Part Number Decoder Table.

1.0 October 1, 2016

Production release. Removed all Preliminary status statements and

indications. Added nominal values to DFN package outline dimensions

table.

1.1 October 12, 2016 Combined with MR25H256 to make single data sheet for both product

families.

1.2 December 13,

2016 Revised product name in header.

1.3 December 20,

2016 Minor Revisions. 8-DFN package option will remain.

1.4 February 1, 2017 Added tHO and tV relationship to Synchronous Data Timing

REVISION HISTORY

MR25H256 / MR25H256A

Information in this document is provided solely to enable system and soft-

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Everspin Technologies reserves the right to make changes without further

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lar purpose, nor does Everspin Technologies assume any liability arising

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or incidental damages. “Typical” parameters, which may be provided in

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Filename:

EST02896 MR25H256-MR25H256A Combined Datasheet_Rev1.4 020117