MR25H10CDFR - Everspin Technologies, Inc.

MR25H10

1Mb 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temperatures

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

packages

• DirectreplacementforserialEEPROM,Flash,FeRAM

• AEC-Q100Grade1Option

INTRODUCTION

TheMR25H10isa1,048,576-bitmagnetoresistiverandomaccessmemory

(MRAM)deviceorganizedas131,072wordsof8bits.TheMR25H10oersserial

EEPROMandserialFlashcompatibleread/writetimingwithnowritedelaysand

unlimitedread/writeendurance.

Unlikeotherserialmemories,bothreadsandwritescanoccurrandomlyinmemorywithnodelaybetween

writes.TheMR25H10istheidealmemorysolutionforapplicationsthatmuststoreandretrievedataand

programsquicklyusingasmallnumberofI/Opins.

TheMR25H10isavailableineithera5mmx6mm8-pinDFNpackageora5mmx6mm8-pinDFNSmall

Flagpackage.BotharecompatiblewithserialEEPROM,Flash,andFeRAMproducts.

TheMR25H10provideshighlyreliabledatastorageoverawiderangeoftemperatures.Theproductis

oeredwithIndustrial(-40°to+85°C)andAEC-Q100Grade1(-40°Cto+125°C)operatingtemperature

rangeoptions.

CONTENTS

1.DEVICEPINASSIGNMENT.........................................................................2

2.SPICOMMUNICATIONSPROTOCOL......................................................4

3.ELECTRICALSPECIFICATIONS.................................................................10

4.TIMINGSPECIFICATIONS.......................................................................... 12

5.ORDERINGINFORMATION.......................................................................12

6.MECHANICALDRAWING..........................................................................13

7.REVISIONHISTORY......................................................................................15

HowtoReachUs..........................................................................................15

DFN

SmallFlagDFN

RoHS

MR25H10

Overview

TheMR25H10isaserialMRAMwithmemoryarraylogicallyorganizedas128Kx8usingthefourpinin-

terfaceofchipselect(CS),serialinput(SI),serialoutput(SO)andserialclock(SCK)oftheserialperipheral

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.

128KB

MRAM ARRAY

Instruction Decode

Clock Generator

Control Logic

Write Protect

HOLD

SCK

Instruction Register

Address Register

Counter

Data I/O Register

Nonvolatile Status

17 8

1. DEVICE PIN ASSIGNMENT

Figure 1.1 Block Diagram

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

System Conguration

SingleormultipledevicescanbeconnectedtothebusasshowninFigure1.2.PinsSCK,SOandSIare

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

Figure 1.2 System Conguration

MR25H10

Signal Name Pin I/O Function Description

CS 1Input 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 Hold 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 1.1 Pin Functions

Figure 1.3 Pin Diagrams (Top View)

8-Pin DFN or 8-Pin DFN Small Flag Package

DEVICE PIN ASSIGNMENT

MR25H10

2. 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3 1to∞

WRITE WriteDataBytes 00000010 02h3 1to∞

SLEEP EnterSleepMode 10111001 B9h0 0

WAKE ExitSleepMode 10101011 ABh0 0

Table 2.1 Command Codes

MR25H10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

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MR25H10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

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 2.2 Status Register Bit Assignments

MR25H10

SPI COMMUNICATIONS PROTOCOL

Figure 2.1 RDSR

WEL SRWD WP Protected Blocks Unprotected Blocks Status

0X X Protected Protected Protected

10XProtected Writable Writable

1 1 Low Protected Writable Protected

1 1 High Protected Writable Writable

Table 2.4 Memory Protection Modes

Status Register Memory Contents

BP1 BP0 Protected Area Unprotected Area

0 0 None AllMemory

01UpperQuarter LowerThree-Quarters

10 UpperHalf LowerHalf

1 1 All None

Table 2.3 Block Memory Write Protection

Read Status Register (RDSR)

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MR25H10,thewriteinprogressbit(bit0)isnotwrittenbythememorybecause

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

thendrivingCShigh.

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registerbitsBP0andBP1canbemodied.OnceSRWDissetto1,WPmustbehightomodifySRWD,

BP0and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

MR25H10

SPI COMMUNICATIONS PROTOCOL

Figure 2.3 WRDI

Figure 2.2 WREN

Write Enable (WREN)

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

Write Disable (WRDI)

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.

Write Status Register (WRSR)

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.

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

MR25H10

SPI COMMUNICATIONS PROTOCOL

Figure 2.4 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WRSRcommandisenteredbydrivingCSlow,sendingthecommandcodeandstatusregisterwrite

databyte,andthendrivingCShigh.TheWRSRcommandisenteredbydrivingCSlow,sendingthecom-

mandcodeandstatusregisterwritedatabyte,andthendrivingCShigh.

Read Data Bytes (READ)

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

24-bitaddress.Onlyaddressbits0-16aredecodedbythememory.Thedatabytesarereadoutsequen-

tially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termi-

natedbybringCShigh.

Figure 2.5 READ

SCK

24-Bit Address

High Impedance

Instruction (03h)

Data Out 1 Data Out 2

00000011XXX 3

765432107

210

MSB

0 1 2 3 4 5 6 7 8 9 10 28 29 30 31 32 33 34 35 36 37 38 39

MR25H10

SPI COMMUNICATIONS PROTOCOL

Write Data Bytes (WRITE)

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

the24-bitaddress.Onlyaddressbits0-16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soitis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 2.6 WRITE

SCK

24-Bit Address

High Impedance

Instruction (02h)

00000010XXX 321076543210

MSB MSB

0 1 2 3 4 5 6 7 8 9 10 28 29 30 31 32 33 34 35 36 37 38 39

SCK

Data Byte 3

High Impedance

Data Byte NData Byte 2

34 210 76543210

MSB

76543210765

MSB

40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 Mode 3

Mode 0

MR25H10

SPI COMMUNICATIONS PROTOCOL

Enter Sleep Mode (SLEEP)

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

Exit Sleep Mode (WAKE)

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 2.7 SLEEP

Figure 2.8 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

MR25H10

3. ELECTRICAL SPECIFICATIONS

Absolute Maximum Ratings

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 Limit Unit

VDD Supplyvoltage2-0.5to4.0 V

VIN Voltageonanypin2-0.5toVDD+0.5 V

IOUT Outputcurrentperpin ±20 mA

PDPackagepowerdissipation30.600 W

TBIAS Temperatureunderbias Industrial -45to95 °C

AEC-Q100Grade1 -45to130 °C

Tstg StorageTemperature -55to150 °C

TLead Leadtemperature 3minutesmax 260 °C

Hmax_write Maximummagneticeldexposure Write

12,000 A/m

Hmax_read Maximummagneticeldexposure ReadorStandby

1Permanentdevicedamagemayoccurifabsolutemaximumratingsareexceeded.Functionaloperation

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 3.1 Absolute Maximum Ratings1

MR25H10

Symbol Parameter Grade Min Max Unit

VDD Powersupplyvoltage Industrial 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Grade1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 3.2 Operating Conditions

ELECTRICAL SPECIFICATIONS

Symbol Parameter Conditions Min Typical Max Unit

ILI Inputleakagecurrent - - ±1 μA

ILO Outputleakagecurrent - - ±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 3.3 DC Characteristics

Table 3.4 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andSPIbusinactive 90 115 μA

Izz StandbySleepModeCurrent CShighandSPIbusinactive 7 30 μA

MR25H10

4. TIMING SPECIFICATIONS

Table 4.1 Capacitance1

Symbol Parameter Typical Max Unit

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 4.2 AC Measurement Conditions

Figure 4.1 Output Load for Impedance Parameter Measurements

Figure 4.2 Output Load for all Other 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

MR25H10

TIMING SPECIFICATIONS

Power-Up Timing

TheMR25H10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references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 4.3 Power-Up

VDD

(max)

VDD(min)

tPU

Time

Normal Operation

Chip Selection not allowed

Reset state

of the

device

Figure 4.3 Power-Up Timing

MR25H10

TIMING SPECIFICATIONS

Symbol Parameter Conditions 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gure4.4)

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

OutputValidIndustrialGrade VDD=2.7to

3.6v. 0 10 ns

OutputValidIndustrialGrade VDD=3.0to

3.6v. 0 9 ns

OutputValidAEC-Q100Grade1 VDD=3.0to

3.6v. 0 10 ns

tHO OutputHoldTime 0 - ns

HOLDTiming(Seegure4.5)

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

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

1OvertheOperatingTemperatureRangeandCL=30pF

Table 4.4 AC Timing Parameters1

Synchronous Data Timing

MR25H10

Figure 4.5 HOLD Timing

SCK

HOLD

Figure 4.4 Synchronous Data Timing

SCK

High Impedance

VIH

VIL

VIH

VIL

VIH

VIL

VIH

VIL

CSS

tWL

CSH

tDIS

MR25H10

5. ORDERING INFORMATION

Table 5.1 Available Parts

Figure 5.1 Part Numbering System

Package Options

DC 8 Pin DFN on Tray

DCR

DFR

8 Pin DFN on Tape and Reel

8 pin DFN Small Flag on Tray

8 pin DFN Small Flag on Tape and Reel

Temperature Range

C-40 to +85 °C ambient (Industrial)

M-40 to +125 °C ambient (AEC-Q100 Grade 1)

Memory Density

10 1 Mb

Interface

25H High Speed Serial SPI Family

Product Type

MR Magnetoresistive RAM

MR 25H 10 C DC

Grade Temperature

Range Package Shipping Container Order Part Number

Industrial -40to+85C

8-DFN Tray MR25H10CDC

TapeandReel MR25H10CDCR

SmallFlag8-DFN Tray MR25H10CDF

TapeandReel MR25H10CDFR

AEC-Q100Grade1 -40to+125C

8-DFN Tray MR25H10MDC

TapeandReel MR25H10MDCR

SmallFlag8-DFN Tray MR25H10MDF

TapeandReel MR25H10MDFR

MR25H10

6. MECHANICAL DRAWINGS

Figure 6.1 DFN Package

ExposedmetalPad.Donot

connectanythingexceptVSS

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

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

DAP Size

4.4 x 4.4

Detail A

Pin 1 Index

MR25H10

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. Warpageshallnotexceed0.10mm.

4. RefertoJEDECMO-229

6. MECHANICAL DRAWINGS

Figure 6.2 Small Flag DFN 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 N

Max

Min

5.10

4.90

6.10

5.90

0.90

0.80

1.27

BSC

0.45

0.35

0.05

0.00

1.60

1.20

0.70

0.50

2.10

1.90

2.10

1.90

.210

.196 C0.45 R0.20 0.05

0.00

MR25H10

Revision Date Description of Change

0 Sep12,2008 InitialAdvanceInformationRelease

1 Jul10,2009 Changeacloadresistance,tPUto400us,tRDPto400us,Change#ofAddressBytesinTable

2to3,NewPackageDrawing,MakePreliminary

2 Jul16,2009 IncreaseAbsoluteMaxMagneticFieldduringwrite,read,andstandbyto12,000A/m

3 Jan5,2010 Describedblockprotectindetailwithpowersequencing.

4 Feb5,2010 Addedsectionsystemconguration.

5 May17,2010 Removedcommercialspecications.Allpartsmeetindustrialspecications.

6 Sep14,2011

Correctedvarioustypos.Clariedblockandstatusregisterprotectiondescription.RevisedTable3.4PowerSupply

specications.AddedAEC-Q100Grade1orderingoption.RevisedTable3.1,Table3.2,Table4.4revisedandNote2

deleted,revisedFigure5.1andTable5.1.

7November18,

2011

CorrectedVOLinTable3.3toreadVOLMax=VSS+0.2v.OperatingConditionsPowerSupplyVoltageforAEC-Q100

Grade1revisedto3.0-3.6v.Table4.4:OutputValidtVspecicationsrevisedtoincludeVDDrangesforIndustrialand

AEC-Q100Grade1options.CorrectedSIwaveforminFigure2.8.OutputValid,tvforAEC-Q100Graderevisedfrom

9nsmaxto10nsmaxinTable4.4.NewSmallFlagDFNpackageoptionaddedtoPage1Featuresandavailable

partsTable5.1.DFNSmallFlagdrawinganddimensionstableaddedasFigure6.2.Figure6.1,DFNPackage,

cleanedupwithbetterqualitydrawinganddimensiontable.NospecicationswerechangedinFigure6.1.

8October19,

2012

ReformattedtablesforSection3ElectricalCharacteristicsandtimingparameters,Table4.4.RevisedOrderingPart

NumbersTable5.1.RemovedMDFandMDFRoptions.MDCandMDCRoptionsarenowqualied.AddedSmall

FlagDFNillustrations.Revised8-DFNpackagedrawingtoshowcorrectproportionforagandpackage.Cor-

rectederrorsinDFNpackageoutlinedrawings.CorrectedVDDrangeforAEC-Q100tVspecication.

9April17,2013 AddedAutomotiveGradeAEC-Q100Grade1forSmallFlagDFNpackage.

7. REVISION HISTORY

MR25H10

How to Reach Us:

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+1-877-347-MRAM(6726)

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Everspin Technologies, Inc.

Information in this document is provided solely to enable system and software

implementers to use Everspin Technologies products. There are no express or

implied licenses granted hereunder to design or fabricate any integrated circuit

or circuits based on the information in this document. Everspin Technologies

reserves the right to make changes without further notice to any products

herein. Everspin makes no warranty, representation or guarantee regarding the

suitability of its products for any particular purpose, nor does Everspin Technol-

ogies assume any liability arising out of the application or use of any product

or circuit, and specically disclaims any and all liability, including without

limitation consequential or incidental damages. “Typical” parameters, which

may be provided in Everspin Technologies data sheets and/or specications can

and do vary in dierent applications and actual performance may vary over

time. All operating parameters including “Typicals” must be validated for each

customer application by customer’s technical experts. Everspin Technologies

does not convey any license under its patent rights nor the rights of others.

Everspin Technologies products are not designed, intended, or authorized for

use as components in systems intended for surgical implant into the body, or

other applications intended to support or sustain life, or for any other applica-

tion in which the failure of the Everspin Technologies product could create a

situation where personal injury or death may occur. Should Buyer purchase or

use Everspin Technologies products for any such unintended or unauthorized

application, Buyer shall indemnify and hold Everspin Technologies and its of-

cers, employees, subsidiaries, aliates, and distributors harmless against all

claims, costs, damages, and expenses, and reasonable attorney fees arising out

of, directly or indirectly, any claim of personal injury or death associated with

such unintended or unauthorized use, even if such claim alleges that Everspin

Technologies was negligent regarding the design or manufacture of the part.

Everspin™ and the Everspin logo are trademarks of Everspin Technologies, Inc.

All other product or service names are the property of their respective owners.