MR0A08B
128K x 8 MRAM Memory
FEATURES
• Fast35nsRead/WriteCycle
• SRAMCompatibleTiming,UsesExistingSRAMControllersWithout
Redesign
• UnlimitedRead&WriteEndurance
• DataAlwaysNon-volatilefor>20-yearsatTemperature
• OneMemoryReplacesFlash,SRAM,EEPROMandBBSRAMin
SystemforSimpler,MoreEcientDesign
• Replacebattery-backedSRAMsolutionswithMRAMtoeliminate
batteryassemblyimprovingreliability
• 3.3VoltPowerSupply
• AutomaticDataProtectiononPowerLoss
• Commercial,Industrial,AutomotiveTemperatures
• RoHS-CompliantSRAMTSOPIIPackage
• RoHS-CompliantSRAMBGAPackageShrinksBoardAreaByThree
Times
INTRODUCTION
TheMR0A08Bisa1,048,576-bitmagnetoresistiverandomaccess
memory(MRAM)deviceorganizedas
131,072wordsof8bits.TheMR0A08BoersSRAMcompatible35
nsread/writetimingwithunlimitedendurance.Dataisalwaysnon-
volatileforgreaterthan20-years.Dataisautomaticallyprotected
onpowerlossbylow-voltageinhibitcircuitrytopreventwriteswithvoltageoutofspecication.The
MR0A08Bistheidealmemorysolutionforapplicationsthatmustpermanentlystoreandretrievecritical
dataandprogramsquickly.
TheMR0A08Bisavailableinsmallfootprint400-mil,44-leadplasticsmall-outlineTSOPtype-IIpackageor
8mmx8mm,48-pinballgridarray(BGA)packagewith0.75mmballcenters.Thesepackagesarecompat-
iblewithsimilarlow-powerSRAMproductsandothernon-volatileRAMproducts.
TheMR0A08Bprovideshighlyreliabledatastorageoverawiderangeoftemperatures.Theproductisof-
feredwithcommercialtemperature(0to+70°C),industrialtemperature(-40to+85°C),andautomotive
temperature(-40to+125°C)rangeoptions.
DocumentNumber:MR0A08BRev.2,6/20091
RoHS
CONTENTS
1.DEVICEPINASSIGNMENT.........................................................................2
2.ELECTRICALSPECIFICATIONS.................................................................4
3.TIMINGSPECIFICATIONS.......................................................................... 7
4.ORDERINGINFORMATION.......................................................................12
5.MECHANICALDRAWING..........................................................................13
6.REVISIONHISTORY......................................................................................15
HowtoReachUs..........................................................................................15
EverspinTechnologies©2009
DocumentNumber:MR0A08BRev.2,6/20092
CHIP
ENABLE
BUFFER
OUTPUT
ENABLE
BUFFER
ADDRESS
BUFFER
WRITE
ENABLE
BUFFER
G
E
17
OUTPUT ENABLE
128k x 8
BIT
MEMORY
ARRAY
ROW
DECODER COLUMN
DECODER
SENSE
AMPS
OUTPUT
BUFFER
WRITE
DRIVER
FINAL
WRITE
DRIVERS
WRITE ENABLE
W
A[16:0]
10
7
88
8
8
8
8
DQ[7:0]
1. DEVICE PIN ASSIGNMENT
Figure 1.1 Block Diagram
Table 1.1 Pin Functions
Signal Name Function
A AddressInput
E ChipEnable
W WriteEnable
G OutputEnable
DQ DataI/O
VDD PowerSupply
VSS Ground
DC DoNotConnect
NC NoConnection-Pin2,40,41,43(TSOPII),BallD3,H1,H6,G2(BGA)ReservedForFutureExpansion
MR0A08B
EverspinTechnologies©2009
A
A
A
A
DQ0
DQ1
VDD
E
VSS
DQ2
DQ3
W
A
A
A
DC
A
DC 22
21
20
19
18
17
16
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44 DC
NC
NC
NC
DC
A
G
DQ7
DQ6
VSS
A
VDD
DQ5
DQ4
DC
A
A
A
A
A
DC
DC
A
A
DC
NC
123456
G A0 A1 A2 A
A3 A4 EB
DQ0 A5 A6
DQ5
DQ4 C
VSS
A15
DQ6
VDD D
VDD
DQ1
DC
NC
A14
VSS E
DQ3
DQ2
A12 A13
DQ7 F
NC
NC
A10 A11
WG
NC
NC
A7
A9 NC H
NC
NCNC
NC
NC
DCDC
DCDC
A16
A8
DocumentNumber:MR0A08BRev.2,6/20093
Figure 1.2 Pin Diagrams for Available Packages (Top View)
44 Pin TSOP II 48 Pin FBGA
Table 1.2 Operating Modes
E1G1W1Mode VDD Current DQ[7:0]2
HX X Notselected ISB1,ISB2 Hi-Z
L H H Outputdisabled IDDR Hi-Z
L L H ByteRead IDDR DOut
LXL ByteWrite IDDW Din
1H=high,L=low,X=don’tcare
2Hi-Z=highimpedance
DEVICE PIN ASSIGNMENT MR0A08B
EverspinTechnologies©2009
2. 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maximumeldintensityspecied
inthemaximumratings.
DocumentNumber:MR0A08BRev.2,6/20094
Parameter Symbol Value Unit
Supplyvoltage2VDD -0.5to4.0 V
Voltageonanpin2VIN -0.5toVDD+0.5 V
Outputcurrentperpin IOUT ±20 mA
Packagepowerdissipation PD0.600 W
Temperatureunderbias
MR0A08B(Commercial)
MR0A08BC(Industrial)
MR0A08BM(Automotive)
TBIAS
-10to85
-45to95
-45to130
°C
StorageTemperature Tstg -55to150 °C
Leadtemperatureduringsolder(3minutemax) TLead 260 °C
Maximummagneticeldduringwrite
MR0A08B(AllTemperatures) Hmax_write 2000 A/m
Maximummagneticeldduringreadorstandby Hmax_read 8000 A/m
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.
3 Powerdissipationcapabilitydependsonpackagecharacteristicsanduseenvironment.
Table 2.1 Absolute Maximum Ratings1
MR0A08B
EverspinTechnologies©2009
DocumentNumber:MR0A08BRev.2,6/20095
Parameter Symbol Value Typical Max Unit
Powersupplyvoltage VDD 3.0i3.3 3.6 V
Writeinhibitvoltage VWI 2.5 2.7 3.0i V
Inputhighvoltage VIH 2.2 - VDD+0.3ii V
Inputlowvoltage VIL -0.5iii - 0.8 V
Temperatureunderbias
MR0A08B(Commercial)
MR0A08BC(Industrial)
MR0A08BM(Automotive)iv
TA
0
-40
-40
70
85
125
°C
i Thereisa2msstartuptimeonceVDDexceedsVDD,(max).SeePower Up and Power Down Sequencing below.
ii VIH(max)=VDD+0.3VDC;VIH(max)=VDD+2.0VAC(pulsewidth≤10ns)forI≤20.0mA.
iii VIL(min)=-0.5VDC;VIL(min)=-2.0VAC(pulsewidth≤10ns)forI≤20.0mA.
iv Automotivetemperatureprofileassumes10%dutycycleatmaximumtemperature(2-yearsoutof20-yearlife)
Table 2.2 Operating Conditions
Power Up and Power Down Sequencing
MRAMisprotectedfromwriteoperationswheneverVDDislessthanVWI.AssoonasVDDexceedsVDD(min),
thereisastartuptimeof2msbeforereadorwriteoperationscanstart.Thistimeallowsmemorypower
suppliestostabilize.
TheEandWcontrolsignalsshouldtrackVDDonpoweruptoVDD-0.2VorVIH(whicheverislower)andremain
highforthestartuptime.Inmostsystems,thismeansthatthesesignalsshouldbepulledupwitharesis-
torsothatsignalremainshighifthedrivingsignalisHi-Zduringpowerup.AnylogicthatdrivesEandW
shouldholdthesignalshighwithapower-onresetsignalforlongerthanthestartuptime.
DuringpowerlossorbrownoutwhereVDDgoesbelowVWI,writesareprotectedandastartuptimemustbe
observedwhenpowerreturnsaboveVDD(min).
BROWNOUT OR POWER LOSS
NORMAL OPERATION NORMAL OPERATION
STARTUP TIME STARTUP TIME
VWI VWI
VDD
VDD
WRITES INHIBITED
W
E
Figure 2.1 Power Up and Power Down Diagram
MR0A08B
Electrical Specications
EverspinTechnologies©2009
DocumentNumber:MR0A08BRev.2,6/20096
Parameter Symbol Min Typical Max Unit
Inputleakagecurrent Ilkg(I) - - ±1 μA
Outputleakagecurrent Ilkg(O) - - ±1 μA
Outputlowvoltage
(IOL=+4mA)
(IOL=+100μA)
VOL - - 0.4
VSS+0.2
V
Outputhighvoltage
(IOL=-4mA)
(IOL=-100μA)
VOH 2.4
VDD-0.2
- - V
Table 2.3 DC Characteristics
Table 2.4 Power Supply Characteristics
Parameter Symbol Typical Max Unit
ACactivesupplycurrent-readmodes1
(IOUT=0mA,VDD=max) IDDR 25 30 mA
ACactivesupplycurrent-writemodes1
(VDD=max)
MR0A08B(Commercial)
MR0A08BC(Industrial)
MR0A08BM(Automotive)
IDDW 55
55
TBD
65
70
TBD
mA
ACstandbycurrent
(VDD=max,E=VIH)
no other restrictions on other inputs
ISB1 6 7 mA
CMOSstandbycurrent
(E≥VDD-0.2VandVInVSS+0.2Vor≥VDD-0.2V)
(VDD=max,f=0MHz)
ISB2 5 6 mA
1 Allactivecurrentmeasurementsaremeasuredwithoneaddresstransitionpercycleandatminimumcycletime.
MR0A08B
Electrical Specications
EverspinTechnologies©2009
DocumentNumber:MR0A08BRev.2,6/20097
MR0A08B
3. TIMING SPECIFICATIONS
Table 3.1 Capacitance1
Parameter Symbol Typical Max Unit
Addressinputcapacitance CIn - 6 pF
Controlinputcapacitance CIn - 6 pF
Input/Outputcapacitance CI/O - 8 pF
1 f=1.0MHz,dV=3.0V,TA=25°C,periodicallysampledratherthan100%tested.
Table 3.2 AC Measurement Conditions
Figure 3.1 Output Load Test Low and High
Figure 3.2 Output Load Test All Others
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3.1
Outputloadforallothertimingparameters SeeFigure3.2
V
Output
L= 1.5 V
RL= 50 Ω
ZD= 50 Ω
Output
435 Ω
590 Ω
5 pF
3.3 V
EverspinTechnologies©2009
MR0A08B
Timing Specications
DocumentNumber:MR0A08BRev.2,6/20098
Parameter Symbol Min Max Unit
Readcycletime tAVAV 35 - ns
Addressaccesstime tAVQV - 35 ns
Enableaccesstime2tELQV - 35 ns
Outputenableaccesstime tGLQV - 15 ns
Outputholdfromaddresschange tAXQX 3 - ns
Enablelowtooutputactive3tELQX 3 - ns
Outputenablelowtooutputactive3tGLQX 0 - ns
EnablehightooutputHi-Z3tEHQZ 0 15 ns
OutputenablehightooutputHi-Z3tGHQZ 0 10 ns
1 Wishighforreadcycle.Powersuppliesmustbeproperlygroundedanddecoupled,andbuscontentionconditionsmustbe
minimizedoreliminatedduringreadorwritecycles.
2 AddressesvalidbeforeoratthesametimeEgoeslow.
3 Thisparameterissampledandnot100%tested.Transitionismeasured±200mVfromthesteady-statevoltage.
Table 3.3 Read Cycle Timing1
Read Mode
Figure 3.3A Read Cycle 1
Figure 3.3B Read Cycle 2
EverspinTechnologies©2009
MR0A08B
Timing Specications
DocumentNumber:MR0A08BRev.2,6/20099
Table 3.4 Write Cycle Timing 1 (W Controlled)1
Parameter Symbol Min Max Unit
Writecycletime2tAVAV 35 - ns
Addressset-uptime tAVWL 0 - ns
Addressvalidtoendofwrite(Ghigh) tAVWH 18 - ns
Addressvalidtoendofwrite(Glow) tAVWH 20 - ns
Writepulsewidth(Ghigh) tWLWH
tWLEH
15 - ns
Writepulsewidth(Glow) tWLWH
tWLEH
15 - ns
Datavalidtoendofwrite tDVWH 10 - ns
Dataholdtime tWHDX 0 - ns
WritelowtodataHi-Z3tWLQZ 0 12 ns
Writehightooutputactive3tWHQX 3 - ns
Writerecoverytime tWHAX 12 - ns
1 AllwriteoccursduringtheoverlapofElowandWlow.Powersuppliesmustbeproperlygroundedanddecoupledandbus
contentionconditionsmustbeminimizedoreliminatedduringreadandwritecycles.IfGgoeslowatthesametimeorafter
Wgoeslow,theoutputwillremaininahighimpedancestate.AfterWorEhasbeenbroughthigh,thesignalmustremainin
steady-statehighforaminimumof2ns.TheminimumtimebetweenEbeingassertedlowinonecycletoEbeingasserted
lowinasubsequentcycleisthesameastheminimumcycletimeallowedforthedevice.
2 Allwritecycletimingsarereferencedfromthelastvalidaddresstothersttransitionaddress.
3 Thisparameterissampledandnot100%tested.Transitionismeasured±200mVfromthesteady-statevoltage.Atanygiven
voltageortemperate,tWLQZ(max)<tWHQX(min)
Figure 3.4 Write Cycle Timing 1 (W Controlled)
EverspinTechnologies©2009
MR0A08B
Timing Specications
EverspinTechnologies©2009 DocumentNumber:MR0A08BRev.2,6/200910
Table 3.5 Write Cycle Timing 2 (E Controlled)1
Figure 3.5 Write Cycle Timing 2 (E Controlled)
Parameter Symbol Min Max Unit
Writecycletime2tAVAV 35 - ns
Addressset-uptime tAVEL 0 - ns
Addressvalidtoendofwrite(Ghigh) tAVEH 18 - ns
Addressvalidtoendofwrite(Glow) tAVEH 20 - ns
Enabletoendofwrite(Ghigh) tELEH
tELWH
15 - ns
Enabletoendofwrite(Glow)3tELEH
tELWH
15 - ns
Datavalidtoendofwrite tDVEH 10 - ns
Dataholdtime tEHDX 0 - ns
Writerecoverytime tEHAX 12 - ns
1 AllwriteoccursduringtheoverlapofElowandWlow.Powersuppliesmustbeproperlygroundedanddecoupledandbus
contentionconditionsmustbeminimizedoreliminatedduringreadandwritecycles.IfGgoeslowatthesametimeorafter
Wgoeslow,theoutputwillremaininahighimpedancestate.AfterWorEhasbeenbroughthigh,thesignalmustremainin
steady-statehighforaminimumof2ns.TheminimumtimebetweenEbeingassertedlowinonecycletoEbeingasserted
lowinasubsequentcycleisthesameastheminimumcycletimeallowedforthedevice.
2 Allwritecycletimingsarereferencedfromthelastvalidaddresstothersttransitionaddress.
3 IfEgoeslowatthesametimeorafterWgoeslow,theoutputwillremaininahigh-impedancestate.IfEgoeshighatthe
sametimeorbeforeWgoeshigh,theoutputwillremaininahigh-impedancestate.
MR0A08B
Timing Specications
DocumentNumber:MR0A08BRev.2,6/200911
Table 3.6 Write Cycle Timing 3 (Shortened tWHAX, W and E Controlled)1
Table 3.6 Write Cycle Timing 3 (Shortened tWHAX, W and E Controlled)
Parameter Symbol Min Max Unit
Writecycletime2tAVAV 35 - ns
Addressset-uptime tAVWL 0 - ns
Addressvalidtoendofwrite(Ghigh) tAVWH 18 - ns
Addressvalidtoendofwrite(Glow) tAVWH 20 - ns
Writepulsewidth tWLWH
tWLEH
15 - ns
Datavalidtoendofwrite tDVWH 10 - ns
Dataholdtime tWHDX 0 - ns
Enablerecoverytime tEHAX -2 - ns
Writerecoverytime3tWHAX 6 - ns
Writetoenablerecoverytime3tWHEL 12 - ns
1 AllwriteoccursduringtheoverlapofElowandWlow.Powersuppliesmustbeproperlygroundedanddecoupledandbus
contentionconditionsmustbeminimizedoreliminatedduringreadandwritecycles.IfGgoeslowatthesametimeorafter
Wgoeslow,theoutputwillremaininahighimpedancestate.AfterW,orEhasbeenbroughthigh,thesignalmustremainin
steady-statehighforaminimumof2ns.TheminimumtimebetweenEbeingassertedlowinonecycletoEbeingasserted
lowinasubsequentcycleisthesameastheminimumcycletimeallowedforthedevice.
2 Allwritecycletimingsarereferencedfromthelastvalidaddresstothersttransitionaddress.
3 IfEgoeslowatthesametimeorafterWgoeslowtheoutputwillremaininahighimpedancestate.IfEgoeshighatthesame
timeorbeforeWgoeshightheoutputwillremaininahighimpedancestate.Emustbebroughthigheachcycle.
tAVWL
tAVAV
tAVWH
tWLWH
t
WLEH
t
DVWH
t
WHDX
tWHAX
t
WHEL
W (WRITE ENABLE)
A (ADDRESS)
E (CHIP ENABLE)
D (DATA IN)
EverspinTechnologies©2009
DocumentNumber:MR0A08BRev.2,6/200912
MR0A08B
4. ORDERING INFORMATION
Figure 4.1 Part Numbering System
Carrier (Blank = Tray, R = Tape & Reel)
Speed (35 ns)
Package (YS = TSOPII, MA = FBGA)
Temperature Range
(Blank= 0 to +70 °C, C= -40 to +85
°C, M= -40 to +125 °C)
Revision (A = 180 nm, B = 130 nm)
Data Width (08 = 8-Bit, 16 = 16-bit)
Type (A = Asynchronous, S = Synchronous)
Density (256 = 256 Kb, 0 = 1Mb, 1 =2Mb,
2 =4Mb, 4 =16Mb)
Magnetoresistive RAM
(MR)
MR 0 A 08 B C YS 35 R
Part Number Description Temperature
MR0A08BYS35 3.3V128Kx8MRAM44-TSOP Commercial
MR0A08BCYS35 3.3V128Kx8MRAM44-TSOP Industrial
MR0A08BMYS3513.3V128Kx8MRAM44-TSOP Automotive
MR0A08BYS35R 3.3V128Kx8MRAM44-TSOPT&RCommercial
MR0A08BCYS35R 3.3V128Kx8MRAM44-TSOPT&R Industrial
MR0A08BMYS35R13.3V128Kx8MRAM44-TSOPT&R Automotive
MR0A08BMA35 3.3V128Kx8MRAM48-BGA Commercial
MR0A08BCMA35 3.3V128Kx8MRAM48-BGAIndustrial
MR0A08BMMA3513.3V128Kx8MRAM48-BGA Automotive
1TheautomotivetemperaturegradepartsareclassiedasPreliminary.
Table 4.1 Available Parts
EverspinTechnologies©2009
DocumentNumber:MR0A08BRev.2,6/200913
Figure 5.1 TSOP-II
MR0A08B
5. MECHANICAL DRAWING
Print Version Not To Scale
1. DimensionsandtolerancesperASMEY14.5M-1994.
2. DimensionsinMillimeters.
3. Dimensionsdonotincludemoldprotrusion.
4. DimensiondoesnotincludeDAMbarprotrusions.
DAMBarprotrusionshallnotcausetheleadwidthtoexceed0.58.
EverspinTechnologies©2009
DocumentNumber:MR0A08BRev.2,6/200914
TOP VIEW
BOTTOM VIEW SIDE VIEW
Figure 5.2 FBGA
Print Version Not To Scale
1. DimensionsinMillimeters.
2. DimensionsandtolerancesperASMEY14.5M-1994.
3. MaximumsolderballdiametermeasuredparalleltoDATUMA
4. DATUMA,theseatingplaneisdeterminedbythesphericalcrowns
ofthesolderballs.
5. Parallelismmeasurementshallexcludeanyeectofmarkontop
surfaceofpackage.
MR0A08B
Mechanical Drawings
EverspinTechnologies©2009
MR0A08B
DocumentNumber:MR0A08BRev.2,6/200915
Revision Date Description of Change
0 Sep12,2008 InitialAdvanceInformationRelease
1 May8,2009
Revisedformat;AddTable3.6WriteTimingCycle3;AddFigure3.6WriteTim-
ingCycle3;AddTSOPIILeadWidthInfo;ChangedtoPreliminaryfromProd-
uctConcept.
2 June18,2009 ChangedfromdatasheetfromPreliminarytoProductionexceptwhere
noted.
6. REVISION HISTORY
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 Technolo-
gies 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 Technologies 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 inci-
dental 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 compo-
nents in systems intended for surgical implant into the body, or other applications intended to support
or sustain life, or for any other application 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
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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
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product or service names are the property of their respective owners.
©Everspin Technologies, Inc. 2008
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