modis collection 6.1 (c6.1) lai/fpar product user’s guide
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MODISCollection6.1(C6.1)LAI/FPAR
ProductUser’sGuide
TheC61MOD/MYD15productisidenticalinformattotheC6product.
This(C61)reprocessingdoesnotcontainanychangetothesciencealgorithmused tomake this product. Any improvement or change in the C61 productcomparedtotheproductfromthepriormajorcollectionreprocessing(C6)isfromchangesandenhancementstothecalibrationapproachusedingenerationof the Terra and AquaMODIS L1B products and changes to the polarizationcorrection used in this collection reprocessing. For further details on C61calibration changes and other changes user is encouraged to refer to theCollection 6.1 specific changes that have been summarized here:https://landweb.modaps.eosdis.nasa.gov/QA_WWW/forPage/MODIS_C61_Land_Proposed_Changes.pdf
(Updated:April21,2020)
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Contents
1.Definitions Page22.SummaryofChangesinC6 Page23.AlgorithmDescription Page24.StandardMODISProducts Page45.HowtoObtaintheData Page66.Contentoftheproductfile Page67.Policies Page118.ContactInformation Page119.RelatedPapers Page11
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1.DefinitionsLeafareaindex(LAI;dimensionless)isdefinedastheone−sidedgreenleafareaper
unitgroundareainbroadleafcanopiesandasone−halfthetotalneedlesurfaceareaperunitgroundareainconiferouscanopies.STD LAI is the estimated retrieval uncertainty, i.e., “true LAI” can differ from its
retrievalcounterpartby±STDLAI(SeeFigure1).Fraction of Photosynthetically Active Radiation absorbed by vegetation (FPAR;
dimensionless)isdefinedasthefractionofincidentphotosyntheticallyactiveradiation(400−700nm)absorbedbythegreenelementsofavegetationcanopy.STDFPARis theestimatedretrievaluncertainty, i.e., “trueFPAR”candiffer fromits
retrievalcounterpartby±STDFPAR(SeeFigure1).2.SummaryofChangesinC6• UsesL2G–litesurfacereflectanceat500mresolutionas(MOD09GA1)inputinplace
ofreflectanceat1kmresolution(MODAGAGG2)inCollection5.Anintermediatedailysurface reflectance product (MOD15IP 3 ) at 500 m resolution is created fromMOD09GAbeforebeingusedforLAI/FPARretrieval.
• Productsaregeneratedataspatialresolutionof500m.• Usesimprovedmulti-yearlandcoverproduct.3.AlgorithmDescriptionThe MODIS LAI/FPAR algorithm consists of a main Look-up-Table (LUT) based
procedurethatexploitsthespectralinformationcontentoftheMODISred(648nm)andnear-infrared (NIR,858nm)surface reflectances,and theback-upalgorithmthatusesempirical relationships between Normalized Difference Vegetation Index (NDVI) andcanopy LAI and FPAR. The LUT was generated using 3D radiative transfer equation[Knyazikhinetal.,1998]. Inputstothealgorithmare(i)vegetationstructuraltype,(ii)sun-sensorgeometry,(iii)BRFsatred(648nm)andnear-infrared(NIR,858nm)spectralbandsand(vi)theiruncertainties(Table1).Figure1illustratesthemainalgorithm:for
1MOD09GA is aMODIS daily surface reflectance product, which provides daily atmosphericallycorrectedsurfacereflectanceat500mresolutioninsevenspectralbands.MOD09GAcanbeaccessedviaReverbtool(PleaserefertotheSection5.HowtoObtaintheData)2 MODAGAGG is a MODIS daily aggregated surface reflectance product, which provides dailyatmospherically corrected surface reflectance at 1 km resolution in seven spectral bands.MODAGAGGisnotanarchivedproduct.3MOD15IPistheintermediateMODISdailysurfacereflectanceproductat500mresolution,whichispreprocessedfromthedailyMOD09GAsurfacereflectanceproduct,forLAI/FPARproduction.ThisproductisanequivalentofMODAGAGGinC5andnotarchived.
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each pixel it compares observed and modeled spectral BRFs for a suite of canopystructuresandsoilpatternsthatrepresentanexpectedrangeoftypicalconditionsforagiven biome type. All canopy/soil patterns and corresponding FPAR values forwhichmodeledandobservedBRFsdifferwithinaspecifieduncertaintylevelareconsideredasacceptablesolutions.ThemeanvaluesofLAI,FPAR,theirdispersions,STDLAIandSTDFPAR,arereportedasretrievalsandtheiruncertainties[Knyazikhinetal.,1998].Inthecaseofdensecanopies,thereflectancessaturate,andarethereforeweaklysensitivetochangesincanopyproperties.Thereliabilityofparametersretrievedundertheconditionof saturation is low, that is, the dispersion of the solution distribution is large. Suchretrievals are flagged inQA layers (Table5).When theLUTmethod fails to localize asolution,theback-upmethodisutilized.Thealgorithmpath(mainorbackup)isarchivedinQAlayers(Table5).Analysesofthealgorithmperformanceindicatethatbestquality,highprecisionretrievalsareobtainedfromthemainalgorithm[Yangetal.2006b;Yangetal.2006c].Thealgorithmpathisthereforeakeyqualityindicator.ThealgorithmhasinterfaceswiththeMODISSurfaceReflectanceProduct(MOD09GA)
andtheMODISLandCoverProduct(MCD12Q1).TechnicaldetailsofthealgorithmcanbefoundintheAlgorithmTheoreticalBasisDocument(ATBD)4.
A
B
Figure 1. Schematic illustration of the main algorithm. Panel A: Distribution ofvegetated pixels with respect to their reflectances at red and near-infrared (NIR)spectralbandsfromTerraMODIStileh12v04.Apointonthered-NIRplaneandanareaaboutit(yellowellipsedefinedbya𝜒!distribution)aretreatedasthemeasuredBRFatagivensun-sensorgeometryanditsuncertainty.Eachcombinationofcanopy/soilparametersandcorrespondingFPARvaluesforwhichmodeledreflectancesbelongtotheellipseisanacceptablesolution.PanelB:Densitydistributionfunctionofacceptable
4ATBDforMODISLAI/FPARproductcanbedirectlydownloadedfrombelowlink:http://modis.gsfc.nasa.gov/data/atbd/atbd_mod15.pdf
Red$
Near(Infrared
$
Soil$line$(LAI=0)$
Prob
abili
ty d
ensi
ty
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solutions.ShownissolutiondensitydistributionfunctionofLAIforfivedifferentpixels.The mean LAI and its dispersion (STD LAI) are taken as the LAI retrieval and itsuncertainty.This technique isused toestimatemeanFPARand itsdispersions(STDFPAR).From[Knyazikhinatal,1998].Table1.Theoreticalestimatesofuncertainties(%)intheBRFsusedintheC6.1LAI/FPARalgorithm
BiomeTypeUncertainty
Red(648nm) NIR(858nm)Biome1(Grasses/Cerealcrops) 20% 5%Biome2(Shrubs) 20% 5%Biome3(Broadleafcrops) 20% 5%Biome4(Savanna) 20% 5%Biome5(EvergreenBroadleafforest) 30% 15%Biome6(DeciduousBroadleafforest) 30% 15%Biome7(EvergreenNeedleleafforest) 30% 15%Biome8(DeciduousNeedleleafforest) 30% 15%4.StandardMODISProductsThestandardMODISC6.1LAI/FPARproducts(M*D15A*H)areat500−meterspatial
resolutionandincludeLAI/FPARretrievals fromTerraMODIS,AquaMODISandTerraMODIS+Aqua MODIS Combined. The temporal compositing periods are 8 and 4 days(Table2).
Table2.DescriptionoftheStandardMODISLAI/FPARproducts
OfficialName Platform RasterTypeSpatialResolution
TemporalGranularity
MOD15A2H Terra Tile 500m 8Day
MYD15A2H Aqua Tile 500m 8Day
MCD15A2H Terra+AquaCombined
Tile 500m 8Day
MCD15A3H Terra+AquaCombined
Tile 500m 4Day
TheMODISLAI/FPARproductsusetheSinusoidalgridtillingsystem(Figure2).Tiles
are10degreesby10degreesattheequator(Table3).Thetilecoordinatesystemstarts
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at (0, 0) (horizontal tile number, vertical tile number) in the upper left corner andproceedsright(horizontal)anddownward(vertical).Thetileinthebottomrightcorneris(35,17).Table3.DatasetcharacteristicsoftheMODISLAI/FPARproducts
Characteristics C6.1Product
TemporalCoverageMOD15:February18,2000–MYD15&MCD15:July4,2002–
Area ~10x10lat/longFileSize ~0.8MBcompressedProjection SinusoidalDataFormat HDF−EOSDimensions 2400x2400rows/columnsResolution 500meterScienceDataSets(SDSHDFLayers) 6
Figure2.MODISSinusoidalTilingSystem
MODISproductfilenames(i.e.,thelocalgranuleID)followanamingconventionthat
gives useful information regarding the specific product. For example, the filenameMOD15A2H.A2006001.h08v05.006.2006012234657.hdfindicates:
ü MOD15A2H–ProductShortName
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ü .A2006001–JulianDateofAcquisition(A−YYYYDDD)ü .h08v05–TileIdentifier(horizontalXX,verticalYY)ü .006–CollectionVersionü .2006012234657–JulianDateofProduction(YYYYDDDHHMMSS)ü .hdf–DataFormat(HDF−EOS)TheMODIS LAI/FPAR products have two sources ofmetadata: the embeddedHDF
metadata, and the external ECS metadata. The HDF metadata contains valuableinformationincludingglobalattributesanddataset−specificattributespertainingtothegranule.TheECS(generatedbytheEOSDISCoreSystem).metfileistheexternalmetadatafile in XML format, which is delivered to the user along with the MODIS product. Itprovidesasubsetof theHDFmetadata.Somekey featuresofcertainMODISmetadataattributesincludethefollowing:
ü TheXdimandYdimrepresenttherowsandcolumnsofthedata,respectively.ü TheProjection andProjParams identify the projection and its corresponding
projectionparameters.ü TheSinusoidalProjectionisusedformostofthegriddedMODISlandproducts,
andhasauniquespheremeasuring6371007.181meters.ü The UpperLeftPoinitMtrs is in projection coordinates, and identifies the very
upperleftcorneroftheupperleftpixeloftheimagedata.ü TheLowerRightMtrsidentifiestheverylowerrightcornerofthelowerrightpixel
of the image data. These projection coordinates are the only metadata thataccuratelyreflecttheextremecornersofthegriddedimage.
ü ThereareadditionalBOUNDINGRECTANGLEandGRINGPOINT fieldswithinthemetadata, which represent the latitude and longitude coordinates of thegeographictilecorrespondingtothedata.
5.HowtoObtaintheDataNASA EARTHDATA (https://earthdata.nasa.gov/): This tool provides access to a
completedatarecordofallMODISproductsavailablefromtheLPDAAC.
6.ContentoftheproductfileTheMODISLAI/FPARproductisat500−meterresolutioninaSinusoidalgrid.Science
Data Sets provided in the product include LAI, FPAR, quality ratings, and standarddeviationforeachvariable,STDLAIandSTDFPAR(Table4).
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Table4.ScientificDataSetsincludedintheMODISLAI/FPARproduct
ScientificDataSets(HDFLayers)(6)
Units BitTypeFillValue
ValidRange
MultiplyByScaleFactor
Fpar_500m Dimensionless8−bitunsignedinteger
249−255 0−100 0.01
Lai_500m Dimensionless8−bitunsignedinteger
249−255 0−100 0.1
FparLai_QC Classflag8−bitunsignedinteger
255 0−254 N/A
FparExtra_QC Classflag8−bitunsignedinteger
255 0−254 N/A
FparStdDev_500m5 Dimensionless8−bitunsignedinteger
248−255 0−100 0.01
LaiStdDev__500m5 Dimensionless8−bitunsignedinteger
248−255 0−100 0.1
6.1.DescriptionofQCSDSQualitycontrol (QC)measuresareproducedatboth the file (containingoneMODIS
tile)andatthepixellevelsfortheM*D15A*Hproduct.Atthetilelevel,theseappearasaset of EOSDIS core system (ECS) metadata fields. At the pixel level, quality controlinformation is representedby2data layers (FparLai_QCandFparExtra_QC) in the filewithM*D15A*Hproduct.NotethattheLAI/FPARalgorithmisexecutedirrespectiveofinputquality.ThereforeusershouldconsulttheQClayersoftheLAI/FPARproducttoselectreliableretrievals.
5ThemainalgorithmemploysaLUTmethodsimulatedfroma3-Dradiativetransfermodel.TheLUTmethodessentiallysearches forLAI/FPARs foraspecificsetof solarandviewzenithangles,observedBRFsatcertainspectralbandsandbiometypes.TheoutputsaretheLAI/FPARmeanvalues(i.e.,Lai_500m/Fpar_500mscientificdata)averagedoverallacceptablesolutions,andthestandarddeviation(i.e.,LaiStdDev/FparStdDevscientificdata)servingasameasureofthesolutionaccuracy.
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Table5.ValuesofFparLAI_QC(8−bit)
BitNo. ParameterName BitComb.
FparLai_QC
0 MODLAND_QCbits0
Goodquality(mainalgorithmwithorwithoutsaturation)
1 Otherquality(back−upalgorithmorfillvalues)
1 Sensor0 Terra1 Aqua
2 DeadDetector0
Detectorsapparentlyfineforupto50%ofchannels1,2
1 Deaddetectorscaused>50%adjacentdetectorretrieval
3−4
CloudState(inheritedfromAggregate_QCbits{0,1}cloudstate)
00 0SignificantcloudsNOTpresent(clear)01 1SignificantcloudsWEREpresent
10 2Mixedcloudpresentinpixel
11 3Cloudstatenotdefined,assumedclear
5−7 SCF_QC(five−levelconfidencescore)
0000Main(RT)methodused,bestresultpossible(nosaturation)
001 1Main(RT)methodusedwithsaturation.Good,veryusable
0102Main(RT)methodfailedduetobadgeometry,empiricalalgorithmused
0113Main(RT)methodfailedduetoproblemsotherthangeometry,empiricalalgorithmused
1004Pixelnotproducedatall,valuecouldn’tberetrieved(possiblereasons:badL1Bdata,unusableMOD09GAdata)
Note, in theFparLai_QC, the fieldMODLAND is thestandardonecommon to theall
MODLANDproductsandspecifiestheoverallqualityoftheproduct.Also,severalbitfieldsintheM*D15A*HQAarepassed-thrufromthecorrespondingbitfieldsoftheMOD09GAsurface reflectancesproduct (CloudState, LandSea, etc.). The key indicator of retrievalqualityoftheLAI/FPARproductisSCF_QCbitfielddthatrepresentsalgorithmpath.M*D15A*Hbitpatternsareparsedfromrighttoleft.Individualbitswithinabitword
are read from left to right. The following example illustrates the interpretation ofFparLai_QC. Let assume a single pixel’s value from FparLai_QC layer is 64, thus this
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decimal value can be converted to a binary value of 1000000 as shown in Figure 3.Interpretationofbit-stringsisalsoshowninFigure3basedonTable5.
Figure3.ExampleofFparLai_QCbit-stringanditsinterpretation
Table5.ValuesofFparExtra_QC(8−bit)
BitNo. ParameterName BitComb. FparExtra_QC
0−1 LandSeaPass−Thru
00 0LANDAggrQC(3,5)values{001}
011SHOREAggrQC(3,5)values{000,010,100}
102FRESHWATERAggrQC(3,5)values{011,101}
11 3OCEANAggrQC(3,5)values{110,111}
2Snow_Ice(fromAggregate_QCbits)
0 Nosnow/icedetected1 Snow/icedetected
3 Aerosol0 Noorlowatmosphericaerosollevels
detected1 Averageorhighaerosollevelsdetected
4Cirrus(fromAggregate_QCbits{8,9})
0 Nocirrusdetected
1 Cirruswasdetected
5 Internal_CloudMask0 Noclouds1 Cloudsweredetected
6 Cloud_Shadow0 Nocloudshadowdetected1 Cloudshadowdetected
7 SCF_Biome_Mask0 Biomeoutsideinterval<1,4>1 Biomeininterval<1,4>
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ExampleforinterpretationofFparExtra_QCbit-stringsisshowninFigure4.
Figure4.ExampleofFparExtra_QCbit-stringanditsinterpretation
6.2.DescriptionofFillvalueforSDSsUsing the MODIS land cover product (MCD12Q1), each 500m pixel is classified
accordingtoitsstatusasalandornon-landpixel.Anumberofnon-terrestrialpixelclassesarenowcarriedthroughintheproductdatapixels(notQA/QCpixels)whenthealgorithmcouldnotretrieveabiophysicalestimate(Table6and7).Table6.LAIandFPARFillvalueLegends
Value Description
255Fillvalue,assignedwhen:theMOD09GAsurfacereflectanceforchannelVIS,NIRwasassignedits_Fillvalue,orlandcoverpixelitselfwasassignedFillvalue255or254
254 landcoverassignedasperennialsaltorinlandfreshwater253 landcoverassignedasbarren,sparsevegetation(rock,tundra,desert)252 landcoverassignedasperennialsnow,ice251 landcoverassignedas“permanent”wetlands/inundatedmarshlands250 landcoverassignedasurban/built−up249 landcoverassignedas“unclassified”ornotabletodetermine
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Table7.STDLAIandSTDFPARFillValueLegends
Value Description
255Fillvalue,assignedwhen:theMOD09GAsurfacereflectanceforchannelVIS,NIRwasassignedits_Fillvalue,orlandcoverpixelitselfwasassigned_Fillvalue255or254
254 landcoverassignedasperennialsaltorinlandfreshwater253 landcoverassignedasbarren,sparsevegetation(rock,tundra,desert)252 landcoverassignedasperennialsnow,ice251 landcoverassignedas“permanent”wetlands/inundatedmarshlands250 landcoverassignedasurban/built−up249 landcoverassignedas“unclassified”ornotabletodetermine248 Nostandarddeviationavailable,pixelproducedusingbackupmethod
7.PoliciesPlease find the currentMODIS−relatedDatapolicies on theMODISPolicies page at
https://lpdaac.usgs.gov/lpdaac/products/modis_policies.For informationonhowtociteLPDAACdata,pleaseseeourDataCitationspageat
https://lpdaac.usgs.gov/about/citing_lp_daac_and_data.
8.ContactInformationRangaMyneniDepartmentofGeographyandEnvironment,BostonUniversityEmail:[email protected]:http://cliveg.bu.edu9.RelatedPapersAhletal.,2006.MonitoringSpringCanopyPhenologyofaDeciduousBroadleafForest
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validationandinter–comparisonofgloballandbiophysicalproducts.Propositionofthe CEOS–BELMANIP. IEEE Trans. Geosci. Remote Sens., 44: 1794–1803. DOI:10.1126/science.1199048,2011.
Gangulyetal.,2008.Generatingvegetationleafareaindexearthsystemdatarecordsfrommultiplesensors.Part1:Theory.RemoteSens.Environ.,Vol.112(2008)4333–4343,doi:10.1016/j.rse.2008.07.014
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Gangulyetal.,2008.Generatingvegetationleafareaindexearthsystemdatarecordsfrommultiple sensors. Part 2: Implementation, Analysis and Validation. Remote Sens.Environ.,112(2008)4318–4332,doi:10.1016/j.rse.2008.07.013
Gaoetal.,2008.AnAlgorithmtoProduceTemporallyandSpatiallyContinuousMODIS–LAITimeSeries.Geophys.Res.Lett.,doi:10.1109/LGRS.2007.907971.
Garrigues et al., 2008. Intercomparison and sensitivity analysis of leaf area indexretrievals fromLAI–2000, AccuPAR, and digital hemispherical photography overcroplands,Agric.For.Meteorol.,doi:10.1016/j.agrformet.2008.02.014.
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Hashimoto et al., 2012 Exploring Simple Algorithms for Estimating Gross PrimaryProduction in Forested Areas from Satellite Data, Remote Sens., 4, 303–326;doi:10.3390/rs4010303
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Shabanovetal.,2003.TheeffectofspatialheterogeneityinvalidationoftheMODISLAIandFPARalgorithmoverbroadleafforests,RemoteSens.Environ.,85:410–423.
Tanetal.,2006.TheimpactofgeolocationoffsetsonthelocalspatialpropertiesofMODISdata: Implications for validation, compositing, and band–to–band registration,RemoteSens.Environ.,105:98–114.
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Tian et al., 2002a. Multiscale Analysis and Validation of the MODIS LAI Product. I.UncertaintyAssessment.RemoteSens.Environ.,83:414–430.
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Tianetal.,2002c.RadiativetransferbasedscalingofLAI/FPARretrievalsfromreflectancedataofdifferentresolutions.RemoteSens.Environ.,84:143–159.
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