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3 Random vectors and multivariate normal distribution

CHAPTER3ST 732,M. DAVIDIAN3 Randomvectorsandmultivariatenormaldistri butionAswe saw in Chapter1, a naturalway to thinkaboutrepeatedmeasurement datais as a seriesofrandomvectors, onevectorcorrespondingto each in which thesevectorsofmeasurements turnoutis governedby probability , we needtodiscussextensionsof usualunivari-ateprobability distributionsfor(scalar)randomvariablest omultivariateprobability ,it is wiseto reviewtheimportant conceptsof randomvariableandprobability distributionandhow we usetheseto :We may thinkof arandomvariableYas a characteristicwhosevaluesmayvary. Theway it takes onvaluesis described by aprobability ,REPEATED:It is customaryto useupper caseletters, , to denotea genericrandomvariableandlower caseletters, , to denotea particularvaluethattherandomvariablemay take onor thatmay be observed(data).

3 Random vectors and multivariate normal distribution As we saw in Chapter 1, a natural way to think about repeated measurement data is as a series of random vectors, one vector corresponding to each unit. Because the way in which these vectors of measurements turn out is governed by probability, we need to discuss extensions of usual univari-

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Transcription of 3 Random vectors and multivariate normal distribution

1 CHAPTER3ST 732,M. DAVIDIAN3 Randomvectorsandmultivariatenormaldistri butionAswe saw in Chapter1, a naturalway to thinkaboutrepeatedmeasurement datais as a seriesofrandomvectors, onevectorcorrespondingto each in which thesevectorsofmeasurements turnoutis governedby probability , we needtodiscussextensionsof usualunivari-ateprobability distributionsfor(scalar)randomvariablest omultivariateprobability ,it is wiseto reviewtheimportant conceptsof randomvariableandprobability distributionandhow we usetheseto :We may thinkof arandomvariableYas a characteristicwhosevaluesmayvary. Theway it takes onvaluesis described by aprobability ,REPEATED:It is customaryto useupper caseletters, , to denotea genericrandomvariableandlower caseletters, , to denotea particularvaluethattherandomvariablemay take onor thatmay be observed(data).

2 EXAMPLE:Supposewe areinterestedin thecharacteristic\bodyweight of rats"in thepopulationofallpossibleratsof a certainage,gender,andtype. We might letY=bodyweight of a (randomlychosen) a may conceptualizethatbodyweights of ratsaredistributedin thispopulationin thesensethatsomevaluesaremorecommon( them) we randomlyselecta ratfromthepopulation,thenthechanceit hasa certainbodyweight willbe governedby thisdistributionof weights in , valuesthatYmay take onaredistributedin thepopulationaccordingto anassociatedprobability distributionthatdescribes how likelythevaluesarein a moment, we willconsidermorecarefullywhyratweights we might seevary.

3 First,we 32 CHAPTER3ST 732,M. DAVIDIAN(POPULATION)MEANANDVARIANCE:Reca llthatthemeanandvarianceof a probabilitydistributionsummarizenotionso f \center"and\spread"or \variability" of all randomvariableYwithanassociatedprobabili ty be thought of as theaverageof allpossiblevaluesthatYcouldtake on,so theaverageof (aremorelikely)thanothers,so thisaveragere writeE(Y):( )todenotethisaverage,thepopulationmean. TheexpectationoperatorEdenotesthatthe\av eraging"operationover allpossiblevaluesof itsargument is to be , theaveragemay be thought of as a \weighted"average,whereeach possiblevalueis representedin accordancetotheprobabilitywithwhich it occursin \ " is be thought of as a way of describingthe\center"of thedistributionof alsoreferredto as we have arandomsampleof observationsona randomvariableY, sayY1; : : : ; Yn, thenthesamplemeanis justtheaverageof these:Y=n 1nXj=1Yj:For example,ifY= ratweight, andwe wereto obtaina randomsampleofn= 50 ratsandweigheach,thenYrepresents theaveragewe wouldobtain.

4 Thesamplemeanis a naturalestimatorforthepopulationmeanof theprobability distributionfromwhich therandomsamplewas be thought of as measuringthespreadof allpossiblevaluesthatmaybe observed,basedonthesquareddeviationsof each valuefromthe\center"of thedistributionof , varianceis basedonaveragingsquareddeviationsacrosst hepopulation,which is representedusingtheexpectationoperator,a ndis givenbyvar(Y) =Ef(Y )2g; =E(Y):( )( )showstheinterpretationof varianceas anaverageof squareddeviationsfromthemeanacrossthepop ulation,takinginto account thatsomevaluesaremorelikely(occurwithhig herprobability) 33 CHAPTER3ST 732,M. DAVIDIAN Theuseof squareddeviationstakes into account magnitudeof thedistancefromthe\center"butnotdirectio n,so is attemptingto measureonly\spread"(ineitherdirection).

5 Thesymbol \ 2" is oftenusedgenericallyto represent showstwo normaldistributionswiththesamemeanbutdi erent variances 21< 22, illustratinghow variancedescribesthe\spread"of :Normaldistributionswithmean butdi erentvariances PSfragreplacements 21 22 Varianceis onthescaleof theresponse, measureof spreadthatis onthesamescaleas theresponseis thepopulationstandarddeviation, de nedaspvar(Y). Thesymbol is randomsampleas above, thesamplevarianceis (almost)theaverageof thesquareddeviationsof each observationYjfromthesamplemeanY :S2= (n 1) 1nXj=1(Yj Y)2: Thesamplevarianceis usedas (n 1) ratherthannis usedso thattheestimatorisunbiased, thesamplesizenis small.

6 Thesamplestandarddeviationis justthesquareroot of thesamplevariance,oftenrepresentedby 34 CHAPTER3ST 732,M. DAVIDIANGENERALFACTS:Ifbis a xedscalarandYis a randomvariable,then E(bY) =bE(Y) =b ; theaveragearejustmultipliedbyb. Also,E(Y+b) =E(Y) +b; addinga constant to each valuein thepopulationwilljustshifttheaverageby thissameamount. var(bY) =Ef(bY b )2g=b2var(Y); theaveragearejustmultipliedbyb2. Also,var(Y+b) = var(Y); addinga constant to each valuein thepopulationdoes nota ecthow theyvaryaboutthemean(which is alsoshiftedby thisamount).SOURCESOFVARIATION:We now considerwhy thevaluesof a characteristicthatwe might observevary.

7 Consideragaintheratweight example. Biological is well-knownthatbiologicalentitiesaredi erent; althoughlivingthingsof thesametype tendto be similarin theircharacteristics,theyarenotexactlyth esame(exceptperhapsin thecaseof genetically-identicalclones).Thus,evenif we focusonratsof thesamestrain,age,andgender,we expectvariationin thepossibleweights of such ratsthatwe mightobserve dueto inherent, theweight of a randomlychosenrat,withprobability distributionhavingmean . If allratswerebiologicallyidentical,thenthe populationvarianceofYwouldbe equalto 0,andwe wouldexpectallratsto have exactlyweight . Ofcourse,becauseratweights varyas aconsequenceof biologicalfactors,thevarianceis>0, andthus theweight of a randomlychosenratis notequalto butratherdeviatesfrom by somepositive or negative amount.

8 Fromthisview,we might thinkofYas beingrepresentedbyY= +b;( )wherebis a randomvariable,withpopulationmeanE(b) = 0 andvariancevar(b) = 2b, ,Yis \decomposed"into itsmeanvalue(asystematiccomponent) andarandomdevia-tionbthatrepresents by how much a ratweight might deviatefromthemeanratweight duetoinherent biologicalfactors.( )is a simplestatisticalmodelthatemphasizesthat we believe ratweights we might seevarybecauseof ( )impliesthatE(Y) = andvar(Y) = 35 CHAPTER3ST 732,M. DAVIDIAN have discussedratweight as though,oncewe have a ratin hand,wemay know itsweight exactly. However,a scaleusuallymustbe , a scaleshouldregisterthetrueweight of an itemeach timeit is weighed,but,becausesuch devicesareimperfect,measurements on thesameitemmay by which themeasurementdi ersfromthetruthmay be thought of as anerror; deviationupor downfromthetruevaluethatcouldbe observedwitha \perfect" \fair"orunbiaseddevicedoes notsystematicallyregisterhighor low mostof thetime;rather,theerrorsmay go in ,if we onlyhave anunbiasedscaleonwhich to weighrats,a ratweight we might observere ectsnotonlythetrueweight of therat,which variesacrossrats,butalsotheerrorin takingthemeasurement.

9 We might thinkof a randomvariablee, say, thatrepresents theerrorthatmightcontaminatea measurement of ratweight, takingon possiblevaluesin a hypothetical\population"of allsuch errorsthescalemight stillbelieve ratweights varydueto biologicalvariation,butwhatwe seeis alsosubjecttomeasurement thus makes senseto reviseourthinkingof whatYrepresents,andthinkofY= \measuredweight of a randomlychosenrat."Thepopulationof allpossiblevaluesYcouldtake onis allpossiblevaluesof ratweight we might measure; ,allvaluesconsistingof atrueweight of a ratfromthepopulationof allratscontaminatedby a measurement errorfromthepopulationof allpossiblesuch ,it is naturalto representYasY= +b+e= + ;( )wherebis as in ( ).

10 Eis thedeviationdueto measurement error,withE(e) = 0 andvar(e) = 2e, ( ), =b+erepresents theaggregatedeviationduetothee ectsofbothbiologicalvariationandmeasurem ent ,E( ) = 0 andvar( ) = 2= 2b+ 2e, so thatE(Y) = andvar(Y) = 2accordingto themodel( ).Here, 2re ectsthe\spread"of measuredratweights anddependsonboththespreadin trueratweightsandthespreadin errorsthatcouldbe committedin variationthatwe couldconsider;we deferdiscussionto laterin now,theimportant messageis that,in consideringstatisticalmodels,it is criticalto beawareof di erentsourcesof variationthatcauseobservationsto vary. Thisis especiallyimportantwithlongitudinaldata, as we 36 CHAPTER3ST 732,M.


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