*! version 1.0.1 PR 30sep2004. program define uvis7, rclass sortpreserve version 7 gettoken cmd 0 : 0 if substr("`cmd'",1,3)=="reg" { local cmd regress } local normal=("`cmd'"=="regress")|("`cmd'"=="rreg") local binary=("`cmd'"=="logit")|("`cmd'"=="logistic") local catcmd=("`cmd'"=="mlogit")|("`cmd'"=="ologit") if !`normal' & !`binary' & !`catcmd' { di in red "invalid or unrecognised command, `cmd'" exit 198 } syntax varlist(min=2 numeric) [if] [in] [aweight fweight pweight iweight] , Gen(string) /* */ [ noCONStant Delta(real 0) BOot DRaw REPLACE SEed(int 0) * ] if "`replace'"=="" { confirm new var `gen' } if "`draw'"=="draw" { di as text "[imputing by drawing from conditional distribution" _cont } else di as text "[imputing by prediction matching" _cont if "`boot'"=="" { di as text " without bootstrap]" } else di as text " with bootstrap]" if "`constant'"=="noconstant" { local options "`options' nocons" } gettoken y xvars : varlist tempvar touse quietly { marksample touse, novarlist markout `touse' `xvars' /* note: does not include `y' */ if `seed'!=0 { set seed `seed' } * Deal with weights frac_wgt `"`exp'"' `touse' `"`weight'"' local wgt `r(wgt)' * Code types of missings: 1=non-missing y, 2=missing y, 3=other missing tempvar obstype yimp gen byte `obstype'=1*(`touse'==1 & !missing(`y')) /* */ +2*(`touse'==1 & missing(`y')) /* */ +3*(`touse'==0) count if `obstype'==1 local nobs=r(N) count if `obstype'==2 local nmis=r(N) local type: type `y' gen `type' `yimp'=. * Fit imputation model `cmd' `y' `xvars' `wgt', `options' tempname b e V chol bstar tempvar xb u matrix `b'=e(b) matrix `e'=e(b) matrix `V'=e(V) local colsofb=colsof(`b') * Check for zeroes on the diagonal of V and replace them with 1. * Otherwise this makes the matrix non-positive definite. * Occurs when e.g. logit drops variables, giving zero variances. * !! Is this safe to do? if diag0cnt(`V')>0 { forvalues j=1/`colsofb' { if `V'[`j',`j']==0 { matrix `V'[`j',`j']=1 } } } matrix `chol'=cholesky(`V') if `catcmd' { tempname cat local nclass=e(k_cat) /* number of classes in (ordered) categoric variable */ matrix `cat'=e(cat) /* row vector giving actual category values */ local cuts=`nclass'-1 } * Draw beta, and if necessary rmse, for proper imputation if `normal' { * draw rmse local rmse=e(rmse) local df=e(df_r) local chi2=2*invgammap(`df'/2,uniform()) local rmsestar=`rmse'*sqrt(`df'/`chi2') matrix `chol'=`chol'*sqrt(`df'/`chi2') } * draw beta forvalues i=1/`colsofb' { matrix `e'[1,`i']=invnorm(uniform()) } matrix `bstar'=`b'+`e'*`chol'' if "`boot'"=="" { * Based on Ian White's code to implement van Buuren et al (1999). * draw y gen `u'=uniform() if `normal' | `binary' { * in normal or binary case, impute by sampling conditional distribution * or by prediction matching if "`draw'"=="draw" { * sampling conditional distribution matrix score `xb'=`bstar' if `touse' if `normal' { replace `yimp'=`xb'+`rmsestar'*invnorm(`u') } else replace `yimp'=`u'<1/(1+exp(-`xb')) if !missing(`xb') } else { * prediction matching tempvar etaobs etamis matrix score `etaobs'=`b' if `obstype'==1 matrix score `etamis'=`bstar' if `obstype'==2 * Include non-response location shift, delta. if `delta'!=0 { replace `etamis'=`etamis'+`delta' } match_normal `obstype' `nobs' `nmis' `etaobs' `etamis' `yimp' `y' } } else { /* catcmd */ if "`draw'"=="draw" { * sampling conditional distribution replace `yimp'=`cat'[1,1] if "`cmd'"=="ologit" { * Predict index independent of cutpoints * (note use of forcezero option to circumvent missing _cut* vars) matrix score `xb'=`bstar' if `touse', forcezero forvalues k=1/`cuts' { * 1/(1+exp(-... is probability of being in category 1 or 2 or ... k local cutpt=`bstar'[1, `k'+`colsofb'-`cuts'] replace `yimp'=`cat'[1,`k'+1] if `u'>1/(1+exp(-(`cutpt'-`xb'))) } } else { /* mlogit */ * care needed dealing with different possible base categories tempvar cusump sumexp local basecat=e(basecat) /* actual basecategory chosen by Stata */ gen `sumexp'=0 if `touse' forvalues i=1/`nclass' { tempvar xb`i' local thiscat=`cat'[1,`i'] if `thiscat'==`basecat' { gen `xb`i''=0 if `touse' } else matrix score `xb`i''=`bstar' if `touse', equation(`thiscat') replace `sumexp'=`sumexp' + exp(`xb`i'') } gen `cusump'=exp(`xb1')/`sumexp' forvalues i=2/`nclass' { replace `yimp'=`cat'[1,`i'] if `u'>`cusump' replace `cusump'=`cusump'+exp(`xb`i'')/`sumexp' replace `yimp'=. if missing(`xb`i'') } } } else { /* prediction matching */ * predict class-specific probabilities and convert to logits if "`cmd'"=="ologit" { * Predict index independent of cutpoints * (note use of forcezero option to circumvent missing _cut* vars) matrix score `xb'=`b' if `touse', forcezero * predict cumulative probabilities for obs data and hence logits of class probs forvalues k=1/`nclass' { tempvar etaobs`k' etamis`k' if `k'==`nclass' { gen `etaobs`nclass''=log((1-`p`cuts'')/`p`cuts'') if `obstype'==1 } else { tempvar p`k' local cutpt=`b'[1, `k'+`colsofb'-`cuts'] * 1/(1+exp(-... is probability of being in category 1 or 2 or ... k gen `p`k''=1/(1+exp(-(`cutpt'-`xb'))) if `k'==1 { gen `etaobs`k''=log(`p`k''/(1-`p`k'')) if `obstype'==1 } else { local k1=`k'-1 gen `etaobs`k''=log((`p`k''-`p`k1'')/(1-(`p`k''-`p`k1''))) /* */ if `obstype'==1 } } } drop `xb' matrix score `xb'=`bstar' if `touse', forcezero * predict cumulative probabilities for missing data and hence logits of class probs forvalues k=1/`nclass' { if `k'==`nclass' { gen `etamis`nclass''=log((1-`p`cuts'')/`p`cuts'') if `obstype'==2 } else { local cutpt=`bstar'[1, `k'+`colsofb'-`cuts'] replace `p`k''=1/(1+exp(-(`cutpt'-`xb'))) if `k'==1 { gen `etamis`k''=log(`p`k''/(1-`p`k'')) if `obstype'==2 } else { local k1=`k'-1 gen `etamis`k''=log((`p`k''-`p`k1'')/(1-(`p`k''-`p`k1''))) /* */ if `obstype'==2 } } } } else { /* mlogit */ * predict cumulative probabilities for obs data and hence logits of class probs * care needed dealing with different possible base categories tempvar sumexp local basecat=e(basecat) /* actual basecategory chosen by Stata */ gen `sumexp'=0 if `touse' forvalues k=1/`nclass' { tempvar etaobs`k' etamis`k' xb`k' local thiscat=`cat'[1,`k'] if `thiscat'==`basecat' { gen `xb`k''=0 if `touse' } else matrix score `xb`k''=`b' if `touse', equation(`thiscat') replace `sumexp'=`sumexp' + exp(`xb`k'') } forvalues k=1/`nclass' { * formula for logit of class prob derived from Pk in Stata mlogit entry gen `etaobs`k''=`xb`k''-log(`sumexp'-exp(`xb`k'')) if `obstype'==1 } * same for missing obs replace `sumexp'=0 forvalues k=1/`nclass' { cap drop `xb`k'' local thiscat=`cat'[1,`k'] if `thiscat'==`basecat' { gen `xb`k''=0 if `touse' } else matrix score `xb`k''=`bstar' if `touse', equation(`thiscat') replace `sumexp'=`sumexp' + exp(`xb`k'') } forvalues k=1/`nclass' { * formula for logit of class prob derived from Pk in Stata mlogit entry gen `etamis`k''=`xb`k''-log(`sumexp'-exp(`xb`k'')) if `obstype'==2 } } * match sort `obstype' tempvar order distance gen `distance'=. gen long `order'=_n * For each missing obs j, find index of obs whose etaobs is closest to prediction [j]. forvalues i=1/`nmis' { local j=`i'+`nobs' * calc summed absolute distances between etamis* and etaobs* replace `distance'=0 in 1/`nobs' forvalues k=1/`nclass' { replace `distance'=`distance'+abs(`etamis`k''[`j']-`etaobs`k'') in 1/`nobs' } * Find index of smallest distance between etamis* and etaobs* sort `distance' local index=`order'[1] * restore correct order sort `order' replace `yimp'=`y'[`index'] in `j' } } } } else { * Bootstrap method if "`draw'"=="" { /* match */ if `catcmd' { * predict class-specific probabilities and convert to logits forvalues k=1/`nclass' { local outk=`cat'[1,`k'] tempvar etaobs`k' etamis`k' predict `etaobs`k'' if `obstype'==1, outcome(`outk') /* probability */ replace `etaobs`k''=log(`etaobs`k''/(1-`etaobs`k'')) /* logit */ } } else { /* normal and binary cases */ tempvar etaobs etamis predict `etaobs' if `obstype'==1, xb } } * Bootstrap observed data tempvar wt gen double `wt'=. bsample if `obstype'==1, weight(`wt') if "`wgt'"!="" { replace `wt' `exp'*`wt' local w [`weight'=`wt'] } else local w [fweight=`wt'] `cmd' `y' `xvars' `w', `options' if `catcmd' { if e(k_cat)<`nclass' { di as error "cannot predict outcome for all classes in bootstrap sample;" di as error "probably one or more classes has a low frequency in the original data:" di as error "try amalgamating small classes of `y' and rerunning" exit 303 } } if "`draw'"=="draw" { /* sampling conditional distribution */ matrix `bstar'=e(b) gen `u'=uniform() if `normal' | `binary' { matrix score `xb'=`bstar' if `touse' if `normal' { replace `yimp'=`xb'+e(rmse)*invnorm(`u') } else replace `yimp'=`u'<1/(1+exp(-`xb')) if !missing(`xb') } else { /* catcmd */ replace `yimp'=`cat'[1,1] if "`cmd'"=="ologit" { matrix score `xb'=`bstar' if `touse', forcezero forvalues k=1/`cuts' { * 1/(1+exp(-... is probability of being in category 1 or 2 or ... k local cutpt=`bstar'[1, `k'+`colsofb'-`cuts'] replace `yimp'=`cat'[1,`k'+1] if `u'>1/(1+exp(-(`cutpt'-`xb'))) } } else { /* mlogit */ * care needed dealing with different possible base categories tempvar cusump sumexp local basecat=e(basecat) /* actual basecategory chosen by Stata */ gen `sumexp'=0 if `touse' forvalues i=1/`nclass' { tempvar xb`i' local thiscat=`cat'[1,`i'] if `thiscat'==`basecat' { gen `xb`i''=0 if `touse' } else matrix score `xb`i''=`bstar' if `touse', equation(`thiscat') replace `sumexp'=`sumexp' + exp(`xb`i'') } gen `cusump'=exp(`xb1')/`sumexp' forvalues i=2/`nclass' { replace `yimp'=`cat'[1,`i'] if `u'>`cusump' replace `cusump'=`cusump'+exp(`xb`i'')/`sumexp' replace `yimp'=. if missing(`xb`i'') } } } } else { /* match */ if `catcmd' { * predict class-specific probabilities and convert to logits forvalues k=1/`nclass' { local outk=`cat'[1,`k'] predict `etamis`k'' if `obstype'==2, outcome(`outk') /* probability */ replace `etamis`k''=log(`etamis`k''/(1-`etamis`k'')) /* logit */ } * match sort `obstype' tempvar order distance gen `distance'=. gen long `order'=_n * For each missing obs j, find index of obs whose etaobs is closest to prediction [j]. forvalues i=1/`nmis' { local j=`i'+`nobs' * calc summed absolute distances between etamis* and etaobs* replace `distance'=0 in 1/`nobs' forvalues k=1/`nclass' { replace `distance'=`distance'+abs(`etamis`k''[`j']-`etaobs`k'') in 1/`nobs' } * Find index of smallest distance between etamis* and etaobs* sort `distance' local index=`order'[1] * restore correct order sort `order' replace `yimp'=`y'[`index'] in `j' } } else { /* normal and binary */ predict `etamis' if `obstype'==2, xb * Include non-response location shift, delta. if `delta'!=0 { replace `etamis'=`etamis'+`delta' } match_normal `obstype' `nobs' `nmis' `etaobs' `etamis' `yimp' `y' } } } cap drop `gen' rename `yimp' `gen' replace `gen'=`y' if `obstype'==1 lab var `gen' "imputed from `y'" } di _n in ye `nmis' in gr " missing observations on `y' imputed from " /* */ in ye `nobs' in gr " complete observations." end program define match_normal * Prediction matching, normal or binary case. args obstype nobs nmis etaobs etamis yimp y quietly { * For each missing obs j, find index of observation * whose etaobs is closest to etamis[j]. tempvar sumgt tempname etamisi gen long `sumgt'=. sort `obstype' `etaobs' forvalues i=1/`nmis' { local j=`i'+`nobs' scalar `etamisi'=`etamis'[`j'] replace `sumgt'=sum((`etamisi'>`etaobs')) in 1/`nobs' sum `sumgt', meanonly local j1=r(max) if `j1'==0 { local index 1 } else if `j1'==`nobs' { local index `nobs' } else { local j2=`j1'+1 if (`etamisi'-`etaobs'[`j1'])<(`etaobs'[`j2']-`etamisi') { local index `j1' } else local index `j2' } replace `yimp'=`y'[`index'] in `j' } } end