/*This ado file gives the log likelihood function used in interval regressions for the SGT distribution. It works with gintreg.ado v 1.1 Author--Jacob Orchard Update--5/26/2016*/ program intllf_sgt_condition_group version 13 args lnf mu sigma p q a tempvar Fu Fl zu zl cond qui gen double `Fu' = . qui gen double `Fl' = . qui gen double `zu' = . qui gen double `zl' = . qui gen double `cond' = 0.75 tempvar lambda qui gen `lambda' = (exp(`a') - 1) / (exp(`a') + 1) *Point data tempvar x s l y qui gen double `x' = $ML_y1 - (`mu') if $ML_y1 != . & $ML_y2 != . /// & $ML_y1 == $ML_y2 qui gen double `s' = exp(`sigma') if $ML_y1 != . & $ML_y2 != . /// & $ML_y1 == $ML_y2 qui gen double `l' = (exp(`lambda')-1)/(exp(`lambda')+1) if $ML_y1 /// != . & $ML_y2 != . & $ML_y1 == $ML_y2 qui gen double `y' = (2 * `s' * `l' * `q'^(1/`p') * exp(lngamma(2/`p') /// + lngamma(`q' - 1/`p') - lngamma(1/`p' + /// `q')))/exp(lngamma(1/`p') + lngamma(`q') - /// lngamma(1/`p' + `q')) if $ML_y1 != . & /// $ML_y2 != . & $ML_y1 == $ML_y2 qui replace `lnf' = ln(`p') - ln(2) - `sigma' - (ln(`q')/`p') - /// (lngamma(1/`p') + lngamma(`q') - lngamma(1/`p' /// + `q')) - (1/`p' + `q') * ln(1 + abs(`x' + /// `y')^`p'/(`q' * `s'^`p' * (1 + `l' * sign(`x' + /// `y'))^`p')) if $ML_y1 != . & $ML_y2 != . & /// $ML_y1 == $ML_y2 *Interval data qui replace `zu' = 1 / (1+ `q'* ((exp(`sigma')*(1+`lambda'*sign($ML_y2 - `mu')))/(abs($ML_y2 - `mu')))^`p') /// if $ML_y1 != . & $ML_y2 != . & $ML_y1 != $ML_y2 qui replace `Fu' = .5*(1-`lambda') + .5*(1+`lambda'*sign($ML_y2- /// `mu'))*sign($ML_y2 - `mu')*ibeta(1/`p',`q',`zu') /// if $ML_y1 != . & $ML_y2 != . & $ML_y1 != $ML_y2 & `zu' <= `cond' qui replace `Fu' = .5*(1-`lambda') + .5*(1+`lambda'*sign($ML_y2- /// `mu'))*sign($ML_y2 - `mu')*(1-ibeta(`q', 1/`p', 1 - `zu')) /// if $ML_y1 != . & $ML_y2 != . & $ML_y1 != $ML_y2 & `zu' > `cond' qui replace `zl' = 1 / (1+ `q'* ((exp(`sigma')*(1+`lambda'*sign($ML_y1 - `mu')))/(abs($ML_y1 - `mu')))^`p') /// if $ML_y1 != . & $ML_y2 != . & $ML_y1 != $ML_y2 qui replace `Fl' = .5*(1-`lambda') + .5*(1+`lambda'*sign($ML_y1- /// `mu'))*sign($ML_y1 - `mu')*ibeta(1/`p',`q',`zl') /// if $ML_y1 != . & $ML_y2 != . & $ML_y1 != $ML_y2 & `zl' <= `cond' qui replace `Fl' = .5*(1-`lambda') + .5*(1+`lambda'*sign($ML_y1- /// `mu'))*sign($ML_y1 - `mu')*(1-ibeta(`q',1/`p',1 - `zl')) /// if $ML_y1 != . & $ML_y2 != . & $ML_y1 != $ML_y2 & `zl' > `cond' qui replace `lnf' = log(`Fu' -`Fl') if $ML_y1 != . & $ML_y2 != . & /// $ML_y1 != $ML_y2 *Bottom coded data qui replace `zl' = 1 / (1+ `q'* ((exp(`sigma')*(1+`lambda'*sign($ML_y1 - `mu')))/(abs($ML_y1 - `mu')))^`p') /// if $ML_y1 != . & $ML_y2 == . qui replace `Fl' = .5*(1-`lambda') + .5*(1+`lambda'*sign($ML_y1- /// `mu'))*sign($ML_y1 - `mu')*ibeta(1/`p',`q',`zl') /// if $ML_y1 != . & $ML_y2 == . & `zl' <= `cond' qui replace `Fl' = .5*(1-`lambda') + .5*(1+`lambda'*sign($ML_y1- /// `mu'))*sign($ML_y1 - `mu')*(1-ibeta(`q',1/`p',1-`zl')) /// if $ML_y1 != . & $ML_y2 == . & `zl' > `cond' qui replace `lnf' = log(1-`Fl') if $ML_y1 != . & $ML_y2 == . *Top coded data qui replace `zu' = 1 / (1+ `q'* ((exp(`sigma')*(1+`lambda'*sign($ML_y2 - `mu')))/(abs($ML_y2 - `mu')))^`p') /// if $ML_y2 != . & $ML_y1 == . qui replace `Fu' = .5*(1-`lambda') + .5*(1+`lambda'*sign($ML_y2- /// `mu'))*sign($ML_y2 - `mu')*ibeta(1/`p',`q',`zu') /// if $ML_y2 != . & $ML_y1 == . & `zu' <= `cond' qui replace `Fu' = .5*(1-`lambda') + .5*(1+`lambda'*sign($ML_y2- /// `mu'))*sign($ML_y2 - `mu')*(1-ibeta(`q',1/`p', 1 - `zu')) /// if $ML_y2 != . & $ML_y1 == . & `zu' > `cond' qui replace `lnf' = log(`Fu') if $ML_y2 != . & $ML_y1 == . *Missing values qui replace `lnf' = 0 if $ML_y2 == . & $ML_y1 == . *Group frequency qui replace `lnf' = `lnf'*$group_per end