X-Git-Url: https://git.auder.net/?p=morpheus.git;a=blobdiff_plain;f=pkg%2FR%2FoptimParams.R;h=4f886ac3fbd60139c8350e2222cb382c791b49d0;hp=2eada8f1f9a4fb98526d82d116bd479ca011f3ba;hb=98b8a5ddffdce7e0b63746d4b58bb923049dca7d;hpb=9007ccc114c127211639e7c5b82495bc39803eb0 diff --git a/pkg/R/optimParams.R b/pkg/R/optimParams.R index 2eada8f..4f886ac 100644 --- a/pkg/R/optimParams.R +++ b/pkg/R/optimParams.R @@ -10,6 +10,7 @@ #' \item 'M' : list of moments of order 1,2,3: will be computed if not provided. #' \item 'X,Y' : input/output, mandatory if moments not given #' \item 'exact': use exact formulas when available? +#' \item weights Weights on moments when minimizing sum of squares #' } #' #' @return An object 'op' of class OptimParams, initialized so that \code{op$run(x0)} @@ -56,9 +57,14 @@ optimParams = function(K, link=c("logit","probit"), optargs=list()) M <- computeMoments(optargs$X,optargs$Y) } + weights <- optargs$weights + if (is.null(weights)) + weights <- rep(1, K) + # Build and return optimization algorithm object methods::new("OptimParams", "li"=link, "M1"=as.double(M[[1]]), - "M2"=as.double(M[[2]]), "M3"=as.double(M[[3]]), "K"=as.integer(K)) + "M2"=as.double(M[[2]]), "M3"=as.double(M[[3]]), + "weights"=weights, "K"=as.integer(K)) } # Encapsulated optimization for p (proportions), β and b (regression parameters) @@ -67,6 +73,7 @@ optimParams = function(K, link=c("logit","probit"), optargs=list()) # @field M1 Estimated first-order moment # @field M2 Estimated second-order moment (flattened) # @field M3 Estimated third-order moment (flattened) +# @field weights Vector of moments' weights # @field K Number of populations # @field d Number of dimensions # @@ -132,9 +139,9 @@ setRefClass( β3 <- apply(β, 2, function(col) col %o% col %o% col) return( - sum( ( β %*% (p * .G(li,1,λ,b)) - M1 )^2 ) + - sum( ( β2 %*% (p * .G(li,2,λ,b)) - M2 )^2 ) + - sum( ( β3 %*% (p * .G(li,3,λ,b)) - M3 )^2 ) ) + weights[1] * sum( ( β %*% (p * .G(li,1,λ,b)) - M1 )^2 ) + + weights[2] * sum( ( β2 %*% (p * .G(li,2,λ,b)) - M2 )^2 ) + + weights[3] * sum( ( β3 %*% (p * .G(li,3,λ,b)) - M3 )^2 ) ) }, grad_f = function(x) @@ -166,9 +173,9 @@ setRefClass( km1 = 1:(K-1) grad <- #gradient on p - t( sweep(as.matrix(β [,km1]), 2, G1[km1], '*') - G1[K] * β [,K] ) %*% F1 + - t( sweep(as.matrix(β2[,km1]), 2, G2[km1], '*') - G2[K] * β2[,K] ) %*% F2 + - t( sweep(as.matrix(β3[,km1]), 2, G3[km1], '*') - G3[K] * β3[,K] ) %*% F3 + weights[1] * t( sweep(as.matrix(β [,km1]), 2, G1[km1], '*') - G1[K] * β [,K] ) %*% F1 + + weights[2] * t( sweep(as.matrix(β2[,km1]), 2, G2[km1], '*') - G2[K] * β2[,K] ) %*% F2 + + weights[3] * t( sweep(as.matrix(β3[,km1]), 2, G3[km1], '*') - G3[K] * β3[,K] ) %*% F3 grad_β <- matrix(nrow=d, ncol=K) for (i in 1:d) @@ -197,14 +204,17 @@ setRefClass( dβ3_right[block,] <- dβ3_right[block,] + β2 dβ3 <- dβ3_left + sweep(dβ3_right, 2, p * G3, '*') - grad_β[i,] <- t(dβ) %*% F1 + t(dβ2) %*% F2 + t(dβ3) %*% F3 + grad_β[i,] <- + weights[1] * t(dβ) %*% F1 + + weights[2] * t(dβ2) %*% F2 + + weights[3] * t(dβ3) %*% F3 } grad <- c(grad, as.double(grad_β)) grad = c(grad, #gradient on b - t( sweep(β, 2, p * G2, '*') ) %*% F1 + - t( sweep(β2, 2, p * G3, '*') ) %*% F2 + - t( sweep(β3, 2, p * G4, '*') ) %*% F3 ) + weights[1] * t( sweep(β, 2, p * G2, '*') ) %*% F1 + + weights[2] * t( sweep(β2, 2, p * G3, '*') ) %*% F2 + + weights[3] * t( sweep(β3, 2, p * G4, '*') ) %*% F3 ) grad },