R/IRT_frequencies_default.R

In alexanderrobitzsch/CDM: Cognitive Diagnosis Modeling

## File Name: IRT_frequencies_default.R
## File Version: 0.09

IRT_frequencies_default <- function(data, post, probs, weights=NULL)
{
    dim_probs <- dim(probs)
    K <- dim_probs[2]
    I <- dim_probs[1]
    TP <- dim_probs[3]
    N <- nrow(data)
    #--- preparation item response data
    dat <- data
    dat.ind <- 1 - is.na(dat)
    dat[ is.na(dat) ] <- 0
    if (is.null(weights)){
        weights <- rep(1,N)
    }
    #--- univariate observed frequencies
    uni_obs <- matrix( 0, nrow=I, ncol=K)
    items <- colnames(dat)
    categories <- paste0("Cat", 1:K - 1 )
    rownames(uni_obs) <- items
    colnames(uni_obs) <- categories
    for (kk in 1:K){
        uni_obs[,kk] <- colSums( ( dat==kk - 1) * dat.ind * weights )
    }
    #--- univariate expected frequencies
    uni_exp <- 0*uni_obs
    for (ii in 1:I){
        for (kk in 1:K){
            counts_ii_kk <- dat.ind[,ii] * weights * post
            uni_exp[ii,kk] <- sum( t(counts_ii_kk) * probs[ii,kk,] )
        }
    }
    #--- univariate marginals descriptive statistics
    M_obs <- rep(NA, I)
    names(M_obs) <- items
    SD_obs <- SD_exp <- M_exp <- M_obs
    for (ii in 1:I){
        res <- univar_table_statistics( freq=uni_obs[ii,] )
        M_obs[ii] <- res$M
        SD_obs[ii] <- res$SD
        res <- univar_table_statistics( freq=uni_exp[ii,] )
        M_exp[ii] <- res$M
        SD_exp[ii] <- res$SD
    }

    #--- bivariate frequency tables
    biv_obs <- array( 0, dim=c(I,I,K,K) )
    dimnames(biv_obs) <- list( items, items, categories, categories )
    biv_exp <- biv_obs
    biv_N <- matrix(0,nrow=I,ncol=I)
    dimnames(biv_N) <- list(items, items)
    chisq <- cov_obs <- cov_exp <- cor_exp <- cor_obs <- biv_N
    attr( chisq, "df") <- chisq
    for (ii in 1:I){
        for (jj in ii:I){
            for (kk in 1:K){
                for (hh in 1:K){
                    dat_temp <- ( dat[,ii]==kk-1 ) * ( dat[,jj]==hh - 1 ) * dat.ind[,ii] * dat.ind[,jj] * weights
                    biv_obs[ii,jj,kk,hh] <- sum( dat_temp )
                    counts_temp <- dat.ind[,ii] * dat.ind[,jj] * weights * post
                    biv_exp[ii,jj,kk,hh] <- sum( t(counts_temp) * probs[ii,kk,] * probs[jj,hh,] )
                }
            }
            biv_N[ii,jj] <- biv_N[jj,ii] <- sum(biv_obs[ii,jj,,])
            biv_obs[jj,ii,,] <- biv_obs[ii,jj,,]
            biv_exp[jj,ii,,] <- biv_exp[ii,jj,,]
        }
    }
    for (ii in 1:I){
        for (jj in ii:I){
            res <- bivariate_table_statistics(freqtable=biv_obs[ii,jj,,])
            cov_obs[ii,jj] <- cov_obs[jj,ii] <- res$cov
            cor_obs[ii,jj] <- cor_obs[jj,ii] <- res$cor
            res <- bivariate_table_statistics(freqtable=biv_exp[ii,jj,,])
            K1 <- res$K1
            K2 <- res$K2
            cov_exp[ii,jj] <- cov_exp[jj,ii] <- res$cov
            cor_exp[ii,jj] <- cor_exp[jj,ii] <- res$cor
            chisq[ii,jj] <- chisq[jj,ii] <- chisq_compute(obs=biv_obs[ii,jj,,], exp=biv_exp[ii,jj,,])
            attr(chisq, "df")[ii,jj] <- attr(chisq, "df")[jj,ii] <- (K1-1)*(K2-1)
        }
    }
    diag(chisq) <- NA
    attr(chisq, "p") <- 1 - stats::pchisq(chisq, df=attr(chisq,"df") )
    #--- output
    res <- list( uni_obs=uni_obs, uni_exp=uni_exp, M_obs=M_obs, M_exp=M_exp, SD_obs=SD_obs,
                SD_exp=SD_exp, biv_obs=biv_obs, biv_exp=biv_exp, biv_N=biv_N,
                cov_obs=cov_obs, cov_exp=cov_exp, cor_obs=cor_obs, cor_exp=cor_exp,
                chisq=chisq )
    return(res)
}