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We start by loading R packages used in this example
required_packages <- Hmisc::Cs(psych,ggplot2,ggExtra,tidyr,Hmisc,tictoc,ClusterR,copula,dplyr,corrplot,ClustImpute)
lapply(required_packages, require, character.only = TRUE)
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First we create a random dataset with some structure and a few uncorrelated variables
### Random Dataset
set.seed(739)
n <- 7500 # numer of points
nr_other_vars <- 4
mat <- matrix(rnorm(nr_other_vars*n),n,nr_other_vars)
me<-4 # mean
x <- c(rnorm(n/3,me/2,1),rnorm(2*n/3,-me/2,1))
y <- c(rnorm(n/3,0,1),rnorm(n/3,me,1),rnorm(n/3,-me,1))
true_clust <- c(rep(1,n/3),rep(2,n/3),rep(3,n/3)) # true clusters
dat <- cbind(mat,x,y)
dat<- as.data.frame(scale(dat)) # scaling
summary(dat)
#> V1 V2 V3 V4
#> Min. :-3.40352 Min. :-4.273673 Min. :-3.82710 Min. :-3.652267
#> 1st Qu.:-0.67607 1st Qu.:-0.670061 1st Qu.:-0.66962 1st Qu.:-0.684359
#> Median : 0.01295 Median :-0.006559 Median :-0.01179 Median : 0.001737
#> Mean : 0.00000 Mean : 0.000000 Mean : 0.00000 Mean : 0.000000
#> 3rd Qu.: 0.67798 3rd Qu.: 0.684672 3rd Qu.: 0.67221 3rd Qu.: 0.687404
#> Max. : 3.35535 Max. : 3.423416 Max. : 3.80557 Max. : 3.621530
#> x y
#> Min. :-2.1994 Min. :-2.151001
#> 1st Qu.:-0.7738 1st Qu.:-0.975136
#> Median :-0.2901 Median : 0.009932
#> Mean : 0.0000 Mean : 0.000000
#> 3rd Qu.: 0.9420 3rd Qu.: 0.975788
#> Max. : 2.8954 Max. : 2.265420
One can clearly see the three clusters of the randomly generated data:
dat4plot <- dat
dat4plot$true_clust_fct <- factor(true_clust)
p_base <- ggplot(dat4plot,aes(x=x,y=y,color=true_clust_fct)) + geom_point()
ggExtra::ggMarginal(p_base, groupColour = TRUE, groupFill = TRUE)
We create a 20% missings using a custom function
dat_with_miss <- miss_sim(dat,p=.2,seed_nr=120)
summary(dat_with_miss)
#> V1 V2 V3 V4
#> Min. :-3.4035 Min. :-4.2737 Min. :-3.8271 Min. :-3.5844
#> 1st Qu.:-0.6756 1st Qu.:-0.6757 1st Qu.:-0.6634 1st Qu.:-0.6742
#> Median : 0.0163 Median :-0.0104 Median :-0.0092 Median : 0.0194
#> Mean : 0.0024 Mean :-0.0063 Mean : 0.0027 Mean : 0.0117
#> 3rd Qu.: 0.6886 3rd Qu.: 0.6683 3rd Qu.: 0.6774 3rd Qu.: 0.7010
#> Max. : 3.2431 Max. : 3.4234 Max. : 3.8056 Max. : 3.6215
#> NA's :1513 NA's :1499 NA's :1470 NA's :1486
#> x y
#> Min. :-2.1994 Min. :-2.1510
#> 1st Qu.:-0.7636 1st Qu.:-0.9745
#> Median :-0.2955 Median : 0.0065
#> Mean : 0.0022 Mean :-0.0019
#> 3rd Qu.: 0.9473 3rd Qu.: 0.9689
#> Max. : 2.8954 Max. : 2.2654
#> NA's :1580 NA's :1516
mis_ind <- is.na(dat_with_miss) # missing indicator
The correlation matrix of the missing indicator shows that the missings are correlated - thus we are not in a missing completely at random stetting:
Clearly, an imputation with the median value does a pretty bad job here. All imputed values lie on either of the two axes thereby completely distorting the marginal distributions:
dat_median_imp <- dat_with_miss
for (j in 1:dim(dat)[2]) {
dat_median_imp[,j] <- Hmisc::impute(dat_median_imp[,j],fun=median)
}
imp <- factor(pmax(mis_ind[,5],mis_ind[,6]),labels=c("Original","Imputed")) # point is imputed if x or y is imputed
p_median_imp <- ggplot(dat_median_imp) + geom_point(aes(x=x,y=y,color=imp))
ggExtra::ggMarginal(p_median_imp,groupColour = TRUE, groupFill = TRUE)
#> Don't know how to automatically pick scale for object of type impute. Defaulting to continuous.
#> Don't know how to automatically pick scale for object of type impute. Defaulting to continuous.
#> Don't know how to automatically pick scale for object of type impute. Defaulting to continuous.
#> Don't know how to automatically pick scale for object of type impute. Defaulting to continuous.
But also a random imputation is not much better: it creates plenty of points in areas with no data. Note how a simple check of the marginal distributions would not reveal this issue!
dat_random_imp <- dat_with_miss
for (j in 1:dim(dat)[2]) {
dat_random_imp[,j] <- impute(dat_random_imp[,j],fun="random")
}
imp <- factor(pmax(mis_ind[,5],mis_ind[,6]),labels=c("Original","Imputed")) # point is imputed if x or y is imputed
p_random_imp <- ggplot(dat_random_imp) + geom_point(aes(x=x,y=y,color=imp))
ggExtra::ggMarginal(p_random_imp,groupColour = TRUE, groupFill = TRUE)
#> Don't know how to automatically pick scale for object of type impute. Defaulting to continuous.
#> Don't know how to automatically pick scale for object of type impute. Defaulting to continuous.
#> Don't know how to automatically pick scale for object of type impute. Defaulting to continuous.
#> Don't know how to automatically pick scale for object of type impute. Defaulting to continuous.
A cluster base on random imputation will thus not provide good results (even if we “know” the number of clusters, which is 3 in this case). Note how the marginal distribution for y differs from the first chart of this vignette where we show the true clusters instead of the predicted clusters from a random imputation.
tictoc::tic("Clustering based on random imputation")
cl_compare <- KMeans_arma(data=dat_random_imp,clusters=3,n_iter=100,seed=751)
tictoc::toc()
#> Clustering based on random imputation: 0 sec elapsed
dat_random_imp$pred <- predict_KMeans(dat_random_imp,cl_compare)
p_random_imp <- ggplot(dat_random_imp) + geom_point(aes(x=x,y=y,color=factor(pred)))
ggExtra::ggMarginal(p_random_imp,groupColour = TRUE, groupFill = TRUE)
#> Don't know how to automatically pick scale for object of type impute. Defaulting to continuous.
#> Don't know how to automatically pick scale for object of type impute. Defaulting to continuous.
#> Don't know how to automatically pick scale for object of type impute. Defaulting to continuous.
#> Don't know how to automatically pick scale for object of type impute. Defaulting to continuous.
We’ll now use ClustImpute and also measure the run-time. In short, the algorithm follows these steps
The intuition is that observation should be clustered with other observations mainly based on their observed values, while the resulting clusters provide donors for the missing value imputation, so that subsequently all variables can be used for the clustering.
nr_iter <- 10 # iterations of procedure
n_end <- 10 # step until convergence of weight function to 1
nr_cluster <- 3 # number of clusters
c_steps <- 50 # numer of cluster steps per iteration
tictoc::tic("Run ClustImpute")
res <- ClustImpute(dat_with_miss,nr_cluster=nr_cluster, nr_iter=nr_iter, c_steps=c_steps, n_end=n_end)
tictoc::toc()
#> Run ClustImpute: 0.32 sec elapsed
To get an overview of what ClustImpute you may run the following commands:
We’ll first look at the complete data and clustering results. Quite obviously, it gives better results than median / random imputation.
p_clustimpute <- ggplot(res$complete_data,aes(x,y,color=factor(res$clusters))) + geom_point()
ggExtra::ggMarginal(p_clustimpute,groupColour = TRUE, groupFill = TRUE)
## Marginal distributions by cluster and feature
In this toy example we already know that we only have to focus on the “real” features x and y, but this will not be the case in practice. Therefore one can also plot the distributions by cluster and feature.The orange bars are showing the cluster centroids. The plots for x and y are in line what we have seen above, and there is not much difference in the noise features V1 to V4 as one would expect.
Alternatively once can also visualize the marginal distributions with a box-plot.
Packages like MICE compute a traceplot of mean and variance for various chain. Here we only have a single realization and thus re-run ClustImpute with various seeds to obtain different realizations.
res2 <- ClustImpute(dat_with_miss,nr_cluster=nr_cluster, nr_iter=nr_iter, c_steps=c_steps, n_end=n_end,seed_nr = 2)
res3 <- ClustImpute(dat_with_miss,nr_cluster=nr_cluster, nr_iter=nr_iter, c_steps=c_steps, n_end=n_end,seed_nr = 3)
mean_all <- rbind(res$imp_values_mean,res2$imp_values_mean,res3$imp_values_mean)
sd_all <- rbind(res$imp_values_sd,res2$imp_values_sd,res3$imp_values_sd)
mean_all <- cbind(mean_all,seed=rep(c(150519,2,3),each=11))
sd_all <- cbind(sd_all,seed=rep(c(150519,2,3),each=11))
The realizations mix nicely with each other.
Below we compare the rand index between true and fitted cluster assignment. For all cases we obtain
It is considerably lower for random imputation:
class(dat_random_imp$pred) <- "numeric"
external_validation(true_clust, dat_random_imp$pred)
#> [1] 0.5908074
Of course, it is much higher on the (small number of) complete cases.
## complete cases
idx <- which(complete.cases(dat_with_miss)==TRUE)
sprintf("Number of complete cases is %s",length(idx))
#> [1] "Number of complete cases is 2181"
sprintf("Rand index for this case %s", external_validation(true_clust[idx], res$clusters[idx]))
#> [1] "Rand index for this case 0.979412552022036"
The function also computes a variety of other stats
external_validation(true_clust, res$clusters,summary_stats = TRUE)
#>
#> ----------------------------------------
#> purity : 0.8597
#> entropy : 0.424
#> normalized mutual information : 0.5708
#> variation of information : 1.3557
#> normalized var. of information : 0.6006
#> ----------------------------------------
#> specificity : 0.8694
#> sensitivity : 0.7541
#> precision : 0.7426
#> recall : 0.7541
#> F-measure : 0.7483
#> ----------------------------------------
#> accuracy OR rand-index : 0.8309
#> adjusted-rand-index : 0.6211
#> jaccard-index : 0.5978
#> fowlkes-mallows-index : 0.7483
#> mirkin-metric : 9507830
#> ----------------------------------------
#> [1] 0.6210542
We assess quality of clusters, we compute the sum of squares within each cluster, sum up this value and compare it by the total sum of squares.
res_var <- var_reduction(res)
res_var$Variance_reduction
#> [1] 0.2737426
res_var$Variance_by_cluster
#> # A tibble: 1 x 6
#> V1 V2 V3 V4 x y
#> <dbl> <dbl> <dbl> <dbl> <dbl> <dbl>
#> 1 0.967 0.982 1.01 0.993 0.218 0.130
We se a reduction of about 27% using only 3 clusters, most strikingly for x and y because that these variables define the subspace of the true clusters.
More clusters will capture the random distribution of the other variables
res <- ClustImpute(dat_with_miss,nr_cluster=10, nr_iter=nr_iter, c_steps=c_steps, n_end=n_end)
res_var <- var_reduction(res)
res_var$Variance_reduction
#> [1] 0.5208357
res_var$Variance_by_cluster
#> # A tibble: 1 x 6
#> V1 V2 V3 V4 x y
#> <dbl> <dbl> <dbl> <dbl> <dbl> <dbl>
#> 1 0.569 0.612 0.574 0.643 0.270 0.170
We’ll do this exercise for a several values of nr_cluster (and need a helper function for that since X is an argument of ClustImpute)
ClustImpute2 <- function(dataFrame,nr_cluster, nr_iter=10, c_steps=1, wf=default_wf, n_end=10, seed_nr=150519) {
return(ClustImpute(dataFrame,nr_cluster, nr_iter, c_steps, wf, n_end, seed_nr))
}
res_list <- lapply(X=1:10,FUN=ClustImpute2,dataFrame=dat_with_miss, nr_iter=nr_iter, c_steps=c_steps, n_end=n_end)
..and put the variances by cluster in a table
tmp <- var_reduction(res_list[[1]])
var_by_clust <- tmp$Variance_by_cluster
for (k in 2:10) {
tmp <- var_reduction(res_list[[k]])
var_by_clust <- rbind(var_by_clust,tmp$Variance_by_cluster)
}
var_by_clust$nr_clusters <- 1:10
While there is a rather gradual improvement for the other variables, x and y have a minimum showing optimality for these variables. Such a plot clearly indicates that 3 clusters are a good choice for this data set.
These binaries (installable software) and packages are in development.
They may not be fully stable and should be used with caution. We make no claims about them.