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outqrf is an R package used for outlier detection. Each numeric variable is regressed onto all other variables using a quantile random forest (QRF). We use ranger to perform the fitting and prediction of quantile regression forests (QRF). Next, we will compute the rank of the observed values in the predicted results’ quantiles. If the rank of the observed value exceeds the threshold, the observed value is considered an outlier.
Since the same predicted value might be distributed across multiple quantiles in the predicted quantile results, this affects our location finding for the observed value. Therefore, we also used a method similar to the outForest package to compare the observed value with the 50% quantile value again to determine the final quantile result.
# Development version
::install_github("flystar233/outqrf") devtools
We first generate a data set with about 5% outliers values in each numeric column.
#Generate data with outliers in numeric columns
irisWithOutliers <- generateOutliers(iris, p = 0.05,seed =2024)
# Find outliers by quantile random forest regressions
out <- outqrf(irisWithOutliers,quantiles_type=400)
out$outliers
# row col observed predicted rank
# 1 32 Sepal.Length 14.9308229 5.4 0.999
# 2 35 Sepal.Length -1.8135664 4.6 0.001
# 3 84 Sepal.Length 11.4849203 6.3 0.999
# 4 129 Sepal.Length -5.6021049 6.2 0.001
# 5 49 Sepal.Width 10.7927619 3.7 0.999
# 6 90 Sepal.Width -0.7648333 2.4 0.001
# 7 131 Sepal.Width -2.1389311 2.7 0.001
# 8 137 Sepal.Width 11.4992802 3.2 0.999
# 9 36 Petal.Length 12.8033669 1.6 0.999
# 10 73 Petal.Length -17.1905846 4.4 0.001
# 11 107 Petal.Length 13.6672827 5.6 0.999
# 12 123 Petal.Length -8.9717894 5.1 0.001
# 13 140 Petal.Length 13.5214560 5.7 0.999
# 14 10 Petal.Width -11.8406790 0.2 0.001
# 15 14 Petal.Width -6.3030372 0.2 0.003
# 16 34 Petal.Width 7.5843853 0.4 0.999
# 17 66 Petal.Width 6.9828746 2.0 0.993
# 18 113 Petal.Width -6.0696862 1.5 0.001
First, let’s simply detect outliers in the data using a box plot.
# find outliers use boxplot
# 32
irisWithOutliers <- outqrf::generateOutliers(iris, p = 0.05,seed =2024)
boxplot_num = 0
for (i in names(irisWithOutliers)[sapply(irisWithOutliers,is.numeric)]){
q1 <- quantile(irisWithOutliers[,i], 0.25)
q3 <- quantile(irisWithOutliers[,i], 0.75)
iqr <- q3 - q1
lower_bound <- q1 - 1.5 * iqr
upper_bound <- q3 + 1.5 * iqr
num <- sum(irisWithOutliers[,i]<lower_bound|irisWithOutliers[,i]>upper_bound)
boxplot_num<-boxplot_num+num
}
boxplot_num
# 28
Then, use outqtf and outForest respectively to detect outliers.
qrf <- outqrf(irisWithOutliers,quantiles_type=400)
rf <- outForest(irisWithOutliers)
evaluateOutliers(iris,irisWithOutliers,qrf$outliers)
#Actual Predicted Cover Coverage Efficiency
# 32.00 17.00 17.00 0.53 1.00
evaluateOutliers(iris,irisWithOutliers,rf$outliers)
#Actual Predicted Cover Coverage Efficiency
# 32.00 19.00 19.00 0.59 1.00
We can even display the original values and outliers of the data using a paired box plot.
plot(qrf)
data <- diamonds|>select(price,carat,cut,color,clarity)
data2 <- outqrf::generateOutliers(data, p = 0.001,seed =2024)
qrf <- outqrf(data2,num.threads=8,quantiles_type=400)
# The process can be slow because it needs to predict the value at 400|1000 quantiles for each observation.
rf <- outForest(data2)
evaluateOutliers(data,data2,qrf$outliers)
#Actual Predicted Cover Coverage Efficiency
#108.00 369.00 103.00 0.95 0.28
evaluateOutliers(data,data2,rf$outliers)
#Actual Predicted Cover Coverage Efficiency
#108.00 687.00 104.00 0.96 0.15
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They may not be fully stable and should be used with caution. We make no claims about them.