Preface

After you have acquired the data, you should do the following:

The dlookr package makes these steps fast and easy:

This document introduces data transformation methods provided by the dlookr package. You will learn how to transform of tbl_df data that inherits from data.frame and data.frame with functions provided by dlookr.

dlookr synergy with dplyr increases. Particularly in data transformation and data wrangle, it increases the efficiency of the tidyverse package group.

datasets

To illustrate the basic use of EDA in the dlookr package, I use a Carseats datasets. Carseats in the ISLR package is simulation dataset that sells children's car seats at 400 stores. This data is a data.frame created for the purpose of predicting sales volume.

library(ISLR)
str(Carseats)
'data.frame':   400 obs. of  11 variables:
 $ Sales      : num  9.5 11.22 10.06 7.4 4.15 ...
 $ CompPrice  : num  138 111 113 117 141 124 115 136 132 132 ...
 $ Income     : num  73 48 35 100 64 113 105 81 110 113 ...
 $ Advertising: num  11 16 10 4 3 13 0 15 0 0 ...
 $ Population : num  276 260 269 466 340 501 45 425 108 131 ...
 $ Price      : num  120 83 80 97 128 72 108 120 124 124 ...
 $ ShelveLoc  : Factor w/ 3 levels "Bad","Good","Medium": 1 2 3 3 1 1 3 2 3 3 ...
 $ Age        : num  42 65 59 55 38 78 71 67 76 76 ...
 $ Education  : num  17 10 12 14 13 16 15 10 10 17 ...
 $ Urban      : Factor w/ 2 levels "No","Yes": 2 2 2 2 2 1 2 2 1 1 ...
 $ US         : Factor w/ 2 levels "No","Yes": 2 2 2 2 1 2 1 2 1 2 ...

The contents of individual variables are as follows. (Refer to ISLR::Carseats Man page)

When data analysis is performed, data containing missing values is often encountered. However, Carseats is complete data without missing. Therefore, the missing values are generated as follows. And I created a data.frame object named carseats.

carseats <- ISLR::Carseats

suppressWarnings(RNGversion("3.5.0"))
set.seed(123)
carseats[sample(seq(NROW(carseats)), 20), "Income"] <- NA

suppressWarnings(RNGversion("3.5.0"))
set.seed(456)
carseats[sample(seq(NROW(carseats)), 10), "Urban"] <- NA

Data Transformation

dlookr imputates missing values and outliers and resolves skewed data. It also provides the ability to bin continuous variables as categorical variables.

Here is a list of the data conversion functions and functions provided by dlookr:

Imputation of missing values

Imputates the missing value with imputate_na()

imputate_na() imputates the missing value in the variable. The predictor with missing values supports both numeric and categorical variables and supports the following methods.

imputate_na() imputates the missing value with “rpart” for the numeric variable, Income. summary() summarizes missing value imputation information, and plot() visualizes imputation information.

income <- imputate_na(carseats, Income, US, method = "rpart")
Warning in imputate_na_impl(.data, vars, target, method, seed, print_flag):
All values returned as NA. The data is not good enough for a imputation.

# result of imputate
income
  [1] NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA
 [24] NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA
 [47] NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA
 [70] NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA
 [93] NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA
[116] NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA
[139] NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA
[162] NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA
[185] NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA
[208] NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA
[231] NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA
[254] NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA
[277] NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA
[300] NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA
[323] NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA
[346] NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA
[369] NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA
[392] NA NA NA NA NA NA NA NA NA
attr(,"var_type")
[1] "numerical"
attr(,"method")
[1] "rpart"
attr(,"na_pos")
 [1]  17  18  40  95 116 126 163 177 179 209 217 222 263 315 347 351 364
[18] 373 374 397
attr(,"type")
[1] "missing values"
attr(,"message")
[1] "All values returned as NA. The data is not good enough for a imputation."
attr(,"success")
[1] FALSE
attr(,"class")
[1] "imputation" "logical"   

# summary of imputate
summary(income)
imputation object isn't success.
NULL

# viz of imputate
plot(income)

plot of chunk imputate_na

The following imputates the categorical variable urban by the “mice” method.

library(mice)

urban <- imputate_na(carseats, Urban, US, method = "mice")

 iter imp variable
  1   1  Income  Urban
  1   2  Income  Urban
  1   3  Income  Urban
  1   4  Income  Urban
  1   5  Income  Urban
  2   1  Income  Urban
  2   2  Income  Urban
  2   3  Income  Urban
  2   4  Income  Urban
  2   5  Income  Urban
  3   1  Income  Urban
  3   2  Income  Urban
  3   3  Income  Urban
  3   4  Income  Urban
  3   5  Income  Urban
  4   1  Income  Urban
  4   2  Income  Urban
  4   3  Income  Urban
  4   4  Income  Urban
  4   5  Income  Urban
  5   1  Income  Urban
  5   2  Income  Urban
  5   3  Income  Urban
  5   4  Income  Urban
  5   5  Income  Urban

# result of imputate
urban
  [1] Yes Yes Yes Yes Yes No  Yes Yes No  No  No  Yes Yes Yes Yes No  Yes
 [18] Yes No  Yes Yes No  Yes Yes Yes No  No  Yes Yes Yes Yes Yes Yes Yes
 [35] Yes No  No  Yes Yes No  No  Yes Yes Yes Yes Yes No  Yes Yes Yes Yes
 [52] Yes Yes Yes No  Yes Yes Yes Yes Yes Yes No  Yes Yes No  No  Yes Yes
 [69] Yes Yes Yes No  Yes No  No  No  Yes No  Yes Yes Yes Yes Yes Yes No 
 [86] No  Yes No  Yes No  No  Yes Yes No  Yes Yes No  Yes No  No  No  Yes
[103] No  Yes Yes Yes No  Yes Yes No  Yes Yes Yes Yes Yes Yes No  Yes Yes
[120] Yes Yes Yes Yes No  Yes No  Yes Yes Yes No  Yes No  Yes Yes Yes No 
[137] No  Yes Yes No  Yes Yes Yes Yes No  Yes Yes No  No  Yes No  No  No 
[154] No  No  Yes Yes No  No  No  No  No  Yes No  No  Yes Yes Yes Yes Yes
[171] Yes Yes Yes Yes No  Yes No  Yes No  Yes Yes Yes Yes Yes No  Yes No 
[188] Yes Yes No  No  Yes No  Yes Yes Yes Yes Yes Yes Yes No  Yes No  Yes
[205] Yes Yes Yes No  Yes No  No  Yes Yes Yes Yes Yes Yes No  Yes Yes Yes
[222] Yes Yes Yes No  Yes Yes Yes No  No  No  No  Yes No  No  Yes Yes Yes
[239] Yes Yes Yes Yes No  Yes Yes No  Yes Yes Yes Yes Yes Yes Yes No  Yes
[256] Yes Yes Yes No  No  Yes Yes Yes Yes Yes Yes No  No  Yes Yes Yes Yes
[273] Yes Yes Yes Yes Yes Yes No  Yes Yes No  Yes No  No  Yes No  Yes No 
[290] Yes No  No  Yes Yes Yes No  Yes Yes Yes No  Yes Yes Yes Yes Yes Yes
[307] Yes Yes Yes Yes Yes Yes No  Yes Yes Yes Yes No  No  No  Yes Yes Yes
[324] Yes Yes Yes Yes Yes Yes Yes No  Yes Yes Yes Yes Yes Yes Yes Yes Yes
[341] Yes No  No  Yes No  Yes No  No  Yes No  No  No  Yes No  Yes Yes Yes
[358] Yes Yes Yes No  No  Yes Yes Yes No  No  Yes No  Yes Yes Yes No  Yes
[375] Yes Yes Yes No  Yes Yes Yes Yes Yes Yes Yes Yes Yes No  Yes Yes Yes
[392] Yes Yes No  Yes Yes No  Yes Yes Yes
attr(,"var_type")
[1] categorical
attr(,"method")
[1] mice
attr(,"na_pos")
 [1]  33  36  84  94 113 132 151 292 313 339
attr(,"type")
[1] missing values
attr(,"message")
[1] complete imputation
attr(,"success")
[1] TRUE
Levels: No Yes

# summary of imputate
summary(urban)
* Information of Imputation (before vs after)
     original imputation original_percent imputation_percent
No        115        121            28.75              30.25
Yes       275        279            68.75              69.75
<NA>       10          0             2.50               0.00

# viz of imputate
plot(urban)

plot of chunk imputate_na2

Collaboration with dplyr

The following is an example of calculating the arithmetic mean of US variables by using the Income variable that imputates the missing value with dplyr.

# The mean before and after the imputation of the Income variable
carseats %>%
  mutate(Income_imp = imputate_na(carseats, Income, US, method = "knn")) %>%
  group_by(US) %>%
  summarise(orig = mean(Income, na.rm = TRUE),
    imputation = mean(Income_imp))
Warning in imputate_na_impl(.data, vars, target, method, seed, print_flag):
All values returned as NA. The data is not good enough for a imputation.
# A tibble: 2 x 3
  US     orig imputation
  <fct> <dbl>      <dbl>
1 No     65.8         NA
2 Yes    70.4         NA

Imputation of outliers

Imputates thr outliers with imputate_outlier()

imputate_outlier() imputates the outliers value. The predictor with outliers supports only numeric variables and supports the following methods.

imputate_outlier() imputates the outliers with the numeric variable Price as the “capping” method, as follows. summary() summarizes outliers imputation information, and plot() visualizes imputation information.

price <- imputate_outlier(carseats, Price, method = "capping")

# result of imputate
price
  [1] 120.00  83.00  80.00  97.00 128.00  72.00 108.00 120.00 124.00 124.00
 [11] 100.00  94.00 136.00  86.00 118.00 144.00 110.00 131.00  68.00 121.00
 [21] 131.00 109.00 138.00 109.00 113.00  82.00 131.00 107.00  97.00 102.00
 [31]  89.00 131.00 137.00 128.00 128.00  96.00 100.00 110.00 102.00 138.00
 [41] 126.00 124.00  77.00 134.00  95.00 135.00  70.00 108.00  98.00 149.00
 [51] 108.00 108.00 129.00 119.00 144.00 154.00  84.00 117.00 103.00 114.00
 [61] 123.00 107.00 133.00 101.00 104.00 128.00  91.00 115.00 134.00  99.00
 [71]  99.00 150.00 116.00 104.00 136.00  92.00  70.00  89.00 145.00  90.00
 [81]  79.00 128.00 139.00  94.00 121.00 112.00 134.00 126.00 111.00 119.00
 [91] 103.00 107.00 125.00 104.00  84.00 148.00 132.00 129.00 127.00 107.00
[101] 106.00 118.00  97.00  96.00 138.00  97.00 139.00 108.00 103.00  90.00
[111] 116.00 151.00 125.00 127.00 106.00 129.00 128.00 119.00  99.00 128.00
[121] 131.00  87.00 108.00 155.00 120.00  77.00 133.00 116.00 126.00 147.00
[131]  77.00  94.00 136.00  97.00 131.00 120.00 120.00 118.00 109.00  94.00
[141] 129.00 131.00 104.00 159.00 123.00 117.00 131.00 119.00  97.00  87.00
[151] 114.00 103.00 128.00 150.00 110.00  69.00 157.00  90.00 112.00  70.00
[161] 111.00 160.00 149.00 106.00 141.00 155.05 137.00  93.00 117.00  77.00
[171] 118.00  55.00 110.00 128.00 155.05 122.00 154.00  94.00  81.00 116.00
[181] 149.00  91.00 140.00 102.00  97.00 107.00  86.00  96.00  90.00 104.00
[191] 101.00 173.00  93.00  96.00 128.00 112.00 133.00 138.00 128.00 126.00
[201] 146.00 134.00 130.00 157.00 124.00 132.00 160.00  97.00  64.00  90.00
[211] 123.00 120.00 105.00 139.00 107.00 144.00 144.00 111.00 120.00 116.00
[221] 124.00 107.00 145.00 125.00 141.00  82.00 122.00 101.00 163.00  72.00
[231] 114.00 122.00 105.00 120.00 129.00 132.00 108.00 135.00 133.00 118.00
[241] 121.00  94.00 135.00 110.00 100.00  88.00  90.00 151.00 101.00 117.00
[251] 156.00 132.00 117.00 122.00 129.00  81.00 144.00 112.00  81.00 100.00
[261] 101.00 118.00 132.00 115.00 159.00 129.00 112.00 112.00 105.00 166.00
[271]  89.00 110.00  63.00  86.00 119.00 132.00 130.00 125.00 151.00 158.00
[281] 145.00 105.00 154.00 117.00  96.00 131.00 113.00  72.00  97.00 156.00
[291] 103.00  89.00  74.00  89.00  99.00 137.00 123.00 104.00 130.00  96.00
[301]  99.00  87.00 110.00  99.00 134.00 132.00 133.00 120.00 126.00  80.00
[311] 166.00 132.00 135.00  54.00 129.00 171.00  72.00 136.00 130.00 129.00
[321] 152.00  98.00 139.00 103.00 150.00 104.00 122.00 104.00 111.00  89.00
[331] 112.00 134.00 104.00 147.00  83.00 110.00 143.00 102.00 101.00 126.00
[341]  91.00  93.00 118.00 121.00 126.00 149.00 125.00 112.00 107.00  96.00
[351]  91.00 105.00 122.00  92.00 145.00 146.00 164.00  72.00 118.00 130.00
[361] 114.00 104.00 110.00 108.00 131.00 162.00 134.00  77.00  79.00 122.00
[371] 119.00 126.00  98.00 116.00 118.00 124.00  92.00 125.00 119.00 107.00
[381]  89.00 151.00 121.00  68.00 112.00 132.00 160.00 115.00  78.00 107.00
[391] 111.00 124.00 130.00 120.00 139.00 128.00 120.00 159.00  95.00 120.00
attr(,"method")
[1] "capping"
attr(,"var_type")
[1] "numerical"
attr(,"outlier_pos")
[1]  43 126 166 175 368
attr(,"outliers")
[1]  24  49 191 185  53
attr(,"type")
[1] "outliers"
attr(,"message")
[1] "complete imputation"
attr(,"success")
[1] TRUE
attr(,"class")
[1] "imputation" "numeric"   

# summary of imputate
summary(price)
Impute outliers with capping

* Information of Imputation (before vs after)
            Original  Imputation
n        400.0000000 400.0000000
na         0.0000000   0.0000000
mean     115.7950000 115.8927500
sd        23.6766644  22.6109187
se_mean    1.1838332   1.1305459
IQR       31.0000000  31.0000000
skewness  -0.1252862  -0.0461621
kurtosis   0.4518850  -0.3030578
p00       24.0000000  54.0000000
p01       54.9900000  67.9600000
p05       77.0000000  77.0000000
p10       87.0000000  87.0000000
p20       96.8000000  96.8000000
p25      100.0000000 100.0000000
p30      104.0000000 104.0000000
p40      110.0000000 110.0000000
p50      117.0000000 117.0000000
p60      122.0000000 122.0000000
p70      128.3000000 128.3000000
p75      131.0000000 131.0000000
p80      134.0000000 134.0000000
p90      146.0000000 146.0000000
p95      155.0500000 155.0025000
p99      166.0500000 164.0200000
p100     191.0000000 173.0000000

# viz of imputate
plot(price)

plot of chunk imputate_outlier

Collaboration with dplyr

The following is an example of calculating the arithmetic mean of US variables by using the Price variable that imputates the outlier with dplyr.

# The mean before and after the imputation of the Price variable
carseats %>%
  mutate(Price_imp = imputate_outlier(carseats, Price, method = "capping")) %>%
  group_by(US) %>%
  summarise(orig = mean(Price, na.rm = TRUE),
    imputation = mean(Price_imp, na.rm = TRUE))
# A tibble: 2 x 3
  US     orig imputation
  <fct> <dbl>      <dbl>
1 No     114.       114.
2 Yes    117.       117.

Standardization and Resolving Skewness

Introduction to the use of transform()

transform() performs data transformation. Only numeric variables are supported, and the following methods are provided.

Standardization with transform()

Use the methods “zscore” and “minmax” to perform standardization.

carseats %>% 
  mutate(Income_minmax = transform(carseats$Income, method = "minmax"),
    Sales_minmax = transform(carseats$Sales, method = "minmax")) %>% 
  select(Income_minmax, Sales_minmax) %>% 
  boxplot()

plot of chunk standardization

Resolving Skewness data with transform()

find_skewness() calculates the skewness and finds the skewed data.

# find index of skewed variables
find_skewness(carseats)
[1] 4

# find names of skewed variables
find_skewness(carseats, index = FALSE)
[1] "Advertising"

# compute the skewness
find_skewness(carseats, value = TRUE)
      Sales   CompPrice      Income Advertising  Population       Price 
      0.185      -0.043          NA       0.637      -0.051      -0.125 
        Age   Education 
     -0.077       0.044 

# compute the skewness & filtering with threshold
find_skewness(carseats, value = TRUE, thres = 0.1)
      Sales Advertising       Price 
      0.185       0.637      -0.125 

The skewness of Advertising is 0.637, which is a little slanted to the left, so I use transformation () to convert it to log. summary() summarizes the transformation information, and plot() visualizes the transformation information.

Advertising_log = transform(carseats$Advertising, method = "log")

# result of transformation
head(Advertising_log)
[1] 2.397895 2.772589 2.302585 1.386294 1.098612 2.564949
# summary of transformation
summary(Advertising_log)
* Resolving Skewness with log

* Information of Transformation (before vs after)
            Original Transformation
n        400.0000000    400.0000000
na         0.0000000      0.0000000
mean       6.6350000           -Inf
sd         6.6503642            NaN
se_mean    0.3325182            NaN
IQR       12.0000000            Inf
skewness   0.6395858            NaN
kurtosis  -0.5451178            NaN
p00        0.0000000           -Inf
p01        0.0000000           -Inf
p05        0.0000000           -Inf
p10        0.0000000           -Inf
p20        0.0000000           -Inf
p25        0.0000000           -Inf
p30        0.0000000           -Inf
p40        2.0000000      0.6931472
p50        5.0000000      1.6094379
p60        8.4000000      2.1265548
p70       11.0000000      2.3978953
p75       12.0000000      2.4849066
p80       13.0000000      2.5649494
p90       16.0000000      2.7725887
p95       19.0000000      2.9444390
p99       23.0100000      3.1359198
p100      29.0000000      3.3672958
# viz of transformation
plot(Advertising_log)

plot of chunk resolving2

It seems that the raw data contains 0, as there is a -Inf in the log converted value. So this time we convert it to “log + 1”.

Advertising_log <- transform(carseats$Advertising, method = "log+1")

# result of transformation
head(Advertising_log)
[1] 2.484907 2.833213 2.397895 1.609438 1.386294 2.639057
# summary of transformation
summary(Advertising_log)
* Resolving Skewness with log+1

* Information of Transformation (before vs after)
            Original Transformation
n        400.0000000   400.00000000
na         0.0000000     0.00000000
mean       6.6350000     1.46247709
sd         6.6503642     1.19436323
se_mean    0.3325182     0.05971816
IQR       12.0000000     2.56494936
skewness   0.6395858    -0.19852549
kurtosis  -0.5451178    -1.66342876
p00        0.0000000     0.00000000
p01        0.0000000     0.00000000
p05        0.0000000     0.00000000
p10        0.0000000     0.00000000
p20        0.0000000     0.00000000
p25        0.0000000     0.00000000
p30        0.0000000     0.00000000
p40        2.0000000     1.09861229
p50        5.0000000     1.79175947
p60        8.4000000     2.23936878
p70       11.0000000     2.48490665
p75       12.0000000     2.56494936
p80       13.0000000     2.63905733
p90       16.0000000     2.83321334
p95       19.0000000     2.99573227
p99       23.0100000     3.17846205
p100      29.0000000     3.40119738
# viz of transformation
plot(Advertising_log)

plot of chunk resolving3

Binning

Binning of individual variables using binning()

binning() transforms a numeric variable into a categorical variable by binning it. The following types of binning are supported.

The following example illustrates some ways to Income binning using binning().:

# Binning the carat variable. default type argument is "quantile"
bin <- binning(carseats$Income)
# Print bins class object
bin
binned type: quantile
number of bins: 10
x
    [21,30]     (30,39]     (39,48]     (48,62]     (62,69]     (69,78] 
         40          37          38          40          42          33 
  (78,86.6] (86.6,96.6]  (96.6,109]   (109,120]        <NA> 
         36          38          38          38          20 
# Summarise bins class object
summary(bin)
        levels freq   rate
1      [21,30]   40 0.1000
2      (30,39]   37 0.0925
3      (39,48]   38 0.0950
4      (48,62]   40 0.1000
5      (62,69]   42 0.1050
6      (69,78]   33 0.0825
7    (78,86.6]   36 0.0900
8  (86.6,96.6]   38 0.0950
9   (96.6,109]   38 0.0950
10   (109,120]   38 0.0950
11        <NA>   20 0.0500
# Plot bins class object
plot(bin)

plot of chunk binning

# Using labels argument
bin <- binning(carseats$Income, nbins = 4,
              labels = c("LQ1", "UQ1", "LQ3", "UQ3"))
bin
binned type: quantile
number of bins: 4
x
 LQ1  UQ1  LQ3  UQ3 <NA> 
  95  102   89   94   20 
# Using another type argument
binning(carseats$Income, nbins = 5, type = "equal")
binned type: equal
number of bins: 5
x
  [21,40.8] (40.8,60.6] (60.6,80.4]  (80.4,100]   (100,120]        <NA> 
         81          65          94          80          60          20 
binning(carseats$Income, nbins = 5, type = "pretty")
binned type: pretty
number of bins: 5
x
  [20,40]   (40,60]   (60,80]  (80,100] (100,120]      <NA> 
       81        65        94        80        60        20 
binning(carseats$Income, nbins = 5, type = "kmeans")
binned type: kmeans
number of bins: 5
x
  [21,37.5] (37.5,55.5] (55.5,75.5] (75.5,97.5]  (97.5,120]        <NA> 
         70          58          91          86          75          20 
binning(carseats$Income, nbins = 5, type = "bclust")
binned type: bclust
number of bins: 5
x
  [21,37.5] (37.5,55.5] (55.5,78.5] (78.5,93.5]  (93.5,120]        <NA> 
         70          58         102          66          84          20 

# -------------------------
# Using pipes & dplyr
# -------------------------
library(dplyr)

carseats %>%
 mutate(Income_bin = binning(carseats$Income)) %>%
 group_by(ShelveLoc, Income_bin) %>%
 summarise(freq = n()) %>%
 arrange(desc(freq)) %>%
 head(10)
Warning: Factor `Income_bin` contains implicit NA, consider using
`forcats::fct_explicit_na`
# A tibble: 10 x 3
# Groups:   ShelveLoc [1]
  ShelveLoc Income_bin  freq
  <fct>     <ord>      <int>
1 Medium    [21,30]       25
2 Medium    (62,69]       24
3 Medium    (48,62]       23
4 Medium    (39,48]       21
# … with 6 more rows

Optimal Binning with binning_by()

binning_by() converts a numeric variable into a categorical variable by optimal binning. This method is often used when developing a scorecard model.

The following binning_by() example optimally binning Advertising if US is a target variable with a binary class.

# optimal binning
bin <- binning_by(carseats, "US", "Advertising")
Warning in binning_by(carseats, "US", "Advertising"): The factor y has been
changed to a numeric vector consisting of 0 and 1.
bin
binned type: optimal
number of bins: 3
x
[-1,0]  (0,6] (6,29] 
   144     69    187 

# summary optimal_bins class
summary(bin)
  levels freq   rate
1 [-1,0]  144 0.3600
2  (0,6]   69 0.1725
3 (6,29]  187 0.4675

# information value 
attr(bin, "iv")
[1] 4.8349

# information value table
attr(bin, "ivtable")
  Cutpoint CntRec CntGood CntBad CntCumRec CntCumGood CntCumBad PctRec
1     <= 0    144      19    125       144         19       125 0.3600
2     <= 6     69      54     15       213         73       140 0.1725
3      > 6    187     185      2       400        258       142 0.4675
4  Missing      0       0      0       400        258       142 0.0000
5    Total    400     258    142        NA         NA        NA 1.0000
  GoodRate BadRate    Odds  LnOdds     WoE     IV
1   0.1319  0.8681  0.1520 -1.8839 -2.4810 2.0013
2   0.7826  0.2174  3.6000  1.2809  0.6838 0.0709
3   0.9893  0.0107 92.5000  4.5272  3.9301 2.7627
4      NaN     NaN     NaN     NaN     NaN    NaN
5   0.6450  0.3550  1.8169  0.5971  0.0000 4.8349

# visualize optimal_bins class
plot(bin, sub = "bins of Advertising variable")

plot of chunk binning_by

Creating a data transformation report using transformation_report()

transformation_report() creates a data transformation report for all the variables in the data frame or objects that inherit the data frame (tbl_df, tbl, etc.).

transformation_report() creates a data transformation report in two forms:

The contents of the report are as follows.:

The following creates a data transformation report for carseats. The file format is pdf, and the file name is Transformation_Report.pdf.

carseats %>%
  transformation_report(target = US)

The following generates a report in html format called transformation.html.

carseats %>%
  transformation_report(target = US, output_format = "html", 
    output_file = "transformation.html")

Data transformation reports are automated reports to assist in the data transformation process. Design data conversion scenarios by referring to the report results.

Data transformation report contents

Contents of pdf file

Data transformation report cover

Table of Contents

Data Transformation Report Table and Visualization Example

Contents of html file

Data transformation report titles and table of contents

Report table example (Web)

Data transformation report Binning information (web)