Pivot Table

David Gerbing

Overview

Descriptive Statistics

Descriptive summarize characteristics of the sample data values for one or more variables. The lessR pivot() function serves as a single source for a wide variety and types of descriptive statistics for one or more variables communicated in the form of a pivot table. Compute statistics either for the entire data set at once or separately for different groups of data.

Aggregation: From the values of categorical variables, form groups of data and then compute one or more statistics for each group.

As an example of aggregation, compute the mean Years worked for each combination of the levels of Gender and Dept (department) of employment. To introduce the ease of use of pivot(), and to provide context for the following discussion, the function call listed below includes the parameter names (in red) for emphasis. However, if the parameters are entered in this order, listing their names is not necessary. Enter multiple values, such as for Gender and Dept as an R vector, defined such as with the base R combine c() function. The output of the analysis is shown later.

The pivot() function computes statistics for three classes of variables:

Any function that processes a single vector of data, such as a column of data values for a variable in a data frame, and outputs a single computed value, the statistic, can be passed to pivot(). The phrase “any function” is quite general, including any function in any active package as well as user-defined functions that satisfy these criteria. The function accessed by pivot() can be one of the many available R statistical functions that summarize data, including those in the following table.

Statistic Meaning
sum sum
mean arithmetic mean
median median
min minimum
max maximum
sd standard deviation
var variance
skew skew
kurtosis kurtosis
IQR inter-quartile range
mad mean absolute deviation

The statistics skew and kurtosis have no counterparts in base R, so are provided by lessR. Computations of all other statistics follow from base R functions.

The quantile and table computations return multiple values. They are accessible to pivot() only because of internal programming that recognizes these functions and then processes the resulting multiple output values.

Statistic Meaning
quantile min, quantiles, max
table cell counts or proportions

The default quantiles for quantile are quartiles. Specify a custom number of quantiles with the q_num parameter other than 4 for quartiles.

The table computation applies to an aggregated variable that consists of discrete categories, such as the numbers 1 through 5 for responses to a 5-pt Likert scale. The result is a table of frequencies or proportions, referred to for two or more variables as either a contingency table, a cross-tabulation table, or a joint frequency distribution. Only the table computation applies to non-numeric as well as numeric variables, though only meaningful if the aggregated variable consists of a relatively small set of discrete values, character strings or numeric.

When calculating a statistic, the analyst should be aware of the present and missing (not available or NA) data that underlies the computed statistic. Accordingly, pivot() by default provides the sample size information for each calculation. Turn off the display of information by setting the show_n parameter to FALSE.

Parameters

The following pivot() parameters specify the data, one or more statistics to compute for the aggregation, the variables over which to aggregate, and the corresponding groups that contain the aggregated values. The first three parameter values listed below are required: the data frame, at least one statistic to compute, and at least one variable for which to compute the statistic(s).

  1. data: The data frame that includes the variables of interest.
  2. compute: One or more functions that specify the corresponding statistics to compute.
  3. variable: One or more numerical variables to summarize, either by aggregation over groups or the entire sample as a single group.
  4. by: Specify the optional aggregation according to the categorical variable(s) that define the groups.
  5. by_cols: The optional categorical variable(s) that define the groups or cells for which to compute the aggregated values, listed as columns in a two-dimensional table instead of a data frame.

For the given data, compute at least one statistic for at least one variable. If aggregating across groups, compute the statistic(s) for each group specified by by and possibly by_cols.

If no categorical (by) variables are selected to define groups, then one or more statistics are computed over multiple variables over the entire data table defined as a single group. For categorical (grouping) variables, defined with by and optionally by_cols, choose to either compute multiple statistics or multiple variable(s), but not both.

Select any two of the three possibilities for multiple parameter values: Multiple compute functions, multiple variables over which to compute, and multiple categorical variables by which to define groups for aggregation.

Specify multiple descriptive statistics to compute, multiple values for which to do the computation, and multiple categorical variables to define groups as vectors such as with the base R c() function.

Output

The default output of pivot() is a data frame, a two-dimensional table, rows and columns. The output table can have multiple rows and multiple columns according to the choice of parameter values. For each numerical variable in the analysis, pivot() displays both the corresponding sample size as n_ and amount of missing or not available data as na_. Prevent displaying sample size information by setting parameter show_n to FALSE.

The output is structured according to the following.

Output as a Long-Form Data Frame

To illustrate, use the 37-row Employee data set included with lessR, here read into the d data frame.

d <- Read("Employee")

Two categorical variables in the d data frame are Dept and Gender, encoded as character strings. Continuous variables include Years employed at the company and annual Salary.

Multiple Grouping Variables

This example does the analysis previously illustrated. The name of the computed mean of Years by default is Years_mean. With no by_cols variables, the output of pivot() is a data frame of the aggregated variables. Optionally save this output for further analysis, as the data frame a in this example.

a <- pivot(data=d, compute=mean, variable=Years, by=c(Dept, Gender))
a
##    Dept Gender n na Years_mean
## 1  ACCT      M 2  0      7.000
## 2  ADMN      M 2  0     15.500
## 3  FINC      M 3  0     11.333
## 4  MKTG      M 1  0     18.000
## 5  SALE      M 9  1     12.333
## 6  <NA>      M 0  0         NA
## 7  ACCT      W 3  0      4.667
## 8  ADMN      W 4  0      7.500
## 9  FINC      W 1  0      7.000
## 10 MKTG      W 5  0      8.200
## 11 SALE      W 5  0      6.600
## 12 <NA>      W 1  0      5.000

Using the lessR function Read(), can read the original data table from which the pivot table was constructed, such as in the form of an Excel worksheet. For many analyses, easier to read the Excel data into R and do the analysis in R than remain in Excel. The result can also be written back into an Excel file with the lessR function Write().

In this example, create an Excel file called MyPivotTable.xlsx from the pivot table stored in the a data frame. To avoid creating this file, the function call is commented out with the # symbol in the first column.

#Write("MyPivotTable", data=a, format="Excel")

The abbreviation wrt_x() for the function name simplifies the preceding expression for writing to an Excel file, with the format parameter dropped.

Aggregate with Multiple Statistics

In this next example, specify multiple statistics for which to aggregate for each group for the specified value variable Salary. For each group, compare the mean to the median, and the standard deviation to the interquartile range. By default, each column of an aggregated statistic is the variable name, here Salary, followed by a “_”, then either the name of the statistic or an abbreviation. The respective abbreviations for mean and median are mn and md.

pivot(d, c(mean, median, sd, IQR), Salary, Dept)
##   Dept Salary_n na     mean Salary_mdn Salary_sd Salary_IQR
## 1 ACCT        5  0 61792.78   69547.60  12774.61   21379.23
## 2 ADMN        6  0 81277.12   71058.60  27585.15   36120.57
## 3 FINC        4  0 69010.68   61937.62  17852.50   16034.81
## 4 MKTG        6  0 70257.13   61658.99  19869.81   26085.69
## 5 SALE       15  0 78830.07   77714.85  23476.84   28810.28
## 6 <NA>        1  0 53772.58   53772.58        NA       0.00

Also have available two functions provided by lessR that are not part of base R: skew() and kurtosis().

pivot(d, c(mean,sd,skew,kurtosis), Salary, Dept, digits_d=3)
##   Dept Salary_n na     mean Salary_sd Salary_skew Salary_kurt
## 1 ACCT        5  0 61792.78  12774.61      -0.623      -3.032
## 2 ADMN        6  0 81277.12  27585.15       0.835      -1.185
## 3 FINC        4  0 69010.68  17852.50       1.689       2.752
## 4 MKTG        6  0 70257.13  19869.81       0.859      -1.458
## 5 SALE       15  0 78830.07  23476.84       0.863       0.856
## 6 <NA>        1  0 53772.58        NA          NA          NA

Can also customize the variable names of the aggregated statistics with the out_names parameter. Here calculate the mean and median Salary for each group defined by each combination of levels for Gender and Dept.

pivot(d, c(mean, median), Salary, c(Gender,Dept), out_names=c("MeanSalary", "MedianSalary"))
##    Gender Dept  n na MeanSalary MedianSalary
## 1       M ACCT  2  0   59626.19     59626.19
## 2       W ACCT  3  0   63237.16     71084.02
## 3       M ADMN  2  0   80963.35     80963.35
## 4       W ADMN  4  0   81434.00     71058.60
## 5       M FINC  3  0   72967.60     66312.89
## 6       W FINC  1  0   57139.90     57139.90
## 7       M MKTG  1  0   99062.66     99062.66
## 8       W MKTG  5  0   64496.02     61356.69
## 9       M SALE 10  0   86150.97     82442.74
## 10      W SALE  5  0   64188.25     56508.32
## 11      M <NA>  0  0         NA           NA
## 12      W <NA>  1  0   53772.58     53772.58

Aggregate Multiple Variables

The pivot() function can aggregate over multiple variables. Here, aggregate Years and Salary. Round the numerical aggregated results to the nearest integer with the digits_d parameter, which specifies the number of decimal digits in the output. Different variables can have different amounts of missing data, so the sample size, n, and number missing, the number of values Not Available, na, are listed separately for each aggregated variable.

pivot(d, mean, c(Years, Salary), c(Dept, Gender), digits_d=0)
##    Dept Gender Years_n Years_na Years_mean Salary_n Salary_na Salary_mean
## 1  ACCT      M       2        0          7        2         0       59626
## 2  ADMN      M       2        0         16        2         0       80963
## 3  FINC      M       3        0         11        3         0       72968
## 4  MKTG      M       1        0         18        1         0       99063
## 5  SALE      M       9        1         12       10         0       86151
## 6  <NA>      M       0        0         NA        0         0          NA
## 7  ACCT      W       3        0          5        3         0       63237
## 8  ADMN      W       4        0          8        4         0       81434
## 9  FINC      W       1        0          7        1         0       57140
## 10 MKTG      W       5        0          8        5         0       64496
## 11 SALE      W       5        0          7        5         0       64188
## 12 <NA>      W       1        0          5        1         0       53773

Turn off the display of the sample size and number of missing values for each group by setting the parameter show_n to FALSE.

pivot(d, mean, c(Years, Salary), Dept, digits_d=2, show_n=FALSE)
##   Dept Years_mean Salary_mean
## 1 ACCT       5.60    61792.78
## 2 ADMN      10.17    81277.12
## 3 FINC      10.25    69010.68
## 4 MKTG       9.83    70257.13
## 5 SALE      10.29    78830.06
## 6 <NA>       5.00    53772.58

Compute over All Data

Aggregation computes one or more statistics for one or more variables across different groups. Or, compute the variables for each statistic for all the data. To compute over all the rows of data, do not specify groups, that is, drop the by parameter.

Get the grand mean of Years, that is, for all the data.

pivot(d, mean, Years)
## 
##  "1": 1 
##   Years_n Years_na Years_mean
## 1      36        1   9.388889
##   n na  mean
##  36  1 9.389

Get the grand mean of Years and Salary. Specify custom names for the results.

pivot(d, mean, c(Years, Salary), digits_d=2, out_names=c("MeanYear", "MeanSalary"))
## 
##  "1": 1 
##   Years_n Years_na MeanYear Salary_n Salary_na MeanSalary
## 1      36        1 9.388889       37         0   73795.56
##  Years_n Years_na MeanYear Salary_n Salary_na MeanSalary
##       36        1     9.39       37         0   73795.56

Consider an example with more variables. Analyze the 6-pt Likert scale responses to the Mach IV scale that assesses Machiavellianism. Items are scored from 0 to 5, Strongly Disagree to Strongly Agree. The data are included with lessR as the Mach4 data file. Suppress output when reading by setting quiet to TRUE.

d <- Read("Mach4", quiet=TRUE)

Calculate the mean, standard deviation, skew, and kurtosis for all of the data for each of the 20 items on the scale. With this specification, the form of a data frame is statistics in the columns and the variables in the rows. The result are the specified summary statistics for the specified variables over the entire data set.

pivot(d, c(mean,sd,skew,kurtosis), m01:m20)
## 
##  "2": 2 
##    X1 X2       X3       X4        X5        X6
## 1 351  0 1.279202 1.285788 0.9836736 0.3563117
## 
##  "2": 2 
##    X1 X2       X3       X4        X5         X6
## 1 351  0 1.279202 1.285788 0.9836736  0.3563117
## 2 351  0 1.746439 1.479800 0.4750667 -0.7836618
## 
##  "2": 2 
##    X1 X2       X3       X4         X5         X6
## 1 351  0 1.279202 1.285788  0.9836736  0.3563117
## 2 351  0 1.746439 1.479800  0.4750667 -0.7836618
## 3 351  0 2.900285 1.449640 -0.3628051 -0.8291409
## 
##  "2": 2 
##    X1 X2       X3       X4         X5         X6
## 1 351  0 1.279202 1.285788  0.9836736  0.3563117
## 2 351  0 1.746439 1.479800  0.4750667 -0.7836618
## 3 351  0 2.900285 1.449640 -0.3628051 -0.8291409
## 4 351  0 3.339031 1.174315 -0.8545394  0.4567202
## 
##  "2": 2 
##    X1 X2       X3       X4          X5         X6
## 1 351  0 1.279202 1.285788  0.98367363  0.3563117
## 2 351  0 1.746439 1.479800  0.47506674 -0.7836618
## 3 351  0 2.900285 1.449640 -0.36280508 -0.8291409
## 4 351  0 3.339031 1.174315 -0.85453943  0.4567202
## 5 351  0 2.233618 1.582803  0.07607808 -1.0949174
## 
##  "2": 2 
##    X1 X2       X3       X4          X5         X6
## 1 351  0 1.279202 1.285788  0.98367363  0.3563117
## 2 351  0 1.746439 1.479800  0.47506674 -0.7836618
## 3 351  0 2.900285 1.449640 -0.36280508 -0.8291409
## 4 351  0 3.339031 1.174315 -0.85453943  0.4567202
## 5 351  0 2.233618 1.582803  0.07607808 -1.0949174
## 6 351  0 3.074074 1.477521 -0.45428558 -0.9230754
## 
##  "2": 2 
##    X1 X2       X3       X4          X5         X6
## 1 351  0 1.279202 1.285788  0.98367363  0.3563117
## 2 351  0 1.746439 1.479800  0.47506674 -0.7836618
## 3 351  0 2.900285 1.449640 -0.36280508 -0.8291409
## 4 351  0 3.339031 1.174315 -0.85453943  0.4567202
## 5 351  0 2.233618 1.582803  0.07607808 -1.0949174
## 6 351  0 3.074074 1.477521 -0.45428558 -0.9230754
## 7 351  0 2.774929 1.472820 -0.06508488 -1.1504259
## 
##  "2": 2 
##    X1 X2       X3       X4          X5         X6
## 1 351  0 1.279202 1.285788  0.98367363  0.3563117
## 2 351  0 1.746439 1.479800  0.47506674 -0.7836618
## 3 351  0 2.900285 1.449640 -0.36280508 -0.8291409
## 4 351  0 3.339031 1.174315 -0.85453943  0.4567202
## 5 351  0 2.233618 1.582803  0.07607808 -1.0949174
## 6 351  0 3.074074 1.477521 -0.45428558 -0.9230754
## 7 351  0 2.774929 1.472820 -0.06508488 -1.1504259
## 8 351  0 2.099715 1.455541  0.13309694 -1.0781871
## 
##  "2": 2 
##    X1 X2       X3       X4          X5         X6
## 1 351  0 1.279202 1.285788  0.98367363  0.3563117
## 2 351  0 1.746439 1.479800  0.47506674 -0.7836618
## 3 351  0 2.900285 1.449640 -0.36280508 -0.8291409
## 4 351  0 3.339031 1.174315 -0.85453943  0.4567202
## 5 351  0 2.233618 1.582803  0.07607808 -1.0949174
## 6 351  0 3.074074 1.477521 -0.45428558 -0.9230754
## 7 351  0 2.774929 1.472820 -0.06508488 -1.1504259
## 8 351  0 2.099715 1.455541  0.13309694 -1.0781871
## 9 351  0 4.225071 1.155384 -1.74473933  2.7434956
## 
##  "2": 2 
##     X1 X2       X3       X4          X5         X6
## 1  351  0 1.279202 1.285788  0.98367363  0.3563117
## 2  351  0 1.746439 1.479800  0.47506674 -0.7836618
## 3  351  0 2.900285 1.449640 -0.36280508 -0.8291409
## 4  351  0 3.339031 1.174315 -0.85453943  0.4567202
## 5  351  0 2.233618 1.582803  0.07607808 -1.0949174
## 6  351  0 3.074074 1.477521 -0.45428558 -0.9230754
## 7  351  0 2.774929 1.472820 -0.06508488 -1.1504259
## 8  351  0 2.099715 1.455541  0.13309694 -1.0781871
## 9  351  0 4.225071 1.155384 -1.74473933  2.7434956
## 10 351  0 3.991453 1.137635 -1.15418554  0.9315304
## 
##  "2": 2 
##     X1 X2       X3       X4          X5         X6
## 1  351  0 1.279202 1.285788  0.98367363  0.3563117
## 2  351  0 1.746439 1.479800  0.47506674 -0.7836618
## 3  351  0 2.900285 1.449640 -0.36280508 -0.8291409
## 4  351  0 3.339031 1.174315 -0.85453943  0.4567202
## 5  351  0 2.233618 1.582803  0.07607808 -1.0949174
## 6  351  0 3.074074 1.477521 -0.45428558 -0.9230754
## 7  351  0 2.774929 1.472820 -0.06508488 -1.1504259
## 8  351  0 2.099715 1.455541  0.13309694 -1.0781871
## 9  351  0 4.225071 1.155384 -1.74473933  2.7434956
## 10 351  0 3.991453 1.137635 -1.15418554  0.9315304
## 11 351  0 1.641026 1.394652  0.64126675 -0.3929747
## 
##  "2": 2 
##     X1 X2       X3       X4          X5         X6
## 1  351  0 1.279202 1.285788  0.98367363  0.3563117
## 2  351  0 1.746439 1.479800  0.47506674 -0.7836618
## 3  351  0 2.900285 1.449640 -0.36280508 -0.8291409
## 4  351  0 3.339031 1.174315 -0.85453943  0.4567202
## 5  351  0 2.233618 1.582803  0.07607808 -1.0949174
## 6  351  0 3.074074 1.477521 -0.45428558 -0.9230754
## 7  351  0 2.774929 1.472820 -0.06508488 -1.1504259
## 8  351  0 2.099715 1.455541  0.13309694 -1.0781871
## 9  351  0 4.225071 1.155384 -1.74473933  2.7434956
## 10 351  0 3.991453 1.137635 -1.15418554  0.9315304
## 11 351  0 1.641026 1.394652  0.64126675 -0.3929747
## 12 351  0 1.800570 1.624843  0.42175863 -1.1163775
## 
##  "2": 2 
##     X1 X2       X3       X4          X5         X6
## 1  351  0 1.279202 1.285788  0.98367363  0.3563117
## 2  351  0 1.746439 1.479800  0.47506674 -0.7836618
## 3  351  0 2.900285 1.449640 -0.36280508 -0.8291409
## 4  351  0 3.339031 1.174315 -0.85453943  0.4567202
## 5  351  0 2.233618 1.582803  0.07607808 -1.0949174
## 6  351  0 3.074074 1.477521 -0.45428558 -0.9230754
## 7  351  0 2.774929 1.472820 -0.06508488 -1.1504259
## 8  351  0 2.099715 1.455541  0.13309694 -1.0781871
## 9  351  0 4.225071 1.155384 -1.74473933  2.7434956
## 10 351  0 3.991453 1.137635 -1.15418554  0.9315304
## 11 351  0 1.641026 1.394652  0.64126675 -0.3929747
## 12 351  0 1.800570 1.624843  0.42175863 -1.1163775
## 13 351  0 1.384615 1.368082  0.83624504 -0.1256438
## 
##  "2": 2 
##     X1 X2       X3       X4          X5         X6
## 1  351  0 1.279202 1.285788  0.98367363  0.3563117
## 2  351  0 1.746439 1.479800  0.47506674 -0.7836618
## 3  351  0 2.900285 1.449640 -0.36280508 -0.8291409
## 4  351  0 3.339031 1.174315 -0.85453943  0.4567202
## 5  351  0 2.233618 1.582803  0.07607808 -1.0949174
## 6  351  0 3.074074 1.477521 -0.45428558 -0.9230754
## 7  351  0 2.774929 1.472820 -0.06508488 -1.1504259
## 8  351  0 2.099715 1.455541  0.13309694 -1.0781871
## 9  351  0 4.225071 1.155384 -1.74473933  2.7434956
## 10 351  0 3.991453 1.137635 -1.15418554  0.9315304
## 11 351  0 1.641026 1.394652  0.64126675 -0.3929747
## 12 351  0 1.800570 1.624843  0.42175863 -1.1163775
## 13 351  0 1.384615 1.368082  0.83624504 -0.1256438
## 14 351  0 1.954416 1.304137  0.20137270 -0.9228997
## 
##  "2": 2 
##     X1 X2       X3       X4          X5         X6
## 1  351  0 1.279202 1.285788  0.98367363  0.3563117
## 2  351  0 1.746439 1.479800  0.47506674 -0.7836618
## 3  351  0 2.900285 1.449640 -0.36280508 -0.8291409
## 4  351  0 3.339031 1.174315 -0.85453943  0.4567202
## 5  351  0 2.233618 1.582803  0.07607808 -1.0949174
## 6  351  0 3.074074 1.477521 -0.45428558 -0.9230754
## 7  351  0 2.774929 1.472820 -0.06508488 -1.1504259
## 8  351  0 2.099715 1.455541  0.13309694 -1.0781871
## 9  351  0 4.225071 1.155384 -1.74473933  2.7434956
## 10 351  0 3.991453 1.137635 -1.15418554  0.9315304
## 11 351  0 1.641026 1.394652  0.64126675 -0.3929747
## 12 351  0 1.800570 1.624843  0.42175863 -1.1163775
## 13 351  0 1.384615 1.368082  0.83624504 -0.1256438
## 14 351  0 1.954416 1.304137  0.20137270 -0.9228997
## 15 351  0 2.122507 1.366677 -0.08769730 -0.9945214
## 
##  "2": 2 
##     X1 X2       X3       X4          X5         X6
## 1  351  0 1.279202 1.285788  0.98367363  0.3563117
## 2  351  0 1.746439 1.479800  0.47506674 -0.7836618
## 3  351  0 2.900285 1.449640 -0.36280508 -0.8291409
## 4  351  0 3.339031 1.174315 -0.85453943  0.4567202
## 5  351  0 2.233618 1.582803  0.07607808 -1.0949174
## 6  351  0 3.074074 1.477521 -0.45428558 -0.9230754
## 7  351  0 2.774929 1.472820 -0.06508488 -1.1504259
## 8  351  0 2.099715 1.455541  0.13309694 -1.0781871
## 9  351  0 4.225071 1.155384 -1.74473933  2.7434956
## 10 351  0 3.991453 1.137635 -1.15418554  0.9315304
## 11 351  0 1.641026 1.394652  0.64126675 -0.3929747
## 12 351  0 1.800570 1.624843  0.42175863 -1.1163775
## 13 351  0 1.384615 1.368082  0.83624504 -0.1256438
## 14 351  0 1.954416 1.304137  0.20137270 -0.9228997
## 15 351  0 2.122507 1.366677 -0.08769730 -0.9945214
## 16 351  0 2.176638 1.781691  0.23741956 -1.3554221
## 
##  "2": 2 
##     X1 X2       X3       X4          X5         X6
## 1  351  0 1.279202 1.285788  0.98367363  0.3563117
## 2  351  0 1.746439 1.479800  0.47506674 -0.7836618
## 3  351  0 2.900285 1.449640 -0.36280508 -0.8291409
## 4  351  0 3.339031 1.174315 -0.85453943  0.4567202
## 5  351  0 2.233618 1.582803  0.07607808 -1.0949174
## 6  351  0 3.074074 1.477521 -0.45428558 -0.9230754
## 7  351  0 2.774929 1.472820 -0.06508488 -1.1504259
## 8  351  0 2.099715 1.455541  0.13309694 -1.0781871
## 9  351  0 4.225071 1.155384 -1.74473933  2.7434956
## 10 351  0 3.991453 1.137635 -1.15418554  0.9315304
## 11 351  0 1.641026 1.394652  0.64126675 -0.3929747
## 12 351  0 1.800570 1.624843  0.42175863 -1.1163775
## 13 351  0 1.384615 1.368082  0.83624504 -0.1256438
## 14 351  0 1.954416 1.304137  0.20137270 -0.9228997
## 15 351  0 2.122507 1.366677 -0.08769730 -0.9945214
## 16 351  0 2.176638 1.781691  0.23741956 -1.3554221
## 17 351  0 2.407407 1.604227  0.08516347 -1.1419607
## 
##  "2": 2 
##     X1 X2       X3       X4          X5         X6
## 1  351  0 1.279202 1.285788  0.98367363  0.3563117
## 2  351  0 1.746439 1.479800  0.47506674 -0.7836618
## 3  351  0 2.900285 1.449640 -0.36280508 -0.8291409
## 4  351  0 3.339031 1.174315 -0.85453943  0.4567202
## 5  351  0 2.233618 1.582803  0.07607808 -1.0949174
## 6  351  0 3.074074 1.477521 -0.45428558 -0.9230754
## 7  351  0 2.774929 1.472820 -0.06508488 -1.1504259
## 8  351  0 2.099715 1.455541  0.13309694 -1.0781871
## 9  351  0 4.225071 1.155384 -1.74473933  2.7434956
## 10 351  0 3.991453 1.137635 -1.15418554  0.9315304
## 11 351  0 1.641026 1.394652  0.64126675 -0.3929747
## 12 351  0 1.800570 1.624843  0.42175863 -1.1163775
## 13 351  0 1.384615 1.368082  0.83624504 -0.1256438
## 14 351  0 1.954416 1.304137  0.20137270 -0.9228997
## 15 351  0 2.122507 1.366677 -0.08769730 -0.9945214
## 16 351  0 2.176638 1.781691  0.23741956 -1.3554221
## 17 351  0 2.407407 1.604227  0.08516347 -1.1419607
## 18 351  0 2.914530 1.326042 -0.55946781 -0.3262722
## 
##  "2": 2 
##     X1 X2       X3       X4          X5         X6
## 1  351  0 1.279202 1.285788  0.98367363  0.3563117
## 2  351  0 1.746439 1.479800  0.47506674 -0.7836618
## 3  351  0 2.900285 1.449640 -0.36280508 -0.8291409
## 4  351  0 3.339031 1.174315 -0.85453943  0.4567202
## 5  351  0 2.233618 1.582803  0.07607808 -1.0949174
## 6  351  0 3.074074 1.477521 -0.45428558 -0.9230754
## 7  351  0 2.774929 1.472820 -0.06508488 -1.1504259
## 8  351  0 2.099715 1.455541  0.13309694 -1.0781871
## 9  351  0 4.225071 1.155384 -1.74473933  2.7434956
## 10 351  0 3.991453 1.137635 -1.15418554  0.9315304
## 11 351  0 1.641026 1.394652  0.64126675 -0.3929747
## 12 351  0 1.800570 1.624843  0.42175863 -1.1163775
## 13 351  0 1.384615 1.368082  0.83624504 -0.1256438
## 14 351  0 1.954416 1.304137  0.20137270 -0.9228997
## 15 351  0 2.122507 1.366677 -0.08769730 -0.9945214
## 16 351  0 2.176638 1.781691  0.23741956 -1.3554221
## 17 351  0 2.407407 1.604227  0.08516347 -1.1419607
## 18 351  0 2.914530 1.326042 -0.55946781 -0.3262722
## 19 351  0 1.156695 1.424662  1.28960129  0.8721203
## 
##  "2": 2 
##     X1 X2        X3       X4          X5         X6
## 1  351  0 1.2792023 1.285788  0.98367363  0.3563117
## 2  351  0 1.7464387 1.479800  0.47506674 -0.7836618
## 3  351  0 2.9002849 1.449640 -0.36280508 -0.8291409
## 4  351  0 3.3390313 1.174315 -0.85453943  0.4567202
## 5  351  0 2.2336182 1.582803  0.07607808 -1.0949174
## 6  351  0 3.0740741 1.477521 -0.45428558 -0.9230754
## 7  351  0 2.7749288 1.472820 -0.06508488 -1.1504259
## 8  351  0 2.0997151 1.455541  0.13309694 -1.0781871
## 9  351  0 4.2250712 1.155384 -1.74473933  2.7434956
## 10 351  0 3.9914530 1.137635 -1.15418554  0.9315304
## 11 351  0 1.6410256 1.394652  0.64126675 -0.3929747
## 12 351  0 1.8005698 1.624843  0.42175863 -1.1163775
## 13 351  0 1.3846154 1.368082  0.83624504 -0.1256438
## 14 351  0 1.9544160 1.304137  0.20137270 -0.9228997
## 15 351  0 2.1225071 1.366677 -0.08769730 -0.9945214
## 16 351  0 2.1766382 1.781691  0.23741956 -1.3554221
## 17 351  0 2.4074074 1.604227  0.08516347 -1.1419607
## 18 351  0 2.9145299 1.326042 -0.55946781 -0.3262722
## 19 351  0 1.1566952 1.424662  1.28960129  0.8721203
## 20 351  0 0.8945869 1.351295  1.49939695  1.2239402
##       n na  mean    sd  skew kurtosis
## m01 351  0 1.279 1.286  0.98     0.36
## m02 351  0 1.746 1.480  0.48    -0.78
## m03 351  0 2.900 1.450 -0.36    -0.83
## m04 351  0 3.339 1.174 -0.85     0.46
## m05 351  0 2.234 1.583  0.08    -1.09
## m06 351  0 3.074 1.478 -0.45    -0.92
## m07 351  0 2.775 1.473 -0.07    -1.15
## m08 351  0 2.100 1.456  0.13    -1.08
## m09 351  0 4.225 1.155 -1.74     2.74
## m10 351  0 3.991 1.138 -1.15     0.93
## m11 351  0 1.641 1.395  0.64    -0.39
## m12 351  0 1.801 1.625  0.42    -1.12
## m13 351  0 1.385 1.368  0.84    -0.13
## m14 351  0 1.954 1.304  0.20    -0.92
## m15 351  0 2.123 1.367 -0.09    -0.99
## m16 351  0 2.177 1.782  0.24    -1.36
## m17 351  0 2.407 1.604  0.09    -1.14
## m18 351  0 2.915 1.326 -0.56    -0.33
## m19 351  0 1.157 1.425  1.29     0.87
## m20 351  0 0.895 1.351  1.50     1.22

Frequency Tables

Aggregating a statistical computation of a continuous variable over groups with pivot(), such as computing the mean for each combination of Dept and Gender, by default includes the tabulation for each group (cell). A tabulation can be requested with no analysis of a variable, instead only a counting of the available levels of the specified categorical variables.

The table value of the compute parameter specifies to compute the frequency table for a categorical aggregated variable across all combinations of the by variables. Specify one categorical variable with the remaining categorical variables specified with the by parameter. Missing values for each combination of the levels of the grouping variables are displayed.

Begin with a one-way frequency table computed over the entire data set.

pivot(d, table, m06)
##   m06   n Prop
## 1   0  18 0.05
## 2   1  47 0.13
## 3   2  63 0.18
## 4   3  44 0.13
## 5   4 121 0.34
## 6   5  58 0.17

In this example, compute a two-way cross-tabulation table with the levels of variable m06 as columns and the levels of the by categorical variable m07 as rows.

pivot(d, table, m06, m07)
##   m07 0  1  2  3  4  5  n _na
## 1   0 4  3  2  3  3  2 17   0
## 2   1 7 24  7  6 18  2 64   0
## 3   2 4 14 30 13 24  2 87   0
## 4   3 2  1 10 16 12  2 43   0
## 5   4 0  3 13  5 56 16 93   0
## 6   5 1  2  1  1  8 34 47   0

To output the data in long form, one tabulation per row, set the table_long parameter to TRUE.

If interested in the inferential analysis of the cross-tabulation table, access the lessR function Prop_test() to obtain both the descriptive and inferential results, though limited to a one- or two-way table.

The default data table is d, but included explicitly in the following example to illustrate the data parameter.

Prop_test(m06, by=m07, data=d)
## variable: m06 
## by: m07 
## 
## <<< Pearson's Chi-squared test 
## 
## --- Description
## 
##      m06
## m07     0   1   2   3   4   5 Sum
##   0     4   3   2   3   3   2  17
##   1     7  24   7   6  18   2  64
##   2     4  14  30  13  24   2  87
##   3     2   1  10  16  12   2  43
##   4     0   3  13   5  56  16  93
##   5     1   2   1   1   8  34  47
##   Sum  18  47  63  44 121  58 351
## 
##  Cramer's V: 0.380 
## 
##  Row Col Observed Expected Residual Stnd Res
##    1   1        4    0.872    3.128    3.526
##    1   2        3    2.276    0.724    0.528
##    1   3        2    3.051   -1.051   -0.681
##    1   4        3    2.131    0.869    0.652
##    1   5        3    5.860   -2.860   -1.496
##    1   6        2    2.809   -0.809   -0.542
##    2   1        7    3.282    3.718    2.330
##    2   2       24    8.570   15.430    6.263
##    2   3        7   11.487   -4.487   -1.616
##    2   4        6    8.023   -2.023   -0.844
##    2   5       18   22.063   -4.063   -1.182
##    2   6        2   10.575   -8.575   -3.192
##    3   1        4    4.462   -0.462   -0.259
##    3   2       14   11.650    2.350    0.853
##    3   3       30   15.615   14.385    4.634
##    3   4       13   10.906    2.094    0.782
##    3   5       24   29.991   -5.991   -1.558
##    3   6        2   14.376  -12.376   -4.119
##    4   1        2    2.205   -0.205   -0.151
##    4   2        1    5.758   -4.758   -2.274
##    4   3       10    7.718    2.282    0.968
##    4   4       16    5.390   10.610    5.216
##    4   5       12   14.823   -2.823   -0.967
##    4   6        2    7.105   -5.105   -2.238
##    5   1        0    4.769   -4.769   -2.615
##    5   2        3   12.453   -9.453   -3.357
##    5   3       13   16.692   -3.692   -1.164
##    5   4        5   11.658   -6.658   -2.432
##    5   5       56   32.060   23.940    6.092
##    5   6       16   15.368    0.632    0.206
##    6   1        1    2.410   -1.410   -1.002
##    6   2        2    6.293   -4.293   -1.976
##    6   3        1    8.436   -7.436   -3.037
##    6   4        1    5.892   -4.892   -2.315
##    6   5        8   16.202   -8.202   -2.705
##    6   6       34    7.766   26.234   11.071
## 
## --- Inference
## 
## Chi-square statistic: 253.103 
## Degrees of freedom: 25 
## Hypothesis test of equal population proportions: p-value = 0.000

Can also aggregate other statistics simultaneously in addition to the frequency table, though, of course, only meaningful if the aggregated variable is numerical. Here, create a 3-way cross-tabulation table with responses to variable m06 in the column and responses to by variables m07 and m10 in the rows, plus the mean and standard deviation of each combination of m07 and m10 across levels of m06.

pivot(d, c(mean,sd,table), m06, c(m07, m10))
##    m07 m10  n na m06_mean m06_sd 2 3  4  5  n _na
## 1    0   0  1  0    0.000     NA 0 0  0  0  1   0
## 2    1   0  1  0    1.000     NA 0 0  0  0  1   0
## 3    2   0 NA  0       NA     NA 0 0  0  0  0   0
## 4    3   0  1  0    2.000     NA 1 0  0  0  1   0
## 5    4   0  1  0    2.000     NA 1 0  0  0  1   0
## 6    5   0 NA  0       NA     NA 0 0  0  0  0   0
## 7    0   1 NA  0       NA     NA 0 0  0  0  0   0
## 8    1   1  4  0    0.750  0.500 0 0  0  0  4   0
## 9    2   1  2  0    1.500  0.707 1 0  0  0  2   0
## 10   3   1  1  0    2.000     NA 1 0  0  0  1   0
## 11   4   1 NA  0       NA     NA 0 0  0  0  0   0
## 12   5   1 NA  0       NA     NA 0 0  0  0  0   0
## 13   0   2  2  0    2.000  1.414 0 1  0  0  2   0
## 14   1   2  9  0    1.222  1.202 1 0  1  0  9   0
## 15   2   2 15  0    2.000  0.845 8 2  1  0 15   0
## 16   3   2  3  0    3.000  0.000 0 3  0  0  3   0
## 17   4   2  3  0    3.333  1.155 1 0  2  0  3   0
## 18   5   2 NA  0       NA     NA 0 0  0  0  0   0
## 19   0   3  5  0    1.200  1.304 1 1  0  0  5   0
## 20   1   3 16  0    2.250  1.390 4 3  4  0 16   0
## 21   2   3 13  0    2.769  0.832 6 4  3  0 13   0
## 22   3   3  7  0    2.000  1.528 2 2  1  0  7   0
## 23   4   3  9  0    3.333  1.323 2 0  5  1  9   0
## 24   5   3 NA  0       NA     NA 0 0  0  0  0   0
## 25   0   4  7  0    2.714  1.799 1 1  2  1  7   0
## 26   1   4 19  0    2.895  1.449 1 2  9  1 19   0
## 27   2   4 29  0    2.690  1.417 8 4  9  2 29   0
## 28   3   4 18  0    3.278  1.074 3 6  6  2 18   0
## 29   4   4 32  0    3.781  1.008 6 2 17  7 32   0
## 30   5   4  5  0    4.400  0.548 0 0  3  2  5   0
## 31   0   5  2  0    4.500  0.707 0 0  1  1  2   0
## 32   1   5 15  0    2.133  1.685 1 1  4  1 15   0
## 33   2   5 28  0    2.571  1.372 7 3 11  0 28   0
## 34   3   5 13  0    3.154  0.801 3 5  5  0 13   0
## 35   4   5 48  0    3.854  0.922 3 3 32  8 48   0
## 36   5   5 42  0    4.452  1.234 1 1  5 32 42   0

Can also express the frequencies as proportions. To convert the frequencies into proportions, invoke the table_prop parameter. The value of "all" computes cell frequencies across the entire table. The values of "row" and "col" compute the proportions with either row sums or column sums.

In this example of a two-way cross-tabulation table, convert the table counts to row proportions, that is, the proportion of each level of m06 for each combination of levels for m07. The sum of the proportions in each row is 1.0.

pivot(d, table, m06, m07, table_prop="row")
##   m07 0  1    2    3    4    5     n _na
## 1   0 4  3 0.07 0.11 0.11 0.07 0.630   0
## 2   1 7 24 0.07 0.06 0.19 0.02 0.660   0
## 3   2 4 14 0.19 0.08 0.15 0.01 0.558   0
## 4   3 2  1 0.12 0.19 0.14 0.02 0.518   0
## 5   4 0  3 0.07 0.03 0.31 0.09 0.508   0
## 6   5 1  2 0.01 0.01 0.09 0.37 0.516   0

Return to the Employee data set for the remaining examples.

d <- Read("Employee", quiet=TRUE)

Quantiles

One way to understand the characteristics of a distribution of data values of a continuous variable is to sort the values and then split into equal-sized groups. The simplest example is the median, which splits a sorted distribution into two groups of equal size, the bottom lowest values and the top highest values. Quartiles divide the sorted distribution into four groups. The first quartile is the smallest 25% of the data values, etc.

Quantiles: Numeric values, not necessarily data values, that divide a distribution of sorted data values into n groups of equal size.

By default, calling the quantile function computes quartiles. Here calculate the quartiles for Years aggregated across levels of Dept and Gender.

pivot(d, quantile, Years, c(Dept, Gender))
##    Dept Gender n na p0   p25  p50   p75 p100
## 1  ACCT      M 2  0  5  6.00  7.0  8.00    9
## 2  ADMN      M 2  0  7 11.25 15.5 19.75   24
## 3  FINC      M 3  0 10 10.00 10.0 12.00   14
## 4  MKTG      M 1  0 18 18.00 18.0 18.00   18
## 5  SALE      M 9  1  5  9.00 13.0 14.00   21
## 6  <NA>      M 0  0 NA    NA   NA    NA   NA
## 7  ACCT      W 3  0  2  2.50  3.0  6.00    9
## 8  ADMN      W 4  0  2  3.50  5.0  9.00   18
## 9  FINC      W 1  0  7  7.00  7.0  7.00    7
## 10 MKTG      W 5  0  1  4.00  8.0 10.00   18
## 11 SALE      W 5  0  2  3.00  8.0 10.00   10
## 12 <NA>      W 1  0  5  5.00  5.0  5.00    5

To compute quantiles other than quartiles, invoke the q_num parameter, the number of quantile intervals. The default value is 4 for quartiles. In the following example, compute the quintiles for Years and Salary, plus the mean and standard deviation. No specification of by, so these descriptive statistics are computed over the entire data set for both specified variables.

pivot(d, c(mean,sd,quantile), c(Years,Salary), q_num=5, digits_d=2)
## 
##  "2": 2 
##   X1 X2       X3       X4
## 1 36  1 9.388889 5.723524
## 
##  "2": 2 
##   X1 X2           X3           X4
## 1 36  1     9.388889     5.723524
## 2 37  0 73795.556757 21799.533464
##         n na     mean       sd       p0      p20      p40      p60      p80     p100
## Years  36  1     9.39     5.72     1.00     4.00     8.00    10.00    14.00     24.0
## Salary 37  0 73795.56 21799.53 46124.97 55737.86 63701.93 72430.04 92415.42 134419.2

Other Features

Drill-Down

One data analysis strategy examines the values of a variable, such as Sales for a business or Mortality for an epidemiology study, at progressively finer levels of detail. Examine by Country or State or City or whatever level of granularity is appropriate.

Data drill down: Examine the values of a variable when holding the values of one or more categorical variables constant.

pivot() indicates drilling down deeper into the data with a display of all categorical variables with unique values, which precedes the primary output. Initiate the drill-down by a previous subset of the data frame, or indicate the subset with pivot() directly. As with other lessR analysis functions, the rows parameter specifies a logical condition for which to subset rows of the data frame for analysis.

In this example, compute the mean of Salary for each level of Dept for just those rows of data with the value of Gender equal to “W”.

pivot(d, mean, Salary, Dept, rows=(Gender=="W"))
## Gender: W
##   Dept Salary_n na     mean
## 1 ACCT        3  0 63237.16
## 2 ADMN        4  0 81434.00
## 3 FINC        1  0 57139.90
## 4 MKTG        5  0 64496.02
## 5 SALE        5  0 64188.25
## 6 <NA>        1  0 53772.58

The parentheses for the rows parameter are not necessary, but do enhance readability.

Can also drill down by subsetting the data frame with a logical condition directly in the data parameter in the call to pivot(). Here drill down with base R Extract[ ] in conjunction with the lessR function .() to simplify the syntax (explained in the vignette Subset a Data Frame). The Extract[ ] function specifies the rows of the data frame to extract before the comma, and the columns to extract after the comma. Here select only those rows of data with Gender declared as Female. There is no information after the comma, so no columns are specified, which means to retain all columns, the variables in the data frame.

pivot(d[.(Gender=="W"),], mean, Salary, Dept)
## Gender: W
##   Dept Salary_n na     mean
## 1 ACCT        3  0 63237.16
## 2 ADMN        4  0 81434.00
## 3 FINC        1  0 57139.90
## 4 MKTG        5  0 64496.02
## 5 SALE        5  0 64188.25
## 6 <NA>        1  0 53772.58

Sort Output

Specify the sort as part of the call to pivot() with the parameter sort. This internal sort works for a single value variable, by default the last column in the output data frame. Set to "-" for a descending sort. Set to "+" for an ascending sort.

pivot(d, mean, Salary, c(Dept, Gender), sort="-")
##    Dept Gender  n na Salary_mean
## 4  MKTG      M  1  0    99062.66
## 5  SALE      M 10  0    86150.97
## 8  ADMN      W  4  0    81434.00
## 2  ADMN      M  2  0    80963.35
## 3  FINC      M  3  0    72967.60
## 10 MKTG      W  5  0    64496.02
## 11 SALE      W  5  0    64188.25
## 7  ACCT      W  3  0    63237.16
## 1  ACCT      M  2  0    59626.19
## 9  FINC      W  1  0    57139.90
## 12 <NA>      W  1  0    53772.58
## 6  <NA>      M  0  0          NA

Specify the sort_var parameter to specify the name or the column number of the variable to sort.

pivot(d, c(mean, median), Salary, c(Gender,Dept), out_names=c("MeanSalary", "MedianSalary"),
      sort="-", sort_var="MeanSalary")
##    Gender Dept  n na MeanSalary MedianSalary
## 7       M MKTG  1  0   99062.66     99062.66
## 9       M SALE 10  0   86150.97     82442.74
## 4       W ADMN  4  0   81434.00     71058.60
## 3       M ADMN  2  0   80963.35     80963.35
## 5       M FINC  3  0   72967.60     66312.89
## 8       W MKTG  5  0   64496.02     61356.69
## 10      W SALE  5  0   64188.25     56508.32
## 2       W ACCT  3  0   63237.16     71084.02
## 1       M ACCT  2  0   59626.19     59626.19
## 6       W FINC  1  0   57139.90     57139.90
## 12      W <NA>  1  0   53772.58     53772.58
## 11      M <NA>  0  0         NA           NA

Because the output of pivot() with no by_cols variables is a standard R data frame, the external call to the lessR function sort_by() is available for custom sorting by one or more variables. Sort in the specified direction with the direction parameter.

a <- pivot(d, mean, Salary, c(Dept, Gender))
sort_by(a, by=Salary_mean, direction="-")
##    Dept Gender  n na Salary_mean
## 4  MKTG      M  1  0    99062.66
## 5  SALE      M 10  0    86150.97
## 8  ADMN      W  4  0    81434.00
## 2  ADMN      M  2  0    80963.35
## 3  FINC      M  3  0    72967.60
## 10 MKTG      W  5  0    64496.02
## 11 SALE      W  5  0    64188.25
## 7  ACCT      W  3  0    63237.16
## 1  ACCT      M  2  0    59626.19
## 9  FINC      W  1  0    57139.90
## 12 <NA>      W  1  0    53772.58
## 6  <NA>      M  0  0          NA

Specify multiple variables to sort with a vector of variable names, and a corresponding vector of "+" and "-" signs of the same length for the directions parameter.

Pipe Operator

The following illustrates as of R 4.1.0 the base R pipe operator |> with pivot(). The pipe operator by default inserts the object on the left-hand side of an expression into the first parameter value for the function on the right-hand side.

In this example, input the d data frame into the first parameter of pivot(), the data parameter. Then direct the output to the data frame a with the standard R assignment statement, though written pointing to the right hand side of the expression.

To avoid problems installing this version of lessR from source with a previous version of R, the code is commented out with a # sign in the first column.

#d |> pivot(mean, Salary, c(Dept, Gender)) -> a
#a

Output as a 2-D Table

Specify up to two by_cols categorical variables to create a two-dimensional table with the specified columns. Specifying one or two categorical variables as by_cols variables moves them from their default position in the rows to the columns, which changes the output structure from a long-form data frame to a table with categorical variables in the rows and columns.

In this example, specify Gender as the by_cols variable.

pivot(d, mean, Salary, by=Dept, by_cols=Gender)
Table: mean of Salary 

 Gender  M          W               
 Dept                        
-------  ---------  ---------
   ACCT   59626.19   63237.16
   ADMN   80963.35   81434.00
   FINC   72967.60   57139.90
   MKTG   99062.66   64496.02
   SALE   86150.97   64188.25
     NA         NA   53772.58

Here two by_cols variables, specified as a vector. There is much missing data for this three-way classification as there is not much data in each group, with many groups having no data.

pivot(d, mean, Salary, Dept, c(Gender, Plan))
Table: mean of Salary 

 Gender  M                                 W                                     
 Plan    1          2           3          1          2          3             
 Dept                                                                     
-------  ---------  ----------  ---------  ---------  ---------  ---------
   ACCT   69547.60          NA   49704.79         NA   63237.16         NA
   ADMN   53788.26   108138.43         NA         NA   67724.21   122563.4
   FINC   61937.62          NA   95027.55         NA   57139.90         NA
   MKTG         NA          NA   99062.66   56772.95   66426.79         NA
   SALE   89393.40    82442.74   80131.91   60941.54   66352.73         NA
     NA         NA          NA         NA   53772.58         NA         NA

Missing Data

There are three different types of missing data in an aggregation: some missing values for one or more aggregated variables for which the statistic is computed, all missing values for the variable so that the group (cell) defined by one or more by variables has no data values, and the data value for the by variable itself is missing. Accordingly, there are three different missing data parameters with pivot().

Some Missing Data at a Level of a by Variable

By default, the data frame output of pivot() lists the number of occurrences of missing data for each group of the variable over which the statistic is computed. The na_remove parameter specifies if NA (missing) values of the aggregated variable should be removed before the computation proceeds. The default value na_remove is TRUE, so the missing values are removed, their number of occurrences reported, and then the computed statistic displayed.

In this example, the variable Years has one missing value, which occurs in the Sales department. That value is dropped from the computation of the mean of Years, which is based on the 14 non-missing values.

pivot(d, mean, Years, Dept)
##   Dept Years_n na   mean
## 1 ACCT       5  0  5.600
## 2 ADMN       6  0 10.167
## 3 FINC       4  0 10.250
## 4 MKTG       6  0  9.833
## 5 SALE      14  1 10.286
## 6 <NA>       1  0  5.000

Set na_remove to FALSE to not remove any missing data in a cell with values to be aggregated. According to the way in which R functions process the data with missing values entered into the function, one missing value implies that the computed statistic has a missing value.

pivot(d, mean, Years, Dept, na_remove=FALSE)
##   Dept Years_n na   mean
## 1 ACCT       5  0  5.600
## 2 ADMN       6  0 10.167
## 3 FINC       4  0 10.250
## 4 MKTG       6  0  9.833
## 5 SALE      14  1     NA
## 6 <NA>       1  0  5.000

All Missing Data at a Level of a by Variable

Another possibility accounts for missing values of the categorical by variables for which all values of the variable for which to compute the statistic for that cell are missing. In that situation, there is no data value for which to compute the statistic.

For this example, first create a cell with no values in the data aggregation. Use base R Extract[] with lessR .() to drop the one male in the Sales department, leaving no data values for that group. Save the result into the dd data frame.

dd <- d[.(!(Gender=="M" & Dept=="SALE")), ]

Also, to focus only on this type of missing data, remove the row of data that has a missing value for Dept, which is the third row.

head(dd)
##                  Years Gender Dept   Salary JobSat Plan Pre Post
## Ritchie, Darnell     7      M ADMN 53788.26    med    1  82   92
## Downs, Deborah       7      W FINC 57139.90   high    2  90   86
## Jones, Alissa        5      W <NA> 53772.58   <NA>    1  65   62
## Afshari, Anbar       6      W ADMN 69441.93   high    2 100  100
## Knox, Michael       18      M MKTG 99062.66    med    3  81   84
## Kimball, Claire      8      W MKTG 61356.69   high    2  93   92
dd <- dd[-3,]

Here, explicitly set na_by_show to TRUE, the default value. The group for male sales employees is shown with the values of the computed variables n_ and na_ set to 0 and the values of the computed statistics necessarily missing for this row of the output data frame.

pivot(dd, c(mean,median), Salary, c(Dept, Gender), na_by_show=TRUE)
##    Dept Gender n na Salary_mean Salary_mdn
## 1  ACCT      M 2  0    59626.19   59626.19
## 2  ADMN      M 2  0    80963.35   80963.35
## 3  FINC      M 3  0    72967.60   66312.89
## 4  MKTG      M 1  0    99062.66   99062.66
## 5  SALE      M 0  0          NA         NA
## 6  ACCT      W 3  0    63237.16   71084.02
## 7  ADMN      W 4  0    81434.00   71058.60
## 8  FINC      W 1  0    57139.90   57139.90
## 9  MKTG      W 5  0    64496.02   61356.69
## 10 SALE      W 5  0    64188.25   56508.32

Drop the groups from the output with missing data for a by variable. To do so, set na_by_show to FALSE. Now the group for the non-existent male sales employee does not display.

pivot(dd, c(mean,median), Salary, c(Dept, Gender), na_by_show=FALSE)
##    Dept Gender n na Salary_mean Salary_mdn
## 1  ACCT      M 2  0    59626.19   59626.19
## 2  ADMN      M 2  0    80963.35   80963.35
## 3  FINC      M 3  0    72967.60   66312.89
## 4  MKTG      M 1  0    99062.66   99062.66
## 6  ACCT      W 3  0    63237.16   71084.02
## 7  ADMN      W 4  0    81434.00   71058.60
## 8  FINC      W 1  0    57139.90   57139.90
## 9  MKTG      W 5  0    64496.02   61356.69
## 10 SALE      W 5  0    64188.25   56508.32

Missing Data for a Level of the by Variable Itself

The parameter na_group_show specifies if a value of the grouping variable itself should be displayed as level <NA>. By default, the <NA> levels are displayed but the na_group_show is explicitly included in the following.

pivot(d, c(mean,median), Salary, c(Dept, Gender), na_group_show=TRUE)
##    Dept Gender  n na Salary_mean Salary_mdn
## 1  ACCT      M  2  0    59626.19   59626.19
## 2  ADMN      M  2  0    80963.35   80963.35
## 3  FINC      M  3  0    72967.60   66312.89
## 4  MKTG      M  1  0    99062.66   99062.66
## 5  SALE      M 10  0    86150.97   82442.74
## 6  <NA>      M  0  0          NA         NA
## 7  ACCT      W  3  0    63237.16   71084.02
## 8  ADMN      W  4  0    81434.00   71058.60
## 9  FINC      W  1  0    57139.90   57139.90
## 10 MKTG      W  5  0    64496.02   61356.69
## 11 SALE      W  5  0    64188.25   56508.32
## 12 <NA>      W  1  0    53772.58   53772.58

Set na_group_show to FALSE to not display as levels when a value of the by variable is missing.

pivot(d, c(mean,median), Salary, c(Dept, Gender), na_group_show=FALSE)
##    Dept Gender  n na Salary_mean Salary_mdn
## 1  ACCT      M  2  0    59626.19   59626.19
## 2  ADMN      M  2  0    80963.35   80963.35
## 3  FINC      M  3  0    72967.60   66312.89
## 4  MKTG      M  1  0    99062.66   99062.66
## 5  SALE      M 10  0    86150.97   82442.74
## 6  ACCT      W  3  0    63237.16   71084.02
## 7  ADMN      W  4  0    81434.00   71058.60
## 8  FINC      W  1  0    57139.90   57139.90
## 9  MKTG      W  5  0    64496.02   61356.69
## 10 SALE      W  5  0    64188.25   56508.32

Build Your Own Function

Any function that processes a single column of data and returns a single value, usually a statistic, can be accessed with pivot(). In this example, define a function named mnmd() that computes the difference between the mean and median of a distribution of data values, here represented by x. For technical reasons, need to include the NA remove parameter, na.rm, in the function definition if there is any missing data. If missing data values are to be dropped in internal function calls, then set the base R parameter na.rm to TRUE for each component function as well.

mnmd <- function(x, na.rm=TRUE)  mean(x, na.rm=na.rm) - median(x, na.rm=na.rm)

Invoke pivot() to compute the mean, the median, and their difference for each group in the aggregation of the variable Years.

pivot(d, c(mean, median, mnmd), Years, by=Dept)
##   Dept Years_n na   mean Years_mdn Years_mnmd
## 1 ACCT       5  0  5.600       5.0      0.600
## 2 ADMN       6  0 10.167       6.5      3.667
## 3 FINC       4  0 10.250      10.0      0.250
## 4 MKTG       6  0  9.833       9.0      0.833
## 5 SALE      14  1 10.286      10.0      0.286
## 6 <NA>       1  0  5.000       5.0      0.000

lessR pivot() vs Base R aggregate()

The lessR pivot() function relies upon the base R function aggregate() for aggregation. By default, except for the table computation, pivot() generates a long-form data frame pivot table (Excel terminology), which can then be directly input into analysis and visualization functions as a standard data frame. The levels across all the by grouping variables are listed in the rows. If there are specified column grouping variables according to by_cols, pivot() relies upon base R reshape() to form a 2-d table for direct viewing instead of a data table to input into further analysis functions.

pivot() provides additional features than aggregate() provides.

  1. For each value over which to aggregate, the sample size and number of missing values for each group is provided.
  2. Multiple statistical functions can be selected for which to compute the aggregated value for each group.
  3. Extends beyond aggregation to compute statistics over the entire data set instead of groups of data.
  4. Missing data analysis by cell or by the value aggregated.
  5. Aggregation not necessary, so can compute the specified statistic(s) for each variable across the entire data set.
  6. The aggregated computations can be displayed as a 2-d table, not just a long-form data frame.
  7. by variables of type Date retain the same variable type in the summary table instead of each converted to a factor (set factors=FALSE to not convert integer and character variables to factors).
  8. The list of parameters lists the data parameter first, which facilitates the use of the pipe operator, such as from base R as of Version 4.1.0 or the magrittr package.
  9. Any non-numeric variables with unique values in the submitted data are listed with their corresponding data value, which identifies when drilling down into the data to study relevant rows.

Although the pivot() function considerably extends the functionality of base R aggregate(), pivot() does rely upon this base R function for most of its computations.