Description of groupdata2

Ludvig Renbo Olsen

2019-08-05

Abstract

groupdata2 is a set of methods for easy grouping, windowing, folding, partitioning, splitting and balancing of data.
Create balanced folds for cross-validation or divide a time series into windows.
Balance group sizes with up- and downsampling.
This vignette contains descriptions of functions and methods, along with simple examples of usage. For a gentler introduction to groupdata2, please see Introduction to groupdata2  
 
Contact author at    


Installing groupdata2

You can either install the CRAN version or the GitHub development version.

CRAN version

GitHub development version

Attach packages


# Attaching groupdata2
library(groupdata2)

# Attaching other packages used in this vignette
library(dplyr)
library(tidyr)
library(ggplot2)
library(knitr)

# We will also be using plyr a few times, but we don't attach this 
# because of possible conflicts with dplyr. Instead we use its functions
# like so: plyr::count()

General information

groupdata2 is a set of functions and methods for easy grouping, windowing, folding, partitioning, splitting and balancing of data.

There are 6 main functions:

group_factor()

Returns a factor with group numbers, e.g. 111222333.
This can be used to subset, aggregate, group_by, etc.

group()

Returns the given data as a data frame with an added grouping factor made with group_factor(). The data frame is grouped by the grouping factor for easy use with %>% pipelines.

splt()

Splits the given data into the specified groups made with group_factor() and returns them in a list.

fold()

Creates (optionally) balanced folds for use in cross-validation. Balance folds on one categorical variable and/or one numerical variable. Ensure that all datapoints sharing an ID is in the same fold. Can create multiple unique fold columns at once, e.g. for repeated cross-validation.

partition()

Creates (optionally) balanced partitions (e.g. training/test sets). Balance partitions on one categorical variable and/or one numerical variable. Make sure that all datapoints sharing an ID is in the same partition.

balance()

Uses up- or downsampling to fix the size of all groups to the min, max, mean, or median group size or to a specific number of rows. Balancing can also happen on the ID level, e.g. to ensure the same number of IDs in each category.

Groups, windows or folds?

When working with time series we would often refer to the kind of groups made by group_factor(), group() and splt() as windows. In this vignette, these will be referred to as groups.

fold() creates balanced groups for cross-validation by using group(). These are referred to as folds.

partition() creates balanced groups of (potentially) different sizes, by using group(). These are referred to as partitions.

Introduction vignettes

Cross-validation with groupdata2
In this vignette, we go through the basics of cross-validation, such as creating balanced train/test sets with partition() and balanced folds with fold(). We also write up a simple cross-validation function and compare multiple linear regression models.

Time series with groupdata2
In this vignette, we divide up a time series into groups (windows) and subgroups using group() with the ‘greedy’ and ‘staircase’ methods. We do some basic descriptive stats of each group and use them to reduce the data size.

Automatic groups with groupdata2
In this vignette, we will use the ‘l_starts’ method with group() to allow transferring of information from one dataset to another. We will use the automatic grouping function that finds group starts all by itself.

Use of kable()

In the examples, we will be using knitr::kable() to visualize some of the data such as data frames. You do not need to use kable() when using the functions in groupdata2.

Grouping Methods

There are currently 9 methods for grouping the data.

It is possible to create groups based on number of groups (default), group size, list of group sizes, list of group start positions, step size or prime number to start at. These can be passed as whole number(s) or percentage(s), while method ‘l_starts’ can also use ‘auto’.

Here, we will take a look at the different methods.

Method: ‘greedy’

‘greedy’ uses group size for dividing up the data.
Greedy means that each group grabs as many elements as possible (up to the specified size), meaning that there might be less elements available to the last group, but that all other groups than the last are guaranteed to have the size specified.

 

Example

We have a vector with 57 values. We want to have group sizes of 10.

The greedy splitter will return groups with this many values in them:
10, 10, 10, 10, 10, 7

 

By setting force_equal to TRUE, we discard the last group if it contains fewer values than the other groups.

 

Example

We have a vector with 57 values. We want to have group sizes of 10.

The greedy splitter with force_equal set to TRUE will return groups with this many values in them:
10, 10, 10, 10, 10

meaning that 7 values have been discarded.

 

Method: ‘n_dist’ (Default)

‘n_dist’ uses a specified number of groups to divide up the data.
First it creates equal groups as large as possible. Then, if there are any excess data points, it distributes them across the groups.

 

Example

We have a vector with 57 values. We want to get back 5 groups.

‘n_dist’ with default settings would return groups with this many values in them:

11, 11, 12, 11, 12

 

By setting force_equal to TRUE, ‘n_dist’ will create the largest possible, equally sized groups by discarding excess data elements.

 

Example

‘n_dist’ with force_equal set to TRUE would return groups with this many values in them:

11, 11, 11, 11, 11

meaning that 2 values have been discarded.

 

Method: ‘n_fill’

‘n_fill’ uses a specified number of groups to divide up the data.
First it creates equal groups as large as possible. Then, if there are any excess data points, it places them in the first groups.
By setting descending to TRUE, it would be the last groups though.

 

Example

We have a vector with 57 values. We want to get back 5 groups.

‘n_fill’ with default settings would return groups with this many values in them:

12, 12, 11, 11, 11

 

By setting force_equal to TRUE, ‘n_fill’ will create the largest possible, equally sized groups by discarding excess data elements.

 

Example

‘n_fill’ with force_equal set to TRUE would return groups with this many values in them:

11, 11, 11, 11, 11

meaning that 2 values have been discarded.

 

Method: ‘n_last’

‘n_last’ uses a specified number of groups to divide up the data.

With default settings, it tries to make the groups as equally sized as possible, but notice that the last group might contain fewer or more elements, if the length of the data is not divisible with the number of groups. All, but the last, groups are guaranteed to contain the same number of elements.

 

Example

We have a vector with 57 values. We want to get back 5 groups.

‘n_last’ with default settings would return groups with this many values in them:

11, 11, 11, 11, 13

 

By setting force_equal to TRUE, ‘n_last’ will create the largest possible, equally sized groups by discarding excess data elements.

 

Example

‘n_last’ with force_equal set to TRUE would return groups with this many values in them:

11, 11, 11, 11, 11

meaning that 2 values have been discarded.

 

Notice that ‘n_last’ will always return the given number of groups. It will never return a group with zero elements. For some situations that means that the last group will contain a lot of elements. Asked to divide a vector with 57 elements into 20 groups, the first 19 groups will contain 2 elements, while the last group will itself contain 19 elements. Had we instead asked it to divide the vector into 19 groups, we would have had 3 elements in all groups.

 

Method: ‘n_rand’

‘n_fill’ uses a specified number of groups to divide up the data.
First it creates equal groups as large as possible. Then, if there are any excess data points, it places them randomly in the groups.
N.B.: It only places one extra element per group.

 

Example

We have a vector with 57 values. We want to get back 5 groups.

‘n_rand’ with default settings could return groups with this many values in them:

12, 11, 11, 11, 12

 

By setting force_equal to TRUE, ‘n_rand’ will create the largest possible, equally sized groups by discarding excess data elements.

 

Example

‘n_rand’ with force_equal set to TRUE would return groups with this many values in them:

11, 11, 11, 11, 11

meaning that 2 values have been discarded.

 

Method: ‘l_sizes’

‘l_sizes’ divides up the data by a list of group sizes.
Excess data points are placed in extra group at the end.

n is a list/vector of group sizes

 

Example

We have a vector with 57 values. We want to get back 3 groups containing 20%, 30% and 50% of the data points.

‘l_sizes’ with n = c(0.2, 0.3) would return groups with this many values in them:

11, 17, 29

 

By setting force_equal to TRUE, ‘l_sizes’ discard any excess elements.

 

Example

‘l_sizes’ with n = c(0.2, 0.3) and force_equal set to TRUE would return groups with this many values in them:

11, 17

meaning that 29 values have been discarded.

 

Method: ‘l_starts’

‘l_starts’ starts new groups at specified values of vector.

n is a list of starting positions. Skip values by c(value, skip_to_number) where skip_to_number is the nth appearance of the value in the vector. Groups automatically start from first data point.

If passing n = ‘auto’ the starting positions are automatically found with find_starts().

If data is a data frame, starts_col must be set to indicate the column to match starts.
Set starts_col to ‘index’ or ‘.index’ for matching with row names. ‘index’ first looks for column named ‘index’ in data, while ‘.index’ completely ignores potential column in data named ‘.index’.

 

Example

We have a vector with 57 values ranging from (1:57). We want to get back groups starting at specific values in the vector.

‘l_starts’ with n = c(1, 3, 7, 25, 50) would return groups with this many values in them:

2, 4, 18, 25, 8

 

force_equal does not have any effect with method ‘l_starts’.

 

Skipping

Groups can start at nth appearance of the value by using c(value, skip_to_number).

 

Example

We have a vector with the values c(“a”, “e”, “o”, “a”, “e”, “o”) and want to start groups at the first “a”, the first following “e” and the second following “o”.

‘l_starts’ with n = list(“a”, “e”, c(“o”, 2)) would return groups with this many values in them:

1, 4, 1

 

Automatically find group starts

Using the find_starts() function, ‘l_starts’ is capable of finding the beginning of groups automatically.
A group start is a value which differs from the previous value.

 

Example

We have a vector with the values c(“a”, “a”, “o”, “o”, “o”, “a”, “a”) and want to automatically discover groups of data and group them.

‘l_starts’ with n = ‘auto’ would return groups with this many values in them:

2, 3, 2

 

find_starts()

find_starts() finds group starts in a given vector.
A group start is a value which differs from the previous value.
Setting return_index to TRUE returns indices of group starts.

 

Example

We have a vector with the values c(“a”, “a”, “o”, “o”, “o”, “a”, “a”) and want to automatically discover group starts.

find_starts() would return these group starts:

“a”, “o”, “a”

 

find_missing_starts()

find_missing_starts() tells you the values and (optionally) skip_to numbers that would be recursively removed when using the ‘l_starts’ method with the remove_missing_starts argument set to TRUE.
Set return_skip_numbers to FALSE to get only the missing values without the skip_to numbers.
 

Example

We have a vector with the values c(“a”, “a”, “o”, “o”, “o”, “a”, “a”) and a vector of starting positions c(“a”,“d”,“o”,“p”,“a”).

find_missing_starts() would return this list of values and skip_to numbers:

list(c(“d”,1), c(“p”,1))

 

Method: ‘staircase’

‘staircase’ uses step_size to divide up the data.
For each group, the group size will be step size multiplied with the group index.

 

Example

We have a vector with 57 values. We specify a step size of 5.

‘staircase’ with default settings would return groups with this many values in them:

5, 10, 15, 20, 7

 

By setting force_equal to TRUE, ‘staircase’ will discard the last group if it does not contain the expected values (step size multiplied by group index).

 

Example

‘staircase’ with force_equal set to TRUE would return groups with this many values in them:

5, 10, 15, 20

meaning that 7 values have been discarded.

 

Find remainder - %staircase%

When using the staircase method the last group might not have the size of the second last group + step size.
Use %staircase% to find the remainder.

If the last group has the size of the second last group + step size, %staircase% will return 0.

 

Example

%staircase% on a vector with size 57 and step size of 5 would look like this:

57 %staircase% 5

and return:

7

meaning that the last group would contain 7 values

Method: ‘primes’

‘primes’ creates groups with sizes of primary numbers in a staircasing design. n is the prime number to start at (size of first group).

Prime numbers are generated with the ‘numbers’ package by Hans Werner Borchers.

 

Example

We have a vector with 57 values. We specify n (start at) as 5.

‘primes’ with default settings would return groups with this many values in them:

5, 7, 11, 13, 17, 4

 

By setting force_equal to TRUE, ‘primes’ will discard the last group if it does not contain the expected number of values.

 

Example

‘primes’ with force_equal set to TRUE would return groups with this many values in them:

5, 7, 11, 13, 17

meaning that 4 values have been discarded.

 

Find remainder - %primes%

When using the primes method, the last group might not have the size of the associated prime number, if there are not enough elements. Use %primes% to find the remainder.

Returns 0 if the last group has the size of the associated prime number.

 

Example

%primes% on a vector with size 57 and n (start at) as 5 would look like this:

57 %primes% 5

and return:

4

meaning that the last group would contain 4 values

Balancing ID Methods

There are currently 4 methods for balancing on ID level in balance().

ID method: ‘n_ids’

Balances on ID level only. It makes sure there are the same number of IDs in each category. This might lead to a different number of rows between categories.

ID method: ‘n_rows_c’

Attempts to level the number of rows per category, while only removing/adding entire IDs.
This is done in 2 steps:

  1. If a category needs to add all its rows one or more times, the data is repeated.

  2. Iteratively, the ID with the number of rows closest to the lacking/excessive number of rows is added/removed. This happens until adding/removing the closest ID would lead to a size further from the target size than the current size. If multiple IDs are closest, one is randomly sampled.

ID method: ‘distributed’

Distributes the lacking/excess rows equally between the IDs. If the number to distribute can not be equally divided, some IDs will have 1 row more/less than the others.

ID method: ‘nested’

Balances the IDs within their categories, meaning that all IDs in a category will have the same number of rows.

Arguments

Grouping arguments

These are the arguments for group_factor(), group(), splt(), fold(), partition()

data

Type: data frame or vector

The data to process.

 

Used in: group_factor(), group(), splt(), fold(), partition()

n

Type: integer, numeric, character, or list

n represents either number of groups (default), group size, list of group sizes, list of group starts, step size or prime number to start at, depending on which method is specified.
n can be given as a whole number(s) (n > 1) or as percentage(s) (0 < n < 1).

Method l_starts allows n = ‘auto’.

 

Used in: group_factor(), group(), splt()

method

Type: character

Choose which method to use when dividing up the data.
Available methods: greedy, n_dist, n_fill, n_last, n_rand, l_starts, l_sizes, staircase, or primes

 

Used in: group_factor(), group(), splt(), fold()

starts_col

Type: character

Name of column with values to match in method ‘l_starts’ when data is a data frame.

Pass ‘index’ or ‘.index’ to use rownames. ‘index’ first looks for column named ‘index’ in data, while ‘.index’ completely ignores potential column in data named ‘.index’.

 

Used in: group_factor(), group(), splt()

force_equal

Type: logical (TRUE or FALSE)

If you need groups with the exact same size, set force_equal to TRUE.
Implementation is different in the different methods. Read more in their sections above.
Be aware that this setting discards excess datapoints!

 

Used in: group_factor(), group(), splt(), partition()

allow_zero

Type: logical (TRUE or FALSE)

If you set n to 0, you get an error.
If you don’t want this behavior, you can set allow_zero to TRUE, and (depending on the function) you will get the following output:

group_factor() will return the factor with NAs instead of numbers. It will be the same length as expected.

group() will return the expected data frame with NAs instead of a grouping factor.

splt() functions will return the given data (data frame or vector) in the same list format as if it had been split.

 

Used in: group_factor(), group(), splt()

descending

Type: logical (TRUE or FALSE)

In methods like ‘n_fill’ where it makes sense to change the direction of the method, you can use this argument.
In ‘n_fill’ it fills up the excess data points starting from the last group instead of the first.
NB. Only some of the methods can use this argument.

 

Used in: group_factor(), group(), splt()

randomize

Type: logical (TRUE or FALSE)

After creating the the grouping factor using the chosen method, it is possible to randomly reorganize it before returning it. Notice that this applies to all the functions that allows for the argument, as group() and splt() uses the grouping factor!

 

Used in: group_factor(), group(), splt()

N.B. fold() and partition() always uses some randomization.

col_name

Type: character

Name of added grouping factor column. Allows multiple grouping factors in a data frame.

 

Used in: group()

remove_missing_starts

Type: logical (TRUE or FALSE)

Recursively remove elements from the list of starts that are not found. For method ‘l_starts’ only.

Used in: group_factor(), group(), splt()

k

Type: integer or numeric

k represents either number of folds (default), fold size, or step size, depending on which method is specified.
k can be given as a whole number (k > 1) or as a percentage (0 < k < 1).

 

Used in: fold()

p

Type: integer or numeric

Size(s) of partition(s). Passed as vector if specifying multiple partitions.
p can be given as whole number(s) (p > 1) or as percentage(s) (0 < p < 1).

 

Used in: partition()

cat_col

Type: categorical vector or factor (passed as column name)

Categorical variable to balance between the groups.

E.g. when predicting a binary variable (‘a’ or ‘b’), we usually want both classes represented in every fold and partition.

 

N.B. If also passing id_col, cat_col should be a constant within IDs.
E.g. a participant must always have the same diagnosis (‘a’ or ‘b’) throughout the dataset. Otherwise, the participant might be placed in multiple folds.

 

Used in: fold(), partition()

num_col

Type: numerical vector (passed as column name)

Numerical variable to balance between groups.

 

N.B. When used with id_col, values for each ID are aggregated using id_aggregation_fn before being balanced.
N.B. When passing num_col, the method argument is not used.

 

Used in: fold(), partition()

id_col

Type: Factor (passed as column name)

Factor with IDs. This will be used to keep all rows with an ID in the same group (if possible).

E.g. If we have measured a participant multiple times and want to see the effect of time, we want to have all observations of this participant in the same fold/partition.

 

Used in: fold(), partition()

id_aggregation_fn

Type: Function

Function for aggregating values in num_col for each ID, before balancing by num_col.

N.B. Only used when num_col and id_col are both specified.

 

Used in: fold(), partition()

extreme_pairing_levels

Type: integer or numeric

How many levels of extreme pairing to do when balancing groups by num_col.

Extreme pairing: Rows/pairs are ordered as smallest, largest, second smallest, second largest, etc. If extreme_pairing_levels > 1, this is done “recursively” on the extreme pairs.

N.B. Values greater than 1 works best with large datasets. Always check if an increase actually makes the groups more balanced. There are examples of how to do this, and more detailed descriptions of the implementations, in the functions’ help files (?fold and ?partition).

 

Used in: fold(), partition()

num_fold_cols

Type: integer or numeric

Number of fold columns to create. This is useful for repeated cross-validation. If num_fold_cols > 1, columns will be named “.folds_1”, “.folds_2”, etc. Otherwise simply “.folds”.

N.B. If unique_fold_cols_only is TRUE, we can end up with fewer columns than specified, see max_iters.

N.B. If data has existing fold columns, see handle_existing_fold_cols.

 

Used in: fold()

unique_fold_cols_only

Type: logical (TRUE or FALSE)

Check if the fold columns are identical and keep only the unique columns.

N.B. As the number of column comparisons can be time consuming, we can run this part in parallel. See parallel.

N.B. We can end up with fewer columns than specified in num_fold_cols, see max_iters.

N.B. Only used when num_fold_cols > 1 or data has existing fold columns.

 

Used in: fold()

max_iters

Type: logical (TRUE or FALSE)

Maximum number of attempts at reaching num_fold_cols unique fold columns.

When only keeping the unique fold columns, we risk having fewer columns than expected. Hence, we repeatedly create the missing columns and remove those that are not unique. This is done until we have num_fold_cols unique fold columns, or we have attempted max_iters times. In some cases, it is not possible to create num_fold_cols unique combinations of the dataset, e.g. when specifying cat_col, id_col and num_col.
max_iters specifies when to stop trying.

N.B. We can end up with fewer columns than specified in num_fold_cols.

N.B. Only used num_fold_cols > 1.

 

Used in: fold()

handle_existing_fold_cols

Type: Character

How to handle existing fold columns. Either “keep_warn”, “keep”, or “remove”.

To add extra fold columns, use “keep” or “keep_warn”. Note that existing fold columns might be renamed.

To replace the existing fold columns, use “remove”.

 

Used in: fold()

parallel

Type: logical (TRUE or FALSE)

Whether to parallelize the fold column comparisons, when unique_fold_cols_only is TRUE.

N.B. Requires a registered parallel backend. Like doParallel:registerDoParallel.

 

Used in: fold()

list_out

Type: logical (TRUE or FALSE)

Return list of partitions (TRUE) or a grouped data frame (FALSE).

 

Used in: partition()

 

Balancing arguments

These are the arguments for balance(), upsample(), downsample()

data

Type: data frame

The data to process.

 

Used in: balance(), upsample(), downsample()

size

Type: character, numeric

Size to balance categories to.

Either a specific number, given as a whole number, or one of the following strings: “min”, “max”, “mean”, “median”.

 

Used in: balance(), upsample(), downsample()

cat_col

Type: categorical vector or factor (passed as column name)

Categorical variable to balance sample size by.

 

Used in: balance(), upsample(), downsample()

id_col

Type: factor (passed as column name)

Factor with IDs. IDs are considered entities, e.g. allowing us to add or remove all rows for an ID. How this is used is up to the id_method.

E.g. If we have measured a participant multiple times and want make sure that we keep all these measurements together. Then we would either remove/add all measurements for the participant or leave in all measurements for the participant.

 

Used in: balance(), upsample(), downsample()

id_method

Type: character

Method for balancing the IDs.

Available ID methods are: n_ids, n_rows_c, or nested.

 

Used in: balance(), upsample(), downsample()

mark_new_rows

Type: logical

Whether to add a column with 1s for added rows, and 0s for original rows.

 

Used in: balance(), upsample(), downsample()

new_rows_col_name

Type: character

Name of column marking new rows.

 

Used in: balance(), upsample(), downsample()

 

Using Functions

We will be using the method ‘n_dist’ on a data frame to showcase the functions. Afterwards we will use and compare the methods.
Note, that you can also use vectors as data with all the functions.
See the necessary attached packages for running the examples under Attach Packages.

group_factor()

  1. We create a data frame
  1. Using group_factor()
x species age groups
1 cat 82 1
2 pig 59 1
3 human 51 2
4 cat 97 2
5 pig 85 3
6 human 21 3
7 cat 54 3
8 pig 74 4
9 human 7 4
10 cat 73 5
11 pig 79 5
12 human 96 5
  1. We could get the mean age of each group
groups mean_age
1 70.50000
2 74.00000
3 53.33333
4 40.50000
5 82.66667

force_equal

Getting an equal number of elements per group with group_factor().

Notice that we discard the excess values so all groups contain the same amount of elements. Since the grouping factor is shorter than the data frame, we can’t combine them as they are. A way to do so would be to shorten the data frame to be the same length as the grouping factor.

  1. We create a data frame
  1. Using group_factor() with force_equal
group size
1 2
2 2
3 2
4 2
5 2
  1. Combining data frame and grouping factor

First we make the data frame the same size as the grouping factor. Then we add the grouping factor to the data frame.

x species age group
1 cat 37 1
2 pig 89 1
3 human 100 2
4 cat 34 2
5 pig 99 3
6 human 44 3
7 cat 79 4
8 pig 33 4
9 human 84 5
10 cat 35 5

 

group()

  1. We create a data frame
  1. Using group()
x species age .groups
1 cat 42 1
2 pig 38 1
3 human 20 2
4 cat 28 2
5 pig 98 3
6 human 44 3
7 cat 87 3
8 pig 70 4
9 human 40 4
10 cat 95 5
11 pig 25 5
12 human 93 5

2.2 Using group() with dplyr pipeline to get mean age

.groups mean_age
1 40.00000
2 24.00000
3 76.33333
4 55.00000
5 71.00000

force_equal

Getting an equal number of elements per group with group().

Notice that we discard the excess rows/elements so all groups contain the same amount of elements.

  1. We create a data frame
  1. Using group() with force_equal
x species age .groups
1 cat 39 1
2 pig 51 1
3 human 42 2
4 cat 6 2
5 pig 24 3
6 human 32 3
7 cat 14 4
8 pig 2 4
9 human 45 5
10 cat 18 5

 

splt()

  1. We create a data frame
  1. Using splt()
x species age
1 cat 65
2 pig 70
x species age
3 3 human 87
4 4 cat 99
x species age
5 5 pig 75
6 6 human 81
7 7 cat 13
x species age
8 8 pig 40
9 9 human 89
x species age
10 10 cat 48
11 11 pig 92
12 12 human 23
  1. Let’s see the format of the list created by splt() without using kable() to visualize it.
    splt() uses base::split() to split the data by the grouping factor.

force_equal

Getting an equal number of elements per group with splt().

Notice that we discard the excess rows/elements so all groups contain the same amount of elements.

  1. We create a data frame
  1. Using splt() with force_equal
x species age
1 cat 84
2 pig 29
x species age
3 3 human 13
4 4 cat 22
x species age
5 5 pig 93
6 6 human 28
x species age
7 7 cat 48
8 8 pig 33
x species age
9 9 human 45
10 10 cat 21

 

fold()

  1. We create a data frame
participant age diagnosis score session
1 73 a 94 1
1 73 a 10 2
1 73 a 58 3
2 87 b 96 1
2 87 b 1 2
2 87 b 29 3
3 83 a 60 1
3 83 a 43 2
3 83 a 24 3
4 90 a 51 1
4 90 a 59 2
4 90 a 42 3
5 48 b 93 1
5 48 b 26 2
5 48 b 48 3
6 64 b 34 1
6 64 b 15 2
6 64 b 76 3
  1. Using fold() without balancing
participant age diagnosis score session .folds
1 73 a 58 3 1
2 87 b 96 1 1
3 83 a 24 3 1
4 90 a 59 2 1
5 48 b 26 2 1
6 64 b 34 1 1
1 73 a 94 1 2
1 73 a 10 2 2
2 87 b 1 2 2
3 83 a 60 1 2
5 48 b 93 1 2
5 48 b 48 3 2
2 87 b 29 3 3
3 83 a 43 2 3
4 90 a 51 1 3
4 90 a 42 3 3
6 64 b 15 2 3
6 64 b 76 3 3
  1. Using fold() with balancing but without id_col
participant age diagnosis score session .folds
1 73 a 10 2 1
4 90 a 51 1 1
4 90 a 42 3 1
2 87 b 96 1 1
5 48 b 93 1 1
5 48 b 48 3 1
1 73 a 94 1 2
3 83 a 24 3 2
4 90 a 59 2 2
2 87 b 29 3 2
6 64 b 34 1 2
6 64 b 76 3 2
1 73 a 58 3 3
3 83 a 60 1 3
3 83 a 43 2 3
2 87 b 1 2 3
5 48 b 26 2 3
6 64 b 15 2 3

Let’s count how many of each diagnosis there are in each group.

.folds diagnosis n
1 a 3
1 b 3
2 a 3
2 b 3
3 a 3
3 b 3
  1. Using fold() with id_col but without balancing
participant age diagnosis score session .folds
2 87 b 96 1 1
2 87 b 1 2 1
2 87 b 29 3 1
6 64 b 34 1 1
6 64 b 15 2 1
6 64 b 76 3 1
1 73 a 94 1 2
1 73 a 10 2 2
1 73 a 58 3 2
4 90 a 51 1 2
4 90 a 59 2 2
4 90 a 42 3 2
3 83 a 60 1 3
3 83 a 43 2 3
3 83 a 24 3 3
5 48 b 93 1 3
5 48 b 26 2 3
5 48 b 48 3 3

Let’s see how participants were distributed in the groups.

.folds participant n
1 2 3
1 6 3
2 1 3
2 4 3
3 3 3
3 5 3
  1. Using fold() with balancing and with id_col

fold() first divides up the data frame by cat_col and then create n folds for both diagnoses. As there are only 3 participants per diagnosis, we can maximally create 3 folds in this scenario.

participant age diagnosis score session .folds
4 90 a 51 1 1
4 90 a 59 2 1
4 90 a 42 3 1
2 87 b 96 1 1
2 87 b 1 2 1
2 87 b 29 3 1
3 83 a 60 1 2
3 83 a 43 2 2
3 83 a 24 3 2
5 48 b 93 1 2
5 48 b 26 2 2
5 48 b 48 3 2
1 73 a 94 1 3
1 73 a 10 2 3
1 73 a 58 3 3
6 64 b 34 1 3
6 64 b 15 2 3
6 64 b 76 3 3

Let’s count how many of each diagnosis there are in each group and find which participants are in which groups.

.folds diagnosis participant n
1 a 4 3
1 b 2 3
2 a 3 3
2 b 5 3
3 a 1 3
3 b 6 3

 

partition()

  1. We create a data frame
participant age diagnosis score session
1 77 a 34 1
1 77 a 99 2
1 77 a 10 3
2 90 b 75 1
2 90 b 16 2
2 90 b 79 3
3 98 a 31 1
3 98 a 40 2
3 98 a 32 3
4 66 a 35 1
4 66 a 9 2
4 66 a 39 3
5 19 b 46 1
5 19 b 50 2
5 19 b 37 3
6 17 b 19 1
6 17 b 24 2
6 17 b 12 3
  1. Using partition() without balancing
.partitions n
1 5
2 13
participant age diagnosis score session .partitions
1 77 a 10 3 1
2 90 b 16 2 1
2 90 b 79 3 1
3 98 a 31 1 1
5 19 b 46 1 1
1 77 a 34 1 2
1 77 a 99 2 2
2 90 b 75 1 2
3 98 a 40 2 2
3 98 a 32 3 2
4 66 a 35 1 2
4 66 a 9 2 2
4 66 a 39 3 2
5 19 b 50 2 2
5 19 b 37 3 2
6 17 b 19 1 2
6 17 b 24 2 2
6 17 b 12 3 2
  1. Using partition() with balancing but without id_col
participant age diagnosis score session .partitions
1 77 a 99 2 1
4 66 a 39 3 1
5 19 b 50 2 1
6 17 b 12 3 1
1 77 a 34 1 2
1 77 a 10 3 2
3 98 a 31 1 2
3 98 a 40 2 2
3 98 a 32 3 2
4 66 a 35 1 2
4 66 a 9 2 2
2 90 b 75 1 2
2 90 b 16 2 2
2 90 b 79 3 2
5 19 b 46 1 2
5 19 b 37 3 2
6 17 b 19 1 2
6 17 b 24 2 2

Let’s count how many of each diagnosis there are in each partition.

diagnosis .partitions n
a 1 2
a 2 7
b 1 2
b 2 7
  1. Using partition() with id_col but without balancing
participant age diagnosis score session .partitions
1 77 a 34 1 1
1 77 a 99 2 1
1 77 a 10 3 1
4 66 a 35 1 1
4 66 a 9 2 1
4 66 a 39 3 1
5 19 b 46 1 1
5 19 b 50 2 1
5 19 b 37 3 1
2 90 b 75 1 2
2 90 b 16 2 2
2 90 b 79 3 2
3 98 a 31 1 2
3 98 a 40 2 2
3 98 a 32 3 2
6 17 b 19 1 2
6 17 b 24 2 2
6 17 b 12 3 2

Let’s see how participants were distributed in the partitions.

.partitions participant n
1 1 3
1 4 3
1 5 3
2 2 3
2 3 3
2 6 3
  1. Using partition() with cat_col and with id_col

partition() first divides up the data frame by cat_col and then create n partitions for both diagnoses.

participant age diagnosis score session .partitions
4 66 a 35 1 1
4 66 a 9 2 1
4 66 a 39 3 1
2 90 b 75 1 1
2 90 b 16 2 1
2 90 b 79 3 1
1 77 a 34 1 2
1 77 a 99 2 2
1 77 a 10 3 2
3 98 a 31 1 2
3 98 a 40 2 2
3 98 a 32 3 2
5 19 b 46 1 2
5 19 b 50 2 2
5 19 b 37 3 2
6 17 b 19 1 2
6 17 b 24 2 2
6 17 b 12 3 2

Let’s count how many of each diagnosis there are in each group and find which participants are in which partitions.

.partitions diagnosis participant n
1 a 4 3
1 b 2 3
2 a 1 3
2 a 3 3
2 b 5 3
2 b 6 3

 

balance()

  1. We create a data frame
diagnosis participant n
a 1 1
a 3 3
a 4 1
b 2 2
b 5 3
b 6 3
diagnosis n
a 5
b 8
participant age diagnosis score session
1 85 a 63 3
2 79 b 8 3
2 79 b 65 2
3 70 a 33 3
3 70 a 3 2
3 70 a 81 1
4 6 a 80 2
5 32 b 95 2
5 32 b 41 1
5 32 b 43 3
6 8 b 55 2
6 8 b 38 3
6 8 b 50 1
  1. Using balance() for downsampling without id_col
diagnosis n
a 5
b 5
participant age diagnosis score session
1 85 a 63 3
3 70 a 33 3
3 70 a 3 2
3 70 a 81 1
4 6 a 80 2
2 79 b 65 2
5 32 b 95 2
5 32 b 41 1
6 8 b 55 2
6 8 b 38 3
  1. Using balance() for downsampling with id_col and id_method ‘n_rows_c’
diagnosis n
a 5
b 5
participant age diagnosis score session
1 85 a 63 3
3 70 a 33 3
3 70 a 3 2
3 70 a 81 1
4 6 a 80 2
2 79 b 8 3
2 79 b 65 2
6 8 b 55 2
6 8 b 38 3
6 8 b 50 1

Let’s count how many of each participant there are in each diagnosis.

diagnosis participant n
a 1 1
a 3 3
a 4 1
b 2 2
b 6 3
  1. Using balance() for upsampling without id_col
diagnosis n
a 8
b 8
participant age diagnosis score session
1 85 a 63 3
1 85 a 63 3
1 85 a 63 3
3 70 a 33 3
3 70 a 3 2
3 70 a 81 1
4 6 a 80 2
4 6 a 80 2
2 79 b 8 3
2 79 b 65 2
5 32 b 95 2
5 32 b 41 1
5 32 b 43 3
6 8 b 55 2
6 8 b 38 3
6 8 b 50 1
  1. Using balance() for upsampling with id_col and id_method ‘n_rows_c’
diagnosis n
a 8
b 8
participant age diagnosis score session
1 85 a 63 3
3 70 a 33 3
3 70 a 33 3
3 70 a 3 2
3 70 a 3 2
3 70 a 81 1
3 70 a 81 1
4 6 a 80 2
2 79 b 8 3
2 79 b 65 2
5 32 b 95 2
5 32 b 41 1
5 32 b 43 3
6 8 b 55 2
6 8 b 38 3
6 8 b 50 1

Let’s count how many of each participant there are in each diagnosis.

diagnosis participant n
a 1 1
a 3 6
a 4 1
b 2 2
b 5 3
b 6 3
  1. Using balance() for downsampling to a specific size without id_col
diagnosis n
a 3
b 3
participant age diagnosis score session
1 85 a 63 3
3 70 a 33 3
4 6 a 80 2
5 32 b 43 3
6 8 b 50 1
6 8 b 55 2

Let’s count how many of each participant there are in each diagnosis.

diagnosis participant n
a 1 1
a 3 1
a 4 1
b 5 1
b 6 2
  1. Using balance() for downsampling to a specific size with id_col and id_method ‘n_rows_c’
diagnosis n
a 3
b 3
participant age diagnosis score session
3 70 a 33 3
3 70 a 3 2
3 70 a 81 1
6 8 b 55 2
6 8 b 38 3
6 8 b 50 1

Let’s count how many of each participant there are in each diagnosis.

diagnosis participant n
a 3 3
b 6 3

 

Extra arguments showcase

randomize

  1. We create a data frame
  1. We use group_factor() with randomize set to TRUE
  1. We use splt() with randomize set to TRUE
    Notice that the index has been shuffled but the group sizes are the same as before!
x species age
4 4 cat 44
11 11 pig 70
x species age
3 3 human 63
8 8 pig 9
x species age
1 1 cat 77
5 5 pig 20
9 9 human 47
x species age
2 2 pig 71
6 6 human 28
x species age
7 7 cat 68
10 10 cat 50
12 12 human 54

Examples of method differences

In this section, we will take a look at the outputs we get from the different methods.

n_ methods

Vector with 57 elements divided into 6 groups

Below you’ll see a data frame with counts of group elements when dividing up the same data with the different n_ methods. The forced_equal column is simply with the force_equal set to TRUE.

forced_equal: Since this is a setting to make sure that all groups are of the same size, it makes sense that all the groups have the same size.

n_dist: compared to forced_equal we see the 3 datapoints that forced_equal had discarded. These are distributed across the groups (in this example group 2,4 and 6)

n_fill: The 3 extra datapoints are located at the first 3 groups. Had we set descending to TRUE, it would have been the last 3 groups instead.

n_last: We see that n_last creates equal group sizes in all but the last group. This means that the last group can sometimes have a group size, which is very large or small compared to the other groups. Here it is a third larger than the other groups.

n_rand: The extra datapoints are placed randomly and so we would see the extra datapoints located at different groups if we ran the script again. Unless we use set.seed() before running the function.

#>   x n_dist n_fill n_last n_rand forced_equal
#> 1 1      9     10      9     10            9
#> 2 2     10     10      9      9            9
#> 3 3      9     10      9     10            9
#> 4 4     10      9      9      9            9
#> 5 5      9      9      9     10            9
#> 6 6     10      9     12      9            9

 

Vector with 117 elements divided into 11 groups

Here is another example.

#>     x n_dist n_fill n_last n_rand forced_equal
#> 1   1     10     11     11     11           10
#> 2   2     11     11     11     11           10
#> 3   3     10     11     11     10           10
#> 4   4     11     11     11     11           10
#> 5   5     11     11     11     10           10
#> 6   6     10     11     11     10           10
#> 7   7     11     11     11     11           10
#> 8   8     11     10     11     11           10
#> 9   9     10     10     11     11           10
#> 10 10     11     10     11     10           10
#> 11 11     11     10      7     11           10

 

Greedy

Vector with 100 elements with sizes of 8, 15, 20

Below you will see group sizes when using the method ‘greedy’ and asking for group sizes of 8, 15, 20. What should become clear is that only the last group can have a different group size than what we asked for. This is important if, say, you want to split a time series into groups of 100 elements, but the time series is not divisible with 100. Then you could use force_equal to remove the excess elements, if you need equal groups.

With a size of 8, we get 13 groups. The last group (13) only contains 4 elements, but all the other groups contain 8 elements as specified.

With a size of 15, we get 7 groups. The last group (7) contains only 10 elements, but all the other groups contain 15 elements as specified.

With a size of 20, we get 5 groups. As 20 is divisible with the 100 elements that the split vector contained, the last group also contains 20 elements, and so we have equal groups.

 

Staircasing

Vector with 1000 elements with step sizes of 2, 5, 11

Below you’ll see a plot with the group sizes at each group when using step sizes 2, 5, and 11.

At a step size of 2 elements it simply increases 2 for each group, until the last group (32) where it runs out of elements. Had we set force_equal to TRUE, this last group would have been discarded, because of the lack of elements.

At a step size of 5 elements it increases with 5 every time. Because of this it runs out of elements faster. Again we see that the last group (20) has fewer elements.

At a step size of 11 elements it increases with 11 every time. It seems that the last group is not too small, but it can be hard to see on this scale. Actually, the last group misses 1 element to be complete and so would have been discarded if force_equal was set to TRUE.

 

 

Below we will take a quick look at the cumulative sum of group elements to get an idea of what is going on under the hood.
Remember that the split vector had 1000 elements? That is why they all stop at 1000 on the y-axis. There are simply no more elements left!

Primes

Vector with 1000 elements with n (start at) as 2, 5, 11

Below you’ll see a plot with the group sizes at each group when starting from prime numbers 2, 5, and 11.

 

 

Below we will take a quick look at the cumulative sum of group elements to get an idea of what is going on under the hood.
Because the split vector had 1000 elements, it stops at 1000 on the y-axis. There are simply no more elements left!

The End

You have reached the end! Now celebrate by taking the week off, splitting data and laughing!