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histcounts

Histogram bin counts

Description

example

[N,edges] = histcounts(X) partitions the X values into bins and returns the bin counts and the bin edges. The histcounts function uses an automatic binning algorithm that returns uniform bins chosen to cover the range of elements in X and reveal the underlying shape of the distribution.

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[N,edges] = histcounts(X,nbins) uses a number of bins specified by the scalar, nbins.

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[N,edges] = histcounts(X,edges) sorts X into bins with the bin edges specified by the vector, edges.

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[N,edges,bin] = histcounts(___) also returns an index array, bin, using any of the previous syntaxes. bin is an array of the same size as X whose elements are the bin indices for the corresponding elements in X. The number of elements in the kth bin is nnz(bin==k), which is the same as N(k).

example

N = histcounts(C), where C is a categorical array, returns a vector, N, that indicates the number of elements in C whose value is equal to each of C’s categories. N has one element for each category in C.

N = histcounts(C,Categories) counts only the elements in C whose value is equal to the subset of categories specified by Categories.

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[N,Categories] = histcounts(___) also returns the categories that correspond to each count in N using either of the previous syntaxes for categorical arrays.

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[___] = histcounts(___,Name,Value) specifies additional parameters using one or more name-value arguments. For example, you can specify BinWidth as a scalar to adjust the width of the bins for numeric data.

Examples

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Distribute 100 random values into bins. histcounts automatically chooses an appropriate bin width to reveal the underlying distribution of the data.

X = randn(100,1);
[N,edges] = histcounts(X)
N = 1×7

     2    17    28    32    16     3     2

edges = 1×8

    -3    -2    -1     0     1     2     3     4

Distribute 10 numbers into 6 equally spaced bins.

X = [2 3 5 7 11 13 17 19 23 29];
[N,edges] = histcounts(X,6)
N = 1×6

     2     2     2     2     1     1

edges = 1×7

         0    4.9000    9.8000   14.7000   19.6000   24.5000   29.4000

Distribute 1,000 random numbers into bins. Define the bin edges with a vector, where the first element is the left edge of the first bin, and the last element is the right edge of the last bin.

X = randn(1000,1);
edges = [-5 -4 -2 -1 -0.5 0 0.5 1 2 4 5];
N = histcounts(X,edges)
N = 1×10

     0    24   149   142   195   200   154   111    25     0

Distribute all of the prime numbers less than 100 into bins. Specify 'Normalization' as 'probability' to normalize the bin counts so that sum(N) is 1. That is, each bin count represents the probability that an observation falls within that bin.

X = primes(100);
[N,edges] = histcounts(X, 'Normalization', 'probability')
N = 1×4

    0.4000    0.2800    0.2800    0.0400

edges = 1×5

     0    30    60    90   120

Distribute 100 random integers between -5 and 5 into bins, and specify 'BinMethod' as 'integers' to use unit-width bins centered on integers. Specify a third output for histcounts to return a vector representing the bin indices of the data.

X = randi([-5,5],100,1);
[N,edges,bin] = histcounts(X,'BinMethod','integers');

Find the bin count for the third bin by counting the occurrences of the number 3 in the bin index vector, bin. The result is the same as N(3).

count = nnz(bin==3)
count = 8

Create a categorical vector that represents votes. The categories in the vector are 'yes', 'no', or 'undecided'.

A = [0 0 1 1 1 0 0 0 0 NaN NaN 1 0 0 0 1 0 1 0 1 0 0 0 1 1 1 1];
C = categorical(A,[1 0 NaN],{'yes','no','undecided'})
C = 1x27 categorical
     no      no      yes      yes      yes      no      no      no      no      undecided      undecided      yes      no      no      no      yes      no      yes      no      yes      no      no      no      yes      yes      yes      yes 

Determine the number of elements that fall into each category.

[N,Categories] = histcounts(C)
N = 1×3

    11    14     2

Categories = 1x3 cell
    {'yes'}    {'no'}    {'undecided'}

Input Arguments

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Data to distribute among bins, specified as a vector, matrix, or multidimensional array. If X is not a vector, then histcounts treats it as a single column vector, X(:).

histcounts ignores all NaN values. Similarly, histcounts ignores Inf and -Inf values unless the bin edges explicitly specify Inf or -Inf as a bin edge.

Data Types: single | double | int8 | int16 | int32 | int64 | uint8 | uint16 | uint32 | uint64 | logical | datetime | duration

Categorical data, specified as a categorical array. histcounts ignores undefined categorical values.

Data Types: categorical

Number of bins, specified as a positive integer. If you do not specify nbins, then histcounts automatically calculates how many bins to use based on the values in X.

Example: [N,edges] = histcounts(X,15) uses 15 bins.

Bin edges, specified as a vector. The first vector element specifies the leading edge of the first bin. The last element specifies the trailing edge of the last bin. The trailing edge is only included for the last bin.

For datetime and duration data, edges must be a datetime or duration vector in monotonically increasing order.

Categories included in count, specified as a string vector, cell vector of character vectors, pattern scalar, or categorical vector. By default, histcounts uses a bin for each category in categorical array C. Use Categories to specify a unique subset of the categories instead.

Example: h = histcounts(C,["Large","Small"]) counts only the categorical data in the categories Large and Small.

Example: h = histcounts(C,"Y" + wildcardPattern) counts categorical data in all the categories whose names begin with the letter Y.

Data Types: string | cell | pattern | categorical

Name-Value Arguments

Specify optional pairs of arguments as Name1=Value1,...,NameN=ValueN, where Name is the argument name and Value is the corresponding value. Name-value arguments must appear after other arguments, but the order of the pairs does not matter.

Before R2021a, use commas to separate each name and value, and enclose Name in quotes.

Example: [N,edges] = histcounts(X,'Normalization','probability') normalizes the bin counts in N, such that sum(N) is 1.

Width of bins, specified as a positive scalar. If you specify BinWidth, then histcounts can use a maximum of 65,536 bins (or 216). If the specified bin width requires more bins, then histcounts uses a larger bin width corresponding to the maximum number of bins.

  • For datetime and duration data, BinWidth can be a scalar duration or calendar duration.

  • If you specify BinWidth with BinMethod, NumBins, or BinEdges, histcounts only honors the last parameter.

  • This option does not apply to categorical data.

Example: histcounts(X,'BinWidth',5) uses bins with a width of 5.

Edges of bins, specified as a numeric vector. The first element specifies the leading edge of the first bin. The last element specifies the trailing edge of the last bin. The trailing edge is only included for the last bin.

If you do not specify the bin edges, then histcounts automatically determines the bin edges.

  • If you specify BinEdges with BinMethod, BinWidth, NumBins, or BinLimits, histcounts only honors BinEdges and BinEdges must be specified last.

  • This option does not apply to categorical data.

Bin limits, specified as a two-element vector, [bmin,bmax]. The first element indicates the first bin edge. The second element indicates the last bin edge.

This option computes using only the data that falls within the bin limits inclusively, X>=bmin & X<=bmax.

This option does not apply to categorical data.

Example: histcounts(X,'BinLimits',[1,10]) bins only the values in X that are between 1 and 10 inclusive.

Binning algorithm, specified as one of the values in this table.

Value

Description

'auto'

The default 'auto' algorithm chooses a bin width to cover the data range and reveal the shape of the underlying distribution.

'scott'

Scott’s rule is optimal if the data is close to being normally distributed. This rule is appropriate for most other distributions, as well. It uses a bin width of 3.5*std(X(:))*numel(X)^(-1/3).

'fd'

The Freedman-Diaconis rule is less sensitive to outliers in the data, and might be more suitable for data with heavy-tailed distributions. It uses a bin width of 2*iqr(X(:))*numel(X)^(-1/3).

'integers'

The integer rule is useful with integer data, as it creates a bin for each integer. It uses a bin width of 1 and places bin edges halfway between integers.

To avoid accidentally creating too many bins, you can use this rule to create a limit of 65536 bins (216). If the data range is greater than 65536, then the integer rule uses wider bins instead.

'integers' does not support datetime or duration data.

'sturges'

Sturges’ rule is popular due to its simplicity. It chooses the number of bins to be ceil(1 + log2(numel(X))).

'sqrt'

The Square Root rule is widely used in other software packages. It chooses the number of bins to be ceil(sqrt(numel(X))).

histcounts adjusts the number of bins slightly so that the bin edges fall on "nice" numbers, rather than using these exact formulas.

For datetime or duration data, specify the binning algorithm as one of these units of time.

ValueDescriptionData Type
"second"

Each bin is 1 second.

datetime and duration
"minute"

Each bin is 1 minute.

datetime and duration
"hour"

Each bin is 1 hour.

datetime and duration
"day"

Each bin is 1 calendar day. This value accounts for daylight saving time shifts.

datetime and duration
"week"Each bin is 1 calendar week.datetime only
"month"Each bin is 1 calendar month.datetime only
"quarter"Each bin is 1 calendar quarter.datetime only
"year"

Each bin is 1 calendar year. This value accounts for leap days.

datetime and duration
"decade"Each bin is 1 decade (10 calendar years).datetime only
"century"Each bin is 1 century (100 calendar years).datetime only

  • If you specify BinMethod for datetime or duration data, then histcounts can use a maximum of 65,536 bins (or 216). If the specified bin duration requires more bins, then histcounts uses a larger bin width corresponding to the maximum number of bins.

  • If you specify BinLimits, NumBins, BinEdges, or BinWidth, then BinMethod is set to 'manual'.

  • If you specify BinMethod with BinWidth, NumBins or BinEdges, histcounts only honors the last parameter.

  • This option does not apply to categorical data.

Example: histcounts(X,'BinMethod','integers') centers the bins on integers.

Type of normalization, specified as one of the values in this table. For each bin i:

  • vi is the bin value.

  • ci is the number of elements in the bin.

  • wi is the width of the bin.

  • N is the number of elements in the input data. This value can be greater than the binned data if the data contains missing values, such as NaN, or if some of the data lies outside the bin limits.

ValueBin ValuesNotes
'count' (default)

vi=ci

  • Count or frequency of observations.

  • Sum of bin values is at most numel(X), or sum(ismember(X(:),'Categories')) for categorical data. The sum is less than this only when some of the input data is not included in the bins.

'probability'

vi=ciN

  • Relative probability.

  • The number of elements in each bin relative to the total number of elements in the input data is at most 1.

'percentage'

vi=100*ciN

  • Relative percentage.

  • The percentage of elements in each bin is at most 100.

'countdensity'

vi=ciwi

  • Count or frequency scaled by width of bin.

  • For categorical data, this is the same as 'count'.

  • 'countdensity' does not support datetime or duration data.

  • The sum of the bin areas is at most numel(X).

'cumcount'

vi=j=1icj

  • Cumulative count, or the number of observations in each bin and all previous bins.

  • N(end) is at most numel(X), or sum(ismember(X(:),'Categories')) for categorical data.

'pdf'

vi=ciNwi

  • Probability density function estimate.

  • For categorical data, this is the same as 'probability'.

  • 'pdf' does not support datetime or duration data.

  • The sum of the bin areas is at most 1.

'cdf'

vi=j=1icjN

  • Cumulative distribution function estimate.

  • The count of each bin is equal to the cumulative relative number of observations in the bin and all previous bins.

  • N(end) is at most 1.

Example: histcounts(X,'Normalization','pdf') bins the data using an estimate of the probability density function.

Number of bins, specified as a positive integer. If you do not specify NumBins, then histcounts automatically calculates how many bins to use based on the input data.

  • If you specify NumBins with BinMethod, BinWidth or BinEdges, histcounts only honors the last parameter.

  • This option does not apply to categorical data.

Output Arguments

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Bin counts, returned as a row vector.

Bin edges, returned as a vector. The first element is the leading edge of the first bin. The last element is the trailing edge of the last bin.

Bin indices, returned as an array of the same size as X. Each element in bin describes which numbered bin contains the corresponding element in X.

A value of 0 in bin indicates an element which does not belong to any of the bins (for example, a NaN value).

Categories included in count, returned as a cell vector of character vectors. Categories contains the categories in C that correspond to each count in N.

Tips

  • The behavior of histcounts is similar to that of the discretize function. Use histcounts to find the number of elements in each bin. On the other hand, use discretize to find which bin each element belongs to (without counting).

Extended Capabilities

Version History

Introduced in R2014b

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