# Bin size in Matplotlib (Histogram)

I'm using matplotlib to make a histogram.

Is there any way to manually set the size of the bins as opposed to the number of bins?

Actually, it's quite easy: instead of the number of bins you can give a list with the bin boundaries. They can be unequally distributed, too:

``````plt.hist(data, bins=[0, 10, 20, 30, 40, 50, 100])
``````

If you just want them equally distributed, you can simply use range:

``````plt.hist(data, bins=range(min(data), max(data) + binwidth, binwidth))
``````

The above line works for `data` filled with integers only. As macrocosme points out, for floats you can use:

``````import numpy as np
plt.hist(data, bins=np.arange(min(data), max(data) + binwidth, binwidth))
``````
• replace range(...) with np.arange(...) to get it to work with floats. Commented Aug 25, 2014 at 8:42
• what is the binwidth here?have u set that value before? Commented Sep 29, 2015 at 13:25
• I believe binwidth in this example could be found by: `(data.max() - data.min()) / number_of_bins_you_want`. The `+ binwidth` could be changed to just `1` to make this a more easily understood example. Commented Jan 22, 2018 at 17:31
• Further to CodingCat's excellent solution above, for float data, if you want the histogram bars centred around integer x-ticks instead of having the bar boundaries at the x-ticks, try the following tweak: bins = np.arange(dmin - 0.5, dmax + 0.5 + binwidth, binwidth) Commented Aug 13, 2018 at 13:59
• option `lw = 5, color = "white"` or similar inserts white gaps between bars Commented Nov 7, 2018 at 12:19

For N bins, the bin edges are specified by list of N+1 values where the first N give the lower bin edges and the +1 gives the upper edge of the last bin.

Code:

``````from numpy import np; from pylab import *

bin_size = 0.1; min_edge = 0; max_edge = 2.5
N = (max_edge-min_edge)/bin_size; Nplus1 = N + 1
bin_list = np.linspace(min_edge, max_edge, Nplus1)
``````

Note that linspace produces array from min_edge to max_edge broken into N+1 values or N bins

• Note that bins are inclusive of their lower bound and exclusive of their upper bound, with the exception of the N+1 (last) bin which is inclusive of both bounds. Commented Mar 1, 2016 at 17:59
• @lukewitmer this should have been highlighted somewhere. I spent literally hours debugging my huge historgram because the graph didn't correspond to reality. I was assuming that both 0, and N+1 are either exclusive or inclusive. Commented Jun 14, 2023 at 11:41

I use quantiles to do bins uniform and fitted to sample:

``````bins=df['Generosity'].quantile([0,.05,0.1,0.15,0.20,0.25,0.3,0.35,0.40,0.45,0.5,0.55,0.6,0.65,0.70,0.75,0.80,0.85,0.90,0.95,1]).to_list()

plt.hist(df['Generosity'], bins=bins, normed=True, alpha=0.5, histtype='stepfilled', color='steelblue', edgecolor='none')
``````

• Great idea. You could replace the list of quantiles by `np.arange(0, 1.01, 0.5)` or `np.linspace(0, 1, 21)`. There are no edges, but I understand the boxes have equal area, but different width in X axis? Commented Jun 13, 2020 at 20:18
• note: normed : bool, optional Deprecated; use the density keyword argument instead. Commented Feb 3, 2023 at 14:42

I guess the easy way would be to calculate the minimum and maximum of the data you have, then calculate `L = max - min`. Then you divide `L` by the desired bin width (I'm assuming this is what you mean by bin size) and use the ceiling of this value as the number of bins.

• that's exactly what I had in mind, thanks. Was just wondering if there was a simpler way but this seems find thanks! Commented Aug 8, 2011 at 19:09
• Using round numbers I don't get a round bin size with this approach. Anyone experienced that? Commented Nov 3, 2013 at 15:12

I had the same issue as OP (I think!), but I couldn't get it to work in the way that Lastalda specified. I don't know if I have interpreted the question properly, but I have found another solution (it probably is a really bad way of doing it though).

This was the way that I did it:

`plt.hist([1,11,21,31,41], bins=[0,10,20,30,40,50], weights=[10,1,40,33,6]);`

Which creates this:

So the first parameter basically 'initialises' the bin - I'm specifically creating a number that is in between the range I set in the bins parameter.

To demonstrate this, look at the array in the first parameter ([1,11,21,31,41]) and the 'bins' array in the second parameter ([0,10,20,30,40,50]):

• The number 1 (from the first array) falls between 0 and 10 (in the 'bins' array)
• The number 11 (from the first array) falls between 11 and 20 (in the 'bins' array)
• The number 21 (from the first array) falls between 21 and 30 (in the 'bins' array), etc.

Then I'm using the 'weights' parameter to define the size of each bin. This is the array used for the weights parameter: [10,1,40,33,6].

So the 0 to 10 bin is given the value 10, the 11 to 20 bin is given the value of 1, the 21 to 30 bin is given the value of 40, etc.

• I think you have a basic misunderstanding how the histogram function works. It expects raw data. So, in your example, your data array should contain 10 values between 0 an 10, 1 value between 10 and 20, and so on. Then the function does the summing-up AND the drawing. What you're doing above is a workaround because you already have the sums (which you then insert into the graph by misusing the "weights" option). Hope this clears up some confusion. Commented Dec 1, 2017 at 15:29

I like things to happen automatically and for bins to fall on "nice" values. The following seems to work quite well.

``````import numpy as np
import numpy.random as random
import matplotlib.pyplot as plt
def compute_histogram_bins(data, desired_bin_size):
min_val = np.min(data)
max_val = np.max(data)
min_boundary = -1.0 * (min_val % desired_bin_size - min_val)
max_boundary = max_val - max_val % desired_bin_size + desired_bin_size
n_bins = int((max_boundary - min_boundary) / desired_bin_size) + 1
bins = np.linspace(min_boundary, max_boundary, n_bins)
return bins

if __name__ == '__main__':
data = np.random.random_sample(100) * 123.34 - 67.23
bins = compute_histogram_bins(data, 10.0)
print(bins)
plt.hist(data, bins=bins)
plt.xlabel('Value')
plt.ylabel('Counts')
plt.title('Compute Bins Example')
plt.grid(True)
plt.show()
``````

The result has bins on nice intervals of bin size.

``````[-70. -60. -50. -40. -30. -20. -10.   0.  10.  20.  30.  40.  50.  60.]
``````

• Excactly what I was looking for! However, in some cases n_bins is rounded down due to floating point precision. E.g. for `desired_bin_size=0.05`, `min_boundary=0.850`, `max_boundary=2.05` the calculation of `n_bins` becomes `int(23.999999999999993)` which results in 23 instead of 24 and therefore one bin too few. A rounding before integer conversion worked for me: `n_bins = int(round((max_boundary - min_boundary) / desired_bin_size, 0)) + 1` Commented Oct 23, 2019 at 11:39

If you are looking on the visualization aspect also, you can add edgecolor='white', linewidth=2 and will have the binned separated :

``````date_binned = new_df[(new_df['k']>0)&(new_df['k']<360)]['k']
plt.hist(date_binned, bins=range(min(date_binned), max(date_binned) + binwidth, binwidth), edgecolor='white', linewidth=2)
``````

This answer support the @ macrocosme suggestion.

I am using heat map as hist2d plot. Additionally I use cmin=0.5 for no count value and cmap for color, r represent the reverse of given color.

Describe statistics.

``````# np.arange(data.min(), data.max()+binwidth, binwidth)
bin_x = np.arange(0.6, 7 + 0.3, 0.3)
bin_y = np.arange(12, 58 + 3, 3)
plt.hist2d(data=fuel_econ, x='displ', y='comb', cmin=0.5, cmap='viridis_r', bins=[bin_x, bin_y]);
plt.xlabel('Dispalcement (1)');
plt.ylabel('Combine fuel efficiency (mpg)');

plt.colorbar();
``````

For a histogram with integer x-values I ended up using

``````plt.hist(data, np.arange(min(data)-0.5, max(data)+0.5))
plt.xticks(range(min(data), max(data)))
``````

The offset of 0.5 centers the bins on the x-axis values. The `plt.xticks` call adds a tick for every integer.

• setting xticks was necessary for my use case Commented Sep 20, 2022 at 8:23