# Adding a scatter of points to a boxplot using matplotlib As you can see, this is a boxplot on which are superimposed a scatter of black points: x indexes the black points (in a random order), y is the variable of interest. I would like to do something similar using Matplotlib, but I have no idea where to start. So far, the boxplots which I have found online are way less cool and look like this: Documentation of matplotlib: http://matplotlib.org/api/pyplot_api.html#matplotlib.pyplot.boxplot

Ways to colorize boxplots: https://github.com/jbmouret/matplotlib_for_papers#colored-boxes

What you're looking for is a way to add jitter to the x-axis.

Something like this taken from here:

``````bp = titanic.boxplot(column='age', by='pclass', grid=False)
for i in [1,2,3]:
y = titanic.age[titanic.pclass==i].dropna()
# Add some random "jitter" to the x-axis
x = np.random.normal(i, 0.04, size=len(y))
plot(x, y, 'r.', alpha=0.2)
`````` One way to add additional information to a boxplot is to overlay the actual data; this is generally most suitable with small- or moderate-sized data series. When data are dense, a couple of tricks used above help the visualization:

1. reducing the alpha level to make the points partially transparent
2. adding random "jitter" along the x-axis to avoid overstriking

The code looks like this:

``````import pylab as P
import numpy as np

# Define data
# Define numBoxes

P.figure()

bp = P.boxplot(data)

for i in range(numBoxes):
y = data[i]
x = np.random.normal(1+i, 0.04, size=len(y))
P.plot(x, y, 'r.', alpha=0.2)

P.show()
``````

Expanding on Kyrubas's solution and using only matplotlib for the plotting part (sometimes I have difficulty formatting pandas plots with matplotlib).

``````from matplotlib import cm
import matplotlib.pyplot as plt
import pandas as pd
import numpy as np

# initialize dataframe
n = 200
ngroup = 3
df = pd.DataFrame({'data': np.random.rand(n), 'group': map(np.floor, np.random.rand(n) * ngroup)})

group = 'group'
column = 'data'
grouped = df.groupby(group)

names, vals, xs = [], [] ,[]

for i, (name, subdf) in enumerate(grouped):
names.append(name)
vals.append(subdf[column].tolist())
xs.append(np.random.normal(i+1, 0.04, subdf.shape))

plt.boxplot(vals, labels=names)
ngroup = len(vals)
clevels = np.linspace(0., 1., ngroup)

for x, val, clevel in zip(xs, vals, clevels):
plt.scatter(x, val, c=cm.prism(clevel), alpha=0.4)
`````` • For Python 3 users, you'll need to wrap the map in a list, like so: `'group': list(map(np.floor, np.random.rand(n) * ngroup))` Jul 1, 2017 at 20:47
• Would be nice to define a function for this that one can call the same way as the classical boxplot (and maybe add an option to only show the points outside the box). I think all boxplots should be replaced by jittered boxplots in general. Dec 9, 2021 at 17:09
• I have added this functionality as a python function in my answer: stackoverflow.com/a/70311225/7735095. There one can also choose to only show the fliers outside of the whiskers. Dec 14, 2021 at 10:34

As a simpler, possibly newer option, you could use `seaborn`'s `swarmplot` option.

``````import seaborn as sns
import matplotlib.pyplot as plt

sns.set(style="whitegrid")

ax = sns.boxplot(x="day", y="total_bill", data=tips, showfliers = False)
ax = sns.swarmplot(x="day", y="total_bill", data=tips, color=".25")

plt.show()
`````` Looking at the original question again (and having more experience myself), I think instead of `sns.swarmplot`, `sns.stripplot` would be more accurate.

• Yeah, the computer will also hang 4ever when dealing with even in the thousands of datapoints with swarmplot. Feb 14, 2020 at 6:19

Extending the solutions by Kyrubas and hwang you can also once define a function `scattered_boxplot` (and add it as a method to `plt.Axes`), such that you can always use `scattered_boxplot` instead of `boxplot`:

``````fig, ax = plt.subplots(figsize=(5, 6))
ax.scattered_boxplot(x=[np.array([1,2,3]*50),np.array([1.1,2.2,3.3])])
``````

The function `scattered_boxplot` can be defined as follows only using `matplotlib`:

``````import matplotlib.pyplot as plt

import numpy as np
from numbers import Number

def scattered_boxplot(ax, x, notch=None, sym=None, vert=None, whis=None, positions=None, widths=None, patch_artist=None, bootstrap=None, usermedians=None, conf_intervals=None, meanline=None, showmeans=None, showcaps=None, showbox=None,
showfliers="unif",
hide_points_within_whiskers=False,
boxprops=None, labels=None, flierprops=None, medianprops=None, meanprops=None, capprops=None, whiskerprops=None, manage_ticks=True, autorange=False, zorder=None, *, data=None):
if showfliers=="classic":
classic_fliers=True
else:
classic_fliers=False
ax.boxplot(x, notch=notch, sym=sym, vert=vert, whis=whis, positions=positions, widths=widths, patch_artist=patch_artist, bootstrap=bootstrap, usermedians=usermedians, conf_intervals=conf_intervals, meanline=meanline, showmeans=showmeans, showcaps=showcaps, showbox=showbox,
showfliers=classic_fliers,
boxprops=boxprops, labels=labels, flierprops=flierprops, medianprops=medianprops, meanprops=meanprops, capprops=capprops, whiskerprops=whiskerprops, manage_ticks=manage_ticks, autorange=autorange, zorder=zorder,data=data)
N=len(x)
datashape_message = ("List of boxplot statistics and `{0}` "
"values must have same the length")
# check position
if positions is None:
positions = list(range(1, N + 1))
elif len(positions) != N:
raise ValueError(datashape_message.format("positions"))

positions = np.array(positions)
if len(positions) > 0 and not isinstance(positions, Number):
raise TypeError("positions should be an iterable of numbers")

# width
if widths is None:
widths = [np.clip(0.15 * np.ptp(positions), 0.15, 0.5)] * N
elif np.isscalar(widths):
widths = [widths] * N
elif len(widths) != N:
raise ValueError(datashape_message.format("widths"))

if hide_points_within_whiskers:
import matplotlib.cbook as cbook
from matplotlib import rcParams
if whis is None:
whis = rcParams['boxplot.whiskers']
if bootstrap is None:
bootstrap = rcParams['boxplot.bootstrap']
bxpstats = cbook.boxplot_stats(x, whis=whis, bootstrap=bootstrap,
labels=labels, autorange=autorange)
for i in range(N):
if hide_points_within_whiskers:
xi=bxpstats[i]['fliers']
else:
xi=x[i]
if showfliers=="unif":
jitter=np.random.uniform(-widths[i]*0.5,widths[i]*0.5,size=np.size(xi))
elif showfliers=="normal":
jitter=np.random.normal(loc=0.0, scale=widths[i]*0.1,size=np.size(xi))
elif showfliers==False or showfliers=="classic":
return
else:
raise NotImplementedError("showfliers='"+str(showfliers)+"' is not implemented. You can choose from 'unif', 'normal', 'classic' and False")

plt.scatter(positions[i]+jitter,xi,alpha=0.2,marker="o", facecolors='none', edgecolors="k")
``````

and can be added as a method to plt.Axes by

``````setattr(plt.Axes, "scattered_boxplot", scattered_boxplot)
``````

One still has acces to all the options of boxplots and additionally one can choose the scatering distribution used for the horizontal jitter (e.g. `showfliers="unif"`) and one can choose if the fliers outside the whiskers should be shown too (e.g. `hide_points_within_whiskers=False`).

This solution works already quite well. An alternative would be to directly change the source code of `matplotlib`, mainly in line: https://github.com/matplotlib/matplotlib/blob/9765379ce6e7343070e815afc0988874041b98e2/lib/matplotlib/axes/_axes.py#L4006