Note

Click here to download the full example code

# Basic Usage#

This tutorial covers some basic usage patterns and best practices to help you get started with Matplotlib.

```
import matplotlib as mpl
import matplotlib.pyplot as plt
import numpy as np
```

## A simple example#

Matplotlib graphs your data on `Figure`

s (e.g., windows, Jupyter
widgets, etc.), each of which can contain one or more `Axes`

, an
area where points can be specified in terms of x-y coordinates (or theta-r
in a polar plot, x-y-z in a 3D plot, etc). The simplest way of
creating a Figure with an Axes is using `pyplot.subplots`

. We can then use
`Axes.plot`

to draw some data on the Axes:

```
fig, ax = plt.subplots() # Create a figure containing a single axes.
ax.plot([1, 2, 3, 4], [1, 4, 2, 3]); # Plot some data on the axes.
```

Out:

```
[<matplotlib.lines.Line2D object at 0x7fb68105b940>]
```

## Parts of a Figure#

Here are the components of a Matplotlib Figure.

`Figure`

#

The **whole** figure. The Figure keeps
track of all the child `Axes`

, a group of
'special' Artists (titles, figure legends, colorbars, etc), and
even nested subfigures.

The easiest way to create a new Figure is with pyplot:

```
fig = plt.figure() # an empty figure with no Axes
fig, ax = plt.subplots() # a figure with a single Axes
fig, axs = plt.subplots(2, 2) # a figure with a 2x2 grid of Axes
```

It is often convenient to create the Axes together with the Figure, but you can also manually add Axes later on. Note that many Matplotlib backends support zooming and panning on figure windows.

`Axes`

#

An Axes is an Artist attached to a Figure that contains a region for
plotting data, and usually includes two (or three in the case of 3D)
`Axis`

objects (be aware of the difference
between **Axes** and **Axis**) that provide ticks and tick labels to
provide scales for the data in the Axes. Each `Axes`

also
has a title
(set via `set_title()`

), an x-label (set via
`set_xlabel()`

), and a y-label set via
`set_ylabel()`

).

The `Axes`

class and its member functions are the primary
entry point to working with the OOP interface, and have most of the
plotting methods defined on them (e.g. `ax.plot()`

, shown above, uses
the `plot`

method)

`Axis`

#

These objects set the scale and limits and generate ticks (the marks
on the Axis) and ticklabels (strings labeling the ticks). The location
of the ticks is determined by a `Locator`

object and the
ticklabel strings are formatted by a `Formatter`

. The
combination of the correct `Locator`

and `Formatter`

gives very fine
control over the tick locations and labels.

`Artist`

#

Basically, everything visible on the Figure is an Artist (even
`Figure`

, `Axes`

, and `Axis`

objects). This includes
`Text`

objects, `Line2D`

objects, `collections`

objects, `Patch`

objects, etc. When the Figure is rendered, all of the
Artists are drawn to the **canvas**. Most Artists are tied to an Axes; such
an Artist cannot be shared by multiple Axes, or moved from one to another.

## Types of inputs to plotting functions#

Plotting functions expect `numpy.array`

or `numpy.ma.masked_array`

as
input, or objects that can be passed to `numpy.asarray`

.
Classes that are similar to arrays ('array-like') such as `pandas`

data objects and `numpy.matrix`

may not work as intended. Common convention
is to convert these to `numpy.array`

objects prior to plotting.
For example, to convert a `numpy.matrix`

```
b = np.matrix([[1, 2], [3, 4]])
b_asarray = np.asarray(b)
```

Most methods will also parse an addressable object like a *dict*, a
`numpy.recarray`

, or a `pandas.DataFrame`

. Matplotlib allows you provide
the `data`

keyword argument and generate plots passing the strings
corresponding to the *x* and *y* variables.

```
np.random.seed(19680801) # seed the random number generator.
data = {'a': np.arange(50),
'c': np.random.randint(0, 50, 50),
'd': np.random.randn(50)}
data['b'] = data['a'] + 10 * np.random.randn(50)
data['d'] = np.abs(data['d']) * 100
fig, ax = plt.subplots(figsize=(5, 2.7), layout='constrained')
ax.scatter('a', 'b', c='c', s='d', data=data)
ax.set_xlabel('entry a')
ax.set_ylabel('entry b');
```

Out:

```
Text(36.334, 0.5, 'entry b')
```

## Coding styles#

### The object-oriented and the pyplot interfaces#

As noted above, there are essentially two ways to use Matplotlib:

Explicitly create Figures and Axes, and call methods on them (the "object-oriented (OO) style").

Rely on pyplot to automatically create and manage the Figures and Axes, and use pyplot functions for plotting.

So one can use the OO-style

```
x = np.linspace(0, 2, 100) # Sample data.
# Note that even in the OO-style, we use `.pyplot.figure` to create the Figure.
fig, ax = plt.subplots(figsize=(5, 2.7), layout='constrained')
ax.plot(x, x, label='linear') # Plot some data on the axes.
ax.plot(x, x**2, label='quadratic') # Plot more data on the axes...
ax.plot(x, x**3, label='cubic') # ... and some more.
ax.set_xlabel('x label') # Add an x-label to the axes.
ax.set_ylabel('y label') # Add a y-label to the axes.
ax.set_title("Simple Plot") # Add a title to the axes.
ax.legend(); # Add a legend.
```

Out:

```
<matplotlib.legend.Legend object at 0x7fb66b0f4dc0>
```

or the pyplot-style:

```
x = np.linspace(0, 2, 100) # Sample data.
plt.figure(figsize=(5, 2.7), layout='constrained')
plt.plot(x, x, label='linear') # Plot some data on the (implicit) axes.
plt.plot(x, x**2, label='quadratic') # etc.
plt.plot(x, x**3, label='cubic')
plt.xlabel('x label')
plt.ylabel('y label')
plt.title("Simple Plot")
plt.legend();
```

Out:

```
<matplotlib.legend.Legend object at 0x7fb66989e380>
```

(In addition, there is a third approach, for the case when embedding Matplotlib in a GUI application, which completely drops pyplot, even for figure creation. See the corresponding section in the gallery for more info: Embedding Matplotlib in graphical user interfaces.)

Matplotlib's documentation and examples use both the OO and the pyplot styles. In general, we suggest using the OO style, particularly for complicated plots, and functions and scripts that are intended to be reused as part of a larger project. However, the pyplot style can be very convenient for quick interactive work.

Note

You may find older examples that use the `pylab`

interface,
via `from pylab import *`

. This approach is strongly deprecated.

### Making a helper functions#

If you need to make the same plots over and over again with different data sets, or want to easily wrap Matplotlib methods, use the recommended signature function below.

which you would then use twice to populate two subplots:

Out:

```
[<matplotlib.lines.Line2D object at 0x7fb680ef9570>]
```

Note that if you want to install these as a python package, or any other customizations you could use one of the many templates on the web; Matplotlib has one at mpl-cookiecutter

## Styling Artists#

Most plotting methods have styling options for the Artists, accessible either
when a plotting method is called, or from a "setter" on the Artist. In the
plot below we manually set the *color*, *linewidth*, and *linestyle* of the
Artists created by `plot`

, and we set the linestyle of the second line
after the fact with `set_linestyle`

.

### Colors#

Matplotlib has a very flexible array of colors that are accepted for most
Artists; see the colors tutorial for a
list of specifications. Some Artists will take multiple colors. i.e. for
a `scatter`

plot, the edge of the markers can be different colors
from the interior:

```
fig, ax = plt.subplots(figsize=(5, 2.7))
ax.scatter(data1, data2, s=50, facecolor='C0', edgecolor='k');
```

Out:

```
<matplotlib.collections.PathCollection object at 0x7fb6697b06d0>
```

### Linewidths, linestyles, and markersizes#

Line widths are typically in typographic points (1 pt = 1/72 inch) and available for Artists that have stroked lines. Similarly, stroked lines can have a linestyle. See the linestyles example.

Marker size depends on the method being used. `plot`

specifies
markersize in points, and is generally the "diameter" or width of the
marker. `scatter`

specifies markersize as approximately
proportional to the visual area of the marker. There is an array of
markerstyles available as string codes (see `markers`

), or
users can define their own `MarkerStyle`

(see
Marker reference):

Out:

```
<matplotlib.legend.Legend object at 0x7fb6697a47c0>
```

## Labelling plots#

### Axes labels and text#

`set_xlabel`

, `set_ylabel`

, and `set_title`

are used to
add text in the indicated locations (see Text in Matplotlib Plots
for more discussion). Text can also be directly added to plots using
`text`

:

```
mu, sigma = 115, 15
x = mu + sigma * np.random.randn(10000)
fig, ax = plt.subplots(figsize=(5, 2.7), layout='constrained')
# the histogram of the data
n, bins, patches = ax.hist(x, 50, density=1, facecolor='C0', alpha=0.75)
ax.set_xlabel('Length [cm]')
ax.set_ylabel('Probability')
ax.set_title('Aardvark lengths\n (not really)')
ax.text(75, .025, r'$\mu=115,\ \sigma=15$')
ax.axis([55, 175, 0, 0.03])
ax.grid(True);
```

All of the `text`

functions return a `matplotlib.text.Text`

instance. Just as with lines above, you can customize the properties by
passing keyword arguments into the text functions:

```
t = ax.set_xlabel('my data', fontsize=14, color='red')
```

These properties are covered in more detail in Text properties and layout.

### Using mathematical expressions in text#

Matplotlib accepts TeX equation expressions in any text expression. For example to write the expression \(\sigma_i=15\) in the title, you can write a TeX expression surrounded by dollar signs:

```
ax.set_title(r'$\sigma_i=15$')
```

where the `r`

preceding the title string signifies that the string is a
*raw* string and not to treat backslashes as python escapes.
Matplotlib has a built-in TeX expression parser and
layout engine, and ships its own math fonts – for details see
Writing mathematical expressions. You can also use LaTeX directly to format
your text and incorporate the output directly into your display figures or
saved postscript – see Text rendering with LaTeX.

### Annotations#

We can also annotate points on a plot, often by connecting an arrow pointing
to *xy*, to a piece of text at *xytext*:

```
fig, ax = plt.subplots(figsize=(5, 2.7))
t = np.arange(0.0, 5.0, 0.01)
s = np.cos(2 * np.pi * t)
line, = ax.plot(t, s, lw=2)
ax.annotate('local max', xy=(2, 1), xytext=(3, 1.5),
arrowprops=dict(facecolor='black', shrink=0.05))
ax.set_ylim(-2, 2);
```

Out:

```
(-2.0, 2.0)
```

In this basic example, both *xy* and *xytext* are in data coordinates.
There are a variety of other coordinate systems one can choose -- see
Basic annotation and Advanced Annotations for
details. More examples also can be found in
Annotating Plots.

### Legends#

Often we want to identify lines or markers with a `Axes.legend`

:

Out:

```
<matplotlib.legend.Legend object at 0x7fb650f185e0>
```

Legends in Matplotlib are quite flexible in layout, placement, and what Artists they can represent. They are discussed in detail in Legend guide.

## Axis scales and ticks#

Each Axes has two (or three) `Axis`

objects representing the x- and
y-axis. These control the *scale* of the Axis, the tick *locators* and the
tick *formatters*. Additional Axes can be attached to display further Axis
objects.

### Scales#

In addition to the linear scale, Matplotlib supplies non-linear scales,
such as a log-scale. Since log-scales are used so much there are also
direct methods like `loglog`

, `semilogx`

, and
`semilogy`

. There are a number of scales (see
Scales for other examples). Here we set the scale
manually:

Out:

```
[<matplotlib.lines.Line2D object at 0x7fb650fd6950>]
```

The scale sets the mapping from data values to spacing along the Axis. This
happens in both directions, and gets combined into a *transform*, which
is the way that Matplotlib maps from data coordinates to Axes, Figure, or
screen coordinates. See Transformations Tutorial.

### Tick locators and formatters#

Each Axis has a tick *locator* and *formatter* that choose where along the
Axis objects to put tick marks. A simple interface to this is
`set_xticks`

:

```
fig, axs = plt.subplots(2, 1, layout='constrained')
axs[0].plot(xdata, data1)
axs[0].set_title('Automatic ticks')
axs[1].plot(xdata, data1)
axs[1].set_xticks(np.arange(0, 100, 30), ['zero', '30', 'sixty', '90'])
axs[1].set_yticks([-1.5, 0, 1.5]) # note that we don't need to specify labels
axs[1].set_title('Manual ticks');
```

Out:

```
Text(0.5, 1.0, 'Manual ticks')
```

Different scales can have different locators and formatters; for instance
the log-scale above uses `LogLocator`

and `LogFormatter`

. See
Tick locators and
Tick formatters for other formatters and
locators and information for writing your own.

### Plotting dates and strings#

Matplotlib can handle plotting arrays of dates and arrays of strings, as well as floating point numbers. These get special locators and formatters as appropriate. For dates:

```
fig, ax = plt.subplots(figsize=(5, 2.7), layout='constrained')
dates = np.arange(np.datetime64('2021-11-15'), np.datetime64('2021-12-25'),
np.timedelta64(1, 'h'))
data = np.cumsum(np.random.randn(len(dates)))
ax.plot(dates, data)
cdf = mpl.dates.ConciseDateFormatter(ax.xaxis.get_major_locator())
ax.xaxis.set_major_formatter(cdf);
```

For more information see the date examples (e.g. Date tick labels)

For strings, we get categorical plotting (see: Plotting categorical variables).

```
fig, ax = plt.subplots(figsize=(5, 2.7), layout='constrained')
categories = ['turnips', 'rutabaga', 'cucumber', 'pumpkins']
ax.bar(categories, np.random.rand(len(categories)));
```

Out:

```
<BarContainer object of 4 artists>
```

One caveat about categorical plotting is that some methods of parsing text files return a list of strings, even if the strings all represent numbers or dates. If you pass 1000 strings, Matplotlib will think you meant 1000 categories and will add 1000 ticks to your plot!

### Additional Axis objects#

Plotting data of different magnitude in one chart may require
an additional y-axis. Such an Axis can be created by using
`twinx`

to add a new Axes with an invisible x-axis and a y-axis
positioned at the right (analogously for `twiny`

). See
Plots with different scales for another example.

Similarly, you can add a `secondary_xaxis`

or
`secondary_yaxis`

having a different scale than the main Axis to
represent the data in different scales or units. See
Secondary Axis for further
examples.

```
fig, (ax1, ax3) = plt.subplots(1, 2, figsize=(7, 2.7), layout='constrained')
l1, = ax1.plot(t, s)
ax2 = ax1.twinx()
l2, = ax2.plot(t, range(len(t)), 'C1')
ax2.legend([l1, l2], ['Sine (left)', 'Straight (right)'])
ax3.plot(t, s)
ax3.set_xlabel('Angle [rad]')
ax4 = ax3.secondary_xaxis('top', functions=(np.rad2deg, np.deg2rad))
ax4.set_xlabel('Angle [°]')
```

Out:

```
Text(0.5, 509.6660000000001, 'Angle [°]')
```

## Color mapped data#

Often we want to have a third dimension in a plot represented by a colors in a colormap. Matplotlib has a number of plot types that do this:

```
X, Y = np.meshgrid(np.linspace(-3, 3, 128), np.linspace(-3, 3, 128))
Z = (1 - X/2 + X**5 + Y**3) * np.exp(-X**2 - Y**2)
fig, axs = plt.subplots(2, 2, layout='constrained')
pc = axs[0, 0].pcolormesh(X, Y, Z, vmin=-1, vmax=1, cmap='RdBu_r')
fig.colorbar(pc, ax=axs[0, 0])
axs[0, 0].set_title('pcolormesh()')
co = axs[0, 1].contourf(X, Y, Z, levels=np.linspace(-1.25, 1.25, 11))
fig.colorbar(co, ax=axs[0, 1])
axs[0, 1].set_title('contourf()')
pc = axs[1, 0].imshow(Z**2 * 100, cmap='plasma',
norm=mpl.colors.LogNorm(vmin=0.01, vmax=100))
fig.colorbar(pc, ax=axs[1, 0], extend='both')
axs[1, 0].set_title('imshow() with LogNorm()')
pc = axs[1, 1].scatter(data1, data2, c=data3, cmap='RdBu_r')
fig.colorbar(pc, ax=axs[1, 1], extend='both')
axs[1, 1].set_title('scatter()')
```

Out:

```
Text(0.5, 1.0, 'scatter()')
```

### Colormaps#

These are all examples of Artists that derive from `ScalarMappable`

objects. They all can set a linear mapping between *vmin* and *vmax* into
the colormap specified by *cmap*. Matplotlib has many colormaps to choose
from (Choosing Colormaps in Matplotlib) you can make your
own (Creating Colormaps in Matplotlib) or download as
third-party packages.

### Normalizations#

Sometimes we want a non-linear mapping of the data to the colormap, as
in the `LogNorm`

example above. We do this by supplying the
ScalarMappable with the *norm* argument instead of *vmin* and *vmax*.
More normalizations are shown at Colormap Normalization.

### Colorbars#

Adding a `colorbar`

gives a key to relate the color back to the
underlying data. Colorbars are figure-level Artists, and are attached to
a ScalarMappable (where they get their information about the norm and
colormap) and usually steal space from a parent Axes. Placement of
colorbars can be complex: see
Placing Colorbars for
details. You can also change the appearance of colorbars with the
*extend* keyword to add arrows to the ends, and *shrink* and *aspect* to
control the size. Finally, the colorbar will have default locators
and formatters appropriate to the norm. These can be changed as for
other Axis objects.

## Working with multiple Figures and Axes#

You can open multiple Figures with multiple calls to
`fig = plt.figure()`

or `fig2, ax = plt.subplots()`

. By keeping the
object references you can add Artists to either Figure.

Multiple Axes can be added a number of ways, but the most basic is
`plt.subplots()`

as used above. One can achieve more complex layouts,
with Axes objects spanning columns or rows, using `subplot_mosaic`

.

Out:

```
Text(0.5, 1.0, 'right')
```

Matplotlib has quite sophisticated tools for arranging Axes: See Arranging multiple Axes in a Figure and Complex and semantic figure composition.

## More reading#

For more plot types see Plot types and the API reference, in particlar the Axes API.

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