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	.. _project_history:

	History
	=======

	.. note::

	The following introductory text was written in 2008 by John D. Hunter
	(1968-2012), the original author of Matplotlib.

	Matplotlib is a library for making 2D plots of arrays in `Python
	<https://www.python.org>`_. Although it has its origins in emulating
	the MATLAB graphics commands, it is
	independent of MATLAB, and can be used in a Pythonic, object-oriented
	way. Although Matplotlib is written primarily in pure Python, it
	makes heavy use of `NumPy <https://numpy.org>`_ and other extension
	code to provide good performance even for large arrays.

	Matplotlib is designed with the philosophy that you should be able to
	create simple plots with just a few commands, or just one! If you
	want to see a histogram of your data, you shouldn't need to
	instantiate objects, call methods, set properties, and so on; it
	should just work.

	For years, I used to use MATLAB exclusively for data analysis and
	visualization. MATLAB excels at making nice looking plots easy. When
	I began working with EEG data, I found that I needed to write
	applications to interact with my data, and developed an EEG analysis
	application in MATLAB. As the application grew in complexity,
	interacting with databases, http servers, manipulating complex data
	structures, I began to strain against the limitations of MATLAB as a
	programming language, and decided to start over in Python. Python
	more than makes up for all of MATLAB's deficiencies as a programming
	language, but I was having difficulty finding a 2D plotting package
	(for 3D `VTK <http://www.vtk.org/>`_ more than exceeds all of my
	needs).

	When I went searching for a Python plotting package, I had several
	requirements:

	* Plots should look great - publication quality. One important
	requirement for me is that the text looks good (antialiased, etc.)

	* Postscript output for inclusion with TeX documents

	* Embeddable in a graphical user interface for application
	development

	* Code should be easy enough that I can understand it and extend
	it

	* Making plots should be easy

	Finding no package that suited me just right, I did what any
	self-respecting Python programmer would do: rolled up my sleeves and
	dived in. Not having any real experience with computer graphics, I
	decided to emulate MATLAB's plotting capabilities because that is
	something MATLAB does very well. This had the added advantage that
	many people have a lot of MATLAB experience, and thus they can
	quickly get up to steam plotting in python. From a developer's
	perspective, having a fixed user interface (the pylab interface) has
	been very useful, because the guts of the code base can be redesigned
	without affecting user code.

	The Matplotlib code is conceptually divided into three parts: the
	pylab interface is the set of functions provided by
	:mod:`pylab` which allow the user to create plots with code
	quite similar to MATLAB figure generating code
	(:ref:`pyplot_tutorial`). The Matplotlib frontend or *Matplotlib
	API* is the set of classes that do the heavy lifting, creating and
	managing figures, text, lines, plots and so on
	(:ref:`artists_tutorial`). This is an abstract interface that knows
	nothing about output. The backends are device-dependent drawing
	devices, aka renderers, that transform the frontend representation to
	hardcopy or a display device (:ref:`what-is-a-backend`). Example
	backends: PS creates `PostScript®
	<https://www.adobe.com/products/postscript.html>`_ hardcopy, SVG
	creates `Scalable Vector Graphics <https://www.w3.org/Graphics/SVG/>`_
	hardcopy, Agg creates PNG output using the high quality `Anti-Grain
	Geometry <http://agg.sourceforge.net/antigrain.com/>`_
	library that ships with Matplotlib, GTK embeds Matplotlib in a
	`Gtk+ <https://www.gtk.org/>`_
	application, GTKAgg uses the Anti-Grain renderer to create a figure
	and embed it in a Gtk+ application, and so on for `PDF
	<https://acrobat.adobe.com/us/en/acrobat/about-adobe-pdf.html>`_, `WxWidgets
	<https://www.wxpython.org/>`_, `Tkinter
	<https://docs.python.org/3/library/tkinter.html>`_, etc.

	Matplotlib is used by many people in many different contexts. Some
	people want to automatically generate PostScript files to send
	to a printer or publishers. Others deploy Matplotlib on a web
	application server to generate PNG output for inclusion in
	dynamically-generated web pages. Some use Matplotlib interactively
	from the Python shell in Tkinter on Windows. My primary use is to
	embed Matplotlib in a Gtk+ EEG application that runs on Windows, Linux
	and Macintosh OS X.

	----

	Matplotlib's original logo (2003 -- 2008).

	..
	The original logo was added in fc8c215.

	.. plot::

	from matplotlib import cbook, pyplot as plt, style
	import numpy as np

	style.use("classic")

	datafile = cbook.get_sample_data('membrane.dat', asfileobj=False)

	# convert data to mV
	x = 1000 * 0.1 * np.fromstring(open(datafile, 'rb').read(), np.float32)
	# 0.0005 is the sample interval
	t = 0.0005 * np.arange(len(x))
	plt.figure(1, figsize=(7, 1), dpi=100)
	ax = plt.subplot(111, facecolor='y')
	plt.plot(t, x)
	plt.text(0.5, 0.5, 'matplotlib', color='r',
	fontsize=40, fontname=['Courier', 'DejaVu Sans Mono'],
	horizontalalignment='center',
	verticalalignment='center',
	transform=ax.transAxes,
	)
	plt.axis([1, 1.72, -60, 10])
	plt.gca().set_xticklabels([])
	plt.gca().set_yticklabels([])

	Matplotlib logo (2008 - 2015).

	..
	This logo was added in 325e47b.

	.. plot::

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

	mpl.rcParams['xtick.labelsize'] = 10
	mpl.rcParams['ytick.labelsize'] = 12
	mpl.rcParams['axes.edgecolor'] = 'gray'


	axalpha = 0.05
	figcolor = 'white'
	dpi = 80
	fig = plt.figure(figsize=(6, 1.1), dpi=dpi)
	fig.patch.set_edgecolor(figcolor)
	fig.patch.set_facecolor(figcolor)


	def add_math_background():
	ax = fig.add_axes([0., 0., 1., 1.])

	text = []
	text.append(
	(r"$W^{3\beta}_{\delta_1 \rho_1 \sigma_2} = "
	r"U^{3\beta}_{\delta_1 \rho_1} + \frac{1}{8 \pi 2}"
	r"\int^{\alpha_2}_{\alpha_2} d \alpha^\prime_2 "
	r"\left[\frac{ U^{2\beta}_{\delta_1 \rho_1} - "
	r"\alpha^\prime_2U^{1\beta}_{\rho_1 \sigma_2} "
	r"}{U^{0\beta}_{\rho_1 \sigma_2}}\right]$", (0.7, 0.2), 20))
	text.append((r"$\frac{d\rho}{d t} + \rho \vec{v}\cdot\nabla\vec{v} "
	r"= -\nabla p + \mu\nabla^2 \vec{v} + \rho \vec{g}$",
	(0.35, 0.9), 20))
	text.append((r"$\int_{-\infty}^\infty e^{-x^2}dx=\sqrt{\pi}$",
	(0.15, 0.3), 25))
	text.append((r"$F_G = G\frac{m_1m_2}{r^2}$",
	(0.85, 0.7), 30))
	for eq, (x, y), size in text:
	ax.text(x, y, eq, ha='center', va='center', color="#11557c",
	alpha=0.25, transform=ax.transAxes, fontsize=size)
	ax.set_axis_off()
	return ax


	def add_matplotlib_text(ax):
	ax.text(0.95, 0.5, 'matplotlib', color='#11557c', fontsize=65,
	ha='right', va='center', alpha=1.0, transform=ax.transAxes)


	def add_polar_bar():
	ax = fig.add_axes([0.025, 0.075, 0.2, 0.85], projection='polar')

	ax.patch.set_alpha(axalpha)
	ax.set_axisbelow(True)
	N = 7
	arc = 2. * np.pi
	theta = np.arange(0.0, arc, arc/N)
	radii = 10 * np.array([0.2, 0.6, 0.8, 0.7, 0.4, 0.5, 0.8])
	width = np.pi / 4 * np.array([0.4, 0.4, 0.6, 0.8, 0.2, 0.5, 0.3])
	bars = ax.bar(theta, radii, width=width, bottom=0.0)
	for r, bar in zip(radii, bars):
	bar.set_facecolor(cm.jet(r/10.))
	bar.set_alpha(0.6)

	ax.tick_params(labelbottom=False, labeltop=False,
	labelleft=False, labelright=False)

	ax.grid(lw=0.8, alpha=0.9, ls='-', color='0.5')

	ax.set_yticks(np.arange(1, 9, 2))
	ax.set_rmax(9)


	main_axes = add_math_background()
	add_polar_bar()
	add_matplotlib_text(main_axes)