FEA-Bench / testbed /matplotlib__matplotlib /galleries /examples /statistics /histogram_cumulative.py
| """ | |
| ================================= | |
| Plotting cumulative distributions | |
| ================================= | |
| This example shows how to plot the empirical cumulative distribution function | |
| (ECDF) of a sample. We also show the theoretical CDF. | |
| In engineering, ECDFs are sometimes called "non-exceedance" curves: the y-value | |
| for a given x-value gives probability that an observation from the sample is | |
| below that x-value. For example, the value of 220 on the x-axis corresponds to | |
| about 0.80 on the y-axis, so there is an 80% chance that an observation in the | |
| sample does not exceed 220. Conversely, the empirical *complementary* | |
| cumulative distribution function (the ECCDF, or "exceedance" curve) shows the | |
| probability y that an observation from the sample is above a value x. | |
| A direct method to plot ECDFs is `.Axes.ecdf`. Passing ``complementary=True`` | |
| results in an ECCDF instead. | |
| Alternatively, one can use ``ax.hist(data, density=True, cumulative=True)`` to | |
| first bin the data, as if plotting a histogram, and then compute and plot the | |
| cumulative sums of the frequencies of entries in each bin. Here, to plot the | |
| ECCDF, pass ``cumulative=-1``. Note that this approach results in an | |
| approximation of the E(C)CDF, whereas `.Axes.ecdf` is exact. | |
| """ | |
| import matplotlib.pyplot as plt | |
| import numpy as np | |
| np.random.seed(19680801) | |
| mu = 200 | |
| sigma = 25 | |
| n_bins = 25 | |
| data = np.random.normal(mu, sigma, size=100) | |
| fig = plt.figure(figsize=(9, 4), layout="constrained") | |
| axs = fig.subplots(1, 2, sharex=True, sharey=True) | |
| # Cumulative distributions. | |
| axs[0].ecdf(data, label="CDF") | |
| n, bins, patches = axs[0].hist(data, n_bins, density=True, histtype="step", | |
| cumulative=True, label="Cumulative histogram") | |
| x = np.linspace(data.min(), data.max()) | |
| y = ((1 / (np.sqrt(2 * np.pi) * sigma)) * | |
| np.exp(-0.5 * (1 / sigma * (x - mu))**2)) | |
| y = y.cumsum() | |
| y /= y[-1] | |
| axs[0].plot(x, y, "k--", linewidth=1.5, label="Theory") | |
| # Complementary cumulative distributions. | |
| axs[1].ecdf(data, complementary=True, label="CCDF") | |
| axs[1].hist(data, bins=bins, density=True, histtype="step", cumulative=-1, | |
| label="Reversed cumulative histogram") | |
| axs[1].plot(x, 1 - y, "k--", linewidth=1.5, label="Theory") | |
| # Label the figure. | |
| fig.suptitle("Cumulative distributions") | |
| for ax in axs: | |
| ax.grid(True) | |
| ax.legend() | |
| ax.set_xlabel("Annual rainfall (mm)") | |
| ax.set_ylabel("Probability of occurrence") | |
| ax.label_outer() | |
| plt.show() | |
| # %% | |
| # | |
| # .. admonition:: References | |
| # | |
| # The use of the following functions, methods, classes and modules is shown | |
| # in this example: | |
| # | |
| # - `matplotlib.axes.Axes.hist` / `matplotlib.pyplot.hist` | |
| # - `matplotlib.axes.Axes.ecdf` / `matplotlib.pyplot.ecdf` | |