FEA-Bench / testbed /matplotlib__matplotlib /galleries /examples /shapes_and_collections /collections.py
| """ | |
| ========================================================= | |
| Line, Poly and RegularPoly Collection with autoscaling | |
| ========================================================= | |
| For the first two subplots, we will use spirals. Their size will be set in | |
| plot units, not data units. Their positions will be set in data units by using | |
| the *offsets* and *offset_transform* keyword arguments of the `.LineCollection` | |
| and `.PolyCollection`. | |
| The third subplot will make regular polygons, with the same | |
| type of scaling and positioning as in the first two. | |
| The last subplot illustrates the use of ``offsets=(xo, yo)``, | |
| that is, a single tuple instead of a list of tuples, to generate | |
| successively offset curves, with the offset given in data | |
| units. This behavior is available only for the LineCollection. | |
| """ | |
| import matplotlib.pyplot as plt | |
| import numpy as np | |
| from matplotlib import collections, transforms | |
| nverts = 50 | |
| npts = 100 | |
| # Make some spirals | |
| r = np.arange(nverts) | |
| theta = np.linspace(0, 2*np.pi, nverts) | |
| xx = r * np.sin(theta) | |
| yy = r * np.cos(theta) | |
| spiral = np.column_stack([xx, yy]) | |
| # Fixing random state for reproducibility | |
| rs = np.random.RandomState(19680801) | |
| # Make some offsets | |
| xyo = rs.randn(npts, 2) | |
| # Make a list of colors cycling through the default series. | |
| colors = plt.rcParams['axes.prop_cycle'].by_key()['color'] | |
| fig, ((ax1, ax2), (ax3, ax4)) = plt.subplots(2, 2) | |
| fig.subplots_adjust(top=0.92, left=0.07, right=0.97, | |
| hspace=0.3, wspace=0.3) | |
| col = collections.LineCollection( | |
| [spiral], offsets=xyo, offset_transform=ax1.transData) | |
| trans = fig.dpi_scale_trans + transforms.Affine2D().scale(1.0/72.0) | |
| col.set_transform(trans) # the points to pixels transform | |
| # Note: the first argument to the collection initializer | |
| # must be a list of sequences of (x, y) tuples; we have only | |
| # one sequence, but we still have to put it in a list. | |
| ax1.add_collection(col, autolim=True) | |
| # autolim=True enables autoscaling. For collections with | |
| # offsets like this, it is neither efficient nor accurate, | |
| # but it is good enough to generate a plot that you can use | |
| # as a starting point. If you know beforehand the range of | |
| # x and y that you want to show, it is better to set them | |
| # explicitly, leave out the *autolim* keyword argument (or set it to False), | |
| # and omit the 'ax1.autoscale_view()' call below. | |
| # Make a transform for the line segments such that their size is | |
| # given in points: | |
| col.set_color(colors) | |
| ax1.autoscale_view() # See comment above, after ax1.add_collection. | |
| ax1.set_title('LineCollection using offsets') | |
| # The same data as above, but fill the curves. | |
| col = collections.PolyCollection( | |
| [spiral], offsets=xyo, offset_transform=ax2.transData) | |
| trans = transforms.Affine2D().scale(fig.dpi/72.0) | |
| col.set_transform(trans) # the points to pixels transform | |
| ax2.add_collection(col, autolim=True) | |
| col.set_color(colors) | |
| ax2.autoscale_view() | |
| ax2.set_title('PolyCollection using offsets') | |
| # 7-sided regular polygons | |
| col = collections.RegularPolyCollection( | |
| 7, sizes=np.abs(xx) * 10.0, offsets=xyo, offset_transform=ax3.transData) | |
| trans = transforms.Affine2D().scale(fig.dpi / 72.0) | |
| col.set_transform(trans) # the points to pixels transform | |
| ax3.add_collection(col, autolim=True) | |
| col.set_color(colors) | |
| ax3.autoscale_view() | |
| ax3.set_title('RegularPolyCollection using offsets') | |
| # Simulate a series of ocean current profiles, successively | |
| # offset by 0.1 m/s so that they form what is sometimes called | |
| # a "waterfall" plot or a "stagger" plot. | |
| nverts = 60 | |
| ncurves = 20 | |
| offs = (0.1, 0.0) | |
| yy = np.linspace(0, 2*np.pi, nverts) | |
| ym = np.max(yy) | |
| xx = (0.2 + (ym - yy) / ym) ** 2 * np.cos(yy - 0.4) * 0.5 | |
| segs = [] | |
| for i in range(ncurves): | |
| xxx = xx + 0.02*rs.randn(nverts) | |
| curve = np.column_stack([xxx, yy * 100]) | |
| segs.append(curve) | |
| col = collections.LineCollection(segs, offsets=offs) | |
| ax4.add_collection(col, autolim=True) | |
| col.set_color(colors) | |
| ax4.autoscale_view() | |
| ax4.set_title('Successive data offsets') | |
| ax4.set_xlabel('Zonal velocity component (m/s)') | |
| ax4.set_ylabel('Depth (m)') | |
| # Reverse the y-axis so depth increases downward | |
| ax4.set_ylim(ax4.get_ylim()[::-1]) | |
| plt.show() | |
| # %% | |
| # | |
| # .. admonition:: References | |
| # | |
| # The use of the following functions, methods, classes and modules is shown | |
| # in this example: | |
| # | |
| # - `matplotlib.figure.Figure` | |
| # - `matplotlib.collections` | |
| # - `matplotlib.collections.LineCollection` | |
| # - `matplotlib.collections.RegularPolyCollection` | |
| # - `matplotlib.axes.Axes.add_collection` | |
| # - `matplotlib.axes.Axes.autoscale_view` | |
| # - `matplotlib.transforms.Affine2D` | |
| # - `matplotlib.transforms.Affine2D.scale` | |