Welcome!

python-ternary

This is a plotting library for use with matplotlib to make ternary plots plots in the two dimensional simplex projected onto a two dimensional plane.

The library provides functions for plotting projected lines, curves (trajectories), scatter plots, and heatmaps. There are several examples and a short tutorial below.

Some ternary functions expect the simplex to be partititioned into some number of steps, determined by the scale parameter. A few functions will do this partitioning automatically for you, but when working with real data or simulation output, you may have partitioned already. If you are working with probability distributions, just use scale=1 (the default). Otherwise the scale parameter effectively controls the resolution of many plot types (e.g. heatmaps).

Gallery

Installation

Anaconda

You can install python-ternary with conda:

conda config --add channels conda-forge
conda install python-ternary

See here for more information.

Pip

You can install the current release (1.0) with pip (you may need to use sudo):

    pip install python-ternary

With setup.py

Alternatively you can clone the repository and run setup.py in the usual manner:

    git clone git@github.com:marcharper/python-ternary.git
    cd python-ternary
    sudo python setup.py install

New features are still being added to python-ternary. The master branch should generally be stable enough for most purposes.

Usage, Examples, Plotting Functions

You can explore some of these examples with this Jupyter notebook.

The easiest way to use python-ternary is with the wrapper class TernaryAxesSubplot, which mimics Matplotlib's AxesSubplot. Start with

    figure, tax = ternary.figure()

With a ternary axes object tax you can use many of the usual matplotlib axes object functions:

    tax.set_title("Scatter Plot", fontsize=20)
    tax.scatter(points, marker='s', color='red', label="Red Squares")
    tax.legend()

Most drawing functions can take standard matplotlib keyword arguments such as linestyle and linewidth. You can use LaTeX in titles and labels.

If you need to act directly on the underyling matplotlib axes, you can access them:

    ax = tax.get_axes()

You can also wrap a Matplotlib AxesSubplot object:

    figure, ax = pyplot.subplots()
    tax = ternary.TernaryAxesSubplot(ax=ax)

This is useful if you want to use ternary as part of another figure, such as

    from matplotlib import pyplot, gridspec

    pyplot.figure()
    gs = gridspec.GridSpec(2,2)
    ax = pyplot.subplot(gs[0,0])
    figure, tax = ternary.figure(ax=ax)
    ...

TernaryAxesSubplot objects keep track of the scale, axes, and other parameters, supplying them as needed to other functions.

Simplex Boundary and Gridlines

The following code draws a boundary for the simplex and gridlines.

    import ternary

    ## Boundary and Gridlines
    scale = 40
    figure, tax = ternary.figure(scale=scale)

    # Draw Boundary and Gridlines
    tax.boundary(linewidth=2.0)
    tax.gridlines(color="black", multiple=5)
    tax.gridlines(color="blue", multiple=1, linewidth=0.5)

    # Set Axis labels and Title
    fontsize = 20
    tax.set_title("Simplex Boundary and Gridlines", fontsize=fontsize)
    tax.left_axis_label("Left label $\\alpha^2$", fontsize=fontsize)
    tax.right_axis_label("Right label $\\beta^2$", fontsize=fontsize)
    tax.bottom_axis_label("Bottom label $\\Gamma - \\Omega$", fontsize=fontsize)

    # Set ticks
    tax.ticks(axis='lbr', linewidth=1)

    # Remove default Matplotlib Axes
    tax.clear_matplotlib_ticks()

    ternary.plt.show()

Drawing lines

You can draw individual lines between any two points with line and lines parallel to the axes with horizonal_line, left_parallel_line, and right_parallel_line:

    import ternary

    scale = 40
    figure, tax = ternary.figure(scale=scale)

    # Draw Boundary and Gridlines
    tax.boundary(linewidth=2.0)
    tax.gridlines(color="blue", multiple=5)

    # Set Axis labels and Title
    fontsize = 20
    tax.set_title("Various Lines", fontsize=20)
    tax.left_axis_label("Left label $\\alpha^2$", fontsize=fontsize)
    tax.right_axis_label("Right label $\\beta^2$", fontsize=fontsize)
    tax.bottom_axis_label("Bottom label $\\Gamma - \\Omega$", fontsize=fontsize)

    # Draw lines parallel to the axes
    tax.horizontal_line(16)
    tax.left_parallel_line(10, linewidth=2., color='red', linestyle="--")
    tax.right_parallel_line(20, linewidth=3., color='blue')
    # Draw an arbitrary line, ternary will project the points for you
    p1 = (12,8,10)
    p2 = (2, 26, 2)
    tax.line(p1, p2, linewidth=3., marker='s', color='green', linestyle=":")

    tax.ticks(axis='lbr', multiple=5, linewidth=1)

    tax.show()

The line drawing functions accept the matplotlib keyword arguments of Line2D.

Curves

Curves can be plotted by specifying the points of the curve, just like matplotlib's plot. Simply use:

    ternary.plot(points)

Points is a list of tuples or numpy arrays, such as [(0.5, 0.25, 0.25), (1./3, 1./3, 1./3)],

    import ternary

    ## Sample trajectory plot
    figure, tax = ternary.figure(scale=1.0)
    tax.boundary()
    tax.gridlines(multiple=0.2, color="black")
    tax.set_title("Plotting of sample trajectory data", fontsize=20)
    points = []
    # Load some data, tuples (x,y,z)
    with open("sample_data/curve.txt") as handle:
        for line in handle:
            points.append(list(map(float, line.split(' '))))
    # Plot the data
    tax.plot(points, linewidth=2.0, label="Curve")
    tax.legend()
    tax.show()

There are many more examples in this paper.

You can also color the curves with a Matplotlib heatmap using:

    plot_colored_trajectory(points, cmap="hsv", linewidth=2.0)

Scatter Plots

Similarly, ternary can make scatter plots:

    import ternary

    ### Scatter Plot
    scale = 40
    figure, tax = ternary.figure(scale=scale)
    tax.set_title("Scatter Plot", fontsize=20)
    tax.boundary(linewidth=2.0)
    tax.gridlines(multiple=5, color="blue")
    # Plot a few different styles with a legend
    points = random_points(30, scale=scale)
    tax.scatter(points, marker='s', color='red', label="Red Squares")
    points = random_points(30, scale=scale)
    tax.scatter(points, marker='D', color='green', label="Green Diamonds")
    tax.legend()
    tax.ticks(axis='lbr', linewidth=1, multiple=5)

    tax.show()

Heatmaps

Ternary can plot heatmaps in two ways and three styles. Given a function, ternary will evaluate the function at the specified number of steps (determined by the scale, expected to be an integer in this case). The simplex can be split up into triangles or hexagons and colored according to one of three styles:

• Triangular -- triangular: coloring triangles by summing the values on the vertices
• Dual-triangular -- dual-triangular: mapping (i,j,k) to the upright triangles △ and blending the neigboring triangles for the downward triangles ▽
• Hexagonal -- hexagonal: which does not blend values at all, and divides the simplex up into heaxagonal regions

The two triangular heatmap styles and the hexagonal heatmap style can be visualized as follows. The dual-triangular style plots the true values on the upright triangles, mapping ternary coordinates to upright triangles otherwise. The triangular style maps ternary coordinates to vertices and computes the triangle color based on the values at the vertices.

Thanks to chebee7i for the above images.

Let's define a function on the simplex for illustration, the Shannon entropy of a probability distribution:

    def shannon_entropy(p):
        """Computes the Shannon Entropy at a distribution in the simplex."""
        s = 0.
        for i in range(len(p)):
            try:
                s += p[i] * math.log(p[i])
            except ValueError:
                continue
        return -1.*s

We can get a heatmap of this function as follows:

    import ternary
    scale = 60

    figure, tax = ternary.figure(scale=scale)
    tax.heatmapf(shannon_entropy, boundary=True, style="triangular")
    tax.boundary(linewidth=2.0)
    tax.set_title("Shannon Entropy Heatmap")

    tax.show()

In this case the keyword argument boundary indicates whether you wish to evaluate points on the boundary of the partition (which is sometimes undesirable). Specify style="hexagonal" for hexagons. Large scalings can use a lot of RAM since the number of polygons rendered is O(n^2).

You may specify a matplotlib colormap (an instance or the colormap name) in the cmap argument.

Ternary can also make heatmaps from data. In this case you need to supply a dictionary mapping (i, j) or (i, j, k) for i + j + k = scale to a float as input for a heatmap. It is not necessary to include k in the dictionary keys since it can be determined from scale, i, and j. This reduces the memory requirements when the partition is very fine (significant when scale is in the hundreds).

Make the heatmap as follows:

    ternary.heatmap(data, scale, ax=None, cmap=None)

or on a TernaryAxesSubplot object

    tax.heatmap(data, cmap=None)

This can produces images such as:

There is a large set of heatmap examples here.

Axes Ticks and Orientations

For a given ternary plot there are two valid ways to label the axes ticks corresponding to the clockwise and counterclockwise orientations. However note that the axes labels need to be adjusted accordingly, and ternary does not do so automatically when you pass clockwise=True to tax.ticks().

There is a more detailed discussion on issue #18 (closed).

RGBA colors

You can alternatively specify colors as rgba tuples (r,g,b,a) (all between zero and one). To use this feature, pass colormap=False to heatmap() so that the library will not attempt to map the tuple to a value with a matplotlib colormap. Note that this disables the inclusion of a colorbar. Here is an example:

    import math
    from matplotlib import pyplot
    import ternary

    def color_point(x, y, z, scale):
        w = 255
        x_color = x * w / float(scale)
        y_color = y * w / float(scale)
        z_color = z * w / float(scale)
        r = math.fabs(w - y_color) / w
        g = math.fabs(w - x_color) / w
        b = math.fabs(w - z_color) / w
        return (r, g, b, 1.)

    def generate_heatmap_data(scale=5):
        from ternary.helpers import simplex_iterator
        d = dict()
        for (i, j, k) in simplex_iterator(scale):
            d[(i, j, k)] = color_point(i, j, k, scale)
        return d

    scale = 80
    data = generate_heatmap_data(scale)
    figure, tax = ternary.figure(scale=scale, permutation="210")
    tax.heatmap(data, style="hexagonal", colormap=False) # Allow colors as rgba tuples
    tax.boundary()
    tax.set_title("RGBA Heatmap")
    pyplot.show()

This produces the following image:

Unittests

You can run the test suite as follows:

python -m unittest discover tests

The included script of examples is intended to act as a series of extended tests.

Contributing

Contributions are welcome! Please share any nice example plots, contribute features, and add unit tests! Use the pull request and issue systems to contribute.

Citation

Please cite as follows:

Marc Harper et al.. (2015). python-ternary: Ternary Plots in Python. Zenodo. 10.5281/zenodo.34938

Recent Usage in Publications:

• pyIAST: Ideal adsorbed solution theory (IAST) Python package by Cory Simon

Contributors

• Marc Harper marcharper
• Bryan Weinstein btweinstein: Hexagonal heatmaps, colored trajectory plots
• chebee7i: Docs and figures, triangular heatmapping
• Cory Simon: Axis Colors, colored heatmap example

Known-Issues

There appears to be an issue with anaconda on macs that causes the axes labels not to render. The workaround is to manually call

tax._redraw_labels()

before showing or rendering the image.