Creating a 3D perspective image

Create 3-D perspective image or surface mesh from a grid using pygmt.Figure.grdview.

Note

This tutorial assumes the use of a Python notebook, such as IPython or Jupyter Notebook. To see the figures while using a Python script instead, use fig.show(method="external") to display the figure in the default PDF viewer.

To save the figure, use fig.savefig("figname.pdf") where "figname.pdf" is the desired name and file extension for the saved figure.

import pygmt

# Load sample earth relief data
grid = pygmt.datasets.load_earth_relief(resolution="10m", region=[-108, -103, 35, 40])

Out:

grdcut [NOTICE]: Remote data courtesy of GMT data server OCEANIA [https://oceania.generic-mapping-tools.org]
grdcut [NOTICE]: Earth Relief at 10x10 arc minutes from Gaussian Cartesian filtering (18 km fullwidth) of SRTM15+V2.1 [Tozer et al., 2019].
grdcut [NOTICE]:   -> Download grid file [3.0M]: earth_relief_10m_p.grd

The pygmt.Figure.grdview method takes the grid input. The perspective parameter changes the azimuth and elevation of the viewpoint; the default is [180, 90], which is looking directly down on the figure and north is “up”. The zsize parameter sets how tall the three-dimensional portion appears.

The default grid surface type is mesh plot.

fig = pygmt.Figure()
fig.grdview(
    grid=grid,
    # Sets the view azimuth as 130 degrees, and the view elevation as 30 degrees
    perspective=[130, 30],
    # Sets the x- and y-axis labels, and annotates the west, south, and east axes
    frame=["xa", "ya", "WSnE"],
    # Sets a Mercator projection on a 15-centimeter figure
    projection="M15c",
    # Sets the height of the three-dimensional relief at 1.5 centimeters
    zsize="1.5c",
)
fig.show()
3d perspective image

Out:

<IPython.core.display.Image object>

The grid surface type can be set with the surftype parameter. The default CPT is turbo and can be customized with the cmap parameter.

fig = pygmt.Figure()
fig.grdview(
    grid=grid,
    perspective=[130, 30],
    frame=["xa", "yaf", "WSnE"],
    projection="M15c",
    zsize="1.5c",
    # Set the surftype to "surface"
    surftype="s",
    # Set the CPT to "geo"
    cmap="geo",
)
fig.show()
3d perspective image

Out:

<IPython.core.display.Image object>

The plane parameter sets the elevation and color of a plane that provides a fill below the surface relief.

fig = pygmt.Figure()
fig.grdview(
    grid=grid,
    perspective=[130, 30],
    frame=["xa", "yaf", "WSnE"],
    projection="M15c",
    zsize="1.5c",
    surftype="s",
    cmap="geo",
    # Set the plane elevation to 1,000 meters and make the fill "gray"
    plane="1000+ggray",
)
fig.show()
3d perspective image

Out:

<IPython.core.display.Image object>

The perspective azimuth can be changed to set the direction that is “up” in the figure. The contourpen parameter sets the pen used to draw contour lines on the surface. pygmt.Figure.colorbar can be used to add a color bar to the figure. The cmap parameter does not need to be passed again. To keep the color bar’s alignment similar to the figure, use True as the perspective parameter.

fig = pygmt.Figure()
fig.grdview(
    grid=grid,
    # Set the azimuth to -130 (230) degrees and the elevation to 30 degrees
    perspective=[-130, 30],
    frame=["xaf", "yaf", "WSnE"],
    projection="M15c",
    zsize="1.5c",
    surftype="s",
    cmap="geo",
    plane="1000+ggrey",
    # Set the contour pen thickness to "0.1p"
    contourpen="0.1p",
)
fig.colorbar(perspective=True, frame=["a500", "x+lElevation", "y+lm"])
fig.show()
3d perspective image

Out:

<IPython.core.display.Image object>

Total running time of the script: ( 0 minutes 8.548 seconds)

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