The Orbitronomy library offers the functionality for plotting, calculating, visualizing, and animating the orbits of various celestial bodies in 3D space. It utilizes Kepler's elliptical orbit equations along with PyAstronomy for orbital calculations, and Matplotlib for 3D plotting.
Project description
Official Orbitronomy Library
The Orbitronomy library offers the functionality for plotting, calculating, visualizing, and animating the orbits of various celestial bodies in 3D space. It utilizes Kepler's elliptical orbit equations along with PyAstronomy for orbital calculations, and Matplotlib for 3D plotting.
SimpleOrbit Class
The SimpleOrbit class provides the capability of simulating single object orbits, and multiple object orbits in the format of a list within list.
Constructor
SimpleOrbit(plot_title, name)
Parameters:
plot_title: Title for the plot.name: Identifier for the celestial body.
Methods
faceColor(color): Sets the face color of the axes.paneColor(color): Sets the color of the 3D panes.gridColor(color): Sets the grid color.orbitTransparency(value): Sets the transparency of the orbits.labelColor(color): Sets the color of axis labels.tickColor(color): Sets the color of axis ticks.plotStyle(background_color): Sets the background style of the plot.semiMajorAxis(value),perihelion(value),eccentricity(value),inclination(value),longitudeOfAscendingNode(value),argumentOfPerihelion(value): Set specific orbital parameters.
Usage Example:
from orbitronomy.orbitCalcs import SimpleOrbit
test = SimpleOrbit(plot_title="Test", name="Earth")
# Styling
test.faceColor("black")
test.paneColor("black")
test.gridColor("#222831")
test.orbitTransparency(0.5)
test.labelColor("white")
test.tickColor("white")
test.plotStyle(background_color="dark_background")
# the form of the "data" list should be as follows:
# "name", semi_major_axis, perihelion, eccentricity, inclination, longitude_of_ascending_node, argument_of_perihelion, color (optional)
data = [["object1", 1, 0.983289891, 0.01671123, 15, 0, 0, "green"], ["object2", 1.5, 0.483289891, 0.02671123, 6, 0, 0, "yellow"], ["object3", 1.3, 0.683289891, 0.01671123, 2, 0, 0, "red"]]
#you can also use the following instead of "data" array if you want to plot a single object
# test.semiMajorAxis(1)
# test.perihelion(0.983289891)
# test.eccentricity(0.01671123)
# test.inclination(0)
# test.longitudeOfAscendingNode(0)
# test.argumentOfPerihelion(0)
# Calculating and plotting orbits
test.calculateOrbit(plot_steps=1000, n_orbits=1, data=data, trajectory=True, sun=True)
#you can choose if you want to set boundaries for the plot
# test.xLim([20, 20])
# test.yLim([20, 20])
# test.zLim([0.1, 0.1])
# Setting axis labels
test.xLabel("X-Axis")
test.yLabel("Y-Axis")
test.zLabel("Z-Axis")
# Animating the orbits
test.animateOrbit(dpi=250, save=False, export_zoom=3, font_size="xx-small", export_folder="results")
Orbitronomy Library with Dataset Functionality
The Orbitronomy library is enhanced with functionality to calculate, visualize, plot, and animate orbits of celestial bodies in 3D using datasets. It utilizes Kepler's elliptical orbit equations, PyAstronomy for orbital calculations, and Matplotlib for 3D plotting.
datasetOrbit Class
The datasetOrbit class extends the capabilities of the SimpleOrbit class, allowing for the use of datasets to plot multiple celestial bodies.
Constructor
datasetOrbit(plot_title, name)
Parameters:
plot_title: Title for the plot.name: Identifier for the celestial body or simulation.
Styling Methods
faceColor(color)paneColor(color)gridColor(color)orbitTransparency(value)labelColor(color)tickColor(color)datasetPlotStyle(background_color)
Dataset Configuration
columnSemiMajorAxis(column_name)columnPerihelion(column_name)columnEccentricity(column_name)columnInclination(column_name)columnLongitudeOfAscendingNode(column_name)columnArgumentOfPerihelion(column_name)columnColor(column_name)columnName(column_name)fileName(file_name)
Orbit Calculation and Animation
datasetCalculateOrbit(plot_steps, n_orbits, color, trajectory, sun, random_color)xLim(lim), yLim(lim), zLim(lim)xLabel(label), yLabel(label), zLabel(label)datasetAnimateOrbit(dpi, save, export_zoom, font_size, export_folder)
Usage Example:
from orbitronomy.datasetOrbit import datasetOrbit
test = datasetOrbit(plot_title="Test", name="Earth")
# Styling
test.faceColor("black")
test.paneColor("black")
test.gridColor("#222831")
test.orbitTransparency(0.5)
test.labelColor("white")
test.tickColor("white")
test.datasetPlotStyle(background_color="dark_background")
# Dataset column configuration
test.columnSemiMajorAxis("semi_major_axis")
test.columnPerihelion("perihelion")
test.columnEccentricity("eccentricity")
test.columnInclination("inclination")
test.columnLongitudeOfAscendingNode("longitude_of_ascending_node")
test.columnArgumentOfPerihelion("argument_of_perihelion")
test.columnColor("color")
test.columnName("name")
# Specifying the dataset file name
test.fileName("datasets/Planetary-Satellite-Data.csv")
# Calculating and plotting orbits from the dataset
test.datasetCalculateOrbit(plot_steps=1000, n_orbits=12, color="yellow", random_color=True, trajectory=True, sun=True)
#you can choose if you want to set boundaries for the plot
# test.xLim([20, 20])
# test.yLim([20, 20])
# test.zLim([0.1, 0.1])
# Setting axis labels
test.xLabel("X-Axis")
test.yLabel("Y-Axis")
test.zLabel("Z-Axis")
# Animating the orbits
test.datasetAnimateOrbit(dpi=250, save=False, export_zoom=3, font_size="xx-small")
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