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A simple physics engine build over a PyGame simulation to model planetary orbits in space

Project description

orbital-sim

A customisable and interactive Python simulation build over PyGame that models the orbits of celestial bodies in 2D space using Newton’s law of universal gravitation!

You can choose from several included preset arrangements or create your own simulation configuration from scratch!

Precise positioning and movement vectors are obtained through built-in access to JPL’s HORIZONS system, a resource that provides precise data for objects in our solar system.

Installing

Dependencies

orbital-sim requires the following:

  • Python 3
  • Pygame
  • Astropy
  • Astroquery

User installation

orbital-sim is available as a package on PyPI and so can be easily installed for Python 3 using pip:

$ pip install orbital-sim

Usage

Once you have the package installed, you’re good to go! From here, you can either try out one of the preset configurations that come with the module, or you can delve into creating your own orbital simulation! Details for both of these are explained below.

Preset configurations


presets.py contains a number of orbital systems with all the celestial bodies already specified, so all that needs to be done is to import it, configure the simulation and get it running.

The following are the available presets and the bodies that are included in them – details to using them are right after:

Preset Description
InnerSolarSystem() The sun, Mercury, Venus, Earth and Mars
SolarSystem() The sun, Mercury, Venus, Earth, Mars, Jupiter, Saturn, Uranus, Neptune and Pluto
EarthMoon() Just the Earth and its Moon

Importing presets

In either your Python shell or a new Python file, import a specific preset configuration:

from orbitalsim.presets import PresetName

Configuring the simulation

Next, instantiate the preset simulation and pass through any parameters if you wish to do so. You can choose to leave everything to its default value by not including anything in the parentheses:

# A preset with default settings
s = PresetName()

Or manually set any or all of the following parameters:

  • dimensions – a tuple (x, y) of the desired width and height
  • scale – the number of pixels represented by a distance of 1 AU in the simulation
  • entity_scale – magnification of an entity’s diameter
  • sim_rate – the number of days that pass in the simulation for every second in real-life
  • start_date – the date to start the simulation from, in format yyyy-mm-dd
  • fullscreen – a boolean for whether the window should be fullscreen or not

Tip: go to Setting up a custom simulation to find out more about these parameters.

For example:

# A preset with all its parameters tweaked
s = PresetName(
    dimensions = (500, 700),
    scale = 250,
    entity_scale = 5,
    sim_rate = 3,
    start_date = '2020-07-12'
    fullscreen = True
)

Running the simulation

Once the simulation has been instantiated, to create the PyGame window and start the simulation, just call its start() function:

s.start()

Controlling the simulation


Once the simulation starts, there are a number of ways to control and interact with it:

Key(s) Action(s)
SPACE Pause/play simulation
↑ ↓ ← ↑ Move window view; pan about
+/- Zoom in and out respectively
r Reset zoom and position
./, Speed up and slow down the simulation respectively
l Toggle labels on the entities
q Quit the simulation

Setting up a custom simulation


By setting up a custom simulation, you have control over exactly what entities to add and where. You can either select existing entities in our solar system through JPL HORIZONS or create entities with custom details and characteristics.

The next few sections will detail how you may go about getting a custom simulation up and running using orbital-sim.

I. Instantiate simulation

First, we need to create a blank simulation that we then add stuff to. This is done by creating an instance of the Simulation class. Just like with the preset configurations, you can use the default parameters by not specifying them, or change certain ones to taste, up to you.

import orbitalsim
s = orbitalsim.Simulation()

Parameters of the Simulation class:

Parameter Default value Description
dimensions (800, 800) A tuple of the width and height of the window in pixels
scale -1 The number of pixels represented by a distance of 1 AU in the simulation (default of -1: automatically calculated)
entity_scale 10 Magnification of an entity’s diameter for better visibility
sim_rate 3 The number of days that pass in the simulation for every second in real-life
start_date None =today The date to start the simulation from in format yyyy-mm-dd (note: if left blank, defaults to the current day
fullscreen False Boolean for whether the PyGame window is fullscreen or not (note: fullscreen mode overrides dimensions parameter

Note: PyGame will often encounter framerate issues on certain devices like the Retina MacBooks. If you encounter this, setting fullscreen = True will help.

II. Adding entities using JPL HORIZONS

JPL HORIZONS assigns a unique ID to every object in the solar system that it tracks. You can search up entities and find their ID on JPL HORIZON’s web interface by looking up a target body by keyword. (While it is possible to refer to objects by name, this can sometimes be ambiguous due to multiple object names containing the same word)

To add an entity that exists in the JPL HORIZONS system to the simulation, we’ll use the add_horizons_entity function of the Simulation object we just created. The function takes in two IDs: entity_id is the entity to add, observer_id is the reference point from where the position of entity_id will be calculated relative to.

Important: when generating the simulation, all entity positions are calculated from the centre of the screen (0, 0). Therefore, it is recommended that entities are added in relation to the same observer to ensure the distances aren’t off.

For example, the following snippet adds the entity with an ID of 3 (which happens to be Earth), with its distance calculated in relation to the sun (approximately 1 AU by definition).

s.add_horizons_entity(
    entity_id = '3',
    observer_id = 'sun',
    mass = 6e24,
    diameter = 8.5e-5
)

Parameters to the add_horizons_entity function:

Parameter Default value Description
entity_id required JPL HORIZONS ID of the entity to add
observer_id required JPL HORIZONS ID of the reference point from where the position and velocity of entity_id is calculated from (if entity_id and observer_id are the same, the object will be rendered at the centre of the screen 0,0)
mass required Mass in kg of the entity to add (mass is not provided by JPL HORIZONS, so it has to be added manually)
diameter 1e-5 Diameter in AU of the entity to add (optional – only used for correct rendering of size)

III. Adding custom entities

You can also add a fully custom entity with the function add_custom_entity. With this function, you give the entity its position, movement vectors and physical characteristics.

s.add_custom_entity(
    position = (1, -0.5),
    mass = 2e24,
    speed = 0.2,
    angle = 3/2 * math.pi,
    name = 'some planet'
)

Some parameters are optional but some are required. See the table below for more information.

Parameter Default value Description
position required Tuple (x, y) describing the distance in AU from the centre of the system (0, 0)
mass required Mass of the entity in kg
speed 0 Magnitude of initial velocity in AU/day
angle 0 Angle of initial velocity in radians
diameter 1e-5 Diameter of the entity in AU
e 0 (if applicable) Eccentricity of the orbit from 0-1
a None (if applicable) Semi-major axis of the orbit in AU
name '' A string for the entity's label name

IV. Running the simulation

Once everything has been setup, call the start function of the simulation object to begin the simulation.

s.start()

That's it! That's all there is to getting a custom simulation up and running!

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