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orb is a library for simple orbital mechanics

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orb

orb offers a few simple methods for several common problems of orbital mechanics, like transformations between various coordinate systems and simple orbit propagation using Keplerian elements.

npm version Build Status

Installation

npm install orbjs

Usage

ES5 - CommonJS

var orb = require('orbjs');

ES6

import orb from 'orbjs';

ES5 - Browser

<script src="dist/orb.min.js"></script>

API

orb.constants

# orb.constants.common

# orb.constants.time

# orb.constants.earth

# orb.constants.earth.wgs84

# orb.constants.earth.grs80

orb.common

# orb.common.deg2rad(deg) Converts degree to radian

# orb.common.rad2deg(rad) Converts radian to degree

orb.time

# orb.time.JDtoMJD(jd) JD to MJD [days]

# orb.time.MJDtoJD(mjd) MJD to JD [days]

# orb.time.TAItoTT(tai) TAI to TT

# orb.time.TTtoTAI(tt) TT to TAI

# orb.time.TAItoUTC(tai) TAI to UTC

# orb.time.UTCtoTAI(utc) UTC to TAI

# orb.time.TAItoGPS(tai) TAI to GPS

# orb.time.GPStoTAI(gps) GPS to TAI

# orb.time.UTCtoGPS(utc) UTC to GPS

# orb.time.GPStoUTC(gps) GPS to UTC

# orb.time.leapSeconds(date) Amount of leap seconds that occurred before date. date is a JS Date object.

# orb.time.dateToJD(date) Convert a date to Julian Date. date is either a Date object, or an array of the form [Y, M, D, h, m, s, ms].

orb.transformations

# orb.transformations.sphericalToCartesian(x)

  • Input:
    • x: [λ, φ, r] Spherical (longitude, (geocentric) latitude, radius)
  • Output:
    • x: [x, y, z] Cartesian

# orb.transformations.cartesianToSpherical(x)

  • Input:
    • x: [x, y, z] Cartesian
  • Output:
    • x: [λ, φ, r] Spherical (longitude, (geocentric) latitude, radius)

# orb.transformations.ellipsoidalToCartesian(x, a, e)

  • Input:
    • x: [L, β] Ellipsoidal (longitude, reduced latitude)
    • a: semimajor-axis of body
    • e: eccentricity of body
  • Output:
    • x: [x, y, z] Cartesian

# orb.transformations.cartesianToEllipsoidal(x, a, e)

  • Input:
    • x: [x, y, z] Cartesian
    • a: semimajor-axis of body
    • e: eccentricity of body
  • Output:
    • x: [L, β] Ellipsoidal (longitude, reduced latitude)

# orb.transformations.geodeticToCartesian(x, a, e)

  • Input:
    • x: [L, B, h] Geodetic (longitude, geodetic latitude, height above ellipsoid)
    • a: semimajor-axis of body
    • e: eccentricity of body
  • Output:
    • x: [x, y, z] Cartesian

# orb.transformations.cartesianToGeodetic(x, a, e)

  • Input:
    • x: [x, y, z] Cartesian
    • a: semimajor-axis of body
    • e: eccentricity of body
  • Output:
    • x: [L, B, h] Geodetic (longitude, geodetic latitude, height above ellipsoid)

# orb.transformations.orbitalPlaneToInertial(x, Ω, ω, i)

  • Input:
    • x: [x, y] Position of object in orbital plane
    • Ω: right ascension of the ascending node
    • ω: argument of periapsis
    • i: inclination
  • Output:
    • x: [x, y, z] Inertial

# orb.transformations.inertialToFixed(x, α, axis)

  • Input:
    • x: [x, y, z] Inertial
    • α: angle between the inertial and fixed systems
    • axis: 1, 2 or 3
  • Output:
    • x: [x, y, z] Fixed

# orb.transformations.fixedToInertial(x, α, axis)

  • Input:
    • x: [x, y, z] Fixed
    • α: angle between the fixed and inertial systems
    • axis: 1, 2 or 3
  • Output:
    • x: [x, y, z] Inertial

# orb.transformations.fixedToTopocentric(x, obs, a, e, nwu)

  • Input:
    • x: [x, y, z] Fixed
    • obs: [L, B, h]
    • a: semimajor-axis of body
    • e: eccentricity of body
  • Output:
    • x: [x, y, z] Topocentric

# orb.transformations.topocentricToFixed(x, obs, a, e, nwu)

  • Input:
    • x: [x, y, z] Topocentric
    • obs: [L, B, h]
    • a: semimajor-axis of body
    • e: eccentricity of body
  • Output:
    • x: [x, y, z] Fixed

# orb.transformations.topocentricToHorizontal(x)

  • Input:
    • x: [x, y, z] Topocentric
  • Output:
    • x: [azimuth, elevation, distance] Horizontal

# orb.transformations.horizontalToTopocentric(x)

  • Input:
    • x: [azimuth, elevation, distance] Horizontal
  • Output:
    • x: [x, y, z] Topocentric

orb.position

# orb.position.keplerEquation(e, M)

  • Input:
    • e: eccentricity
    • M: mean anomaly
  • Output:
    • ν: true anomaly

# orb.position.keplerian(a, e, i, Ω, ω, t, t0, M0, m1, m2)

  • Input:
    • a: semimajor-axis of orbit
    • e: eccentricity
    • i: inclination
    • Ω: right ascension of the ascending node
    • ω: argument of periapsis
    • t: time t
    • t0: epoch of given elements
    • M0: mean anomaly at epoch (optional, default: 0)
    • m1: mass of body 1 (optional, default: GM = orb.constants.earth.GM)
    • m2: mass of body 2 (optional, default: 0)
  • Output:
    • [ x, xDot ]
      • x: [x, y, z] Position in inertial CRS
      • xDot: [vx, vy, vz] Velocity in inertial CRS

# orb.position.stateToKepler(x, xDot, t, m1, m2)

  • Input:
    • x: [x, y, z] Position in inertial CRS
    • xDot: [vx, vy, vz] Velocity in inertial CRS
    • t: time t
    • m1: mass of body 1 (optional, default: GM = orb.constants.earth.GM)
    • m2: mass of body 2 (optional, default: 0)
  • Output:
    • [a, e, i, Ω, ω, T0]
      • a: semimajor-axis of orbit (or focal parameter for e = 1)
      • e: eccentricity
      • i: inclination
      • Ω: right ascension of the ascending node
      • ω: argument of periapsis
      • T0: time of perihelion passage

orb.functions

# orb.functions.era(days)

  • Input:
    • days: UT1 days since J2000.0
  • Output:
    • era: ERA (radians)

orb.vector

Common vector and matrix operations, these are only included to make dependencies unnecessary. Don’t use these, there are a lot of better, more comprehensive and well tested libraries to do this.

License

MIT

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orb is a library for simple orbital mechanics

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