The most comprehensive collection of accurate astronomical algorithms (AA) in JavaScript (TypeScript).
The v3 offered arbitrary-precision computations, thanks to decimal.js. But it was thousands (if not millions) of times slower than the original implementation, making its usage in a browser very difficult. After some nightly hours to optimise it and having most of both implementations side-by-side, we decided to remove decimal.js entirely.
Other AA implementations: Swift (SwiftAA), C# (AASharp).
At the beginning, aa-js
is the port in javascript of the C++ implementation of Astronomical
Algorithms by J.P. Naughter, called AA+,
based on the reference text book by Jean Meeus. It is written in TypeScript, and
covered as much as possible with tests validating the correctness
of the algorithms. Tests are inspired from Jean Meeus' book and those written in
SwiftAA, and are much more extended than what is available
in AA+.
aa-js
is the backbone of scientific algorithms used
in Arcsecond.io.
No big API changes, except there are no more Decimal.js at all, and thus no highPrecision
parameter. The method
signatures have not changed, but all return types are based on number
.
Small changes:
- The return type of
getJulianDay
is now alwaysJulianDay
and notJulianDay | undefined
. If really the build of a JD is not correct,J2000
is returned with a warning.
All algorithms based on arbitrary-precision operations thanks to decimal.js.-
BREAKING (since v3.2) Equatorial coordinates uses right ascension expressed in
Degree
notHour
. -
BREAKING (since v3.2) Input parameters of the
coordinates
modules now use complete coordinates objects, rather than individual members to reduce the number of parameters in the functions. BREAKING (since v3.4) The precision of Decimal.js is not set to a default value. It is left to the consumer.- Moved all (non-Earth) planets modules inside a
planets
folder. - Addition of numerous orbital getters for planets (mean longitude, semi-major axis, inclination, eccentricity...)
- Much easier and cleaner distinction between heliocentric and geocentric coordinates of planets.
- Added easy accessor for apparent geocentric equatorial coordinates of planets.
- Added a transformation from equatorial to topocentric coordinates.
- Important bugfix on
getPositionAngle
andgetPhaseAngle
in theMoon
module. - Added easy accessors for rise, transit and set times for every planet.
- Numerous bugfixes, and added methods for dates, julian days
- Planets: all the (static and dynamic) details, coordinates, quantities about
Mercury
,Venus
,Mars
,Jupiter
,Saturn
,Neptune
and of coursePluto
: planet constants, aphelion, perihelion, phase angle, illuminated fraction, magnitude, semi-diameters, heliocentric & geocentric coordinates, distance from earth, velocities, orbital details etc. - In addition, for
Mars
: the planetocentric declination of the Sun and the Earth. - In addition, for
Jupiter
: the planetocentric declination of the Sun and the Earth. - In addition, for
Saturn
: the details of the rings system. -
Sun
: mean & true anomaly, coordinates. -
Earth
: all the coordinates, mean anomaly, radius vector (distance) etc. - Inside
Earth
module:nutation
: in longitude, for obliquity, true & mean obliquity of the ecliptic. - Inside
Earth
module:aberration
: ecliptic and equatorial. -
Earth.Moon
: phases, age, apparent coordinates etc. -
juliandays
: creation, transformation, local mean sidereal time. -
times
: transformation between UTC, TT, AI, UT1... -
cosmology
: the cosmology calculator from Ned Wright's, but re-implemented, and tested. -
distances
: all the conversions of small and extra-galactic distances. -
coordinates
: all computation of parallactic angle, great circle angle, precessions, transformations (equatorial to ecliptic, galactic, topocentric, and inverse etc.). -
sexagesimal
: utilities for transforming values between decimal and sexagesimal. -
risetransitset
: get rise, transit and set hours, dates, julian days, as well as altitude. -
exoplanets
: WIP module to hold exoplanet transit details calculations. as altitude.
npm install aa-js
import { juliandays, Earth } from 'aa-js'
const jd = juliandays.getJulianDay(new Date())
const coords = Earth.Moon.getEquatorialCoordinates(jd)
Almost every method is documented (quite sparingly sometimes). A good knowledge of basic astronomy helps very much. A copy of the Astronomical Algorithms textbook, by Jean Meeus (amazon) would also help, since many methods refer to it.
The documentation is published in onekiloparsec.dev/aa-js.
To run benchmarks, install vite-node
globally (npm i -g vite-node
), then run
individual benchmark like this:
npx vite-node benchmark/planets/jupiter/apparent-equatorial-coordinates.js