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observerly's lightweight, zero-dependency, type safe astrometry library written in TypeScript. This library can be used to ascertain to positions of the Sun, Moon and the planets, as well as ascertain transit times for any astronomical object.

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@observerly/astrometry


Introduction

🔭 astrometry is observerly's lightweight, zero-dependency*, type safe astrometry library written in TypeScript. It is aimed to be easy to use, and malleable to your usage, for amateur-astronomers and the general astronomy community to understand how positional astronomy works on a soft high-level.

The key tenants of the library is to use as JavaScript primatives. The notion of the JavaScript Date is relied upon heavily and we do not rely on, or enforce reliance on, any third-party datetime or timezone related libraries. This is to ensure that the library can be used in any environment, and that the user can supplement usage with their own datetime libraries of choice, if required.

The second key tenant, is that all coordinates are required to be in degrees for mathematical calculations, and, importantly, in the standard ICRS epoch J2000.

N.B. This project is currently in the early stages of development and is not yet ready for production use. As it is still in the early stages of development, the API is subject to change.

Features

It can be used to calculate the horizontal position of the sun, moon, planets, and stars in the sky at a given time and location. You can convert any equatorial coordinate to horizontal coordinate, for any given time and location.

It can apply corrections for atmospheric refraction, parallax, nutation and aberration for epoch J2000 coordinates.

It can calculate the rise, transit, and set times of the sun, moon, and planets, as well as for any astronomical bodies.

It can calculate the phase, elongation, and angular size of the moon.

It can calculate horizontal altitude and the associated airmass of an object given a location and time.

Usage

Installation

You can install astrometry using your favorite package manager:

npm install @observerly/astrometry

or

yarn add @observerly/astrometry
pnpm add @observerly/astrometry

Documentation

TBD

Common Usage Examples

For all of the below examples, an "observer" at Manua Kea, Hawaii, US on the 14th May 2021 is assumed:

Setup

// For these examples we need to specify a date because most calculations are
// differential w.r.t a time component. We set it to the author's birthday:
export const datetime = new Date('2021-05-14T00:00:00.000+00:00')

// For example we will fix the latitude to be Manua Kea, Hawaii, US
export const latitude = 19.820611

// For example we will fix the longitude to be Manua Kea, Hawaii, US:
export const longitude = -155.468094

To find the horizontal coordinate of, e.g., the star Betelgeuse, at a given time and location:

Horizontal Position of Betelgeuse

import { type EquatorialCoordinate, convertEquatorialToHorizontal } from '@observerly/astrometry'

// Our astronomical target in this example is Betelgeuse, where
// the coordinate is given relative to the epoch J2000 and in units of degrees:
const betelgeuse: EquatorialCoordinate = { ra: 88.7929583, dec: 7.4070639 }

// Perform the conversion:
const { alt, az } = convertEquatorialToHorizontal(datetime, { latitude, longitude }, betelgeuse)

// alt: 72.78539444063765
// az: 134.44877920325155

Precession of Equinoxes

Let's say we also wish to apply corrections for the precession of equinoxes:

// Get the correction to the equatorial coordinate for for the precession of equinoxes:
const { ra: δra, dec: δdec } = getCorrectionToEquatorialForPrecessionOfEquinoxes(
  datetime,
  betelgeuse
)

// Perform the conversion:
const { alt, az } = convertEquatorialToHorizontal(
  datetime,
  { latitude, longitude },
  {
    ra: betelgeuse.ra + δra,
    dec: betelgeuse.dec + δdec
  }
)

// alt: 72.59159652271458
// az: 133.7382466535349

This will give you the horizontal coordinates of Betelgeuse at the given time and location, with the correction for the precession of equinoxes applied.

Corrections for atmospheric refraction, parallax, nutation and aberration can also be applied in a similar manner to get an accurate horizontal position of the star.

Contributing

observerly welcomes contributions from everyone. Please read our contributing guide for more information.

The TL;DR of the guideline is to follow these steps:

  • Before creating an issue, ensure a similar issue does not already exist.
  • Before creating a pull request, ensure a similar pull request does not already exist.

Private Publishing

To ensure that the private package repository is correctly configured, you will need to add the following to your .npmrc file:

//npm.pkg.github.com/:_authToken=${GITHUB_TOKEN}
@observerly:registry=https://npm.pkg.github.com

And then run the following command from the root of the repository:

pnpm publish --registry=https://npm.pkg.github.com/ --access public --//npm.pkg.github.com/:_authToken=$GITHUB_AUTH_TOKEN

Miscellany

*It is dependency-free to ensure it can be used safely within both node, deno, bun and browser environments.

License

@observerly/astrometry is licensed under the MIT license. See MIT for details.

About

observerly's lightweight, zero-dependency, type safe astrometry library written in TypeScript. This library can be used to ascertain to positions of the Sun, Moon and the planets, as well as ascertain transit times for any astronomical object.

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