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Unitful coordinate reference systems for geographic maps in Julia

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JuliaEarth/CoordRefSystems.jl

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CoordRefSystems.jl provides conversions between Coordinate Reference Systems (CRS) in native Julia. It was designed to work with units from Unitful.jl, respects projection bounds catalogued in https://epsg.io, and is very fast thanks to advanced parametrizations at compile-time.

This package addresses various design issues encountered in previous attempts such as Geodesy.jl and MapMaths.jl. Our benchmarks show that CoordRefSystems.jl is sometimes faster than PROJ, which is the most widely used software library for cartography in the world (written in C/C++).

Installation

Get the latest stable release with Julia's package manager:

] add CoordRefSystems

Usage

Basic usage

Consider the following conversions between Cartesian, Spherical, Cylindrical and Polar coordinates to get started:

Cartesian <> Spherical

julia> cartesian = Cartesian(1, 1, 1)
Cartesian{NoDatum} coordinates
├─ x: 1.0 m
├─ y: 1.0 m
└─ z: 1.0 m

julia> spherical = convert(Spherical, cartesian)
Spherical{NoDatum} coordinates
├─ r: 1.7320508075688772 m
├─ θ: 0.9553166181245093 rad
└─ ϕ: 0.7853981633974483 rad

julia> convert(Cartesian, spherical)
Cartesian{NoDatum} coordinates
├─ x: 1.0 m
├─ y: 0.9999999999999998 m
└─ z: 0.9999999999999999 m

Cartesian <> Cylindrical

julia> cartesian = Cartesian(1, 1, 1)
Cartesian{NoDatum} coordinates
├─ x: 1.0 m
├─ y: 1.0 m
└─ z: 1.0 m

julia> cylindrical = convert(Cylindrical, cartesian)
Cylindrical{NoDatum} coordinates
├─ ρ: 1.4142135623730951 m
├─ ϕ: 0.7853981633974483 rad
└─ z: 1.0 m

julia> convert(Cartesian, cylindrical)
Cartesian{NoDatum} coordinates
├─ x: 1.0000000000000002 m
├─ y: 1.0 m
└─ z: 1.0 m

Cartesian <> Polar

julia> cartesian = Cartesian(1, 1)
Cartesian{NoDatum} coordinates
├─ x: 1.0 m
└─ y: 1.0 m

julia> polar = convert(Polar, cartesian)
Polar{NoDatum} coordinates
├─ ρ: 1.4142135623730951 m
└─ ϕ: 0.7853981633974483 rad

julia> convert(Cartesian, polar)
Cartesian{NoDatum} coordinates
├─ x: 1.0000000000000002 m
└─ y: 1.0 m

Special syntax

Julia's convert methods can be triggered with special syntax assuming that a list of coordinates is available:

julia> Mercator[LatLon(0, 0), LatLon(30, 30), LatLon(20,30)]
3-element Vector{Mercator}:
 Mercator{WGS84Latest}(x: 0.0 m, y: 0.0 m)
 Mercator{WGS84Latest}(x: 3.33958e6 m, y: 3.48219e6 m)
 Mercator{WGS84Latest}(x: 3.33958e6 m, y: 2.25842e6 m)

The example above is equivalent to running convert(Mercator, latlon) for all latlon coordinates in the list.

Advanced usage

CRS are most useful to locate objets in the physical world. Given an ellipsoid of revolution and a standardized origin (a.k.a. datum), it is possible assign coordinates to points without ambiguity.

Below is an example converting geodetic LatLon coordinates on the WGS84Latest datum to Mercator, WebMercator, and Robinson projected coordinates on the same datum:

julia> latlon = LatLon(30, 60)
GeodeticLatLon{WGS84Latest} coordinates
├─ lat: 30.0°
└─ lon: 60.0°

julia> convert(Mercator, latlon)
Mercator{WGS84Latest} coordinates
├─ x: 6.679169447596414e6 m
└─ y: 3.482189085408618e6 m

julia> convert(WebMercator, latlon)
WebMercator{WGS84Latest} coordinates
├─ x: 6.679169447596414e6 m
└─ y: 3.5035498435043753e6 m

julia> convert(Robinson, latlon)
Robinson{WGS84Latest} coordinates
├─ x: 5.441866544132874e6 m
└─ y: 3.2085576115038935e6 m

julia> latlon = LatLon(30, 60)
GeodeticLatLon{WGS84Latest} coordinates
├─ lat: 30.0°
└─ lon: 60.0°

julia> mercator = convert(Mercator, latlon)
Mercator{WGS84Latest} coordinates
├─ x: 6.679169447596414e6 m
└─ y: 3.482189085408618e6 m

julia> convert(LatLon, mercator)
GeodeticLatLon{WGS84Latest} coordinates
├─ lat: 29.999999999999996°
└─ lon: 59.99999999999999°

It is also possible to convert between different datum, transparently. In the following examples, we convert coordinates between the WGS84Latest datum, currently an alias to WGS84{1762}, and the ITRF{2008} datum:

julia> latlon = LatLon{WGS84Latest}(30, 60)
GeodeticLatLon{WGS84Latest} coordinates
├─ lat: 30.0°
└─ lon: 60.0°

julia> convert(LatLon{ITRF{2008}}, latlon)
GeodeticLatLon{ITRF{2008}} coordinates
├─ lat: 30.00000000081754°
└─ lon: 59.99999999999999°

julia> mercator = convert(Mercator{WGS84Latest}, latlon)
Mercator{WGS84Latest} coordinates
├─ x: 6.679169447596414e6 m
└─ y: 3.482189085408618e6 m

julia> convert(WebMercator{WGS84Latest}, mercator)
WebMercator{WGS84Latest} coordinates
├─ x: 6.679169447596414e6 m
└─ y: 3.5035498435043753e6 m

julia> convert(WebMercator{ITRF{2008}}, mercator)
WebMercator{ITRF{2008}} coordinates
├─ x: 6.679169447596414e6 m
└─ y: 3.5035498436094625e6 m

EPSG/ERSI codes

CRS are catalogued with numerical codes in https://epsg.io. The package provides EPSG{code} and ERSI{code}, and the utility CoordRefSystems.get function to query the database:

julia> CRS1 = CoordRefSystems.get(EPSG{4326})
GeodeticLatLon{WGS84Latest}

julia> CRS2 = CoordRefSystems.get(EPSG{3395})
Mercator{WGS84Latest}

julia> CRS1(0, 90)
GeodeticLatLon{WGS84Latest} coordinates
├─ lat: 0.0°
└─ lon: 90.0°

julia> convert(CRS2, CRS1(0, 90))
Mercator{WGS84Latest} coordinates
├─ x: 1.0018754171394622e7 m
└─ y: 0.0 m

Credits

Most implementations in this package are adaptations from PROJ - Cartographic Projections and Coordinate Transformations Library and its list of references. Our tests were designed to match their results to the last digit via the Proj.jl wrapper.