A Julia package for working with multivectors from geometric (or Clifford) algebra.
This package readily usable, but unregistered. (Mostly because I haven’t thought of a good package name appropriate for the General registry!)
julia> using Pkg
julia> Pkg.add(url="https://github.com/Jollywatt/GeometricAlgebra.jl", rev="v0.2.1")Construct multivectors by providing a metric signature and grade as type parameters:
julia> using GeometricAlgebra
julia> u = Multivector{3,1}([1, -1, 0]) # 3D Euclidean vector
3-component Multivector{3, 1, Vector{Int64}}:
1 v1
-1 v2
0 v3Non-euclidean metric signatures may be specified:
julia> v = Multivector{Cl("-+++"),2}(1:6) # Lorentzian bivector
6-component Multivector{Cl("-+++"), 2, UnitRange{Int64}}:
1 v12
2 v13
3 v23
4 v14
5 v24
6 v34
julia> exp(v)
8-component Multivector{Cl("-+++"), 0:2:4, MVector{8, Float64}}:
1.18046
0.818185 v12 + -0.141944 v13 + 0.153208 v23 + 1.076 v14 + 1.16194 v24 + 1.03866 v34
0.999268 v1234Notice that this bivector exponential has grades 0:2:4.
The grade parameter K of a Multivector{Sig,K} can be a single integer
(for homogeneous multivectors) or a collection of grades.
A general 4D multivector has grades 0:4, but an even multivector
may be more efficiently represented with grades 0:2:4.
You may also obtain an orthonormal basis for a metric signature:
julia> v = basis(3)
3-element Vector{BasisBlade{3, 1, Int64}}:
v1
v2
v3
julia> exp(10000*2π*v[2]v[3])
4-component Multivector{3, 0:2:2, Vector{Float64}}:
1.0
-9.71365e-13 v23Macros are provided for interactive use:
julia> @basis "+---"
[ Info: Defined basis blades v1, v2, v3, v4, v12, v13, v23, v14, v24, v34, v123, v124, v134, v234, v1234, I in Main
julia> @basis (t = +1, x = -1) allperms=true
[ Info: Defined basis blades t, x, tx, xt, I in MainThere are two concrete types for representing elements in a geometric algebra:
AbstractMultivector{Sig}
/ \
BasisBlade{Sig,K,T} Multivector{Sig,K,S}
BasisBlade: a scalar multiple of a wedge product of orthogonal basis vectors.Multivector: a homogeneous or inhomogeneous multivector; a sum of basis blades.
Type parameters:
Sig: The metric signature which defines the geometric algebra. This can be any all-bits value which satisfies the metric signature interface.K: The grade(s) of a multivector. ForBasisBlades, this is an integer, but forMultivectors, it may be a collection (e.g.,0:3for a general 3D multivector).T: The numerical type of the coefficient of aBasisBlade.S: The storage type of the components of aMultivector, usually anAbstractVectorsubtype.
Thanks to the wonderful SymbolicUtils package, the same code originally written for numerical multivectors readily works with symbolic components.
For example, we can compute the product of two vectors symbolically as follows:
julia> GeometricAlgebra.symbolic_components.([:x, :y], 3)
2-element Vector{Vector{Any}}:
[x[1], x[2], x[3]]
[y[1], y[2], y[3]]
julia> Multivector{3,1}.(ans)
2-element Vector{Multivector{3, 1, Vector{Any}}}:
x[1]v1 + x[2]v2 + x[3]v3
y[1]v1 + y[2]v2 + y[3]v3
julia> prod(ans)
4-component Multivector{3, 0:2:2, Vector{Any}}:
x[1]*y[1] + x[2]*y[2] + x[3]*y[3]
x[1]*y[2] - x[2]*y[1] v12 + x[1]*y[3] - x[3]*y[1] v13 + x[2]*y[3] - x[3]*y[2] v23
This makes it easy to optimize multivector operations by first performing the calculation symbolically, then converting the resulting expression into unrolled code. By default, symbolic code generation is used for most products in up to eight dimensions (above which general algebraic expressions become unwieldy).
This package derives inspiration from many others. Here is a list of Julia implementations (of varying completeness) which I have come across:
- ATell-SoundTheory/CliffordAlgebras.jl
- brainandforce/CliffordNumbers.jl
- chakravala/Grassmann.jl
- digitaldomain/Multivectors.jl
- MasonProtter/GeometricMatrixAlgebras.jl
- serenity4/GeometricAlgebra.jl
- serenity4/SymbolicGA.jl
- velexi-research/GeometricAlgebra.jl
- in the future, JuliaGeometricAlgebra/GeometricAlgebra.jl