GMMParameterEstimation.jl Documentation

estimate_parameters(d::Integer, k::Integer, sample::Array{Float64}, diagonal::Bool)

Compute an estimate for the parameters of a d-dimensional Gaussian k-mixture model from the moments.

If diagonal is true, the covariance matrices are assumed to be diagonal. If w is provided it is taken as the mixing coefficients, otherwise those are computed as well. first should be a list of moments 0 through 3k for the first dimension, second should be a matrix of moments 1 through 2k+1 for the remaining dimensions, and last should be a dictionary of the indices as lists of integers and the corresponding moments or nothing if diagonal is true.

estimate_parameters(d::Integer, k::Integer, sample::Array{Float64}, diagonal::Bool)

Compute an estimate for the parameters of a d-dimensional Gaussian k-mixture model from the moments.

If diagonal is true, the covariance matrices are assumed to be diagonal. If w is provided it is taken as the mixing coefficients, otherwise those are computed as well. first should be a list of moments 0 through 3k for the first dimension, second should be a matrix of moments 1 through 2k+1 for the remaining dimensions, and last should be a dictionary of the indices as lists of integers and the corresponding moments or nothing if diagonal is true.

makeCovarianceMatrix(d::Integer, diagonal::Bool)

Generate random dxd covariance matrix.

If diagonal==true, returns a diagonal covariance matrix.

generateGaussians(d::Integer, k::Integer, diagonal::Bool)

Generate means and covariances for k Gaussians with dimension d.

diagonal should be true for spherical case, and false for dense covariance matrices.

getSample(numb::Integer, w::Vector{Float64}, means::Matrix{Float64}, covariances::Array{Float64, 3})

Generate a Gaussian mixture model sample with numb entries, mixing coefficients w, means means, and covariances covariances.

sampleMoments(sample::Matrix{Float64}, k; diagonal = false)

Use the sample to compute the moments necessary for parameter estimation using method of moments.

Returns moments 0 to 3k for the first dimension, moments 1 through 2k+1 for the other dimensions as a matrix, and a dictionary with indices and moments for the off-diagonal system if diagonal is false.

perfectMoments(d, k, w, true_means, true_covariances)

Use the given parameters to compute the exact moments necessary for parameter estimation.

Returns moments 0 to 3k for the first dimension, moments 1 through 2k+1 for the other dimensions as a matrix, and a dictionary with indices and moments for the off-diagonal system.

build1DSystem(k::Integer, m::Integer)

Build the polynomial system for a mixture of 1D Gaussians where 'm' is the highest desired moment.

If a is given, use a as the mixing coefficients, otherwise leave them as unknowns.

build1DSystem(k::Integer, m::Integer, a::Union{Vector{Float64}, Vector{Variable}})

Build the polynomial system for a mixture of 1D Gaussians where 'm' is the highest desired moment.

If a is given, use a as the mixing coefficients, otherwise leave them as unknowns.

selectSol(k::Integer, solution::Result, polynomial::Expression, moment::Number)

Select a k mixture solution from solution accounting for polynomial and moment.

Sort out a k mixture statistically significant solutions from solution, and return the one closest to moment when polynomial is evaluated at those values.

tensorPower(tensor, power::Integer)

Compute the power tensor power of tensor.

convert_indexing(moment_i, d)

Convert the d dimensional multivariate moment_i index to the corresponding tensor moment index.

mixedMomentSystem(d, k, mixing, ms, vs)

Build a linear system for finding the off-diagonal covariances entries.

For a d dimensional Gaussian k-mixture model with mixing coefficients mixing, means ms, and covariances vs where the diagonal entries have been filled in and the off diagonals are variables.