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R/vdp.mixt.R
In netresponse: Functional Network Analysis
Defines functions
vdp.mixt
Documented in
vdp.mixt
# system('~/local/R/R-2.13.0/bin/R CMD SHLIB ../src/netresponse.c');
# dyn.load('../src/netresponse.so')
#' vdp.mixt
#'
#' Accelerated variational Dirichlet process Gaussian mixture.
#'
#' Implementation of the Accelerated variational Dirichlet process Gaussian
#' mixture model algorithm by Kenichi Kurihara et al., 2007.
#'
#' ALGORITHM SUMMARY
#' This code implements Gaussian mixture models with diagonal covariance matrices.
#' The following greedy iterative approach is taken in order to obtain the number
#' of mixture models and their corresponding parameters:
#'
#' 1. Start from one cluster, $T = 1$.
#' 2. Select a number of candidate clusters according to their values of
#' 'Nc' = \\sum_{n=1}^N q_{z_n} (z_n = c) (larger is better).
#' 3. For each of the candidate clusters, c:
#' 3a. Split c into two clusters, c1 and c2, through the bisector of its
#' principal component. Initialise the responsibilities
#' q_{z_n}(z_n = c_1) and q_{z_n}(z_n = c_2).
#' 3b. Update only the parameters of c1 and c2 using the observations that
#' belonged to c, and determine the new value for the free energy, F{T+1}.
#' 3c. Reassign cluster labels so that cluster 1 corresponds to the largest
#' cluster, cluster 2 to the second largest, and so on.
#' 4. Select the split that lead to the maximal reduction of free energy, F{T+1}.
#' 5. Update the posterior using the newly split data.
#' 6. If FT - F{T+1} < \\epsilon then halt, else set T := T +1 and go to step 2.
#'
#' The loop is implemented in the function greedy(...)
#'
#' @param dat Data matrix (samples x features).
#' @param prior.alpha,prior.alphaKsi,prior.betaKsi Prior parameters for
#' Gaussian mixture model (normal-inverse-Gamma prior). alpha tunes the mean;
#' alphaKsi and betaKsi are the shape and scale parameters of the inverse Gamma
#' function, respectively.
#' @param do.sort When true, qOFz will be sorted in decreasing fashion by
#' component size, based on colSums(qOFz). The qOFz matrix describes the
#' sample-component assigments in the mixture model.
#' @param threshold Defines the minimal free energy improvement that stops the
#' algorithm: used to define convergence limit.
#' @param initial.K Initial number of mixture components.
#' @param ite Defines maximum number of iterations on posterior update
#' (updatePosterior). Increasing this can potentially lead to more accurate
#' results, but computation may take longer.
#' @param implicit.noise Adds implicit noise; used by vdp.mk.log.lambda.so and
#' vdp.mk.hp.posterior.so. By adding noise (positive values), one can avoid
#' overfitting to local optima in some cases, if this happens to be a problem.
#' @param c.max Maximum number of candidates to consider in
#' find.best.splitting. During mixture model calculations new mixture
#' components can be created until this upper limit has been reached. Defines
#' the level of truncation for a truncated stick-breaking process.
#' @param speedup When learning the number of components, each component is
#' splitted based on its first PCA component. To speed up, approximate by using
#' only subset of data to calculate PCA.
#' @param min.size Minimum size for a component required for potential
#' splitting during mixture estimation.
#'
#' @return \item{ prior }{Prior parameters of the vdp-gm model (qofz: priors on observation lables; Mu: centroids; S2: variance).}
#' \item{ posterior }{Posterior estimates for the model parameters and statistics.}
#' \item{ weights }{Mixture proportions, or weights, for the Gaussian mixture components.}
#' \item{ centroids }{Centroids of the mixture components.}
#' \item{ sds }{ Standard deviations for the mixture model components (posterior modes of the covariance diagonals square root). Calculated as sqrt(invgam.scale/(invgam.shape + 1)). }
#' \item{ qOFz }{ Sample-to-cluster assigments (soft probabilistic associations).}
#' \item{ Nc }{Component sizes}
#' \item{ invgam.shape }{ Shape parameter (alpha) of the inverse Gamma distribution }
#' \item{ invgam.scale }{ Scale parameter (beta) of the inverse Gamma distribution }
#' \item{ Nparams }{ Number of model parameters }
#' \item{ K }{ Number of components in the mixture model }
#' \item{ opts }{Model parameters that were used.}
#' \item{ free.energy }{Free energy of the model.}
#'
#' @note This implementation is based on the Variational Dirichlet Process
#' Gaussian Mixture Model implementation, Copyright (C) 2007 Kenichi Kurihara
#' (all rights reserved) and the Agglomerative Independent Variable Group
#' Analysis package (in Matlab): Copyright (C) 2001-2007 Esa Alhoniemi, Antti
#' Honkela, Krista Lagus, Jeremias Seppa, Harri Valpola, and Paul Wagner.
#' @author Maintainer: Leo Lahti \email{leo.lahti@@iki.fi}
#' @references Kenichi Kurihara, Max Welling and Nikos Vlassis: Accelerated
#' Variational Dirichlet Process Mixtures. In B. Sch\'olkopf and J. Platt and
#' T. Hoffman (eds.), Advances in Neural Information Processing Systems 19,
#' 761--768. MIT Press, Cambridge, MA 2007.
#' @keywords methods iteration
#' @export
#' @examples
#'
#' set.seed(123)
#'
#' # Generate toy data with two Gaussian components
#' dat <- rbind(array(rnorm(400), dim = c(200,2)) + 5,
#' array(rnorm(400), dim = c(200,2)))
#'
#' # Infinite Gaussian mixture model with
#' # Variational Dirichlet Process approximation
#' mixt <- vdp.mixt( dat )
#'
#' # Centroids of the detected Gaussian components
#' mixt$posterior$centroids
#'
#' # Hard mixture component assignments for the samples
#' apply(mixt$posterior$qOFz, 1, which.max)
#'
#'
vdp.mixt <- function(dat, prior.alpha = 1, prior.alphaKsi = 0.01, prior.betaKsi = 0.01,
do.sort = TRUE, threshold = 1e-05, initial.K = 1, ite = Inf, implicit.noise = 0,
c.max = 10, speedup = TRUE, min.size = 5) {
# qOFz sorted in decreasing fashion based on colSums(qOFz) threshold: minimal
# free energy improvement that stops the algorithm initial.K initial number of
# components ite # used on updatePosterior: maximum number of iterations
# implicit.noise # Adds implicit noise in vdp.mk.log.lambda.so and
# vdp.mk.hp.posterior.so
# c.max max. candidates to consider in Candidates are chosen based on their Nc
# value (larger = better). Nc = colSums(qOFz) find.best.splitting. i.e.
# truncation parameter speedup: during DP, components are splitted based on their
# first PCA component. To speed up, approximate by using only subset data to
# calculate PCA. min.size # min size for a component to be splitted
# Prior parameters
opts <- list(prior.alpha = prior.alpha, prior.alphaKsi = prior.alphaKsi, prior.betaKsi = prior.betaKsi,
speedup = speedup, do.sort = do.sort, threshold = threshold, initial.K = initial.K,
ite = ite, implicitnoisevar = implicit.noise, c.max = c.max)
# alphaKsi smaller -> less clusters (and big!) -> quite sensitive betaKsi larger
# -> less clusters (and big!)
data <- list()
data[["given.data"]] <- list()
data[["given.data"]][["X1"]] <- dat
# sample-component assignments
qOFz <- rand.qOFz(nrow(dat), initial.K)
# The hyperparameters of priors
hp.prior <- mk.hp.prior(data, opts)
# Posterior
hp.posterior <- mk.hp.posterior(data, qOFz, hp.prior, opts)
# Note: greedy gives components in decreasing order by size
templist <- greedy(data, hp.posterior, hp.prior, opts, min.size)
templist$hp.prior <- c(templist$hp.prior, list(qOFz = qOFz))
qOFz <- matrix(templist$hp.posterior$qOFz, nrow(dat))
###############################################
# Retrieve model parameters
# number of mixture components (nonempty components only!) response must have
# non-negligible' probability mass! i.e. at least some points associated with it
Kreal <- max(apply(qOFz, 1, which.max)) #sum(colSums(qOFz) > 1e-3)
qOFz <- matrix(qOFz[, seq_len(Kreal)], nrow(dat))
rownames(qOFz) <- rownames(dat)
# Calculate mixture model parameters FIXME: move this outside from this vdp.mixt
# function
# Negative free energy is (variational) lower bound for P(D|H) Use it to
# approximate P(D|HClist <- list(C))
# number of parameters (d-dim. centroid + diag. cov. matrix + component weight
# for each Kreal)
Nparams <- Kreal * (2 * ncol(dat) + 1)
# Calculate map estimates of model parameters from the posterior
# variances are assumed inverse Gamma distributed and here beta/alpha gives the
# expectation)
# Parameters of the inverse Gamma function for component variances
invgam.shape <- matrix(templist$hp.posterior$KsiAlpha[seq_len(Kreal), ], Kreal)
invgam.scale <- matrix(templist$hp.posterior$KsiBeta[seq_len(Kreal), ], Kreal)
# Calculate variances (mean and mode of the invgam distr.) from scale and shape
# FIXME: beta/alpha used in C code var.update <-
# matrix(invgam.scale/invgam.shape, Kreal) var.mean <-
# matrix(invgam.scale/(invgam.shape - 1), Kreal)
var.mode <- matrix(invgam.scale/(invgam.shape + 1), Kreal)
variances <- var.mode # select mean, mode, or their average for update
# Ignore empty components assuming that the components have been ordered in
# decreasing order by size component centroids
centroids <- matrix(templist$hp.posterior$Mubar[seq_len(Kreal), ], Kreal)
#############################################
# Estimate weights directly from mass on each component; with large sample size
# the solution should converge there
w <- colSums(qOFz)
w <- w/sum(w) # normalize
# FIXME: improve later, or retrieve weight directly from vdp code or the
# densities to make more robust also for small sample size NOTE: the way we
# calculate weights here is not in exact agreement with the real weights in the
# model that would give qOFz but it is an approximation, and needed for end
# analysis
posterior <- list(weights = w, centroids = centroids, sds = sqrt(variances),
qOFz = qOFz, Nc = colSums(qOFz), invgam.shape = invgam.shape, invgam.scale = invgam.scale,
Nparams = Nparams, K = Kreal)
# centroids: mubar sds alpha, beta Nc: # component sizes invgam shape # KsiAlpha
# invgam.scale # KsiBeta Nparams = Nparams, # number of model parameters K =
# Kreal # number of components
# Later: include these from hp.posterior to the output later if needed.
# 'Mutilde[1:Kreal,]' 'gamma[,1:Kreal]' 'Uhat'
list(prior = templist$hp.prior, posterior = posterior, opts = opts, free.energy = templist$free.energy)
}
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Defines functions vdp.mixt
Documented in vdp.mixt
# system('~/local/R/R-2.13.0/bin/R CMD SHLIB ../src/netresponse.c');
# dyn.load('../src/netresponse.so')
#' vdp.mixt
#'
#' Accelerated variational Dirichlet process Gaussian mixture.
#'
#' Implementation of the Accelerated variational Dirichlet process Gaussian
#' mixture model algorithm by Kenichi Kurihara et al., 2007.
#'
#' ALGORITHM SUMMARY
#' This code implements Gaussian mixture models with diagonal covariance matrices.
#' The following greedy iterative approach is taken in order to obtain the number
#' of mixture models and their corresponding parameters:
#'
#' 1. Start from one cluster, $T = 1$.
#' 2. Select a number of candidate clusters according to their values of
#' 'Nc' = \\sum_{n=1}^N q_{z_n} (z_n = c) (larger is better).
#' 3. For each of the candidate clusters, c:
#' 3a. Split c into two clusters, c1 and c2, through the bisector of its
#' principal component. Initialise the responsibilities
#' q_{z_n}(z_n = c_1) and q_{z_n}(z_n = c_2).
#' 3b. Update only the parameters of c1 and c2 using the observations that
#' belonged to c, and determine the new value for the free energy, F{T+1}.
#' 3c. Reassign cluster labels so that cluster 1 corresponds to the largest
#' cluster, cluster 2 to the second largest, and so on.
#' 4. Select the split that lead to the maximal reduction of free energy, F{T+1}.
#' 5. Update the posterior using the newly split data.
#' 6. If FT - F{T+1} < \\epsilon then halt, else set T := T +1 and go to step 2.
#'
#' The loop is implemented in the function greedy(...)
#'
#' @param dat Data matrix (samples x features).
#' @param prior.alpha,prior.alphaKsi,prior.betaKsi Prior parameters for
#' Gaussian mixture model (normal-inverse-Gamma prior). alpha tunes the mean;
#' alphaKsi and betaKsi are the shape and scale parameters of the inverse Gamma
#' function, respectively.
#' @param do.sort When true, qOFz will be sorted in decreasing fashion by
#' component size, based on colSums(qOFz). The qOFz matrix describes the
#' sample-component assigments in the mixture model.
#' @param threshold Defines the minimal free energy improvement that stops the
#' algorithm: used to define convergence limit.
#' @param initial.K Initial number of mixture components.
#' @param ite Defines maximum number of iterations on posterior update
#' (updatePosterior). Increasing this can potentially lead to more accurate
#' results, but computation may take longer.
#' @param implicit.noise Adds implicit noise; used by vdp.mk.log.lambda.so and
#' vdp.mk.hp.posterior.so. By adding noise (positive values), one can avoid
#' overfitting to local optima in some cases, if this happens to be a problem.
#' @param c.max Maximum number of candidates to consider in
#' find.best.splitting. During mixture model calculations new mixture
#' components can be created until this upper limit has been reached. Defines
#' the level of truncation for a truncated stick-breaking process.
#' @param speedup When learning the number of components, each component is
#' splitted based on its first PCA component. To speed up, approximate by using
#' only subset of data to calculate PCA.
#' @param min.size Minimum size for a component required for potential
#' splitting during mixture estimation.
#'
#' @return \item{ prior }{Prior parameters of the vdp-gm model (qofz: priors on observation lables; Mu: centroids; S2: variance).}
#' \item{ posterior }{Posterior estimates for the model parameters and statistics.}
#' \item{ weights }{Mixture proportions, or weights, for the Gaussian mixture components.}
#' \item{ centroids }{Centroids of the mixture components.}
#' \item{ sds }{ Standard deviations for the mixture model components (posterior modes of the covariance diagonals square root). Calculated as sqrt(invgam.scale/(invgam.shape + 1)). }
#' \item{ qOFz }{ Sample-to-cluster assigments (soft probabilistic associations).}
#' \item{ Nc }{Component sizes}
#' \item{ invgam.shape }{ Shape parameter (alpha) of the inverse Gamma distribution }
#' \item{ invgam.scale }{ Scale parameter (beta) of the inverse Gamma distribution }
#' \item{ Nparams }{ Number of model parameters }
#' \item{ K }{ Number of components in the mixture model }
#' \item{ opts }{Model parameters that were used.}
#' \item{ free.energy }{Free energy of the model.}
#'
#' @note This implementation is based on the Variational Dirichlet Process
#' Gaussian Mixture Model implementation, Copyright (C) 2007 Kenichi Kurihara
#' (all rights reserved) and the Agglomerative Independent Variable Group
#' Analysis package (in Matlab): Copyright (C) 2001-2007 Esa Alhoniemi, Antti
#' Honkela, Krista Lagus, Jeremias Seppa, Harri Valpola, and Paul Wagner.
#' @author Maintainer: Leo Lahti \email{leo.lahti@@iki.fi}
#' @references Kenichi Kurihara, Max Welling and Nikos Vlassis: Accelerated
#' Variational Dirichlet Process Mixtures. In B. Sch\'olkopf and J. Platt and
#' T. Hoffman (eds.), Advances in Neural Information Processing Systems 19,
#' 761--768. MIT Press, Cambridge, MA 2007.
#' @keywords methods iteration
#' @export
#' @examples
#'
#' set.seed(123)
#'
#' # Generate toy data with two Gaussian components
#' dat <- rbind(array(rnorm(400), dim = c(200,2)) + 5,
#' array(rnorm(400), dim = c(200,2)))
#'
#' # Infinite Gaussian mixture model with
#' # Variational Dirichlet Process approximation
#' mixt <- vdp.mixt( dat )
#'
#' # Centroids of the detected Gaussian components
#' mixt$posterior$centroids
#'
#' # Hard mixture component assignments for the samples
#' apply(mixt$posterior$qOFz, 1, which.max)
#'
#'
vdp.mixt <- function(dat, prior.alpha = 1, prior.alphaKsi = 0.01, prior.betaKsi = 0.01,
do.sort = TRUE, threshold = 1e-05, initial.K = 1, ite = Inf, implicit.noise = 0,
c.max = 10, speedup = TRUE, min.size = 5) {
# qOFz sorted in decreasing fashion based on colSums(qOFz) threshold: minimal
# free energy improvement that stops the algorithm initial.K initial number of
# components ite # used on updatePosterior: maximum number of iterations
# implicit.noise # Adds implicit noise in vdp.mk.log.lambda.so and
# vdp.mk.hp.posterior.so
# c.max max. candidates to consider in Candidates are chosen based on their Nc
# value (larger = better). Nc = colSums(qOFz) find.best.splitting. i.e.
# truncation parameter speedup: during DP, components are splitted based on their
# first PCA component. To speed up, approximate by using only subset data to
# calculate PCA. min.size # min size for a component to be splitted
# Prior parameters
opts <- list(prior.alpha = prior.alpha, prior.alphaKsi = prior.alphaKsi, prior.betaKsi = prior.betaKsi,
speedup = speedup, do.sort = do.sort, threshold = threshold, initial.K = initial.K,
ite = ite, implicitnoisevar = implicit.noise, c.max = c.max)
# alphaKsi smaller -> less clusters (and big!) -> quite sensitive betaKsi larger
# -> less clusters (and big!)
data <- list()
data[["given.data"]] <- list()
data[["given.data"]][["X1"]] <- dat
# sample-component assignments
qOFz <- rand.qOFz(nrow(dat), initial.K)
# The hyperparameters of priors
hp.prior <- mk.hp.prior(data, opts)
# Posterior
hp.posterior <- mk.hp.posterior(data, qOFz, hp.prior, opts)
# Note: greedy gives components in decreasing order by size
templist <- greedy(data, hp.posterior, hp.prior, opts, min.size)
templist$hp.prior <- c(templist$hp.prior, list(qOFz = qOFz))
qOFz <- matrix(templist$hp.posterior$qOFz, nrow(dat))
###############################################
# Retrieve model parameters
# number of mixture components (nonempty components only!) response must have
# non-negligible' probability mass! i.e. at least some points associated with it
Kreal <- max(apply(qOFz, 1, which.max)) #sum(colSums(qOFz) > 1e-3)
qOFz <- matrix(qOFz[, seq_len(Kreal)], nrow(dat))
rownames(qOFz) <- rownames(dat)
# Calculate mixture model parameters FIXME: move this outside from this vdp.mixt
# function
# Negative free energy is (variational) lower bound for P(D|H) Use it to
# approximate P(D|HClist <- list(C))
# number of parameters (d-dim. centroid + diag. cov. matrix + component weight
# for each Kreal)
Nparams <- Kreal * (2 * ncol(dat) + 1)
# Calculate map estimates of model parameters from the posterior
# variances are assumed inverse Gamma distributed and here beta/alpha gives the
# expectation)
# Parameters of the inverse Gamma function for component variances
invgam.shape <- matrix(templist$hp.posterior$KsiAlpha[seq_len(Kreal), ], Kreal)
invgam.scale <- matrix(templist$hp.posterior$KsiBeta[seq_len(Kreal), ], Kreal)
# Calculate variances (mean and mode of the invgam distr.) from scale and shape
# FIXME: beta/alpha used in C code var.update <-
# matrix(invgam.scale/invgam.shape, Kreal) var.mean <-
# matrix(invgam.scale/(invgam.shape - 1), Kreal)
var.mode <- matrix(invgam.scale/(invgam.shape + 1), Kreal)
variances <- var.mode # select mean, mode, or their average for update
# Ignore empty components assuming that the components have been ordered in
# decreasing order by size component centroids
centroids <- matrix(templist$hp.posterior$Mubar[seq_len(Kreal), ], Kreal)
#############################################
# Estimate weights directly from mass on each component; with large sample size
# the solution should converge there
w <- colSums(qOFz)
w <- w/sum(w) # normalize
# FIXME: improve later, or retrieve weight directly from vdp code or the
# densities to make more robust also for small sample size NOTE: the way we
# calculate weights here is not in exact agreement with the real weights in the
# model that would give qOFz but it is an approximation, and needed for end
# analysis
posterior <- list(weights = w, centroids = centroids, sds = sqrt(variances),
qOFz = qOFz, Nc = colSums(qOFz), invgam.shape = invgam.shape, invgam.scale = invgam.scale,
Nparams = Nparams, K = Kreal)
# centroids: mubar sds alpha, beta Nc: # component sizes invgam shape # KsiAlpha
# invgam.scale # KsiBeta Nparams = Nparams, # number of model parameters K =
# Kreal # number of components
# Later: include these from hp.posterior to the output later if needed.
# 'Mutilde[1:Kreal,]' 'gamma[,1:Kreal]' 'Uhat'
list(prior = templist$hp.prior, posterior = posterior, opts = opts, free.energy = templist$free.energy)
}
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