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Other selection criteria with pulsar
In pulsar: Parallel Utilities for Lambda Selection along a Regularization Path
library(pulsar)
In addition to StARS' edge stability and G-StARS' induced subgraph stability, pulsar can
be used to compute other model selection criteria. By defining a few auxiliary functions,
pulsar can conveniently recapitulate a number of recently proposed selection criteria, e.g.,
@Tandon2014's sufficiency measure for hub discovery or @Caballe:2015's augmented AGNES scheme.
Learning Graphs with a few hubs
The sufficiency criterion defined by @Tandon2014
uses edge stability to identify hub and non-hub nodes. Graphs are learned from the neighborhoods
of non-hub nodes only, but, since hub nodes neighbor non-hubs, an entire graph can be learned more accurately
with fewer samples. The paper includes sample complexity bounds for Ising graphical models. In this
example, we generate correlated binary data for cheap (compared to Gibbs sampling) with Normal
copula functions.
library(huge)
library(Matrix)
p <- 40
n <- round(8*p * log(p))
set.seed(10010)
dat <- huge.generator(n, p, 'hub', verbose=FALSE, v=.3, u=.1)
## Generate correlated binomial data with the Normal copula method
X <- apply(apply(scale(dat$data), 2, pnorm), 2, qbinom, size=1, prob=.5)
ising.net <- function(Z, lambda, link='binomial') {
p <- ncol(Z)
l <- length(lambda)
estFun <- function(i) {
betamat <- matrix(NA, p, l)
betamat[-i,] <- as.matrix(glmnet::glmnet(Z[,-i], Z[,i], family=link, lambda=lambda)$beta)
betamat
}
est <- parallel::mcmapply(estFun, 1:p, mc.cores=1, SIMPLIFY='array')
list(path=apply(est, 2, function(x) { diag(x) <- 0 ; as(x!=0, "lgCMatrix") }))
}
lams <- getLamPath(.2, .005, 30)
out <- pulsar(X, ising.net, fargs=list(lambda=lams), criterion=c('stars', 'sufficiency'),
subsample.ratio=.6, rep.num=60, seed=10010)
For non-hubs, the sufficiency metric should have a large dip in the regularization path while hub
nodes are expected to be relatively flat:
plot(lams, out$sufficiency$merge[1,], type='l', ylab="sufficiency")
points(lams, out$sufficiency$merge[4,], type='l', col='red')
Estimate the hub graph by excluding hub nodes from neighborhood selection (algorithm 2 from the paper)
tandonest <- function(i, out, tu, tl) {
rmerge <- out$sufficiency$merge
p <- nrow(rmerge)
l <- ncol(rmerge)
prime <- tail(which(rmerge[i,] > tu), 1)
if (length(prime) == 0) return(rep(FALSE, p))
naught <- tail(which(rmerge[i,1:prime] < tl), 1)
if (length(naught) == 1) {
pmerge <- out$stars$merge[[naught]][i,]
return(pmerge >= (1+sqrt(1-4*tl))/2)
} else return(rep(FALSE, p))
}
net <- sapply(1:p, tandonest, out=out, tu=.2, tl=.15)
## Symmetrize
net <- sign(t(net) + net)
Augmented AGNES
To replicate the augmented AGNES (A-AGNES) method of @Caballe:2015, use the node-wise dissimilarity metric (diss) and the AGNES algorithm as implemented in the cluster package. A-AGNES selects the lambda that minimizes the variance of the estimated diss + the [squared] bias of the expected estimated dissimilarities w.r.t. the AGNES-selected graph - that has the maximum agglomerative coefficient over the path.
dat <- huge.generator(n, p, 'hub', verbose=FALSE, v=.1, u=.4)
out.diss <- pulsar(dat$data, fargs=list(lambda=lams, verbose=FALSE),
rep.num=20, criterion=c('diss', 'stars'))
fit <- refit(out.diss, 'stars')
## Compute the max agglomerative coefficient over the full path
path.diss <- lapply(fit$est$path, pulsar:::graph.diss)
library(cluster)
acfun <- function(x) agnes(x, diss=TRUE)$ac
ac <- sapply(path.diss, acfun)
ac.sel <- out.diss$diss$merge[[which.max(ac)]]
## Estimate the diss bias
dissbias <- sapply(out.diss$diss$merge,
function(x) mean((x-ac.sel)^2)/2)
varbias <- out.diss$diss$summary + dissbias
## Select the index and refit
opt.index(out.diss, 'diss') <- which.min(varbias)
fit.diss <- refit(out.diss)
plot(out.diss)
par(mfrow=c(1,2))
plot(network::network(as.matrix(fit.diss$refit$diss)), main='A-AGNES')
plot(network::network(as.matrix(fit.diss$refit$stars)), main='stars')
Please contact the package authors to request your favorite selection criterion to include with this package.
References
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pulsar documentation built on Sept. 25, 2023, 1:08 a.m.
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library(pulsar)
In addition to StARS' edge stability and G-StARS' induced subgraph stability, pulsar can
be used to compute other model selection criteria. By defining a few auxiliary functions,
pulsar can conveniently recapitulate a number of recently proposed selection criteria, e.g.,
@Tandon2014's sufficiency measure for hub discovery or @Caballe:2015's augmented AGNES scheme.
Learning Graphs with a few hubs
The sufficiency criterion defined by @Tandon2014 uses edge stability to identify hub and non-hub nodes. Graphs are learned from the neighborhoods of non-hub nodes only, but, since hub nodes neighbor non-hubs, an entire graph can be learned more accurately with fewer samples. The paper includes sample complexity bounds for Ising graphical models. In this example, we generate correlated binary data for cheap (compared to Gibbs sampling) with Normal copula functions.
library(huge) library(Matrix) p <- 40 n <- round(8*p * log(p)) set.seed(10010) dat <- huge.generator(n, p, 'hub', verbose=FALSE, v=.3, u=.1) ## Generate correlated binomial data with the Normal copula method X <- apply(apply(scale(dat$data), 2, pnorm), 2, qbinom, size=1, prob=.5) ising.net <- function(Z, lambda, link='binomial') { p <- ncol(Z) l <- length(lambda) estFun <- function(i) { betamat <- matrix(NA, p, l) betamat[-i,] <- as.matrix(glmnet::glmnet(Z[,-i], Z[,i], family=link, lambda=lambda)$beta) betamat } est <- parallel::mcmapply(estFun, 1:p, mc.cores=1, SIMPLIFY='array') list(path=apply(est, 2, function(x) { diag(x) <- 0 ; as(x!=0, "lgCMatrix") })) } lams <- getLamPath(.2, .005, 30) out <- pulsar(X, ising.net, fargs=list(lambda=lams), criterion=c('stars', 'sufficiency'), subsample.ratio=.6, rep.num=60, seed=10010)
For non-hubs, the sufficiency metric should have a large dip in the regularization path while hub nodes are expected to be relatively flat:
plot(lams, out$sufficiency$merge[1,], type='l', ylab="sufficiency") points(lams, out$sufficiency$merge[4,], type='l', col='red')
Estimate the hub graph by excluding hub nodes from neighborhood selection (algorithm 2 from the paper)
tandonest <- function(i, out, tu, tl) { rmerge <- out$sufficiency$merge p <- nrow(rmerge) l <- ncol(rmerge) prime <- tail(which(rmerge[i,] > tu), 1) if (length(prime) == 0) return(rep(FALSE, p)) naught <- tail(which(rmerge[i,1:prime] < tl), 1) if (length(naught) == 1) { pmerge <- out$stars$merge[[naught]][i,] return(pmerge >= (1+sqrt(1-4*tl))/2) } else return(rep(FALSE, p)) } net <- sapply(1:p, tandonest, out=out, tu=.2, tl=.15) ## Symmetrize net <- sign(t(net) + net)
Augmented AGNES
To replicate the augmented AGNES (A-AGNES) method of @Caballe:2015, use the node-wise dissimilarity metric (diss) and the AGNES algorithm as implemented in the cluster package. A-AGNES selects the lambda that minimizes the variance of the estimated diss + the [squared] bias of the expected estimated dissimilarities w.r.t. the AGNES-selected graph - that has the maximum agglomerative coefficient over the path.
dat <- huge.generator(n, p, 'hub', verbose=FALSE, v=.1, u=.4) out.diss <- pulsar(dat$data, fargs=list(lambda=lams, verbose=FALSE), rep.num=20, criterion=c('diss', 'stars')) fit <- refit(out.diss, 'stars') ## Compute the max agglomerative coefficient over the full path path.diss <- lapply(fit$est$path, pulsar:::graph.diss) library(cluster) acfun <- function(x) agnes(x, diss=TRUE)$ac ac <- sapply(path.diss, acfun) ac.sel <- out.diss$diss$merge[[which.max(ac)]] ## Estimate the diss bias dissbias <- sapply(out.diss$diss$merge, function(x) mean((x-ac.sel)^2)/2) varbias <- out.diss$diss$summary + dissbias ## Select the index and refit opt.index(out.diss, 'diss') <- which.min(varbias) fit.diss <- refit(out.diss) plot(out.diss) par(mfrow=c(1,2)) plot(network::network(as.matrix(fit.diss$refit$diss)), main='A-AGNES') plot(network::network(as.matrix(fit.diss$refit$stars)), main='stars')
Please contact the package authors to request your favorite selection criterion to include with this package.
References
Try the pulsar package in your browser
Any scripts or data that you put into this service are public.
R Package Documentation
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We want your feedback!
Note that we can't provide technical support on individual packages. You should contact the package authors for that.
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