[epclust.git] / code / stage2 / src / 02_cluster_2009.r

## File: extract-features.r

rm(list = ls())

## a. Load data & libraries ####

library(cluster)
MOJARRITA <- Sys.info()[4] ==  "mojarrita"

#source('http://eric.univ-lyon2.fr/~jcugliari/codes/functional-clustering.r')
source('01_StBr.r')

if(MOJARRITA){ 
  setwd("~/Documents/projects/2014_EDF-Orsay-Lyon2/codes/")
} else {
  setwd("~/ownCloud/projects/2014_EDF-Orsay-Lyon2/codes/")
}


matcontrib0 <- read.table(file = "~/tmp/2009_contrib.txt")
n     <- nrow(matcontrib0)

sdcontrib <- apply(matcontrib0, 1, sd)
lims      <- quantile(sdcontrib, probs = c(.005, .995)) # obtain 1%-extreme data
is_normal <- which((sdcontrib > lims[1]) & (sdcontrib < lims[2]))

matcontri_ext <- matcontrib0[-is_normal, ]""
matcontrib    <- matcontrib0[is_normal, ]     # wipe out aberrant data

matcontrib <- t(apply(matcontrib, 1, function(x) x / sum(x)))
matcontrib <- t(apply(matcontrib, 1, function(p) log(p / (1 - p)) ))


## b. Transform data & compute CI ####
ci     <- CI(matcontrib)
tdata  <- ci$tdata; rownames(tdata) <- rownames(matcontrib)
selvar <- ci$selectv
  
## c. Clustering  ##########
K <- 200
system.time(
  clfit <- clara(x        = tdata[, selvar], 
                 k        = K, 
                 sampsize = 4000, 
                 samples  = 4, 
                 rngR     = TRUE)
)

#save(clfit, file = 'clfit500.Rdata')
# save(clfit, file = 'clfit200RC.Rdata')
save(clfit, file = 'clfit200.Rdata')

rm(ci, matcontrib0, is_normal, lims, selvar)
gc()

## d. Analyze results  ##########

#1. Répartition du nombre d'observation par cluster
#plot(sort(table(clfit$clustering), decreasing = TRUE), 
#     type = 'l', ylab = 'Fréquence', xlab = 'Classe')


#clust <- res$clustering
#  centres <- aggregate(conso, clust)
#  table(clust)
  
  #sel_veille    <- as.Date(rownames(conso)[sel - 1])
  #sel_lendemain <- as.Date(rownames(conso)[sel + 1])
  
  #res_clust <- data.frame(date     = rownames(conso),
                          #veille    = weekdays(sel_veille),
                          #lendemain = weekdays(sel_lendemain),
  #                        clust     = clust)
  
  #for(k in 1:K) {
  #  assign(paste0("dates_clust", K),
  #         substr(subset(res_clust, clust == k)$date, 1, 7) )
  #}
  
  #dev.off()
  
  #save(file = paste0(dtitle, "_clust.Rdata"), 
       #res_clust, selvar, K, gap)
#}

#dates_clust1 <- substr(subset(dates, clust == 1)$date, 1, 7)
Commit	Line	Data
ad642dc6 BA	1	## File: extract-features.r
	2
	3	rm(list = ls())
	4
	5	## a. Load data & libraries ####
	6
	7	library(cluster)
	8	MOJARRITA <- Sys.info()[4] == "mojarrita"
	9
	10	#source('http://eric.univ-lyon2.fr/~jcugliari/codes/functional-clustering.r')
	11	source('01_StBr.r')
	12
	13	if(MOJARRITA){
	14	setwd("~/Documents/projects/2014_EDF-Orsay-Lyon2/codes/")
	15	} else {
	16	setwd("~/ownCloud/projects/2014_EDF-Orsay-Lyon2/codes/")
	17	}
	18
	19
	20	matcontrib0 <- read.table(file = "~/tmp/2009_contrib.txt")
	21	n <- nrow(matcontrib0)
	22
	23	sdcontrib <- apply(matcontrib0, 1, sd)
	24	lims <- quantile(sdcontrib, probs = c(.005, .995)) # obtain 1%-extreme data
	25	is_normal <- which((sdcontrib > lims[1]) & (sdcontrib < lims[2]))
	26
	27	matcontri_ext <- matcontrib0[-is_normal, ]""
	28	matcontrib <- matcontrib0[is_normal, ] # wipe out aberrant data
	29
	30	matcontrib <- t(apply(matcontrib, 1, function(x) x / sum(x)))
	31	matcontrib <- t(apply(matcontrib, 1, function(p) log(p / (1 - p)) ))
	32
	33
	34	## b. Transform data & compute CI ####
	35	ci <- CI(matcontrib)
	36	tdata <- ci$tdata; rownames(tdata) <- rownames(matcontrib)
	37	selvar <- ci$selectv
	38
	39	## c. Clustering ##########
	40	K <- 200
	41	system.time(
	42	clfit <- clara(x = tdata[, selvar],
	43	k = K,
	44	sampsize = 4000,
	45	samples = 4,
	46	rngR = TRUE)
	47	)
	48
	49	#save(clfit, file = 'clfit500.Rdata')
	50	# save(clfit, file = 'clfit200RC.Rdata')
	51	save(clfit, file = 'clfit200.Rdata')
	52
	53	rm(ci, matcontrib0, is_normal, lims, selvar)
	54	gc()
	55
	56	## d. Analyze results ##########
	57
	58	#1. Répartition du nombre d'observation par cluster
	59	#plot(sort(table(clfit$clustering), decreasing = TRUE),
	60	# type = 'l', ylab = 'Fréquence', xlab = 'Classe')
	61
	62
	63	#clust <- res$clustering
	64	# centres <- aggregate(conso, clust)
65	# table(clust)
66
67	#sel_veille <- as.Date(rownames(conso)[sel - 1])
68	#sel_lendemain <- as.Date(rownames(conso)[sel + 1])
69
70	#res_clust <- data.frame(date = rownames(conso),
71	#veille = weekdays(sel_veille),
72	#lendemain = weekdays(sel_lendemain),
73	# clust = clust)
74
75	#for(k in 1:K) {
76	# assign(paste0("dates_clust", K),
77	# substr(subset(res_clust, clust == k)$date, 1, 7) )
78	#}
79
80	#dev.off()
81
82	#save(file = paste0(dtitle, "_clust.Rdata"),
83	#res_clust, selvar, K, gap)
84	#}
85
86	#dates_clust1 <- substr(subset(dates, clust == 1)$date, 1, 7)