[valse.git] / pkg / R / plot_valse.R

#' Plot
#'
#' It is a function which plots relevant parameters
#'
#'
#' @return several plots
#'
#' @examples TODO
#'
#' @export
#'
plot_valse = function(){
  require("gridExtra")
  require("ggplot2")
  require("reshape2")
  
  ## regression matrices
  gReg = list()
  for (r in 1:K){
    Melt = melt(t((model$phi[,,r])))
    gReg[[r]] = ggplot(data = Melt, aes(x=Var1, y=Var2, fill=value)) +  geom_tile() + 
      scale_fill_gradient2(low = "blue", high = "red", mid = "white", midpoint = 0,  space = "Lab") +
      ggtitle(paste("Regression matrices in cluster",r))
  }
  print(gReg)
  
  ## Differences between two clusters
  k1 = 1
  k2 = 2
  Melt = melt(t(model$phi[,,k1]-model$phi[,,k2]))
  gDiff = ggplot(data = Melt, aes(x=Var1, y=Var2, fill=value)) +  geom_tile() + 
    scale_fill_gradient2(low = "blue", high = "red", mid = "white", midpoint = 0,  space = "Lab") +
    ggtitle(paste("Difference between regression matrices in cluster",k1, "and", k2))
  print(gDiff)
  
  ### Covariance matrices
  matCov = matrix(NA, nrow = dim(model$rho[,,1])[1], ncol = K)
  for (r in 1:K){
    matCov[,r] = diag(model$rho[,,r])
  }
  MeltCov =  melt(matCov)
  gCov = ggplot(data =MeltCov, aes(x=Var1, y=Var2, fill=value)) +  geom_tile() + 
    scale_fill_gradient2(low = "blue", high = "red", mid = "white", midpoint = 0,  space = "Lab") +
    ggtitle("Covariance matrices")
  print(gCov )
  
  ### proportions
  Gam = matrix(0, ncol = K, nrow = n)
  gam  = Gam
  for (i in 1:n){
    for (r in 1:K){
      sqNorm2 = sum( (Y[i,]%*%model$rho[,,r]-X[i,]%*%model$phi[,,r])^2 )
      Gam[i,r] = model$pi[r] * exp(-0.5*sqNorm2)* det(model$rho[,,r])
    }
    gam[i,] = Gam[i,] / sum(Gam[i,])
  }
  affec = apply(gam, 1,which.max)
  gam2 = matrix(NA, ncol = K, nrow = n)
  for (i in 1:n){
    gam2[i, ] = c(gam[i, affec[i]], affec[i])
  }
  bp <- ggplot(data.frame(gam2), aes(x=X2, y=X1, color=X2, group = X2)) +
    geom_boxplot() + theme(legend.position = "none")
  print(bp + background_grid(major = "xy", minor = "none"))
  
  ### Mean in each cluster
  XY = cbind(X,Y)
  XY_class= list()
  meanPerClass= matrix(0, ncol = K, nrow = dim(XY)[2])
  for (r in 1:K){
    XY_class[[r]] = XY[affec == r, ]
    meanPerClass[,r] = apply(XY_class[[r]], 2, mean)
  }
  data = data.frame(mean = as.vector(meanPerClass), cluster = as.character(rep(1:K, each = dim(XY)[2])), time = rep(1:dim(XY)[2],K))
  g = ggplot(data, aes(x=time, y = mean, group = cluster, color = cluster))
  print(g + geom_line(aes(linetype=cluster, color=cluster))+  geom_point(aes(color=cluster)) + ggtitle('Mean per cluster'))
  
}
Commit	Line	Data
4c9cc558	1	#' Plot
	2	#'
	3	#' It is a function which plots relevant parameters
	4	#'
	5	#'
	6	#' @return several plots
	7	#'
	8	#' @examples TODO
	9	#'
	10	#' @export
	11	#'
	12	plot_valse = function(){
	13	require("gridExtra")
	14	require("ggplot2")
	15	require("reshape2")
	16
	17	## regression matrices
	18	gReg = list()
	19	for (r in 1:K){
	20	Melt = melt(t((model$phi[,,r])))
	21	gReg[[r]] = ggplot(data = Melt, aes(x=Var1, y=Var2, fill=value)) + geom_tile() +
	22	scale_fill_gradient2(low = "blue", high = "red", mid = "white", midpoint = 0, space = "Lab") +
	23	ggtitle(paste("Regression matrices in cluster",r))
	24	}
	25	print(gReg)
	26
	27	## Differences between two clusters
	28	k1 = 1
	29	k2 = 2
	30	Melt = melt(t(model$phi[,,k1]-model$phi[,,k2]))
	31	gDiff = ggplot(data = Melt, aes(x=Var1, y=Var2, fill=value)) + geom_tile() +
	32	scale_fill_gradient2(low = "blue", high = "red", mid = "white", midpoint = 0, space = "Lab") +
	33	ggtitle(paste("Difference between regression matrices in cluster",k1, "and", k2))
	34	print(gDiff)
	35
	36	### Covariance matrices
	37	matCov = matrix(NA, nrow = dim(model$rho[,,1])[1], ncol = K)
	38	for (r in 1:K){
	39	matCov[,r] = diag(model$rho[,,r])
	40	}
	41	MeltCov = melt(matCov)
	42	gCov = ggplot(data =MeltCov, aes(x=Var1, y=Var2, fill=value)) + geom_tile() +
	43	scale_fill_gradient2(low = "blue", high = "red", mid = "white", midpoint = 0, space = "Lab") +
	44	ggtitle("Covariance matrices")
	45	print(gCov )
	46
	47	### proportions
	48	Gam = matrix(0, ncol = K, nrow = n)
	49	gam = Gam
	50	for (i in 1:n){
	51	for (r in 1:K){
	52	sqNorm2 = sum( (Y[i,]%%model$rho[,,r]-X[i,]%%model$phi[,,r])^2 )
	53	Gam[i,r] = model$pi[r] * exp(-0.5sqNorm2) det(model$rho[,,r])
	54	}
	55	gam[i,] = Gam[i,] / sum(Gam[i,])
	56	}
	57	affec = apply(gam, 1,which.max)
	58	gam2 = matrix(NA, ncol = K, nrow = n)
	59	for (i in 1:n){
	60	gam2[i, ] = c(gam[i, affec[i]], affec[i])
	61	}
	62	bp <- ggplot(data.frame(gam2), aes(x=X2, y=X1, color=X2, group = X2)) +
	63	geom_boxplot() + theme(legend.position = "none")
	64	print(bp + background_grid(major = "xy", minor = "none"))
65
66	### Mean in each cluster
67	XY = cbind(X,Y)
68	XY_class= list()
69	meanPerClass= matrix(0, ncol = K, nrow = dim(XY)[2])
70	for (r in 1:K){
71	XY_class[[r]] = XY[affec == r, ]
72	meanPerClass[,r] = apply(XY_class[[r]], 2, mean)
73	}
74	data = data.frame(mean = as.vector(meanPerClass), cluster = as.character(rep(1:K, each = dim(XY)[2])), time = rep(1:dim(XY)[2],K))
75	g = ggplot(data, aes(x=time, y = mean, group = cluster, color = cluster))
76	print(g + geom_line(aes(linetype=cluster, color=cluster))+ geom_point(aes(color=cluster)) + ggtitle('Mean per cluster'))
77
78	}