R/data_generator.R
In XiDsLab/DtracePLN: PLNet: Sparse precision matrix estimation via lasso penalized D-trace loss in the multivariate Poisson log-normal model
Defines functions
data_generator
Documented in
data_generator
#Function for generating the synthetic data
data_generator<-function(n = 100, p = 50, densy_degree = 0.05, sd_ls = 0.1, mean_ls = log(10),value_nondiagonal = 0.3){
##
## Step 1: generate the graph and the corresponding precision matrix
G_1<-matrix(rep(0,p^2),nrow = p)
G_1[upper.tri(G_1)][sample(1:(p*(p-1)/2),floor(densy_degree*(p*(p-1)/2))+1,replace = FALSE)]<-1
index_1<-G_1[upper.tri(G_1)]
G_1<-t(G_1)+G_1
diag(G_1)<-rep(1,p)
bg_mat<-diag(p)
bg_mat[upper.tri(bg_mat)][index_1==1]<-value_nondiagonal
bg_mat<-bg_mat+t(bg_mat)-diag(p)
#generate a precision matrix
scalar_para1<-0.3
scalar_para2<-0.1
Pre_mat<-G_1*bg_mat+diag(rep(abs(min(eigen(G_1*bg_mat)$values))+scalar_para2,p))
##
## Step 2: generate the library size
S_depth<-exp(rnorm(n,mean = mean_ls,sd = sd_ls))
S_depth<-ifelse(S_depth==0,0.5,S_depth)
##
## Step 3: generator the observed count data
log_a<-MASS::mvrnorm(n=n, c(rep(-2,floor(p*0.6)),rep(-0.5,(p - floor(p*0.6)))), solve(Pre_mat))
log_a<-ifelse(log_a>50,50,log_a)
a<-exp(log_a)
b<-a * matrix(rep(S_depth,each=p),nrow = n,byrow = TRUE)
Y<-matrix(NA,nrow = n,ncol = p)
for(i in 1:n){
for(j in 1:p){
Y[i,j]<-rpois(1,b[i,j])
}
}
##names
colnames(Y)<-paste("Gene",1:ncol(Y),sep = "")
rownames(Y)<-paste("Cell",1:nrow(Y),sep = "")
rownames(Pre_mat)<-paste("Gene",1:ncol(Y),sep = "")
colnames(Pre_mat)<-paste("Gene",1:ncol(Y),sep = "")
names(S_depth)<-paste("Cell",1:nrow(Y),sep = "")
##
## Return the result
return(list(obs_mat = Y, S_depth = S_depth, Pre_mat = Pre_mat))
##
}
XiDsLab/DtracePLN documentation built on Dec. 18, 2021, 7:21 p.m.
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Defines functions data_generator
Documented in data_generator
#Function for generating the synthetic data
data_generator<-function(n = 100, p = 50, densy_degree = 0.05, sd_ls = 0.1, mean_ls = log(10),value_nondiagonal = 0.3){
##
## Step 1: generate the graph and the corresponding precision matrix
G_1<-matrix(rep(0,p^2),nrow = p)
G_1[upper.tri(G_1)][sample(1:(p*(p-1)/2),floor(densy_degree*(p*(p-1)/2))+1,replace = FALSE)]<-1
index_1<-G_1[upper.tri(G_1)]
G_1<-t(G_1)+G_1
diag(G_1)<-rep(1,p)
bg_mat<-diag(p)
bg_mat[upper.tri(bg_mat)][index_1==1]<-value_nondiagonal
bg_mat<-bg_mat+t(bg_mat)-diag(p)
#generate a precision matrix
scalar_para1<-0.3
scalar_para2<-0.1
Pre_mat<-G_1*bg_mat+diag(rep(abs(min(eigen(G_1*bg_mat)$values))+scalar_para2,p))
##
## Step 2: generate the library size
S_depth<-exp(rnorm(n,mean = mean_ls,sd = sd_ls))
S_depth<-ifelse(S_depth==0,0.5,S_depth)
##
## Step 3: generator the observed count data
log_a<-MASS::mvrnorm(n=n, c(rep(-2,floor(p*0.6)),rep(-0.5,(p - floor(p*0.6)))), solve(Pre_mat))
log_a<-ifelse(log_a>50,50,log_a)
a<-exp(log_a)
b<-a * matrix(rep(S_depth,each=p),nrow = n,byrow = TRUE)
Y<-matrix(NA,nrow = n,ncol = p)
for(i in 1:n){
for(j in 1:p){
Y[i,j]<-rpois(1,b[i,j])
}
}
##names
colnames(Y)<-paste("Gene",1:ncol(Y),sep = "")
rownames(Y)<-paste("Cell",1:nrow(Y),sep = "")
rownames(Pre_mat)<-paste("Gene",1:ncol(Y),sep = "")
colnames(Pre_mat)<-paste("Gene",1:ncol(Y),sep = "")
names(S_depth)<-paste("Cell",1:nrow(Y),sep = "")
##
## Return the result
return(list(obs_mat = Y, S_depth = S_depth, Pre_mat = Pre_mat))
##
}
R Package Documentation
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Note that we can't provide technical support on individual packages. You should contact the package authors for that.
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