# how to convert loop statement to r style code

I am familiar with R - and i am finding it difficult to do r style matrix functions (instead of loops) with a problem i am working on.

The basic function is this - i have a bunch of variables obtained from multiple subjects. I run a PCA on the variables for dimension reduction. Then i select a number of principal components that explains 90% of the variance. I create a regression model to be able to predict the principal components from the demographic information from the original dataset.

I then attempt to go in reverse - i create a simulated dataset with the demographic variables. I use the simulated variables to predict a new set of principal components. I use the predicted components to calculate the measured variable that would be associated with the simulated subject.

The code i have for this -

``````    #create a random dataset
library (truncnorm)
subject= c(1:10)
age = rtruncnorm(10,a=10,b=90, mean=30,sd=40)
gender = sample(c("M","F"), prob=c(.48,.52), 10, replace = TRUE)
#5 variables obtained from each subject
v1 = rtruncnorm(10,a=12,b=23, mean=18,sd=6)
v2 = rtruncnorm(10,a=14,b=28, mean=16,sd=10)
v3 = rtruncnorm(10,a=25,b=43, mean=34,sd=8)
v4 = rtruncnorm(10,a=9,b=33, mean=21,sd=12)
v5 = rtruncnorm(10,a=3,b=8, mean=5.5,sd=2.5)

#this is our main data frame
mydata = data.frame(subject,age,gender,v1,v2,v3,v4,v5)

#run pca on the main data
mypca <- prcomp(mydata[4:8], center = TRUE, scale = TRUE )
summary(mypca)

#add the principal components to the data frame
mydata = data.frame(mydata,mypca\$x)

#create a simple regression model
#predict the principal component using demographics from our data
#only use 3 principal components
regression_model <- list()
for (i in 1:3)
{
var <- sprintf("lm(PC%d~as.numeric(age)+as.factor(gender),mydata)", i)
regression_model[[i]] <- eval(parse(text = var))
summary(regression_model[[i]])
}

#simulate data for prediction
subject= c(1:100)
age = rtruncnorm(100,a=10,b=90, mean=30,sd=40)
gender = sample(c("M","F"), prob=c(.48,.52), 100, replace = TRUE)

simulated_data = data.frame(subject, age, gender)

#predict the principal components from the simulated data
#project the principal components back to original variables
predicted_data = data.frame()
for (row in 1:nrow(simulated_data))
{
predicted_pc = list()
#predict each PC from the regression model using predict function
newdata = simulated_data[row,]
for (i in 1:3)
{

prediction<-predict(regression_model[[i]],newdata = newdata, interval = "prediction")
#once we have a prediction we choose a random value between
#the lower and upper prediction interval
#This is done to effectively add random noise into the predicted value
lower_interval = prediction
upper_interval = prediction
mean = prediction
sd=upper_interval-mean
predicted_pc[[i]]=rtruncnorm(1,a=lower_interval,b=upper_interval,mean=mean,sd=sd)
}

#convert the predicted PCs into a data frame
predicted_pc_matrix<- t(as.matrix(as.numeric(predicted_pc)))
colnames(predicted_pc_matrix)<-c(colnames(mypca\$x[,1:3]))

#use the newly predicted PCs to calculate back to our variables
predicted_vars<-t(t(predicted_pc_matrix %*% t(mypca\$rotation[,1:3])) * mypca\$scale + mypca\$center)

#build the predicted data frame
predicted_data<-rbind(predicted_data,cbind(newdata,predicted_vars))

}

#the predicted data frame has the predicted data for the 100 simulated subjects
``````

This works and i am getting a predicted data frame at the end. It seems to slow down as i increase the number of simulated data (to be expected).

My question is - how would i remove the for loops and take advantage of R's matrix formats and faster processing of matrices?

After some research i found a way to convert the loops to matrix statements - Here it is

``````    #create a random dataset
library (truncnorm)
subject= c(1:10)
age = rtruncnorm(10,a=10,b=90, mean=30,sd=40)
gender = sample(c("M","F"), prob=c(.48,.52), 10, replace = TRUE)
#5 variables obtained from each subject
v1 = rtruncnorm(10,a=12,b=23, mean=18,sd=6)
v2 = rtruncnorm(10,a=14,b=28, mean=16,sd=10)
v3 = rtruncnorm(10,a=25,b=43, mean=34,sd=8)
v4 = rtruncnorm(10,a=9,b=33, mean=21,sd=12)
v5 = rtruncnorm(10,a=3,b=8, mean=5.5,sd=2.5)

#this is our main data frame
mydata = data.frame(subject,age,gender,v1,v2,v3,v4,v5)

#run pca on the main data
mypca <- prcomp(mydata[4:8], center = TRUE, scale = TRUE )
summary(mypca)

#simulate data for prediction
subject= c(1:100)
age = rtruncnorm(100,a=10,b=90, mean=30,sd=40)
gender = sample(c("M","F"), prob=c(.48,.52), 100, replace = TRUE)

simulated_data = data.frame(subject, age, gender)

#################old loop based approach #########################

##add the principal components to the data frame
##mydata = data.frame(mydata,mypca\$x)
##
##create a simple regression model
##predict the principal component using demographics from our data
##only use 3 principal components
##
##
##regression_model <- list()
##for (i in 1:3)
##{
##  var <- sprintf("lm(PC%d~as.numeric(age)+as.factor(gender),mydata)", i)
##  regression_model[[i]] <- eval(parse(text = var))
##  summary(regression_model[[i]])
##}
##
##predict the principal components from the simulated data
##project the principal components back to original variables
##predicted_data = data.frame()
##for (row in 1:nrow(simulated_data))
##{
##  predicted_pc = list()
##  #predict each PC from the regression model using predict function
##  newdata = simulated_data[row,]
##  for (i in 1:3)
##  {
##
##   prediction<-predict(regression_model[[i]],newdata = newdata, interval = "prediction")
##   #once we have a prediction we choose a random value between
##   #the lower and upper prediction interval
##   #This is done to effectively add random noise into the predicted value
##   lower_interval = prediction
##   upper_interval = prediction
##   mean = prediction
##   sd=upper_interval-mean
##   predicted_pc[[i]]=rtruncnorm(1,a=lower_interval,b=upper_interval,mean=mean,sd=sd)
##  }
##
##  #convert the predicted PCs into a data frame
##  predicted_pc_matrix<- t(as.matrix(as.numeric(predicted_pc)))
##  colnames(predicted_pc_matrix)<-c(colnames(mypca\$x[,1:3]))
##
##
##  #use the newly predicted PCs to calculate back to our variables
##  predicted_vars<-t(t(predicted_pc_matrix %*% t(mypca\$rotation[,1:3])) * mypca\$scale + mypca\$center)
##
##  #build the predicted data frame
##  predicted_data<-rbind(predicted_data,cbind(newdata,predicted_vars))
##
##}
###################################################################

#################new matrix based approach #######################

#add the principal components to the data frame
mydata\$x = mypca\$x

#create a simple regression model
regression_model = lm(x~as.numeric(age)+factor(gender),data=mydata)

#predict the principal components from the simulated data
output=predict(regression_model,newdata = simulated_data)

#unfortunately MLM doesnt give us prediction intervals
#so calculate intervals manually

object = regression_model
newdata = simulated_data
level = 0.95
tfrac <- qt((1 - level)/2, object\$df.residual)

form <- formula(object)
form[] <- NULL
X <- model.matrix(form, newdata)
Q =  forwardsolve(t(qr.R(object\$qr)), t(X))
unscaled.se <- sqrt(colSums(Q ^ 2))
res.var <- sqrt(colSums(residuals(object) ^ 2) / object\$df.residual)
pred.var = res.var
ip=tcrossprod(unscaled.se, res.var)

hwid <- tfrac * sqrt(ip + pred.var)

#prediction interval - lower and upper
lwr = output - hwid
upr = output + hwid
mn = output
sd = hwid

#use the prediction interval to find a random value
#between lower and upper interval
#this will serve as our predicted pc
predicted_pc= rtruncnorm(1,a=lwr, b= upr, mean = mn, sd = sd)
predicted_pc = matrix(unlist(predicted_pc),ncol=ncol(mypca\$x),byrow = FALSE)

#use the newly predicted PCs to calculate back to our variables
predicted_vars<-t(t(predicted_pc %*% t(mypca\$rotation)) * mypca\$scale + mypca\$center)

#build the predicted data frame
predicted_data=cbind(simulated_data,predicted_vars)

###################################################################

#the predicted data frame has the predicted data for the 100 simulated subjects