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I would like to write the 10-fold CV code to determine the optimal degree for a polynomial regression model on wage~age from the Wage data in ISLR library. I would like write the code without using the cv.glm() function. I implemented this code from a given code on CV for best subset selection, and from this answer (https://stackoverflow.com/a/24580419/12753007). However there is some flaw with it as resulting MSE for each column shows one same value.

predict.regsubsets=function(object,newdata,id,...){
  form=as.formula(object$call[[2]])
  mat=model.matrix(form,newdata)
  coefi=coef(object,id=id)
  xvars=names(coefi)
  mat[,xvars]%*%coefi
}
library(ISLR)
attach(Wage)
names(Wage)
Wage<- na.omit(Wage)
# first create a grid for the range of the tuning parameter:
degreegrid<- seq(from= 1, to= 10)
# set 10-fold:
k<-10

yourData<- Wage
#Randomly shuffle the data
yourData<-yourData[sample(nrow(yourData)),]
#Create 10 equally size folds:
folds <- cut(seq(1,nrow(yourData)),breaks=k,labels=FALSE)

# set the cverror matrix, row= number of folds; col= values of possible tuning parameters:
cv.errors=matrix(0,k,max(degreegrid))
# Perform 10 fold cross validation
for(j in 1:k){
  #Segement your data by fold using the which() function 
  testIndexes <- which(folds==j,arr.ind=TRUE)
  testData <- yourData[testIndexes, ]
  trainData <- yourData[-testIndexes, ]
  #Use test and train data partitions however you desire...
  
  polyfit<- glm(wage~ poly(age, degree = degreegrid), data = trainData)
  for (i in 1:max(degreegrid)) {
    polypred<- predict(polyfit, newdata= testData, degree=i)
    cv.errors[j,i]=mean((testData$wage-polypred)^2)
  }
}
mean.cv.errors=colMeans(cv.errors) 
mean.cv.errors  
plot(1:k,mean.cv.errors,xlab="Number of Degrees",
     ylab="Cross-Validation Error",type='b')
which.min(mean.cv.errors)

Output:

> mean.cv.errors  
 [1] 1676.175 1676.175 1676.175 1676.175 1676.175 1676.175 1676.175
 [8] 1676.175 1676.175 1676.175

###-----------------------------------------------------------------------

I have just figured out the code. The model fitted in the double-loop has to be placed in the loop of the tuning parameter values (i in 1:length(degreegrid)). Because this loop iterates through the possible values of the tuning parameter, we want to test each one of them out with the glm_model.

library(ISLR)
attach(Wage)
names(Wage)
Wage<- na.omit(Wage)
tr= sample(1:nrow(Wage), nrow(Wage)/2)
te= (-tr)
# first create a grid for the range of the tuning parameter:
degreegrid<- seq(from= 1, to= 10)
# set 10-fold:
k<-10
folds<- sample(1:k, length(tr), replace = T)
cverr<- matrix(0, k, max(degreegrid))
Wagetr<- Wage[tr,]
for(j in 1:k){
  for(i in 1:max(degreegrid)){
    polyfit<- glm(wage~ poly(age, i), data = Wagetr[folds!= j, ])
    polypred<- predict(polyfit, newdata= Wagetr[folds==j,], id=i)
    cverr[j,i]<- mean((Wagetr$wage[folds==j]- polypred)^2)
    
  }
  
}

mean_cverr<- colMeans(cverr)
mean_cverr
plot(1:10,mean_cverr,xlab="Number of degree",
     ylab="Cross-Validation Error",type='b')

which.min(mean_cverr)
  • This isn't an instant answer, but I'd thoroughly recommend reading tidymodels.org for a very well-organised way to do any type of analysis like this – p0bs Jul 5 at 10:31
  • @p0bs well at this stage I would like to get this versatile block of CV code straight, instead of using packages for each situation. But thanks anyways. – siegfried Jul 5 at 11:59

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