penalizedSVM (version 1.1.2)

predict: Predict Method for Feature Selection SVM

Description

This function predicts values based upon a model trained by svm. If class assigment is provided, confusion table, missclassification table, sensitivity and specificity are calculated.

Usage

# S3 method for penSVM
predict(object, newdata, newdata.labels = NULL, labels.universe=NULL, …)

Arguments

object

Object of class "penSVM", created by 'svmfs'

newdata

A matrix containing the new input data, samples in rows, features in columns

newdata.labels

optional, new data class labels

labels.universe

important for models produced by loocv: all possible labels in the particular data set

...

additional argument(s)

Value

returns a list of prediction values for classes

pred.class

predicted class

tab

confusion table

error

missclassification error

sensitivity

sensitivity

specificity

specificity

See Also

svm, svmfs

Examples

Run this code
# NOT RUN {
seed<- 123
train<-sim.data(n = 200, ng = 100, nsg = 10, corr=FALSE, seed=seed )
print(str(train)) 

#train standard svm
my.svm<-svm(x=t(train$x), y=train$y, kernel="linear")

# test with other data
test<- sim.data(n = 200, ng = 100, nsg = 10, seed=(seed+1) )

# Check accuracy standard SVM
my.pred <-ifelse( predict(my.svm, t(test$x)) >0,1,-1)
# Check accuracy:
table(my.pred, test$y)

# }
# NOT RUN {
# define set values of tuning parameter lambda1 for SCAD 
lambda1.scad <- c (seq(0.01 ,0.05, .01),  seq(0.1,0.5, 0.2), 1 ) 
# for presentation don't check  all lambdas : time consuming! 
# computation intensive; for demostration reasons only for the first 100 features
# and only for 10 Iterations maxIter=10, default maxIter=700

system.time(fit.scad<- svmfs(x=t(train$x)[,1:100],y=train$y, fs.method="scad", cross.outer= 0,
	grid.search = "discrete",  lambda1.set=lambda1.scad[1:3], show="none",
	parms.coding = "none", maxIter=10,
	inner.val.method = "cv", cross.inner= 5, seed=seed, verbose=FALSE))


# SCAD 
test.error.scad<-predict(fit.scad, newdata=t(test$x)[,1:100],newdata.labels=test$y )
 # Check accuracy SCAD SVM  	
print(test.error.scad$tab)	
# }
# NOT RUN {
#########################################
## analog for 1-norm SVM
#epsi.set<-vector(); for (num in (1:9)) epsi.set<-sort(c(epsi.set, c(num*10^seq(-5, -1, 1 ))) )
#lambda1.1norm <- 	epsi.set[c(3,5)] # 2 params
#
## train 1norm SVM
# norm1.fix<- svmfs(t(train$x), y=train$y, fs.method="1norm", 
#		cross.outer= 0, grid.search = "discrete",  
#		lambda1.set=lambda1.1norm, show="none",
#		parms.coding = "none",
#		maxIter = 700, inner.val.method = "cv", cross.inner= 5,
#		seed=seed, verbose=FALSE ) 	
#	
#	print(norm1.fix)   
#
## L1-norm SVM
#test.error.1norm<-predict(norm1.fix, newdata=t(test$x),newdata.labels=test$y )
# # Check accuracy L1-norm SVM  	
#print(test.error.1norm$tab)	
# }

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