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boosting_source.r
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192 lines (162 loc) · 7.76 KB
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XGBoost_ensemble_ts_para = function(target, target_test, nmodel, Kmax, test_number,time_sample,rank)
# input:
# target: traning data
# target_test: test data set
# nmodel: number of models to save for changepoint detection
# Kmax: max number of features for model building
# test_number: number of sample in validation set
# time_sample: Boolean whether the data is a time series data
# rank: Boolean for variable importance rank. Mute for iid data ( time_sample is FALSE)
# output:
# list of 3
# item 1: frct value
# item 2: frct [low, mean, high] for each model in the ensemble
# item 3: variable rank
{
hard_dummy1 = function(modeldata, testdata)
{
AA = sapply(modeldata, class)
if ('factor' %in% AA){
temp_name = names(AA)[AA == 'factor']
for (i in 1:length(temp_name)){
B = levels(modeldata[, temp_name[i]])
temp_dataframe = data.frame(as.numeric(levels(modeldata[, temp_name[i]])[modeldata[, temp_name[i]]]))
colnames(temp_dataframe) = paste(temp_name[i],'_num', sep= "")
modeldata = cbind(modeldata, temp_dataframe)
temp_dataframe1 = data.frame(as.numeric(levels(modeldata[, temp_name[i]])[testdata[, temp_name[i]]]))
colnames(temp_dataframe1) = paste(temp_name[i],'_num', sep= "")
testdata = cbind(testdata, temp_dataframe1)
}
modeldata = modeldata[, -which(names(modeldata) %in% temp_name)]
testdata = testdata[, -which(names(testdata) %in% temp_name)]
}
return(list(modeldata, testdata))
}
error = ones(nmodel, 1) * Inf
variable_number = ncol(target_all1) -1
error = ones(nmodel, 1) * Inf
b = ones(1, test_number)/test_number
temp_final = matrix (data = NA, nmodel, test_number)
sale_final = matrix (data = NA, nmodel, test_number)
lowsale_final = matrix (data = NA, nmodel, test_number)
upsale_final = matrix (data = NA, nmodel, test_number)
index_final = vector(mode = "list", length = nmodel)
number_factor = vector(mode = "list", length = nmodel)
stime <- system.time({
for (K in 2:Kmax)
{
print (K)
test = combn (variable_number,K)+ 1
temp =matrix (data = NA, test_number, ncol(test))
temp1 =matrix (data = NA, test_number, ncol(test))
sale =matrix (data = NA, test_number, ncol(test))
lower_sale =matrix (data = NA, test_number, ncol(test))
upper_sale =matrix (data = NA, test_number, ncol(test))
K_results <- foreach (i = 1:ncol(test), .combine = cbind) %dopar%
{
index_predictor = c(1,test[, i])
if (time_sample){
modelData = target[1:(nrow(target)-test_number), index_predictor, drop = FALSE]
newdata =data.frame(target[nrow(target):(nrow(target)-test_number + 1), test[, i], drop = FALSE])
after = hard_dummy1(modelData, newdata)
modelData = after[[1]]
newdata = after[[2]]
fit_std = xgboost(label= modelData[,1], data = as.matrix(modelData[,-1]), objective='reg:linear', eta = 0.01, nrounds=1000, nthread = 5, verbose = 0)
pred_sale = predict(fit_std, as.matrix(newdata))
temp[, i]= (pred_sale/ target[nrow(target):(nrow(target)-test_number + 1), 1]-1) * 100
}else{
index_test = sample.int(nrow(target), test_number, replace = FALSE)
index_train = setdiff(1:nrow(target),index_test)
modelData = target[index_train, index_predictor, drop = FALSE]
newdata =data.frame(target[index_test, test[, i], drop = FALSE])
after = hard_dummy1(modelData, newdata)
modelData = after[[1]]
newdata = after[[2]]
fit_std = xgboost(label= modelData[,1], data = as.matrix(modelData[,-1]), objective='reg:linear', eta = 0.01, nrounds=1000, nthread = 5, verbose = 0)
pred_sale = predict(fit_std, as.matrix(newdata))
temp[, i]= (pred_sale[,1]/ target[index_test, 1]-1) * 100
}
sale[,i] = pred_sale
list(i, sum(as.matrix( b * abs(temp[1:test_number, i]))) , temp[, i], sale[, i], K)
}
K_results= as.matrix(K_results)
if (min(unlist(K_results[2,]), na.rm = TRUE)< max(error))
{
total_error = rbind(as.matrix(unlist(K_results[2,])), error)
index_model = order(total_error, na.last = TRUE, decreasing = FALSE)[1:nmodel]
temp_final = rbind(matrix(unlist(K_results[3,]), ncol = test_number, byrow = TRUE), temp_final)[index_model, ]
sale_final = rbind(matrix(unlist(K_results[4,]), ncol = test_number, byrow = TRUE), sale_final)[index_model, ]
index_final = append(split(test, col(test)), index_final)[index_model]
error = as.matrix(total_error[index_model])
}
}
})
test = total_error[index_model]
quartz()
barplot(test[1:nmodel])
if (nmodel>=4){
ansmean=cpt.meanvar(test[1:nmodel])
par(mar=c(5,6,4,2))
plot(ansmean,yaxt="n", xaxt="n",cpt.col='dark blue', cpt.width=5, lwd = 5, xlab ='', ylab ='')
axis(2, cex.axis=2)
axis(1, cex.axis=2)
title(xlab = 'order of models', cex.lab=2)
title(ylab = 'MAPE on validation set', cex.lab=2)
print(ansmean)
model_max = ansmean@cpts[1]
}else{
model_max = nmodel
}
##########################
if (rank && time_sample){
rep = 10
error_permuate = array(data=NA, dim=c(model_max,rep, ncol(target) -1))
for (ii in 1:(ncol(target)-1))
{
for(iii in 1:rep)
{
target_p = target
target_p[, ii+1] = target[sample(1:nrow(target), nrow(target), replace = FALSE), ii+1]
for (i in 1:model_max)
{
index_predictor = c(1, index_final[[i]])
modelData = target_p[1:(nrow(target)-test_number), index_predictor, drop = FALSE]
newdata =target_p[(nrow(target)-test_number + 1):nrow(target), index_final[[i]] , drop = FALSE]
after = hard_dummy1(modelData, newdata)
modelData = after[[1]]
newdata = after[[2]]
fit_std = xgboost(label= modelData[,1], data = as.matrix(modelData[,-1]), objective='reg:linear', eta = 0.01, nrounds=1000, nthread = 5, verbose = 0)
pred_sale = predict(fit_std, as.matrix(newdata))
error_permuate[i, iii, ii] = mean(abs((pred_sale/ target[(nrow(target)-test_number + 1):nrow(target), 1]-1) * 100))
}
}
}
output = rbind(names(target)[order(apply(error_permuate, 3, mean, trim = .2), decreasing=T) + 1],
sort(apply(error_permuate, 3, mean, trim = .2), decreasing = T))
quartz()
par(las=2) # make label text perpendicular to axis
par(mar=c(5,15,4,2)) # increase y-axis margin.
barplot(as.numeric(rev(output[2,1:5])), horiz=TRUE, xlab='MAPE increase',names.arg=rev(output[1,1:5]),
cex.names =2, cex.lab = 2, cex.axis= 1.2, col=rainbow(10))
} else{
output = 'Did not rank'
}
########################################
# forecast
#########################################
pred_sale = array(data=NA, dim=c(nrow(target_test), 1, model_max))
for (i in 1:model_max)
{
names(target_all1)[index_final[[i]]]
index_predictor = c(1, index_final[[i]])
modelData = target
modelData = modelData[, index_predictor, drop = FALSE]
newdata = target_test[, index_predictor[2:length(index_predictor)], drop = FALSE]
after = hard_dummy1(modelData, newdata)
modelData = after[[1]]
newdata = after[[2]]
fit_std = xgboost(label= modelData[,1], data = as.matrix(modelData[,-1]), objective='reg:linear', eta = 0.01, nrounds=1000, nthread = 5, verbose = 0)
pred_sale[, , i] = predict(fit_std, as.matrix(newdata))
}
return (list(frct_value = mean(pred_sale[, 1, ]), models_lm_output_perrow = pred_sale, variables_rank = output))
}