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searchModelGAKknnMAA.R
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searchModelGAKknnMAA.R
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# Title : Daily generalized aspects / planet Y activation count KNN regression model
# with GA feature selection that maximize Rsquared on train data to fit for
# daily price percent change estimation.
# Purpose : Based on ModelLD this model has some variations:
# 1) Planets MO, ME, VE, SU fast planets applying to all slow planets.
# 2) CV folds to 5 with 1 repeats for weak learners, folds to 5 with 5 repeats for ensamble.
# 3) Split to 80/20 proportion.
# 4) Validate fit using Actbin daily price change (buy / sell) instead of Effect
# 5) GA feature detection that fit to maximize Rsquared train data.
# 6) Fit 5 weak learners for diff percent change.
# 7) Ensamble weak learnets to fit for Actbin to predict categorical (buy / sell) signal.
# 8) Optimize weak learners for RMSE.
# 9) GA feature selection popSize = 50 and iter = 20.
# 10) KKNN K param set to 7.
library(boot)
library(caret)
library(psych)
library(gbm)
library(ModelMetrics)
source("./analysis.r")
source("./indicatorPlots.r")
modelId <- "ensamble-gakknn-MAA"
zdiffPercentCut <- 2
maPriceFsPeriod <- 2
maPriceSlPeriod <- 3
trainDataStartDate <- as.Date("2010-01-01")
trainDataEndDate <- as.Date("2020-08-15")
testDataStartDate <- as.Date("2020-09-01")
orbLimit <- 4
kMax <- 7
gaPopSize <- 100
gaMaxIter <- 20
nBits <- 13
wlCVFolds <- 5
wlCVRepeats <- 1
enCVFolds <- 5
enCVRepeats <- 5
pxSelectAll <- c(
'MO',
'ME',
'VE',
'SU'
)
pySelectAll <- c(
'ME',
'VE',
'SU',
'MA',
#'CE',
#'VS',
'JU',
'SA',
#'NN',
#'CH',
'UR',
'NE',
'PL'
)
idCols <- c('Date', 'Hour')
setModernMixAspectsSet1()
setPlanetsMOMEVESUMACEVSJUNNSAURCHNEPL()
hourlyPlanets <<- openHourlyPlanets('planets_12', clear = F)
dailyAspectsRows <- dailyHourlyAspectsTablePrepare(hourlyPlanets, idCols, orbLimit)
control <- trainControl(
method = "repeatedcv",
number = wlCVFolds,
repeats = wlCVRepeats,
savePredictions = "all",
verboseIter = F,
allowParallel = T,
trim = F
)
searchModel <- function(symbol) {
cat("\nProcessing", symbol, "model search...\n")
securityData <- mainOpenSecurity(
symbol, maPriceFsPeriod, maPriceSlPeriod,
"%Y-%m-%d", trainDataStartDate, trainDataEndDate
)
# Filter the extreme outliers.
cat(paste("Original days observations rows:", nrow(securityData)), "\n")
securityData <- securityData[abs(zdiffPercent) <= zdiffPercentCut]
hist(securityData$diffPercent)
cat(paste("Post filter days observations rows:", nrow(securityData)), "\n\n")
prepareDailyAspects <- function(pxSelect, pySelect) {
dailyAspectsGeneralizedCount <- dailyAspectsGeneralizedCount(
dailyAspects = dailyAspectsRows,
orbLimit = orbLimit,
pxSelect = pxSelect,
pySelect = pySelect
)
dailyPlanetYActivationCount <- dailyPlanetYActivationCount(
dailyAspects = dailyAspectsRows,
orbLimit = orbLimit,
pxSelect = pxSelect,
pySelect = pySelect
)
dailyAspects <- merge(dailyAspectsGeneralizedCount, dailyPlanetYActivationCount, date = "Date")
return(dailyAspects)
}
modelTrain <- function(pxSelect, pySelect) {
cat("Using PX:", pxSelect, "- PY:", pySelect, "\n")
if (length(pxSelect) == 0) {
cat("Invalid pxSelect params\n\n")
return(NULL)
}
if (length(pySelect) <= 3) {
cat("Invalid pySelect params\n\n")
return(NULL)
}
dailyAspects <- prepareDailyAspects(pxSelect, pySelect)
aspectView <- merge(
securityData[, c('Date', 'diffPercent', 'Actbin', 'Eff')],
dailyAspects, by = "Date"
)
trainIndex <- createDataPartition(aspectView$diffPercent, p = 0.80, list = FALSE)
aspectViewTrain <- aspectView[trainIndex,]
aspectViewValidate <- aspectView[-trainIndex,]
useFeatures <- names(dailyAspects)[-1]
selectCols <- c('diffPercent', useFeatures)
#cat("Selected cols:", selectCols, "\n")
fitModel <- train(
formula(diffPercent ~ .),
data = aspectViewTrain[, ..selectCols],
method = "kknn",
metric = "RMSE",
trControl = control,
tuneGrid = expand.grid(
kmax = kMax,
distance = 2,
kernel = "optimal"
)
)
# Validate data predictions.
validateDiffPercentPred <- predict(fitModel, aspectViewValidate, type = "raw")
validateMAE <- mae(aspectViewValidate$diffPercent, validateDiffPercentPred)
validateRMSE <- rmse(aspectViewValidate$diffPercent, validateDiffPercentPred)
validateR2 <- cor(aspectViewValidate$diffPercent, validateDiffPercentPred)^2
cat("Validate MAE:", validateMAE, "RMSE:", validateRMSE, "R2:", validateR2, "\n")
trainMAE <- fitModel$results$MAE
trainRMSE <- fitModel$results$RMSE
trainR2 <- fitModel$results$Rsquared
cat("Train MAE:", trainMAE, "RMSE:", trainRMSE, "R2:", trainR2, "\n\n")
return(fitModel)
}
parseSolutionParameters <- function(solution) {
pxSelect <- pxSelectAll[solution[1:4] == 1]
pySelect <- pySelectAll[solution[5:nBits] == 1]
return(list(
pxSelect = pxSelect,
pySelect = pySelect
))
}
findRelevantFeatures <- function(solution) {
params <- parseSolutionParameters(solution)
fitModel <- modelTrain(params$pxSelect, params$pySelect)
# Invalid GA parameters that failed fit, penalize with high negative value.
if (is.null(fitModel)) {
return(-1)
}
#return(fitModel$results$RMSE)
#return(fitModel$results$MAE)
return(fitModel$results$Rsquared)
}
solutionModelTrain <- function(params) {
# Different partition for each weak learner train
trainIndex <- createDataPartition(securityData$diffPercent, p = 0.80, list = FALSE)
securityDataTrain <- securityData[trainIndex,]
securityDataValidate <- securityData[-trainIndex,]
fitModel <- modelTrain(params$pxSelect, params$pySelect)
return(fitModel)
}
cat("\nProcessing GA features selection\n")
gar <- ga(
"binary",
fitness = findRelevantFeatures,
nBits = nBits,
names = c(
'MOX',
'MEX',
'VEX',
'SUX',
'MEY',
'VEY',
'SUY',
'MAY',
'JUY',
'SAY',
'URY',
'NEY',
'PLY'
),
popSize = gaPopSize, maxiter = gaMaxIter, run = gaMaxIter,
selection = gabin_rwSelection, mutation = gabin_raMutation,
crossover = gabin_spCrossover, population = gabin_Population,
elitism = base::max(1, round(gaPopSize * 0.3)),
pmutation = 0.4, pcrossover = 0.3,
parallel = F, monitor = gaMonitor, keepBest = T
)
cat("\n")
summary(gar) %>% print()
cat("\nProcessing weak learners train\n")
params <- parseSolutionParameters(gar@solution)
fitModel1 <- solutionModelTrain(params)
fitModel1 %>% varImp() %>% print()
fitModel2 <- solutionModelTrain(params)
fitModel2 %>% varImp() %>% print()
fitModel3 <- solutionModelTrain(params)
fitModel3 %>% varImp() %>% print()
fitModel4 <- solutionModelTrain(params)
fitModel4 %>% varImp() %>% print()
fitModel5 <- solutionModelTrain(params)
fitModel5 %>% varImp() %>% print()
dailyAspects <- prepareDailyAspects(params$pxSelect, params$pySelect)
aspectView <- merge(
securityData[, c('Date', 'diffPercent', 'Actbin', 'Eff')],
dailyAspects, by = "Date"
)
# Predict outcomes for all weak learner models.
aspectView$DiffPred1 <- predict(fitModel1, aspectView, type = "raw")
aspectView$DiffPred2 <- predict(fitModel2, aspectView, type = "raw")
aspectView$DiffPred3 <- predict(fitModel3, aspectView, type = "raw")
aspectView$DiffPred4 <- predict(fitModel4, aspectView, type = "raw")
aspectView$DiffPred5 <- predict(fitModel5, aspectView, type = "raw")
# Ensamble model data partition.
trainIndex <- createDataPartition(aspectView$Actbin, p = 0.80, list = FALSE)
aspectViewTrain <- aspectView[trainIndex,]
aspectViewValidate <- aspectView[-trainIndex,]
cat("\nProcessing ensamble train\n")
probCols <- c("DiffPred1", "DiffPred2", "DiffPred3", "DiffPred4", "DiffPred5")
topModel <- train(
x = aspectViewTrain[, ..probCols],
y = aspectViewTrain$Actbin,
method = "gbm",
metric = "Kappa",
trControl = trainControl(
method = "repeatedcv",
number = enCVFolds,
repeats = enCVRepeats,
savePredictions = "all",
classProbs = T,
verboseIter = F,
allowParallel = T,
trim = F
),
tuneLength = 3,
verbose = F
)
topModel %>% summary() %>% print()
# Validate data predictions.
aspectViewValidate$EffPred <- predict(topModel, aspectViewValidate, type = "raw")
cat("\n", symbol, "MODEL VALIDATE RESULT:\n")
table(
actual = aspectViewValidate$Actbin,
predicted = aspectViewValidate$EffPred
) %>% caret::confusionMatrix() %>% print()
# Reserved data for validation.
securityDataTest <- mainOpenSecurity(
symbol, maPriceFsPeriod, maPriceSlPeriod,
"%Y-%m-%d", testDataStartDate
)
aspectViewTest <- merge(
securityDataTest[, c('Date', 'Actbin', 'Eff')],
dailyAspects,
by = "Date"
)
# Predict outcomes for all weak learner models.
aspectViewTest$DiffPred1 <- predict(fitModel1, aspectViewTest, type = "raw")
aspectViewTest$DiffPred2 <- predict(fitModel2, aspectViewTest, type = "raw")
aspectViewTest$DiffPred3 <- predict(fitModel3, aspectViewTest, type = "raw")
aspectViewTest$DiffPred4 <- predict(fitModel4, aspectViewTest, type = "raw")
aspectViewTest$DiffPred5 <- predict(fitModel5, aspectViewTest, type = "raw")
# Final ensamble prediction.
aspectViewTest$EffPred <- predict(topModel, aspectViewTest, type = "raw")
cat("\n", symbol, "MODEL TEST RESULT:\n")
testResult <- table(
actualclass = aspectViewTest$Actbin,
predictedclass = aspectViewTest$EffPred
) %>% caret::confusionMatrix()
print(testResult)
# Full data set prediction.
dailyAspects$DiffPred1 <- predict(fitModel1, dailyAspects, type = "raw")
dailyAspects$DiffPred2 <- predict(fitModel2, dailyAspects, type = "raw")
dailyAspects$DiffPred3 <- predict(fitModel3, dailyAspects, type = "raw")
dailyAspects$DiffPred4 <- predict(fitModel4, dailyAspects, type = "raw")
dailyAspects$DiffPred5 <- predict(fitModel5, dailyAspects, type = "raw")
# Ensamble buy probability and class prediction.
dailyAspects$BuyProb <- predict(topModel, dailyAspects, type = "prob")$buy
dailyAspects$EffPred <- predict(topModel, dailyAspects, type = "raw")
# Round probabilities.
dailyAspects[, DiffPred1 := format(DiffPred1, format = "f", big.mark = ",", digits = 2)]
dailyAspects[, DiffPred2 := format(DiffPred2, format = "f", big.mark = ",", digits = 2)]
dailyAspects[, DiffPred3 := format(DiffPred3, format = "f", big.mark = ",", digits = 2)]
dailyAspects[, DiffPred4 := format(DiffPred4, format = "f", big.mark = ",", digits = 2)]
dailyAspects[, DiffPred5 := format(DiffPred5, format = "f", big.mark = ",", digits = 2)]
dailyAspects[, BuyProb := format(BuyProb, format = "f", big.mark = ",", digits = 2)]
aspectsCols <- names(aspectView)[-seq(2, 4)]
exportCols <- c(aspectsCols, "EffPred")
fwrite(dailyAspects[, ..exportCols], paste("./predictions/", symbol, "-predict-", modelId, ".csv", sep = ""))
return(
list(symbol=symbol, results=testResult)
)
}
listFilePath <- npath(paste("./symbols/working.csv", sep=""))
symbolsList <- read.csv(listFilePath, header=F, stringsAsFactors=F)
testResults <- lapply(symbolsList$V1, searchModel)
cat("\nMODEL SEARCH SUMMARY:\n\n")
for(idx in 1:length(testResults)) {
cat(testResults[[idx]]$symbol, "TEST RESULT:\n")
print(testResults[[idx]]$results)
}