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DJI_TimeSeries_65to45Ratio_BigVAR~
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DJI_TimeSeries_65to45Ratio_BigVAR~
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## ----global_options, include=FALSE---------------------------------------
#knitr::opts_chunk$set(include=TRUE, warning=FALSE, message=FALSE,echo=FALSE)
## ----install_libraries, results='hide'-----------------------------------
#install.packages("sqldf")
#install.packages("dummies")
#install.packages("forecast")
#install.packages("orderedLasso")
#install.packages("glmnet")
#install.packages("h2o")
#install.packages("addendum")
#install.packages("testthat")
#install.packages("imputateTS")
#install.packages("BigVAR")
#install.packages("reshape")
#install.packages("ggplot2")
#install.packages("Quandl")
#install.packages("knitr")
#devtools::use_testthat
#library(devtools)
#install.packages("devtools")
#install_github("SteffenMoritz/imputeTS")
#install_github("gabrielrvsc/HDeconometrics")
#install.packages("HDeconometrics")
#install.packages("githubinstall")
#install.packages("quantmod")
rm(list=ls())
#setwd("R:/AnalyticsTeam/Personal/May/BitBucket/Gemini Time Series")
#setwd("C:/Users/rmcpherson/Documents/Segments/Phil Welt Segment/Gemini")
library(sqldf) #for running sql on data frames
library(dummies) #for creating one-hot encoding
library(forecast) #for the Holt-Winters forecast filter
library(glmnet) #for running regularized GLM
library(knitr) #for reproducible research, i.e., Markdown
#library(testthat)
library(BigVAR)
library(orderedLasso)
library(reshape)
library(ggplot2)
library(Quandl)
library(HDeconometrics)
library(imputeTS)
library(quantmod)
library(xts)
## ----set_globals---------------------------------------------------------
##########################
##Input Global Variables##
##########################
##########################
#Input the column name of the dependent variable to predict.
dependent.variable <- "DJI.Chg"
##########################
##########################
#Set the maximum lag for adjusting the variables in the data.
#each variable will get a new column for each lag, up to the maximum set here.
maxlag <- 30
##########################
##########################
#Type 'TRUE' if you want to include an offset in the GLM calculation, FALSE otherwise.
include.offset <- FALSE
##########################
##########################
#Type the column name of the variable you would like to use as an offset, if any.
#offset.variable <- "UnitCount"
##########################
##########################
#Input the column name that has the time increments in it, such as years, or year/months.
time.increment.variable <- "Date"
##########################
##########################
#Select whether to include plots with the arima, pre-whitening step
include.arima.plots <- FALSE
##########################
##########################
#Select whether to include cross correlation plots
include.cross.correlation.plots <- TRUE
##########################
##########################
#Select whether to include quartile to quartile (QQ) plots
include.QQ.plots <- FALSE
##########################
## ----load_data, results='hide'-------------------------------------------
#Note: this process takes the data in descending order, with the most recent data at the
CPI <- Quandl("RATEINF/CPI_USA", api_key="DJGcfzQc5RYP1JSycMBv", collapse="annual", start_date="1960-12-31", end_date="2017-12-31", type="raw", order="asc", force_irregular=TRUE)
#Nonfinancial corporate business; short-term debt as a percentage of total debt, Annual
shortTermDebtToLongTerm <- Quandl("FED/FL104140006_A", api_key="DJGcfzQc5RYP1JSycMBv", collapse="annual", start_date="1960-12-31", end_date="2017-12-31", type="raw", order="asc", force_irregular=TRUE)
#Financial soundness indicator, households; debt as a percent of gross domestic product
debtToGDP <- Quandl("FED/FL010000336_Q", api_key="DJGcfzQc5RYP1JSycMBv",collapse="annual", start_date="1960-12-31", end_date="2017-12-31", type="raw", order="asc", force_irregular=TRUE)
GDP <- Quandl("FED/FU086902001_A", api_key="DJGcfzQc5RYP1JSycMBv", collapse="annual", start_date="1960-12-31", end_date="2017-12-31", type="raw", order="asc", force_irregular=TRUE)
m1Velocity <- Quandl("FRED/M1V", api_key="DJGcfzQc5RYP1JSycMBv",collapse="annual", start_date="1960-12-31", end_date="2017-12-31", type="raw", order="asc", force_irregular=TRUE)
m2Velocity <- Quandl("FRED/M2V", api_key="DJGcfzQc5RYP1JSycMBv", collapse="annual", start_date="1960-12-31", end_date="2017-12-31", type="raw", order="asc", force_irregular=TRUE)
raw.ts <- cbind(m1Velocity, m2Velocity, GDP[-1,], debtToGDP[-1,], shortTermDebtToLongTerm[-1,], CPI[-1,])
raw.ts <- cbind(m1Velocity, m2Velocity, GDP[-1,], debtToGDP[-1,], shortTermDebtToLongTerm[-1,], CPI[-1,])
#save time increment vector
#time.increments <- unique(raw_data_dummies[,time.increment.variable])
#time.increments <- time.increments[sort.list(time.increments, decreasing=FALSE)]
time.increments <- raw.ts[,time.increment.variable]
rownames(raw.ts) <- raw.ts[,1]
data <- raw.ts[, !(names(raw.ts) %in% "Date")]
colnames(data) <- c("CPI","shortTermDebtToLongTerm","debtToGDP","GDP","m1Velocity","m2Velocity")
##Import birth data
births <- read.csv("BirthsModified.csv")
#impute the na values
births.interp <- na.interpolation(ts(births))
births.export <- apply(births.interp, 2, rev)
head(births.export)
write.csv(births.export, "births_interp_no_blanks.csv")
births.trunc <- births.interp[1:57,3:5]
births.2009 <- apply(births.trunc, 2, rev)
head(births.2009)
#na.interpolation(ts(births.trunc[,2]))
#births.interp <- apply(births.trunc, 2, na.interpolation)
#colnames(births.interp) <- c("Year", "Births", "BirthRate")
#head(births.interp)
#head(data)
#str(data)
#?rev
#births.2009 <- apply(births.interp[], 2, rev)
#################################
##Not included - series too short
##Get SPX data
SPX <- getSymbols("^GSPC",auto.assign = FALSE)
?getSymbols
SPX.xts <- as.xts(SPX)
SPX.yearly <- to.yearly(SPX.xts)
#getSymbols("DJI", src = "yahoo", from = start_date, to = end_date)
DJI <- getSymbols("DJI", src = "yahoo")
DJI.xts <- as.xts(DJI)
DJI.interp <- na.interpolation(DJI.xts)
DJI.yearly <- to.yearly(DJI.interp)
#################################
##Import historical Dow Jones Industrial Average data
Dow <- read.csv("DJI_Historical_Chg_Data.csv")
head(Dow)
Dow.interp <- na.interpolation(Dow)
DJI.Chg <- Dow[1:57,2]
SeriesData <- cbind(births.2009, data, DJI.Chg)
SeriesData <- SeriesData[,-1] #remove the "Year" column
head(SeriesData)
col.names <- colnames(SeriesData)
x <- SeriesData[, !(names(SeriesData) %in% dependent.variable)]
head(x)
#scale the dependent variable
x.scaled <- scale(x)
#Isolate dependent variable values, based on name given in global variable inputs above
y <- SeriesData[,dependent.variable]
y.unscaled <- y
#scale the dependent variable
y.scaled <- scale(y)
#save column names
x.colnames <- colnames(x)
## ----ARIMA, results='asis'-----------------------------------------------
#i=20
num.cols <- length(x[1,])
#apply(x,1,function(x) sum(is.na(x)))
#str(x)
#?auto.arima
#generate ARIMA plots...intent is to get ARIMA parameters, rather than forecasts
x.arima.residuals = NULL
for (i in 1:num.cols){
fit <- auto.arima(x.scaled[,i])
pdf(file=paste("plots/arima_",x.colnames[i],".pdf",sep=""))
if(include.arima.plots == TRUE){
par(mar=c(8,4,2,2))
plot(forecast(fit,h=maxlag), sub=paste(x.colnames[i]))
}
dev.off()
#assemble a table of ARIMA residuals for use in cross-correlation analysis
temp.resid <- resid(fit)
x.arima.residuals <- as.matrix(cbind(x.arima.residuals, temp.resid))
}
#run arima transformation on the dependent variable
fit=NULL
fit <- auto.arima(y.scaled)
par(mar=c(8,4,2,2))
pdf(file=paste("plots/arima_",dependent.variable,".pdf",sep=""))
plot(forecast(fit,h=1), sub=paste(dependent.variable, sep=""))
dev.off()
y.arima.residuals <- resid(fit)
## ------------------------------------------------------------------------
if(include.QQ.plots == TRUE){
#check distributions of independent variables for normality
for (i in 1:length(x.scaled[1,])){
pdf(file=paste("plots/qqnorm_",x.colnames[i],".pdf",sep=""))
qqnorm(x.arima.residuals[,i], main=paste(x.colnames[i]))
dev.off()
}
#check dependent variable for normality
pdf(file=paste("plots/qqnorm_",dependent.variable,".pdf",sep=""))
qqnorm(y.arima.residuals, main=paste(dependent.variable,sep=""))
dev.off()
}
## ------------------------------------------------------------------------
#i=2
##cross correlation analysis
#leading indicators in 'x' will have negative lag values for the most significant
#correlations in the chart.
#note: analysis is run on ARIMA residuals so as to pre-whiten the data
#i=1
dir.create("plots")
if(include.cross.correlation.plots == TRUE){
for (i in 1:length(x[1,])){
pdf(file=paste("plots/ccf_",x.colnames[i],".pdf",sep=""))
par(mar=c(5,7,4,2)) #set the margins so title does not get cut off
ccf(x.arima.residuals[,i], y.arima.residuals, plot=TRUE, main=paste(x.colnames[i]), na.action = na.contiguous)
dev.off()
}
}
## ----analytical_dataset, results='hide'----------------------------------
#x
#y
#x.arima.residuals <- apply(x.arima.residuals, 2, rev)
#y.arima.residuals <- rev(y.arima.residuals)
#time.increments <- rev(time.increments)
#x2 <- subset(x, select= -c(X.Dividends, X.From.the.rest.of.the.world.6.))
Y <- cbind.data.frame(x, y)
colnames(Y) <- col.names
nms <- dependent.variable
Y <- as.matrix(Y)
# Fit a Basic VAR-L(3,4) on simulated data
T1=floor(nrow(Y)/3)
T2=floor(2*nrow(Y)/3)
#?constructModel
#m1=constructModel(Y,p=4,struct="Basic",gran=c(20,10),verbose=FALSE,IC=FALSE,T1=T1,T2=T2,ONESE=TRUE)
#m1=constructModel(Y,p=4,struct="Tapered",gran=c(50,10),verbose=FALSE,T1=T1,T2=T2,IC=FALSE)
#plot(m1)
#results=cv.BigVAR(m1)
#plot(results)
#predict(results,n.ahead=1)
#SparsityPlot.BigVAR.results(results)
#str(results)
#results@preds
#results@alpha
#results@Granularity
#results@Structure
#results@lagmax
#results@Data
#plot(results@Data)
#install.packages("devtools")
#library(devtools)
#install_github("gabrielrvsc/HDeconometrics")
###################################
#The above, BigVAR package will not handle data sets this wide. Trying the
#Bayesian Vector Auto Regression (BVAR) algorithm
###################################
##Perform analysis on pre-whitened data
# = load package and data = #
#install.packages("HDeconometrics")
#library(HDeconometrics)
#data("voldata")
# = Break data into in and out of sample to test model accuracy= #
#Yin=voldata[1:5499,]
#Yout=voldata[-c(1:5499),]
Yin = Y[1:T2,]
Yout = Y[(T2+1):(T1+T2),]
# = Run models = #
# = OLS = #
#modelols=HDvar(Yin,p=2) # takes a while to run
#predols=predict(modelols,h=2)
# = BVAR = #
#?lbvar
#?predict
modelbvar=lbvar(Yin, p = 5, delta = 0.5)
predbvar=predict(modelbvar,h=5)
# = Forecasts of the volatility = #
k=paste(dependent.variable)
pdf(file=paste("plots/forecast.pdf",sep=""))
plot(c(Y[,k],predbvar[,k]),type="l", main=paste(dependent.variable))
#lines(c(rep(NA,length(Y[,k])),predols[,k]))
lines(c(rep(NA,length(Y[,k])),predbvar[,k]))
abline(v=length(Y[,k]),lty=2,col=4)
#legend("topleft",legend="BVAR",col=2,lty=1,lwd=1,seg.len=1,cex=1,bty="n")
dev.off()
# = Overall percentual error = #
#MAPEols=abs((Yout-predols)/Yout)*100
#MAPEbvar=abs((Yout-predbvar)/Yout)*100
#matplot(MAPEols,type="l",ylim=c(0,80),main="Overall % error",col="lightsalmon",ylab="Error %")
#aux=apply(MAPEbvar,2,lines,col="lightskyblue1")
#lines(rowMeans(MAPEols),lwd=3,col=2,type="b")
#lines(rowMeans(MAPEbvar),lwd=3,col=4,type="b")
#legend("topleft",legend=c("OLS","BVAR"),col=c(2,4),lty=1,lwd=1,seg.len=1,cex=1,bty="n")
# = Influences = #
#aux=modelbvar$coef.by.block[2:23]
#impacts=abs(Reduce("+", aux ))
#diag(impacts)=0
#I=colSums(impacts)
#R=rowSums(impacts)
#par(mfrow=c(2,1))
#barplot(I,col=rainbow(30),cex.names = 0.3, main = "Most Influent")
#barplot(R,col=rainbow(30),cex.names = 0.3, main = "Most Influenced")
pdf(file=paste("plots/barchart.pdf",sep=""))
aux=modelbvar$coef.by.block
impacts=abs(Reduce("+", aux ))
diag(impacts)=0
I=colSums(impacts)
R=rowSums(impacts)
par(mfrow=c(2,1))
barplot(I,col=rainbow(30),cex.names = 0.3, main = "Most Influent")
barplot(R,col=rainbow(30),cex.names = 0.3, main = "Most Influenced")
dev.off()
###################################
##Perform analysis on NON pre-whitened data
Y <- cbind.data.frame(x.scaled, y.unscaled)
colnames(Y) <- col.names
head(Y)
nms <- dependent.variable
Y <- as.matrix(Y)
# Fit a Basic VAR-L(3,4) on simulated data
T1=floor(nrow(Y)/3)
T2=floor(2*nrow(Y)/3)
# = Break data into in and out of sample to test model accuracy= #
Yin = Y[1:T2,]
Yout = Y[(T2+1):(T1+T2),]
# = Run models = #
# = OLS = #
#modelols=HDvar(Yin,p=2) # takes a while to run
#predols=predict(modelols,h=2)
# = BVAR = #
#?lbvar
#?predict
modelbvar=lbvar(Yin, p = 5, delta = 0.5)
predbvar=predict(modelbvar,h=5)
# = Forecasts of the volatility = #
k=paste(dependent.variable)
pdf(file=paste("plots/forecast_not_whitened.pdf",sep=""))
plot(c(Y[,k],predbvar[,k]),type="l", main=paste(dependent.variable, "Not Whitened"))
#lines(c(rep(NA,length(Y[,k])),predols[,k]))
lines(c(rep(NA,length(Y[,k])),predbvar[,k]))
abline(v=length(Y[,k]),lty=2,col=4)
#legend("topleft",legend="BVAR",col=2,lty=1,lwd=1,seg.len=1,cex=1,bty="n")
dev.off()
# = Overall percentual error = #
#MAPEols=abs((Yout-predols)/Yout)*100
#MAPEbvar=abs((Yout-predbvar)/Yout)*100
#matplot(MAPEols,type="l",ylim=c(0,80),main="Overall % error",col="lightsalmon",ylab="Error %")
#aux=apply(MAPEbvar,2,lines,col="lightskyblue1")
#lines(rowMeans(MAPEols),lwd=3,col=2,type="b")
#lines(rowMeans(MAPEbvar),lwd=3,col=4,type="b")
#legend("topleft",legend=c("OLS","BVAR"),col=c(2,4),lty=1,lwd=1,seg.len=1,cex=1,bty="n")
# = Influences = #
#aux=modelbvar$coef.by.block[2:23]
#impacts=abs(Reduce("+", aux ))
#diag(impacts)=0
#I=colSums(impacts)
#R=rowSums(impacts)
#par(mfrow=c(2,1))
#barplot(I,col=rainbow(30),cex.names = 0.3, main = "Most Influent")
#barplot(R,col=rainbow(30),cex.names = 0.3, main = "Most Influenced")
pdf(file=paste("plots/barchart_not_whitened.pdf",sep=""))
aux=modelbvar$coef.by.block
impacts=abs(Reduce("+", aux ))
diag(impacts)=0
I=colSums(impacts)
R=rowSums(impacts)
par(mfrow=c(2,1))
barplot(I,col=rainbow(30),cex.names = 0.3, main = "Most Influent")
barplot(R,col=rainbow(30),cex.names = 0.3, main = "Most Influenced")
dev.off()