# Automatic vlookup and multiply coefficients with R

I´m trying to code a function in R (stats programming language) that would allow me to automate the calculation of a linear regression (lm)

The problem: The regression is calculated through the "step" function, so the coefficients selected cannot be known in advance. Problem

1. Automate identifying the coefficients selected by the step function.

2. Vlookup and cross multiply the second column of the results Ex."View(OpenCoefs)" (estimates) with the last row(last day) of respective columns of the original data frame "sp"

The desirable solution would be a function that i would just type "run()" that would return the "y"s for each regression, namely, the forecast of the S&P500 index for the following day(Open, Low, High,Close).

The code retrieves data from the yahoo finance website, so it´s operational if you run it.

Here´s the code.

sp<-sp[nrow(sp):1,]

sp<-as.data.frame(sp)

for ( i in 2:nrow( sp ) ) {
sp[ i , "Gr_Open" ] <-
( sp[ i , "Open" ] / sp[ i - 1 , "Open" ] ) - 1
}

for ( i in 2:nrow( sp ) ) {
sp[ i , "Gr_High" ] <-
( sp[ i , "High" ] / sp[ i - 1 , "High" ] ) - 1
}

for ( i in 2:nrow( sp ) ) {
sp[ i , "Gr_Low" ] <-
( sp[ i , "Low" ] / sp[ i - 1 , "Low" ] ) - 1
}

for ( i in 2:nrow( sp ) ) {
sp[ i , "Gr_Close" ] <-
( sp[ i , "Close" ] / sp[ i - 1 , "Close" ] ) - 1
}

for ( i in 2:nrow( sp ) ) {
sp[ i , "Gr_Volume" ] <-
( sp[ i , "Volume" ] / sp[ i - 1 , "Volume" ] ) - 1
}

nRows_in_sp<-1:nrow(sp)

sp<-cbind(sp,nRows_in_sp)

Open_Rollin<-NA

sp<-cbind(sp,Open_Rollin)
for ( i in 2:nrow( sp ) ) {
if(sp[i,"nRows_in_sp"]<=1000)
{
sp[ i , "Open_Rollin" ]<-0
} else {
sp[ i , "Open_Rollin" ]<-(( mean(sp[,"Open"][(i-100):i])))
}
}

Close_Rollin<-NA

nRows_in_sp<-1:nrow(sp)

sp<-cbind(sp,Close_Rollin)

for ( i in 2:nrow( sp ) ) {
if(sp[i,"nRows_in_sp"]<=1000)
{
sp[ i , " Close_Rollin" ]<-0
} else {
sp[ i , "Close_Rollin" ]<-(( mean(sp[,"Close"][(i-100):i])))
}
}

Low_Rollin<-NA

sp<-cbind(sp,Low_Rollin)
for ( i in 2:nrow( sp ) ) {
if(sp[i,"nRows_in_sp"]<=1000)
{
sp[ i , "Low_Rollin" ]<-0
} else {
sp[ i , "Low_Rollin" ]<-(( mean(sp[,"Low"][(i-100):i])))
}
}

High_Rollin<-NA

sp<-cbind(sp,High_Rollin)
for ( i in 2:nrow( sp ) ) {
if(sp[i,"nRows_in_sp"]<=1000)
{
sp[ i , "High_Rollin" ]<-0
} else {
sp[ i , "High_Rollin" ]<-(( mean(sp[,"High"][(i-100):i])))
}
}

Open_GR_Rollin<-NA

sp<-cbind(sp,Open_GR_Rollin)
for ( i in 2:nrow( sp ) ) {
if(sp[i,"nRows_in_sp"]<=1000)
{
sp[ i , "Open_GR_Rollin" ]<-0
} else {
sp[ i , "Open_GR_Rollin" ]<-(( mean(sp[,"Gr_Open"][(i-100):i])))
}
}

Close_GR_Rollin<-NA

sp<-cbind(sp, Close_GR_Rollin)
for ( i in 2:nrow( sp ) ) {
if(sp[i,"nRows_in_sp"]<=1000)
{
sp[ i , "Close_GR_Rollin" ]<-0
} else {
sp[ i , "Close_GR_Rollin" ]<-(( mean(sp[,"Gr_Close"][(i-100):i])))
}
}

Low_GR_Rollin<-NA

sp<-cbind(sp, Low_GR_Rollin)
for ( i in 2:nrow( sp ) ) {
if(sp[i,"nRows_in_sp"]<=1000)
{
sp[ i , "Low_GR_Rollin" ]<-0
} else {
sp[ i , "Low_GR_Rollin" ]<-(( mean(sp[,"Gr_Low"][(i-100):i])))
}
}

High_GR_Rollin<-NA

sp<-cbind(sp, High_GR_Rollin)
for ( i in 2:nrow( sp ) ) {
if(sp[i,"nRows_in_sp"]<=1000)
{
sp[ i , "High_GR_Rollin" ]<-0
} else {
sp[ i , "High_GR_Rollin" ]<-(( mean(sp[,"Gr_High"][(i-100):i])))
}
}

Open_SD_Rollin<-NA

sp<-cbind(sp,Open_SD_Rollin)
for ( i in 2:nrow( sp ) ) {
if(sp[i,"nRows_in_sp"]>100)
{
sp[ i, "Open_SD_Rollin" ] <- sd(sp[,"Open"][(i-100):i])
}
}

Close_SD_Rollin<-NA

sp<-cbind(sp, Close_SD_Rollin)
for ( i in 2:nrow( sp ) ) {
if(sp[i,"nRows_in_sp"]>100)
{
sp[ i, "Close_SD_Rollin" ] <- sd(sp[,"Close"][(i-100):i])
}
}

Low_SD_Rollin<-NA

sp<-cbind(sp, Low_SD_Rollin)
for ( i in 2:nrow( sp ) ) {
if(sp[i,"nRows_in_sp"]>100)
{
sp[ i, "Low_SD_Rollin" ] <- sd(sp[,"Low"][(i-100):i])
}
}

High_SD_Rollin<-NA

sp<-cbind(sp, High_SD_Rollin)
for ( i in 2:nrow( sp ) ) {
if(sp[i,"nRows_in_sp"]>100)
{
sp[ i, "High_SD_Rollin" ] <- sd(sp[,"High"][(i-100):i])
}
}

N <- length(sp[,"Open"])

Openlag <- c(NA, sp[,"Open"][1:(N-1)])
sp<-cbind(sp,Openlag)

Highlag <- c(NA, sp[,"High"][1:(N-1)])

sp<-cbind(sp,Highlag)

Lowlag <- c(NA, sp[,"Low"][1:(N-1)])

sp<-cbind(sp,Lowlag)

Closelag <- c(NA, sp[,"Close"][1:(N-1)])

sp<-cbind(sp,Closelag)

Gr_Openlag <- c(NA, sp[,"Gr_Open"][1:(N-1)])

sp<-cbind(sp,Gr_Openlag)

Gr_Highlag <- c(NA, sp[,"Gr_High"][1:(N-1)])

sp<-cbind(sp,Gr_Highlag)

Gr_Lowlag <- c(NA, sp[,"Gr_Low"][1:(N-1)])

sp<-cbind(sp,Gr_Lowlag)

Gr_Closelag <- c(NA, sp[,"Gr_Close"][1:(N-1)])

sp<-cbind(sp,Gr_Closelag)

Gr_Volumelag <- c(NA, sp[,"Gr_Volume"][1:(N-1)])

sp<-cbind(sp,Gr_Volumelag)

Open_GR_Rollinlag <- c(NA, sp[,"Open_GR_Rollin"][1:(N-1)])

sp<-cbind(sp, Open_GR_Rollinlag)

Low_GR_Rollinlag <- c(NA, sp[,"Low_GR_Rollin"][1:(N-1)])

sp<-cbind(sp, Low_GR_Rollinlag)

High_GR_Rollinlag <- c(NA, sp[,"High_GR_Rollin"][1:(N-1)])
sp<-cbind(sp, High_GR_Rollinlag)

Close_GR_Rollinlag <- c(NA, sp[,"Close_GR_Rollin"][1:(N-1)])

sp<-cbind(sp, Close_GR_Rollinlag)

Open_SD_Rollinlag <- c(NA, sp[,"Open_SD_Rollin"][1:(N-1)])

sp<-cbind(sp, Open_SD_Rollinlag)

Low_SD_Rollinlag <- c(NA, sp[,"Low_SD_Rollin"][1:(N-1)])

sp<-cbind(sp, Low_SD_Rollinlag)

High_SD_Rollinlag <- c(NA, sp[,"High_SD_Rollin"][1:(N-1)])

sp<-cbind(sp, High_SD_Rollinlag)

Close_SD_Rollinlag <- c(NA, sp[,"Close_SD_Rollin"][1:(N-1)])

sp<-cbind(sp, Close_SD_Rollinlag)

OpenCoefs<-coefficients(summary(step(lm(sp[,"Open"] ~ Openlag + Lowlag + Highlag + Closelag + Gr_Openlag + Gr_Lowlag + Gr_Highlag + Gr_Closelag + Gr_Volumelag + Open_GR_Rollinlag + Low_GR_Rollinlag + High_GR_Rollinlag + Close_GR_Rollinlag + Open_SD_Rollinlag + Low_SD_Rollinlag + High_SD_Rollinlag + Close_SD_Rollinlag),direction="both",test="F")))

LowCoefs<-coefficients(summary(step(lm(sp[,"Low"] ~ Openlag + Lowlag + Highlag + Closelag + Gr_Openlag + Gr_Lowlag + Gr_Highlag + Gr_Closelag + Gr_Volumelag + Open_GR_Rollinlag + Low_GR_Rollinlag + High_GR_Rollinlag + Close_GR_Rollinlag + Open_SD_Rollinlag + Low_SD_Rollinlag + High_SD_Rollinlag + Close_SD_Rollinlag),direction="both",test="F")))

HighCoefs<-coefficients(summary(step(lm(sp[,"High"] ~ Openlag + Lowlag + Highlag + Closelag + Gr_Openlag + Gr_Lowlag + Gr_Highlag + Gr_Closelag + Gr_Volumelag + Open_GR_Rollinlag + Low_GR_Rollinlag + High_GR_Rollinlag + Close_GR_Rollinlag + Open_SD_Rollinlag + Low_SD_Rollinlag + High_SD_Rollinlag + Close_SD_Rollinlag),direction="both",test="F")))

CloseCoefs<-coefficients(summary(step(lm(sp[,"Close"] ~ Openlag + Lowlag + Highlag + Closelag + Gr_Openlag + Gr_Lowlag + Gr_Highlag + Gr_Closelag + Gr_Volumelag + Open_GR_Rollinlag + Low_GR_Rollinlag + High_GR_Rollinlag + Close_GR_Rollinlag + Open_SD_Rollinlag + Low_SD_Rollinlag + High_SD_Rollinlag + Close_SD_Rollinlag),direction="both",test="F")))

View(OpenCoefs)

View(LowCoefs)

View(HighCoefs)

View(CloseCoefs)

View(sp)
-
Look at the predict function. It will give what a model will evaluate (predict) for a given set of inputs. If you just want to predict for the last row, use newdata=sp[nrow(sp),]. –  Brian Diggs Feb 4 '13 at 20:42

library(quantmod)
sp <- getSymbols("^GSPC", auto.assign=FALSE)
colnames(sp) <- gsub("^GSPC\\.","",colnames(sp))

sp\$Gr_Open   <- ROC(Op(sp), type="discrete")
sp\$Gr_High   <- ROC(Hi(sp), type="discrete")
sp\$Gr_Low    <- ROC(Lo(sp), type="discrete")
sp\$Gr_Close  <- ROC(Cl(sp), type="discrete")
sp\$Gr_Volume <- ROC(Vo(sp), type="discrete")

N <- 100
sp\$Open_Rollin  <- runMean(sp\$Open, N)
sp\$High_Rollin  <- runMean(sp\$High, N)
sp\$Low_Rollin   <- runMean(sp\$Low, N)
sp\$Close_Rollin <- runMean(sp\$Close, N)

sp\$Open_GR_Rollin  <- runMean(sp\$Gr_Open, N)
sp\$High_GR_Rollin  <- runMean(sp\$Gr_High, N)
sp\$Low_GR_Rollin   <- runMean(sp\$Gr_Low, N)
sp\$Close_GR_Rollin <- runMean(sp\$Gr_Close, N)

sp\$Open_SD_Rollin  <- runSD(sp\$Open, N)
sp\$High_SD_Rollin  <- runSD(sp\$High, N)
sp\$Low_SD_Rollin   <- runSD(sp\$Low, N)
sp\$Close_SD_Rollin <- runSD(sp\$Close, N)

spLag <- lag(sp)
colnames(spLag) <- paste(colnames(sp),"lag",sep="")
sp <- na.omit(merge(sp, spLag))

There's no need to answer your first question in order to answer your second question. You don't have to cross-multiply coefficients with data by hand. You can simply access the fitted values from the model. That requires that you preserve the model though...

f <- Open ~ Openlag + Lowlag + Highlag + Closelag +
Gr_Openlag + Gr_Lowlag + Gr_Highlag + Gr_Closelag + Gr_Volumelag +
Open_GR_Rollinlag + Low_GR_Rollinlag + High_GR_Rollinlag + Close_GR_Rollinlag +
Open_SD_Rollinlag + Low_SD_Rollinlag + High_SD_Rollinlag + Close_SD_Rollinlag

OpenLM <- lm(f, data=sp)
HighLM <- update(OpenLM, High ~ .)
LowLM <- update(OpenLM, Low ~ .)
CloseLM <- update(OpenLM, Close ~ .)

OpenStep <- step(OpenLM,direction="both",test="F")
HighStep <- step(HighLM,direction="both",test="F")
LowStep <- step(LowLM,direction="both",test="F")
CloseStep <- step(CloseLM,direction="both",test="F")

tail(fitted(OpenStep),1)
# 2013-02-01
#    1497.91
tail(fitted(HighStep),1)
# 2013-02-01
#    1504.02
tail(fitted(LowStep),1)
# 2013-02-01
#   1491.934
tail(fitted(CloseStep),1)
# 2013-02-01
#   1499.851
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In my inital post, I mentioned that I was a noob to programming and quantitative analysis. It was edited out :). I appreciate the tip about the predict function, but it´s about the journey. I´m sure I´ll learn alot from your comments. Thanks in advance –  Pedro9 Feb 4 '13 at 20:56
@Pedro9 -- Joshua could see how hard you're working at this, which I'm sure is why he was willing to help. Welcome to SO, and enjoy the journey! –  Josh O'Brien Feb 4 '13 at 22:05
@Pedro9: Josh O'Brien is correct. I could see that you really put forth some effort, so I wanted to show you how I would do it. –  Joshua Ulrich Feb 4 '13 at 22:19