# Calculate Returns over Period of Time

I'm trying to get a time series of returns for holding a certain asset for a specific time.

My dataframe looks like this:

``````Date          Price
1998-01-01     20
1998-01-02     22
1998-01-03     21
1998-01-04     25
...
1998-01-20     25
1998-01-21     19
1998-01-21     20
....
1998-02-01     30
1998-02-02     28
1998-02-03     25
1998-02-04     26
etc.
``````

I have 1 observation for each day and my time series goes from 1998-1999.

What I would like to do now is calculate a return for holding my asset for 20 days (i.e. buying it at the first day and selling it at day 20), and do this for each day. So I would like to calculate this:

1.day: Return(20days) = log (Price(t=20) / Price (t=0)),

2.day: Return(20days) = log (Price(t=21) / Price (t=1)),

3.day: Return(20days) = log (Price(t=22) / Price (t=2))

etc., i.e. do this for every day in my sample.

So, my resulting dataframe would look like this:

``````Date          Return
1998-01-01     0.2
1998-01-02     0.4
1998-01-03     0.6
1998-01-04     0.1
...
1998-01-20     0.1
1998-01-21     0.2
1998-01-21     0.5
....
1998-02-01     0.1
1998-02-02     0.2
1998-02-03     0.5
1998-02-04     0.01
etc.
``````

Is there a way in R to say: take the first 20 observations, calculate the return. Take observation 2-21, calculate the return. Take observation 3-22, calculate the return etc.?

I'm totally stuck and would appreciate some help. Thanks! Dani

-

I suggest switching to a time series class, like `xts` or `zoo`. But if you just want to get it done, and learn more later, you can do it pretty easily as a data frame. Note that I have to pad the return vectors with `NA`s to make it line up correctly and that a `hold` of 20 really buy on 1 and sells on 1 + 20:

``````> library(xts)
> set.seed(2001)
> n <- 50
> hold <- 20
> price <- rep(55, n)
> walk <- rnorm(n)
> for (i in 2:n) price[i] <- price[i-1] + walk[i]
> data <- data.frame(date=as.Date("2001-05-25") + seq(n), price=price)
> data <- transform(data, return=c(diff(log(price), lag=hold), rep(NA, hold)))
``````

If you're ready for `xts` or `zoo` (this should work in either), then I suggest using `rollapply` to get the forward look (assuming you want the forward looking return, which makes it a lot easier to form portfolios today and see how it works into the future):

``````> data.xts <- xts(data[, -1], data[, 1])
> f <- function(x) log(tail(x, 1)) - log(head(x, 1))
> data.xts\$returns.xts <- rollapply(data.xts\$price, FUN=f, width=hold+1, align="left", na.pad=T)
``````

The two approaches are the same:

``````> head(data.xts, hold+2)
price       return  returns.xts
[1,] 55.00000  0.026746496  0.026746496
[2,] 54.22219  0.029114744  0.029114744
[3,] 53.19811  0.047663206  0.047663206
[4,] 53.50088  0.046470723  0.046470723
[5,] 53.85202  0.041843116  0.041843116
[6,] 54.75061  0.018464467  0.018464467
[7,] 55.52704 -0.001105607 -0.001105607
[8,] 56.15930 -0.024183803 -0.024183803
[9,] 56.61779 -0.010757559 -0.010757559
[10,] 55.51042  0.005494771  0.005494771
[11,] 55.17217  0.044864991  0.044864991
[12,] 56.07005  0.025411005  0.025411005
[13,] 55.47287  0.052408720  0.052408720
[14,] 56.10754  0.034089602  0.034089602
[15,] 56.35584  0.075726190  0.075726190
[16,] 56.40290  0.072824657  0.072824657
[17,] 56.05761  0.070589032  0.070589032
[18,] 55.93916  0.069936575  0.069936575
[19,] 56.50367  0.081570964  0.081570964
[20,] 56.12105  0.116041931  0.116041931
[21,] 56.49091  0.095520517  0.095520517
[22,] 55.82406  0.137245367  0.137245367
``````
-

You can use the `ROC` function in the TTR package, or you can just create your own function.

``````> library(quantmod)  # loads TTR
> getSymbols("SPY")
> tail(ROC(Cl(SPY),20))
SPY.Close
2010-12-09 0.01350383
2010-12-10 0.02307920
2010-12-13 0.03563051
2010-12-14 0.03792853
2010-12-15 0.04904805
2010-12-16 0.05432540
> tail(log(Cl(SPY)/lag(Cl(SPY),20)))
SPY.Close
2010-12-09 0.01350383
2010-12-10 0.02307920
2010-12-13 0.03563051
2010-12-14 0.03792853
2010-12-15 0.04904805
2010-12-16 0.05432540
``````
-

Alternatively, if you are using the package xts, then life is made incredibly simple. This is a straight copy-paste of a function I wrote myself a while ago:

``````ret<-function(x,k=1){
return(diff(log(x),k))
}
``````
-
I think you want the `k` applied as the `lag` for `diff` function and not the `base` for the `log` function. Simple parenthesis shift will do it. –  shabbychef Aug 27 '11 at 22:53
thanks, fixed now –  Chris Taylor Aug 29 '11 at 0:05

You can just use offset indices by subtracting from a range. (.... but remember that R does not use 0 as a valid index.) Let's say your prices are the second column in a dataframe named prcs2 the first three returns with an interval of 19 days with your data would be :

``````prcs2[ (20:22)-19, 2] <-c(20,22,21)
prcs2[ (20:22), 2] <-c(25,19,20)
log(prcs2[20:22, 2]/prcs2[ (20:22)-19, 2])
#[1]  0.22314355 -0.14660347 -0.04879016
``````
-

The following function should do it:

``````getReturn <- function(data, n=20) {

#Assumes 'data' is a two-column data frame with date in the first column, price in the second

num.rows <- nrow(data)

output.range <- 1:(num.rows-20)

sell.price <- data[output.range+20,2]

returns <- cbind(data[output.range,],returns)
names(returns) <- c("Date","Price","Return")

return(returns)

}
``````

Sample input and output:

``````> head(data)
Date Price
1 2001-01-01    20
2 2001-01-02    19
3 2001-01-03    19
4 2001-01-04    18
5 2001-01-05    18
6 2001-01-06    18
> return<-getReturn(data)
Date Price     Return
1 2001-01-01    20 0.09531018
2 2001-01-02    19 0.14660347
3 2001-01-03    19 0.14660347
4 2001-01-04    18 0.20067070
5 2001-01-05    18 0.24512246
6 2001-01-06    18 0.20067070
``````
-

Sample Data

``````price <- matrix(c(20,22,21,25,25,19,20,30,28,25,26,27,30,32,31,30),ncol= 1);
``````

Calculate 1 day Log Return

``````OneDayLogReturn <- c(diff(log(price)));
``````

Calculate 10 days Log Return

``````TenDaysLogReturn <- c(diff(log(price),10))
``````

results:

``````0.2623643 0.2047944 0.3566749 0.2468601 0.2151114 0.4567584
``````

verify by :

``````for (i in 1:6) {print(log(price[10+i]/price[i]))}
``````

Similarly, 20 Days return can be calculated using larger sample date and use

``````c(diff(log(price),20))
``````

``````c(diff(log(price\$Return),20))