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I have a large data frame (named z) that looks like this:

    RPos    M1
    1   -0.00020
    2   0.00010
    3   -0.00012
    4   -0.00035
    5   -0.00038 
...etc (about 300,000 observations)

It is essentially a time series (although it is actually a data frame, not ts or zoo). Where RPos is the index number (explicitly stored), and M1 is any metric.

I have another data frame (named actionlist) with about 30,000 *non-consecutive observations. Each value in actionlist's RPos column represents the last of 34 consecutive points.

My final piece of data is a single data frame (named x) of only 34 consecutive observations.

My goal is to calculate the correlation coefficients between x and each observation in actionlist (which, again, is the end-point of 34 consecutive observations).

To do this I must generate these 34-point consecutive point time series segments from z (the large data frame).

Currently, I am doing it like this:

n1<-33:0
for(i in 1:nrow(actionlist))
{
    crs[i,2]<-cor(z[actionlist$RPos[i]+n1,2],x[,2])  
}

When looking at the Rprof readout this is what I get:

$by.self
              self.time self.pct total.time total.pct
[.data.frame       0.68    25.37       0.98     36.57
.Call              0.22     8.21       0.22      8.21
cor                0.16     5.97       2.30     85.82
...etc

It looks as though [.data.frame is taking the longest. Specifically I am pretty sure that it is this part: z[actionlist$RPos[i]+n1,2]

How can I speed up (eliminate the need for?) this part of the function?

I asked a similar question before, except instead of looking within a restricted list (actionlist) I was looking through every possible consecutive 34-observation within z. The answer was posted here, but I cannot figure out how to adapt it to a restricted list.

Any help would be very appreciated!

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1  
It will be easier to help you if you post some reproducible code and test data. –  Andrie Feb 15 '12 at 21:30
3  
Also, it would be easier (for me especially!) if you used the same terminology in this as in the previous answer. And is there any reason you need z and x to be data.frames?? It's very wasteful to repeatedly subset things you don't need to, so for instance, you could easily take x[,2] outside of the loop, by doing x2 <- x[,2] once outside, and then referring to that vector in the loop as x2. Likewise, indexing using $Rpos[i] isn't needed at all if Rpos itself just runs from 1:nrow(z)... –  Josh O'Brien Feb 15 '12 at 21:53
    
Yeah you are definitely right, in the future I will use consistent terminology. I'll keep the subsetting thing in mind. –  Mike Furlender Feb 16 '12 at 23:04

1 Answer 1

up vote 4 down vote accepted

The most straightforward is probably to build a matrix containing the data you want to compute the correlation with, and eschew the loop altogether.

# Sample data
n <- 3e5
m <- 3e4
k <- 35
z <- data.frame(
  RPos = 1:n,
  M1   = rnorm(n)
)
actionlist <- sample( k:n, m )
x <- rnorm(k)

system.time( for (j in 1:10) {
  # Index of the observations we want
  i <- sapply( (k-1):0, function(u) actionlist - u )
  # Data we want to compute the correlation with
  y <- matrix( z$M1[i], nr=nrow(i) )
  # Computations
  result <- cor(t(y),x)
} ) # 150ms per iteration
share|improve this answer
    
Excellent! That sped things up a ton. Thanks a lot! –  Mike Furlender Feb 16 '12 at 23:05

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