# How to write for loop when function increases with each iteration?

I am trying to estimate the probability of detecting animals from n.sites over multiple observation periods when animals are removed and detection changes in time and space. It works if I do something like this for 5 observation periods:

``````for(i in 1:nsites){
mu[i,1] <- p[i,1]
mu[i,2] <- p[i,2]*(1-p[i,1])
mu[i,3] <- p[i,3]*(1-p[i,1])*(1-p[i,2])
mu[i,4] <- p[i,4]*(1-p[i,1])*(1-p[i,2])*(1-p[i,3])
mu[i,5] <- p[i,5]*(1-p[i,1])*(1-p[i,2])*(1-p[i,3])*(1-p[i,4])
}
``````

The probability at time 2 is dependent on the probability at time 1 and the probability at time 3 is dependent on the probabilities at times 1 and 2. If I were only doing this for 5 time periods it wouldn't be a big deal to write this out. But as I get 10, 15, 20+ time periods, it's is quite messy to write out. I feel like there should be a way to write this loop without typing out each step, but I just can't think of how to do it. Maybe additional indexing or other control statement or power function. If p[i] were the same in each jth observation (i.e. p[i,1] = p[i,2] = p[i,3], etc.) it would be:

``````p[i]*(1-p[i])^5
``````

Any suggestions would be greatly appreciated.

This is BUGS language code. I work in R and sent the code to JAGS via the rjags package. BUGS, R, or pseudo code would suit my purposes.

Here is R code that would simulate the problem:

``````set.seed(123)
testp <- matrix(runif(108, 0.1, 0.5), 108, 5)
testmu <- matrix(NA, 108, 5)

for(i in 1:nsites){
testmu[i,1] <- testp[i,1]
testmu[i,2] <- testp[i,2]*(1-testp[i,1])
testmu[i,3] <- testp[i,3]*(1-testp[i,1])*(1-testp[i,2])
testmu[i,4] <- testp[i,4]*(1-testp[i,1])*(1-testp[i,2])*(1-testp[i,3])
testmu[i,5] <- testp[i,5]*(1-testp[i,1])*(1-testp[i,2])*(1-testp[i,3])*(1-testp[i,4])
}
``````

Thanks for any help. Dan

-

@Frank's answer is cleaner (and faster, probably), but this will also work and might be a little easier to understand.

``````testmu2 <- matrix(NA, 108, 5)
nsites = 108
np = 5

for (i in 1:nsites) {
fac <- 1
testmu2[i,1] <- testp[i,1]
for (j in 2:np) {
fac <- fac * (1-testp[i,j-1])
testmu2[i,j] <- testp[i,j] * fac
}
}
max(abs(testmu2-testmu))
[1] 2.775558e-17
``````
-
+1. I don't know if it's easier to read, but I might write the inner loop's body as `testmu2[i,j] <- testp[i,j]*(fac <- fac * (1-testp[i,j-1]))` –  Frank Nov 22 '13 at 1:01
@Frank - I didn't even know you could use two assignments on one line. Thanks #somuchtolearn –  djhocking Nov 22 '13 at 3:06
You were correct in your estimates of speed. Frank's method was ten times faster than yours or mine. –  BondedDust Nov 22 '13 at 3:07
I chose this because it's more general (doesn't use R specific functions). It may still have an issue in BUGS language because fac is being reassigned, but I hopefully can work around that. –  djhocking Nov 22 '13 at 23:34

This really does look like a task well suited to R's `Reduce`:

``````testmu3 <- matrix(NA, 108, 5)
nsites = 108
np = 5

for (i in 1:nsites) {
testmu3[ i, ] <- Reduce( function(x,y) x*(1-y), testp[i, ],
accumulate=TRUE)
}
max(abs(testmu3-testmu))
[1] 0
``````

The accumulate parameter creates a growing vector of intermediate results.

``````> testp[1, ]
[1] 0.215031 0.215031 0.215031 0.215031 0.215031

> Reduce( function(x,y) x*(1-y), testp[1, ],  accumulate=TRUE)
[1] 0.21503101 0.16879267 0.13249701 0.10400605 0.08164152
``````
-
+1, Cool. I didn't know about that `accumulate` option, even though I use `Reduce` quite a lot. For the OP's reference... the loop could be eliminated here, too, using `t(apply(testp,1,function(z) Reduce( function(x,y) x*(1-y),z,accumulate=TRUE)))` –  Frank Nov 22 '13 at 0:53
I actually never heard of the Reduce function before. Very neat. Thanks for the answer as well as the new function! –  djhocking Nov 22 '13 at 2:55

Here's one way:

``````testmu2 <- testp*t(apply(cbind(1,1-testp[,-5]),1,cumprod))
``````

On my computer, they almost match:

``````> max(abs(testmu2-testmu))
[1] 2.775558e-17
``````

I don't know about BUGS/JAGS, but the idea is to take the cumulative product of your 1-p matrix across its columns first, and then take p*result.

-
Very slick, thank you. I still have trouble wrapping my head around the apply function. For loops are much more natural for me, but the apply function is so much faster. –  djhocking Nov 22 '13 at 3:00