Vectorize function to avoid loop

I'm trying to speed up my code because it's running very long. I already found out where the problem lies. Consider the following example:

``````x<-c((2+2i),(3+1i),(4+1i),(5+3i),(6+2i),(7+2i))
P<-matrix(c(2,0,0,3),nrow=2)
out<-sum(c(0.5,0.5)%*%mtx.exp(P%*%(matrix(c(x,0,0,x),nrow=2)),5))
``````

I have a vector x with complex values, the vector has 12^11 entries and then I want to calculate the sum in the third row. (I need the function mtx.exp because it's a complex matrix power (the function is in the package Biodem). I found out that the %^% function does not support complex arguments.)

So my problem is that if I try

``````sum(c(0.5,0.5)%*%mtx.exp(P%*%(matrix(c(x,0,0,x),nrow=2)),5))
``````

I get an error: "Error in pot %*% pot : non-conformable arguments." So my solution was to use a loop:

``````tmp<-NULL
for (i in 1:length(x)){
tmp[length(tmp)+1]<-sum(c(0.5,0.5)%*%mtx.exp(P%*%matrix(c(x[i],0,0,x[i]),nrow=2),5))
}
``````

But as said, this takes very long. Do you have any ideas how to speed up the code? I also tried sapply but that takes just as long as the loop.

I hope you can help me, because i have to run this function approximatly 500 times and this took in first try more than 3 hours. Which is not very satisfying..

Thank u very much

-

The code can be sped up by pre-allocating your vector,

``````tmp <- rep(NA,length(x))
``````

but I do not really understand what you are trying to compute: in the first example,
you are trying to take the power of a non-square matrix, in the second, you are taking the power of a diagonal matrix (which can be done with `^`).

The following seems to be equivalent to your computations:

``````sum(P^5/2) * x^5
``````

EDIT

If `P` is not diagonal and `C` not scalar, I do not see any easy simplification of `mtx.exp( P %*% C, 5 )`.

You could try something like

``````y <- sapply(x, function(u)
sum(
c(0.5,0.5)
%*%
mtx.exp( P %*% matrix(c(u,0,0,u),nrow=2), 5 )
)
)
``````

but if your vector really has 12^11 entries, that will take an insanely long time.

Alternatively, since you have a very large number of very small (2*2) matrices, you can explicitely compute the product `P %*% C` and its 5th power (using some computer algebra system: Maxima, Sage, Yacas, Maple, etc.) and use the resulting formulas: these are just (50 lines of) straightforward operations on vectors.

``````/* Maxima code */
p: matrix([p11,p12], [p21,p22]);
c: matrix([c1,0],[0,c2]);
display2d: false;
factor(p.c . p.c . p.c . p.c . p.c);
``````

I then copy and paste the result in R:

``````c1 <- dnorm(abs(x),0,1); # C is still a diagonal matrix
c2 <- dnorm(abs(x),1,3);
p11 <- P[1,1]
p12 <- P[1,2]
p21 <- P[2,1]
p22 <- P[2,2]
# Result of the Maxima computations:
# I just add all the elements of the resulting 2*2 matrix,
# but you may want to do something slightly different with them.

c1*(c2^4*p12*p21*p22^3+2*c1*c2^3*p11*p12*p21*p22^2
+2*c1*c2^3*p12^2*p21^2*p22
+3*c1^2*c2^2*p11^2*p12*p21*p22
+3*c1^2*c2^2*p11*p12^2*p21^2
+4*c1^3*c2*p11^3*p12*p21+c1^4*p11^5)
+
c2*p12
*(c2^4*p22^4+c1*c2^3*p11*p22^3+3*c1*c2^3*p12*p21*p22^2
+c1^2*c2^2*p11^2*p22^2+4*c1^2*c2^2*p11*p12*p21*p22
+c1^3*c2*p11^3*p22+c1^2*c2^2*p12^2*p21^2
+3*c1^3*c2*p11^2*p12*p21+c1^4*p11^4)
+
c1*p21
*(c2^4*p22^4+c1*c2^3*p11*p22^3+3*c1*c2^3*p12*p21*p22^2
+c1^2*c2^2*p11^2*p22^2+4*c1^2*c2^2*p11*p12*p21*p22
+c1^3*c2*p11^3*p22+c1^2*c2^2*p12^2*p21^2
+3*c1^3*c2*p11^2*p12*p21+c1^4*p11^4)
+
c2*(c2^4*p22^5+4*c1*c2^3*p12*p21*p22^3
+3*c1^2*c2^2*p11*p12*p21*p22^2
+3*c1^2*c2^2*p12^2*p21^2*p22
+2*c1^3*c2*p11^2*p12*p21*p22
+2*c1^3*c2*p11*p12^2*p21^2+c1^4*p11^3*p12*p21)
``````
-
Sorry, maybe I didn't explain the problem properly: So I have this matrix P (which is normaly not a diagonal matrix) consider P<-matrix(c(2.1,20.,0.3,3.2),nrow=2) this matrix gets multiplied by another (diagonal, this time) matrix let's call it C C<-matrix(c(x[i],0,0,x[i]),nrow=2) (for each i in (1:length(x)) Then i want to take the n-th power in this case n=5 (P*C)^5 This is again multiplied by a vector and the elements sumed up. My problem is that I do not want to do it with a loop (so for every entry in x this sum has to be calculated) –  rainer Apr 4 '12 at 13:57
If the matrix `C` is scalar (i.e., diagonal, with the same element everywhere on the diagonal), this can still be written `sum(mtx.exp(P,5)/2) * x^5`. –  Vincent Zoonekynd Apr 5 '12 at 3:14
Okey thank you, that helps a bit. The next problem I face is that my entries in the matrix C are not the same they depend on a function for example: C<-matrix(dnorm(x[i],0,1),0,0,dnorm(x[i],1,3)) –  rainer Apr 5 '12 at 6:09
And the complex matrix exponential is in the matrix C. P is just a square matrix with real entries. I'm sorry, it's a little bit confusing. But I do not want to upload the whole code. –  rainer Apr 5 '12 at 6:52
In this case, I do not see any easy way to simplify the problem -- but I have edited my answer with a complicated way to speed up the computations. –  Vincent Zoonekynd Apr 5 '12 at 7:52