I want to numerically maximize an expression in R. In order to keep it simple, suppose that the expression I want to maximize is

\int_0^1 2x y(x)(y(x) -2) dx


y(x) = \int_0^1 y(x,t) dt

and where I maximize over the set of functions y: [0,1]^2 -> {0,1}.

I want to numerically maximize this expression in R and this is how I thought I'd do it:

  1. Discretize the unit square using a matrix
  2. Discretize the integrand
  3. Calculate the value of the sum
  4. Do this for all matrices see which maximizes the value

Since the functions I want to maximize over only take values in {0,1} I thought of using a matrix taking values 0/1 to approximate the function and to then approximate the rest of the integrand on that grid. Here's the code:

    Value <- function(grid){
    # The argument grid is the matrix taking values 0 or 1
    # For now, consider a 10-times-10 matrix
    Value <- 2*seq(1/20, 19/20, 1/10) %*% apply(grid, 1, sum)/10

How can I now create a list of all 0/1 matrices in order to then apply the above function to all of them to see which grid, i.e., which approximation of the function y reaches the maximum? Or is there an altogether different and better way to do this numerical optimization?

  • I managed to create a list of all the 0/1 matrices, but (not surprisingly) this object is too large very quickly. So I need an altogether different approach. Any advice is welcome. – shomi Dec 1 '15 at 22:12

Your search algorithm which enumerates all possible 2^(10*10) discretised functions is extremely poor. You should better try local optimisation like Nelder-Mead to maximise the function.

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

Not the answer you're looking for? Browse other questions tagged or ask your own question.