# Constrain Optimisation Problems in R

I am trying to set up an optimisation script that will look at a set of models, fit curves to the models and then optimise across them, subject to a few parameters.

Essentially, I have revenue as a function of cost, in a diminishing function, and I have this for multiple portfolios, say 4 or 5. As an input, I have cost and revenue figures, at set increments. What I want to do is fit a curve to the portfolio of the form Revenue=A*cost^B, and then optimise across the different portfolios to find the optimal cost split between each portfolio for a set budget.

The code below (I apologise for the inelegance of it, I'm sure there are MANY improvements to be made!) essentially reads in my data, in this case, a simulation, creates the necessary data frames (this is likely where my inelegance comes in), calculates the necessary variables for the curves for each simulation and produces graphics to check the fitted curve to the data.

My problem is that now I have 5 curves of the form:

revenue = A * Cost ^ B (different A, B and cost for each function)

And I want to know, given the 5 variables, how should I split my cost between them, so I want to optimise the sum of the 5 curves subject to

Cost <= Budget

I know that I need to use constrOptim, but I have spent literally hours banging my head against my desk (literally hours, not literally banging my head...) and I still can't figure out how to set up the function so that it maximises revenue, subject to the cost constraint...

Any help here would be greatly appreciated, this has been bugging me for weeks.

Thanks!

Rich

``````## clear all previous data

rm(list=ls())
detach()
objects()

library(base)
library(stats)

sim2<-data.frame(sim\$Wrevenue,sim\$Cost)

## identify how many simulations there are - here you can change the 20 to the number of steps but all simulations must have the same number of steps

portfolios<-(length(sim2\$sim.Cost)/20)

## create a matrix to input the variables into

a<-rep(1,portfolios)
b<-rep(2,portfolios)
matrix<-data.frame(a,b)

## create dummy vector to hold the revenue predictions

k<-1
j<-20

for(i in 1:portfolios){

test<-sim2[k:j,]

rev9<-test[,1]
cost9<-test[,2]

ds<-data.frame(rev9,cost9)

rhs<-function(cost, b0, b1){
b0 * cost^b1

m<- nls(rev9 ~ rhs(cost9, intercept, power), data = ds, start = list(intercept = 5,power = 1))

matrix[i,1]<-summary(m)\$coefficients[1]
matrix[i,2]<-summary(m)\$coefficients[2]

k<-k+20
j<-j+20

}

## now there exists a matrix of all of the variables for the curves to optimise

matrix
multiples<-matrix[,1]
powers<-matrix[,2]
coststarts<-rep(0,portfolios)

## check accuracy of curves

k<-1
j<-20

for(i in 1:portfolios){

dev.new()

plot(sim\$Wrevenue[k:j])
lines(multiples[i]*(sim\$Cost[k:j]^powers[i]))

k<-k+20
j<-j+20

}
``````
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Related question: stackoverflow.com/questions/9592369/… – Vincent Zoonekynd Mar 12 '12 at 12:17

If you want to find the values `cost[1]`,...,`cost[5]` that maximize `revenue[1]+...+revenue[5]` subject to the constraints `cost[1]+...+cost[5]<=budget` (and `0 <= cost[i] <= budget`), you can parametrize the set of feasible solutions as follows

``````cost[1] = s(x[1]) * budget
cost[2] = s(x[2]) * ( budget - cost[1] )
cost[3] = s(x[3]) * ( budget - cost[1] - cost[2])
cost[4] = s(x[4]) * ( budget - cost[1] - cost[2] - cost[3] )
cost[5] = budget - cost[1] - cost[2] - cost[3] - cost[4]
``````

where `x[1]`,...,`x[4]` are the parameters to find (with no constraints on them) and `s` is any bijection between the real line R and the segment (0,1).

``````# Sample data
a <- rlnorm(5)
b <- rlnorm(5)
budget <- rlnorm(1)

# Reparametrization
s <- function(x) exp(x) / ( 1 + exp(x) )
cost <- function(x) {
cost <- rep(NA,5)
cost[1] = s(x[1]) * budget
cost[2] = s(x[2]) * ( budget - cost[1] )
cost[3] = s(x[3]) * ( budget - cost[1] - cost[2])
cost[4] = s(x[4]) * ( budget - cost[1] - cost[2] - cost[3] )
cost[5] = budget - cost[1] - cost[2] - cost[3] - cost[4]
cost
}

# Function to maximize
f <- function(x) {
result <- sum( a * cost(x) ^ b )
cat( result, "\n" )
result
}

# Optimization
r <- optim(c(0,0,0,0), f, control=list(fnscale=-1))
cost(r\$par)
``````
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Thanks! I am going to spend tomorrpw morning trying to understand what you've written and I'll get back to you if i have any questions (I inevitably will). But thanks so much for your help! – Rich Garrod Mar 12 '12 at 17:38
Hi,Thanks, that was really useful, and it now works a treat. The only thing I'm trying to make work now is for the optimisation to be variable depending on how many portfolios I have (could be anyway from 2 to 100). But I'm sure I'll figure it out :). Thanks! – Rich Garrod Mar 15 '12 at 13:56
Did you had a look on the LIM package? cran.r-project.org/package=LIM – user2030503 Mar 11 '14 at 17:43