# constrained optimization in R setting up constraints

I have been trying to solve a constrained optimization problem in R using constrOptim() (my first time) but am struggling to set up the constraints for my problem.

The problem is pretty straight forward and i can set up the function ok but am a bit at a loss about passing the constraints in.

e.g. problem i've defined is (am going to start with N fixed at 1000 say so i just want to solve for X ultimately i'd like to choose both N and X that max profit):

so i can set up the function as:

``````fun <- function(x, N, a, c, s) {   ## a profit function
x1 <- x[1]
x2 <- x[2]
x3 <- x[3]
a1 <- a[1]
a2 <- a[2]
a3 <- a[3]
c1 <- c[1]
c2 <- c[2]
c3 <- c[3]
s1 <- s[1]
s2 <- s[2]
s3 <- s[3]
((N*x1*a1*s1)-(N*x1*c1))+((N*x2*a2*s2)-(N*x2*c2))+((N*x3*a3*s3)-(N*x3*c3))
}
``````

The constraints i need to implement are that:

``````x1>=0.03
x1<=0.7
x2>=0.03
x2<=0.7
x3>=0.03
x2<=0.7
x1+x2+x3=1
``````

The X here represents buckets into which i need to optimally allocate N, so x1=pecent of N to place in bucket 1 etc. with each bucket having at least 3% but no more than 70%.

Any help much appreciated...

e.g. here is an example i used to test the function does what i want:

``````    fun <- function(x, N, a, c, s) {   ## profit function
x1 <- x[1]
x2 <- x[2]
x3 <- x[3]
a1 <- a[1]
a2 <- a[2]
a3 <- a[3]
c1 <- c[1]
c2 <- c[2]
c3 <- c[3]
s1 <- s[1]
s2 <- s[2]
s3 <- s[3]
((N*x1*a1*s1)-(N*x1*c1))+((N*x2*a2*s2)-(N*x2*c2))+((N*x3*a3*s3)-(N*x3*c3))
};

x <-matrix(c(0.5,0.25,0.25));

a <-matrix(c(0.2,0.15,0.1));

s <-matrix(c(100,75,50));

c <-matrix(c(10,8,7));

N <- 1000;

fun(x,N,a,c,s);
``````
-
So... `x[1:3]` are variables, while `a[1:3]`, `s[1:3]` and `c[1:3]` are given values ? Could you elaborate the formulation you need ? It is not clear to me... –  digEmAll Dec 20 '12 at 16:52
yes exactly - a[1:3], s[1:3], c[1:3] represent historic average activation rate, spend, acquisition cost..i'm trying to choose the x[1:3] to maximize the function –  user1919374 Dec 20 '12 at 16:56

You can use The lpSolveAPI package.

``````## problem constants
a <- c(0.2, 0.15, 0.1)
s <- c(100, 75, 50)
c <- c(10, 8, 7)
N <- 1000

## Problem formulation
# x1          >= 0.03
# x1          <= 0.7
#     x2      >= 0.03
#     x2      <= 0.7
#          x3 >= 0.03
# x1 +x2 + x3  = 1
#N*(c1- a1*s1)* x1 + (a2*s2 - c2)* x2 + (a3*s3-  c3)* x3

library(lpSolveAPI)
my.lp <- make.lp(6, 3)
``````

The best way to build a model in lp solve is columnwise;

``````#constraints by columns
set.column(my.lp, 1, c(1, 1, 0, 0, 1, 1))
set.column(my.lp, 2, c(0, 0, 1, 1, 0, 1))
set.column(my.lp, 3, c(0, 0, 0, 0, 1, 1))
#the objective function ,since we need to max I set negtive max(f) = -min(f)
set.objfn (my.lp, -N*c(c[1]- a[1]*s[1], a[2]*s[2] - c[2],a[3]*s[3]-  c[3]))
set.rhs(my.lp, c(rep(c(0.03,0.7),2),0.03,1))
#constraint types
set.constr.type(my.lp, c(rep(c(">=","<="), 2),">=","="))
``````

take a look at my model

``````my.lp
Model name:

Model name:
C1     C2     C3
Minimize  10000  -3250   2000
R1            1      0      0  >=  0.03
R2            1      0      0  <=   0.7
R3            0      1      0  >=  0.03
R4            0      1      0  <=   0.7
R5            1      0      1  >=  0.03
R6            1      1      1   =     1
Kind        Std    Std    Std
Type       Real   Real   Real
Upper       Inf    Inf    Inf
Lower         0      0      0
solve(my.lp)

[1] 0    ## sucess :)

get.objective(my.lp)
[1] -1435
get.constraints(my.lp)
[1] 0.70 0.70 0.03 0.03 0.97 1.00
## the decisions variables
get.variables(my.lp)
[1] 0.03 0.70 0.27
``````
-
that's great thanks, will take a look to see if i can figure it out. Is N missing from the specification you gave (e.g. i just had N=1000 to start simple). also how can i find the optimum values for x[1:3] after i run solve(my.lp)...? many thanks –  user1919374 Dec 20 '12 at 17:20
@user1919374 Yes The N is missing but you can add it. But the more important is to see if you have constraints on the type of your decisions variables? are all integer ,binary for example? –  agstudy Dec 20 '12 at 17:27
all integer..... –  user1919374 Dec 20 '12 at 17:47
@user1919374 I add N and the decisions variables. But you need to integrate the decisions variables types, e.g sset.type(my.lp, c(1,2,3), "integer"). –  agstudy Dec 20 '12 at 17:49

Hi Just in case of use to anyone i also found an answer as below:

First of all, your objective function can be written a lot more concisely using vector operations:

``````> my_obj_coeffs <- function(N,a,c,s) N*(a*s-c)

> fun <- function(x,N,a,c,s) sum(my_obj_coeffs(N,a,c,s) * x)
``````

You're trying to solve a linear program, so you can use solve it using the simplex algorithm. There's a lightweight implementation of it in the 'boot' package.

``````> library(boot)

> solution <- function(obj) simplex(obj, diag(3), rep(0.7,3), diag(3), rep(0.03,3), rep(1,3), 1, maxi=TRUE)

Then for the example parameters you used, you can call that solution function:

> a <- c(0.2,0.15,0.1)
> s <- c(100,75,50)
> c <- c(10,8,7)
> N <- 1000
> solution(my_obj_coeffs(N,a,c,s))

Linear Programming Results

Call : simplex(a = obj(N, a, s, c), A1 = diag(3), b1 = rep(0.7, 3),
A2 = diag(3), b2 = rep(0.03, 3), A3 = matrix(1, 1, 3), b3 = 1,
maxi = TRUE)

Maximization Problem with Objective Function Coefficients
[,1]
[1,] 10000
[2,]  3250
[3,] -2000
attr(,"names")
[1] "x1" "x2" "x3"

Optimal solution has the following values
x1   x2   x3
0.70 0.27 0.03
The optimal value of the objective  function is 7817.5.
``````
-
i should also say the problem as i have formulated it always has a simple solution which is to portion as much as possible into the 'best' buckets subject to the constraints - which is pretty obvious in hindsight! –  user1919374 Dec 21 '12 at 11:13