I faced an optimization problem. I need to optimize portfolio for return Omega measure. I found suggestions that this can be done by using differential evolution through DEoptim(Yollin's very nice slides on R tools for portfolio optimization. Original code can be found there).

I tried to adapt this method to my problem (since I only changed numbers and I hope didn't make any mistakes. Full credit for the author here for the idea):

```
optOmega <-function(x,ret,L){ #function I want to optimize and
retu = ret %*% x # x is vector of asset weights
obj = -Omega(retu,L=L,method="simple") #Omega from PerformanceAnalytics
weight.penalty = 100*(1-sum(x))^2
return( obj + weight.penalty )
}
L=0 #Parameter which defines loss
#in Omega calculation
lower = rep(0,30) #I want weight to be in bounds
upper = rep(1,30) # 0<=x<=1
res = DEoptim(optOmega,lower,upper, #I have 30 assets in StockReturn
control=list(NP=2000,itermax=100,F=0.2,CR=0.8),
ret=coredata(StockReturn),L=L)
```

Omega is calculated as mean(pmax(retu-L,0))/mean(pmax(L-retu,0))

When asset number is very small (5 for example), I get results which pretty much satisfy me: asset weights add up to 0.999???? which is fairly close to one and the Omega of such portfolio is greater than Omega of any single asset (otherwise, why not invest everything in that single asset). This can be reached with 100 iterations. But when I increase asset number up to 30, result is not satisfying. Sum of weights comes to be 3 or more and Omega lower than that of some single assets. I thought this might be due to small number of iterations (I used 1000), so I tried 10 000 which is painfully slow. But the result is pretty much the same: weighs add up to way more than 1 and Omega does not seem optimal. With 10 asset algorithm seems to find weights close to 1, but Omega is lower than the one of a single asset.

My PC is quite old and it has Intel Core Duo 2 GHZ. Though, is it normal for such optimization with 1000 iterations to run ~40 minutes?

What might be the problem here? Is number of iterations too small, or my interpretation of provided algorithm is totally wrong. Thank You for your help!

`penalty <- (1-sum(x))^2; x <- x/sum(x)`

. – Vincent Zoonekynd Apr 26 '13 at 8:25