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I would like to solve a fairly common (and simple) optimization problem, though it seems there are no posts on this: long/short market neutral minimum variance optimization. The form of the optimization in "R pseudo-code":

min (t(h) %*% D %*% h ) s.t.    # minimize portfolio variance, h weights, D covar matrix
  sum(h) == 0                   # market neutral; weights sum to 0
  sum(abs(h)) == 1              # book-size/fully-invested; abs(weights) sum to 1
  h %*% e >= threshold          # the portfolio expected return is > some threshold
  h <= maxPos                   # each long position is less than some maxPos
  h >= -maxPos                  # each short position is greater than -maxPos

The key in this question which is missing in other questions is the "book-size" constraint. In long/short optimization, you need this constraint otherwise you get nonsense results. This is a quadratic optimization problem however because of the "abs" in the constraints, we have non-linear constraints. There is a well-known (in certain circles I suppose) trick to transform an "abs" constraint from a non-linear constraint to a linear constraint. We do this by introducing auxiliary variables into the equation (see this explanation at lp_solve reference guide: absolute values).

I have written this function to calculate the minimum portfolio variance weights, given a multi-factor risk model input:

portSolveMinVol <- function(er,targetR,factorVols,factorCorrel,idioVol) {
  require(quadprog)

  # min ( -d'b + 1/2 b'Db)
  # A'b >= b_0

  # b = weights --> what we are solving for
  # D = covariance matrix
  # d = we can set this to zero as we have no linear term in the objective function

  # set up the A matrix with all the constraints
  #   weights sum to 0
  #   abs weights sum to 1
  #   max pos < x, greater than -x
  #   return > some thresh

  numStocks <- length(er) # er is the expected return vector
  numAbs <- numStocks # this is redundant but I do this to make the code easier to read
  VCV <- factorVols %*% t(factorVols) * factorCorrel  # factor covariance matrix
  S <- matrix(0,ncol=numStocks,nrow=numStocks)
  diag(S) <- idioVol * idioVol # stock specific covariance (i.e., 0's except for diagonal)
  common <- factorBetas %*% VCV %*% t(factorBetas) # stock common risk covar matrix

  # need to fill in the Dmat b/c of the abs constraint
  Dmat <- matrix(0,ncol=numStocks+numAbs,nrow=numStocks+numAbs)
  Dmat[1:numStocks,1:numStocks] <- (common + S)  # full covariance matrix

  dvec <- rep(0,numStocks + numAbs)  # ignored but solve.QP wants it

  # A'b >= b_0
  Amat <- matrix(0,nrow= 3,ncol=numStocks + numAbs)
  Amat[1,] <- c(rep(1,numStocks),rep(0,numAbs)) # sum weights equal zero
  Amat[2,] <- c(rep(0,numStocks),rep(1,numAbs)) # sum abs weights equal 1

  Amat[3,] <- c(er,rep(0,numAbs)) # expected return >= threshold

  # add contraints on min and max pos size
  maxpos <- matrix(0,nrow=numStocks,ncol=numStocks + numAbs)
  minpos <- matrix(0,nrow=numStocks,ncol=numStocks + numAbs)
  for(i in 1:numStocks) {
    maxpos[i,i] = -1  # neg and neg b/c of >= format of contraints
    minpos[i,i] = 1  # pos and neg b/c of >= format of contraints
  }

  absmaxpos <- matrix(0,nrow=numStocks,ncol=numStocks + numAbs)
  absminpos <- matrix(0,nrow=numStocks,ncol=numStocks + numAbs)

  # add contraints on the sum(abs(wi)) = 1 and each
  for(i in 1:numStocks) {
    absmaxpos[i,i] = 1
    absmaxpos[i,i+numAbs] = -1

    absminpos[i,i] = 1
    absminpos[i,i+numAbs] = 1
  }

  # Set up the Amat

  Amat <- rbind(Amat,maxpos,minpos,absmaxpos,absminpos)

  # set up the rhs
  bvec <- c(0,                         # sum of weights
            1,                         # sum of abs weights
            0.005,                     # min expected return
            rep(-0.025,numStocks),     # max pos
            rep(-0.025,numStocks),     # min pos
            rep(0,numAbs),             # abs long dummy var
            rep(0,numAbs))             # abs short dummy var

  # meq is the number of first constraints that are equality
  res <- solve.QP(Dmat, dvec, t(Amat), bvec, meq=2)

  res

}

Which I call with the following unit testing (spoofing the multi-factor model inputs):

set.seed(1)
nStocks <- 100
nBetas <- 5
er <-rnorm(nStocks,mean=0.0012,0.0075)
factorVols <- 0.08 + runif(nBetas,0,0.15)
factorCorrel <- matrix(rep(0,nBetas*nBetas),nrow=nBetas,ncol=nBetas)
for(i in 1:(nBetas)) {
  for(j in 1:(nBetas)) {
    factorCorrel[i,j] = rnorm(1,mean=0.2,sd=0.05)
    factorCorrel[j,i] = factorCorel[i,j]
  }
}
diag(factorCorrel) <- 1
idioVol <- abs(rnorm(nStocks,mean=0.01,sd=0.05))
res <- portSolveMinVol(er,0.005,factorVols,factorCorrel,idioVol)

This throws the following error:

Error in solve.QP(Dmat, dvec, t(Amat), bvec, meq = 2) :    matrix D in
quadratic function is not positive definite!

As such, my question is, how does one implement the abs constraint in long/short optimization in solve.QP in R?

As a further note, the paper Portfolio Optimization with Transaction Costs shows how to do this in Matlab, however this does not seem to work in solve.QP in R.

share|improve this question
    
From the excellent Systematic Investor Toolbox see 130/30 optimization (systematicinvestor.wordpress.com/2011/10/18/…) –  Osssan Jun 23 '14 at 20:44
    
Thank you @Osssan; there is great code there, though I was hoping to learn why my approach does not work; also his code solves the risk/return trade-off, not the optimization I am try to solve (with a minimum expected return); I don't know if that is meaningful for the error I am getting. –  user3768822 Jun 24 '14 at 15:38
    
Yes, I was aware that this will not probably answer your question directly but maybe the functions min.risk.portfolio,min.te.portfolio etc. might give you some insight on your specific problem. –  Osssan Jun 24 '14 at 15:47

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