# Python: Using CVXOPT for quadratic programming

I'm using CVXOPT to do quadratic programming to compute the optimal weights of a potfolio using mean-variance optimization. There is a great example at http://abel.ee.ucla.edu/cvxopt/userguide/coneprog.html#quadratic-programming. However, the arguments are in a regularized form (according to the author). The example is a basic version. I am looking to do a bit of a more complex problem where:

``````min:

x'Sx

s.t.:

x'a >= g
x'1 = 0
x >= -Wb
x <= c1 - Wb

where:
x: active weights of assets (active weight = portfolio weight - benchmark weight)
S: covariance matrix of asset returns
a: expected stock excess returns
g: target gain
Wb: weights of assets in the benchmark
c: upper limit (weight) of any asset in the portfolio
``````

Assume all the variables are computed or known.

The basic example presented in the documentation:

``````min:

x'Sx

s.t.

p'x >= g
1'x = 1
``````

Where p are the asset returns.

What I do not know (referring to the code at http://abel.ee.ucla.edu/cvxopt/examples/book/portfolio.html and optimization problem above):

1.I think these arguments setup the constraints but I'm not entirely sure:

``````G = matrix(0.0, (n,n))
G[::n+1] = -1.0
h = matrix(0.0, (n,1))
A = matrix(1.0, (1,n))
b = matrix(1.0)
``````

2.I believe this is part of the minimization problem in "regulated form", which I'm not sure what means:

``````mus = [ 10**(5.0*t/N-1.0) for t in xrange(N) ]
``````

3.What the arguments to qp are (solver.qp is the quadratic optimizer):

``````xs = [ qp(mu*S, -pbar, G, h, A, b)['x'] for mu in mus ]
``````

Looking at the documentation, I'm pretty sure that mu*S (the first argument) is the objective function to be minimzed and -pbar are the returns. This looks like a maximization problem however (maximizing negative returns).

I do not know, however how the other arguments are used.

I am looking for help using the optimizer given my minimization problem and constraints above.

-

I read the docs and I think you have to use the function with the following parameters. I assume that `x` has size `n`:

``````P = S
q = (0,....0)

A = (1, ...... 1)
b = (0)
``````

`G` is vertically stacked from

`````` -a
+I_n
-I_n
``````

where `I_n` is the identity matrix of size `n x n` . And the corresponding right hand side `h` is

``````  -g
Wb
...
Wb
C1-Wb
...
C1-Wb
``````

That is: one `-g`, `n` times `Wb` and `n` times `C1-Wb`.

HTH.

-
Thanks for the response, but I'm not following for `G` and `h`... For `G`, what do you mean `-a, ... -a`? and `+I_n`? For `h`, I'm not clear at all. Also, what is your logic for your thoughts? –  strimp099 Sep 27 '11 at 20:47
I just formulated your problem so that it matches the specification given by your link to cvxopt. –  rocksportrocker Sep 28 '11 at 5:15
-a .... -a was wrong. I_n is the identity matrix of size n, that is the matrix is zero outside the diagonl. The diagonal contains only ones. –  rocksportrocker Sep 28 '11 at 5:17
h is a vector. it's entries are given as I described it. The first entry is -g, then n times Wb, then n times "C1-Wb" –  rocksportrocker Sep 28 '11 at 5:18