Your question appears to reference this paper.

Theorem 2 you reference is the solution to the following optimization problem (see error/typos section, I've had to make at least one correction).

```
minimize (over w) w' * (Sigma + delta * delta') * w - 2 * cov_vect' * w
subject to: w'*ones(n, 1) = 1
```

### This can be solved using Matlab function quadprog with:

```
H = 2 * (Sigma + delta * Delta'); % see quadprog docs, it solves 1/2 so we need 2
f = - 2 * cov_vect;
A = [];
b = [];
Aeq = ones(1,6);
beq = 1;
w = quadprog(H, f, A, b, Aeq, beq);
```

You can add the lower bound constraint of 0 with:

```
lb = zeros(6, 1);
ub = [];
w2 = quadprog(H, f, A, b, Aeq, beq, lb, ub);
```

### How to solve this in CVX (awesome optimization package)

```
cvx_begin
variables y(n);
minimize(y' * (Sigma + Delta * Delta') * y - 2 * cov_vect * y)
subject to:
y'*ones(n,1) == 1;
y >= 0;
cvx_end
```

Link to cvx.

### Typo in appendix of paper as posted on researchgate:

(typo) Their proof of theorem 2 omits the `2*w`

in term 2*cov_vect' * w of thier objective function. The minimization problem *should be*:

```
minimize (over w) w' * (Sigma + delta * delta') * w - 2*cov_vect' * w
```

Which indeed gives solution:

```
0.1596 0.1596 0.2090 0.2090 0.1314 0.1314
```

Or equivalently:

```
minimize (over w) .5 * w' * (Sigma + delta * delta') * w - cov_vect' * w
```

Ax + b'*x subject to C * x <= 0 or whatever. Matlab has several tools for efficiently solving linear or quadratic optimization problems (and indeed others). Eg. quadprog or linprog. – Matthew Gunn Dec 9 '15 at 0:43`lsqnonneg`

: mathworks.com/help/matlab/ref/lsqnonneg.html - This determines the best solution to a least squares problem ensuring that the solution is all positive. Something worth considering. – rayryeng Dec 9 '15 at 1:55