Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

I'm trying to solve the constrained orienteering problem in Matlab, my problem is I don't understand how to get the hessian matrix of an objective function like the one in this formulation (specifically, ones where there are summations and variable indices).

For a simple 2 node problem size, with weights 2 and 3, I've tried writing the objective function as

f = 2*x11 + 2*x12 + 2*x13 + 2*x14 + 2*x15 + 3*x21 + 3*x22 + 3*x23 + 3*x24 + 3*x25

and obtaining the hessian matrix using hessian(f). This outputs a matrix of 0's which makes sense since it gets the second-order partial derivative for each element. The main reason for my confusion is when when I call quadprog(H, f) I get an error saying H and f need to be of data type double.

But I'm not sure whether this is correct? Can someone point me in the right direction?

EDIT: Here's the code I'm using. I did it for a 5-node instance, and I did it all by hand (i.e. no loops). It's pretty terrible but I'm new to Matlab and I was hoping I'd get a better understanding of the algorithm itself by doing this by hand the first time around:

COP for 5 spots

AOI = 5;
M = 10;
full_AOI = AOI*AOI;

variables = cell(80, 1);

for i=1:AOI
    variables{i} = ['w' num2str(i)];
end

var_count = AOI+1;
for i=1:5
    for j=1:5
        variables{var_count} = ['x' num2str(i) num2str(j)];
        var_count = var_count + 1;
    end
end

for i=1:5
    for j=1:5
        variables{var_count} = ['d' num2str(i) num2str(j)];
        var_count = var_count + 1;
    end
end

for i=1:5
    for j=1:5
        variables{var_count} = ['f' num2str(i) num2str(j)];
        var_count = var_count + 1;
    end
end

var_size = size(variables);

% Combine Variables Into One Vector 
N = length(variables);
for v = 1:N
    eval([variables{v}, ' = ', num2str(v), ';']);
end

% Lower Bounds
lb = zeros(size(variables));
lb([f11,f12,f13,f14,f15,f21,f22,f23,f24,f25,...
    f31,f32,f33,f34,f35,f41,f42,f43,f44,f45,...
    f51,f52,f53,f54,f55,x11,x12,x13,x14,x15,...
    x21,x22,x23,x24,x25,x31,x32,x33,x34,x35,...
    x41,x42,x43,x44,x45,x51,x52,x53,x54,x55]) = [0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,...
                             0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0];

% Upee                        
ub = Inf(size(variables));
ub([x11,x12,x13,x14,x15,x21,x22,x23,x24,x25,...
    x31,x32,x33,x34,x35,x41,x42,x43,x44,x45,...
    x51,x52,x53,x54,x55,x12,x22,x32,x42,x13,...
    x23,x33,x43,x14,x14,x24,x34,x44,x22,x23,...
    x24,x25,x32,x33,x34,x35,x42,x43,x44,x45]) = [1,1,1,1,1,1,1,1,1,1,1,1,...
                                                 1,1,1,1,1,1,1,1,1,1,1,1,...
                                                 1,1,1,1,1,1,1,1,1,1,1,1,...
                                                 1,1,1,1,1,1,1,1,1,1,1,1,1,1];

% Linear Inequalities

% Constraint 3
A = zeros(27, 80);

A(1, x12) = 1;
A(2, x22) = 1;
A(3, x32) = 1;
A(4, x42) = 1;
A(5, x13) = 1;
A(6, x23) = 1;
A(7, x33) = 1;
A(8, x43) = 1;
A(9, x14) = 1;
A(10, x24) = 1;
A(11, x34) = 1;
A(12, x44) = 1;

A(13, x21) = 1;
A(14, x22) = 1;
A(15, x23) = 1;
A(16, x24) = 1;
A(17, x25) = 1;
A(18, x31) = 1;
A(19, x32) = 1;
A(20, x33) = 1;
A(21, x34) = 1;
A(22, x35) = 1;
A(23, x41) = 1;
A(24, x42) = 1;
A(25, x43) = 1;
A(26, x44) = 1;
A(27, x45) = 1;

b = ones(27, 1);


Aeq = zeros(77, 80); beq = zeros(77, 1);
% Constraint 1
Aeq(1, [x12, 1]) = [1, -1];
Aeq(2, [x13, 1]) = [1, -1];
Aeq(3, [x14, 1]) = [1, -1];
Aeq(4, [x15, 1]) = [1, -1];
Aeq(5, [x15, 1]) = [1, -1];     % Repeat from line 69 (ha), may not need this
Aeq(6, [x25, 1]) = [1, -1];
Aeq(7, [x35, 1]) = [1, -1];
Aeq(8, [x45, 1]) = [1, -1];

% constraint 2
Aeq(9, x21) = 1;
Aeq(10, x31) = 1;
Aeq(11, x41) = 1;
Aeq(12, x51) = 1;
Aeq(13, x52) = 1;
Aeq(14, x53) = 1;
Aeq(15, x54) = 1;

% constraint 4
Aeq(16, [x11, 1]) = [1, -1];
Aeq(17, [x21, 1]) = [1, -1];
Aeq(18, [x31, 1]) = [1, -1];
Aeq(19, [x41, 1]) = [1, -1];
Aeq(20, [x12, 1]) = [1, -1];
Aeq(21, [x22, 1]) = [1, -1];
Aeq(22, [x32, 1]) = [1, -1];
Aeq(23, [x42, 1]) = [1, -1];
Aeq(24, [x13, 1]) = [1, -1];
Aeq(25, [x23, 1]) = [1, -1];
Aeq(26, [x33, 1]) = [1, -1];
Aeq(27, [x43, 1]) = [1, -1];
Aeq(28, [x14, 1]) = [1, -1];
Aeq(29, [x24, 1]) = [1, -1];
Aeq(30, [x34, 1]) = [1, -1];
Aeq(31, [x44, 1]) = [1, -1];
Aeq(32, [x15, 1]) = [1, -1];
Aeq(33, [x25, 1]) = [1, -1];
Aeq(34, [x35, 1]) = [1, -1];
Aeq(35, [x45, 1]) = [1, -1];

Aeq(36, [x11, 1]) = [1, -1];
Aeq(37, [x12, 1]) = [1, -1];
Aeq(38, [x13, 1]) = [1, -1];
Aeq(39, [x14, 1]) = [1, -1];
Aeq(40, [x15, 1]) = [1, -1];
Aeq(41, [x21, 1]) = [1, -1];
Aeq(42, [x22, 1]) = [1, -1];
Aeq(43, [x23, 1]) = [1, -1];
Aeq(44, [x24, 1]) = [1, -1];
Aeq(45, [x25, 1]) = [1, -1];
Aeq(46, [x31, 1]) = [1, -1];
Aeq(47, [x32, 1]) = [1, -1];
Aeq(48, [x33, 1]) = [1, -1];
Aeq(49, [x34, 1]) = [1, -1];
Aeq(50, [x35, 1]) = [1, -1];
Aeq(51, [x41, 1]) = [1, -1];
Aeq(52, [x42, 1]) = [1, -1];
Aeq(53, [x43, 1]) = [1, -1];
Aeq(54, [x44, 1]) = [1, -1];
Aeq(55, [x45, 1]) = [1, -1];
Aeq(56, [x51, 1]) = [1, -1];
Aeq(57, [x52, 1]) = [1, -1];
Aeq(58, [x53, 1]) = [1, -1];
Aeq(59, [x54, 1]) = [1, -1];
Aeq(60, [x55, 1]) = [1, -1];

% Constraint 7
Aeq(61, [f22, d12, x12]) = [1, -1, 1];
Aeq(62, [f23, d22, x22]) = [1, -1, 1];
Aeq(63, [f24, d32, x32]) = [1, -1, 1];
Aeq(64, [f25, d42, x42]) = [1, -1, 1];
Aeq(65, [f32, d13, x13]) = [1, -1, 1];
Aeq(66, [f33, d23, x23]) = [1, -1, 1];
Aeq(67, [f34, d33, x33]) = [1, -1, 1];
Aeq(68, [f35, d43, x43]) = [1, -1, 1];
Aeq(69, [f42, d14, x14]) = [1, -1, 1];
Aeq(70, [f43, d24, x24]) = [1, -1, 1];
Aeq(71, [f44, d34, x34]) = [1, -1, 1];
Aeq(72, [f45, d44, x44]) = [1, -1, 1];

% Constraint 8
Aeq(73, [f11, AOI, 1]) = [1, -1, 1];
Aeq(74, [f12, AOI, 1]) = [1, -1, 1];
Aeq(75, [f13, AOI, 1]) = [1, -1, 1];
Aeq(76, [f14, AOI, 1]) = [1, -1, 1];
Aeq(77, [f15, AOI, 1]) = [1, -1, 1];



% Objective Function

f = 2*x11 + 2*x12 + 2*x13 + 2*x14 + 2*x15 + 3*x21 + 3*x22 + 3*x23 + 3*x24 + 3*x25 +...
    4*x31 + 4*x32 + 3*x33 + 3*x34 + 3*x35 + 5*x41 + 5*x42 + 5*x43 + 5*x44 + 5*x45 + ...
    6*x51 + 6*x52 + 6*x53 + 6*x54 + 6*x55;

syms x11 x12 x13 x14 x15;
syms x21 x22 x23 x24 x25;
syms x31 x32 x33 x34 x35;
syms x41 x42 x43 x44 x45;
syms x51 x52 x53 x54 x55;

H = hessian(f);
opts = optimoptions('quadprog', 'Algorithm', 'active-set', 'Display', 'off');

[x fval] = quadprog(H, f, A, b, Aeq, beq, lb, ub);
share|improve this question
    
Could you add your code? Perhaps there's an error in your definition of the constraints? –  Naveh Apr 18 '14 at 15:52
    
I added it to the original comment. It's the COP for 5 nodes, it's pretty awful code but I wanted to do the whole thing by hand first to get a better grip on the algorithm itself. –  shabby Apr 19 '14 at 19:03

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Browse other questions tagged or ask your own question.