Models Quadratic Programming Problems: qp prob
This page is part of TOMLAB Models. See TOMLAB Models. |
In qp_prob there are 41 quadratic programming test problems with sizes to nearly 1200 variables and nearly 500 constraints. In order to define the problem n and solve it execute the following in Matlab:
Prob = probInit('qp_prob',n); Result = tomRun('',Prob);
The basic structure of a general nonlinear Quadratic Programming problem is:
An example of a problem of this class, (that is also found in the TOMLAB quickguide) is qpQG:
where Failed to parse (unknown function "\MATHSET"): {\displaystyle c, x, x_L, x_U \in \MATHSET{R}^n} , Failed to parse (unknown function "\MATHSET"): {\displaystyle F \in \MATHSET{R}^{n \times n}} , Failed to parse (unknown function "\MATHSET"): {\displaystyle A \in \MATHSET{R}^{m_1 \times n}} , and Failed to parse (unknown function "\MATHSET"): {\displaystyle b_L,b_U \in \MATHSET{R}^{m_1}} . Equality constraints are defined by setting the lower bound equal to the upper bound, i.e. for constraint : . Fixed variables are handled the same way.
An example of a problem of this class, (that is also found in the TOMLAB quickguide) is qpQG:
File: tomlab/quickguide/qpQG.m
Open the file for viewing, and execute qpQG in Matlab.
% qpQG is a small example problem for defining and solving
% quadratic programming problems using the TOMLAB format.
Name = 'QP Example';
F = [ 8 1 % Matrix F in 1/2 * x' * F * x + c' * x
1 8 ];
c = [ 3 -4 ]'; % Vector c in 1/2 * x' * F * x + c' * x
A = [ 1 1 % Constraint matrix
1 -1 ];
b_L = [-inf 0 ]'; % Lower bounds on the linear constraints
b_U = [ 5 0 ]'; % Upper bounds on the linear constraints
x_L = [ 0 0 ]'; % Lower bounds on the variables
x_U = [ inf inf ]'; % Upper bounds on the variables
x_0 = [ 0 1 ]'; % Starting point
x_min = [-1 -1 ]; % Plot region lower bound parameters
x_max = [ 6 6 ]; % Plot region upper bound parameters
% Assign routine for defining a QP problem.
Prob = qpAssign(F, c, A, b_L, b_U, x_L, x_U, x_0, Name,...
[], [], [], x_min, x_max);
% Calling driver routine tomRun to run the solver.
% The 1 sets the print level after optimization.
Result = tomRun('qpSolve', Prob, 1);
%Result = tomRun('snopt', Prob, 1);
%Result = tomRun('sqopt', Prob, 1);
%Result = tomRun('cplex', Prob, 1);
%Result = tomRun('knitro', Prob, 1);
%Result = tomRun('conopt', Prob, 1);