Active-set method

"Active set" redirects here. For the band, see The Active Set.

In mathematical optimization, a problem is defined using an objective function to minimize or maximize, and a set of constraints

${\displaystyle g_{1}(x)\geq 0,\dots ,g_{k}(x)\geq 0}$

that define the feasible region, that is, the set of all x to search for the optimal solution. Given a point ${\displaystyle x}$ in the feasible region, a constraint

${\displaystyle g_{i}(x)\geq 0}$

is called active at ${\displaystyle x}$ if ${\displaystyle g_{i}(x)=0}$ and inactive at ${\displaystyle x}$ if ${\displaystyle g_{i}(x)>0.}$ Equality constraints are always active. The active set at ${\displaystyle x}$ is made up of those constraints ${\displaystyle g_{i}(x)}$ that are active at the current point (Nocedal & Wright 2006, p. 308).

The active set is particularly important in optimization theory as it determines which constraints will influence the final result of optimization. For example, in solving the linear programming problem, the active set gives the hyperplanes that intersect at the solution point. In quadratic programming, as the solution is not necessarily on one of the edges of the bounding polygon, an estimation of the active set gives us a subset of inequalities to watch while searching the solution, which reduces the complexity of the search.

Active set methods

In general an active set algorithm has the following structure:

Find a feasible starting point

repeat until "optimal enough"

solve the equality problem defined by the active set (approximately)

compute the Lagrange multipliers of the active set

remove a subset of the constraints with negative Lagrange multipliers

search for infeasible constraints

end repeat

Methods that can be described as active set methods include^{[citation needed]}:

• Successive linear programming (SLP)
• Sequential quadratic programming (SQP)
• Sequential linear-quadratic programming (SLQP)
• Reduced gradient method (RG)
• Generalized reduced gradient method (GRG)

References

• Murty, K. G. (1988). Linear complementarity, linear and nonlinear programming. Sigma Series in Applied Mathematics. Vol. 3. Berlin: Heldermann Verlag. pp. xlviii+629 pp. ISBN 3-88538-403-5. MR949214
• Nocedal, Jorge; Wright, Stephen J. (2006). Numerical Optimization (2nd ed.). Berlin, New York: Springer-Verlag. ISBN 978-0-387-30303-1. {{cite book}}: Invalid |ref=harv (help).