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The pattern search algorithm uses the Augmented Lagrangian Pattern Search (ALPS) algorithm to solve nonlinear constraint problems. The optimization problem solved by the ALPS algorithm is

$$\underset{x}{\mathrm{min}}f(x)$$

such that

$$\begin{array}{c}{c}_{i}(x)\le 0,\text{\hspace{0.17em}}\text{\hspace{0.17em}}i=1\dots m\\ ce{q}_{i}(x)=0,\text{\hspace{0.17em}}\text{\hspace{0.17em}}\text{}i=m+1\dots mt\\ A\cdot x\le b\\ Aeq\cdot x=beq\\ lb\le x\le ub,\end{array}$$

where * c*(

The ALPS algorithm attempts to solve a nonlinear optimization problem with nonlinear constraints, linear constraints, and bounds. In this approach, bounds and linear constraints are handled separately from nonlinear constraints. A subproblem is formulated by combining the objective function and nonlinear constraint function using the Lagrangian and the penalty parameters. A sequence of such optimization problems are approximately minimized using a pattern search algorithm such that the linear constraints and bounds are satisfied.

Each subproblem solution represents one iteration. The number of function evaluations per iteration is therefore much higher when using nonlinear constraints than otherwise.

A subproblem formulation is defined as

$$\Theta (x,\lambda ,s,\rho )=f(x)-{\displaystyle \sum _{i=1}^{m}{\lambda}_{i}}{s}_{i}\mathrm{log}({s}_{i}-{c}_{i}(x))+{\displaystyle \sum _{i=m+1}^{mt}{\lambda}_{i}}ce{q}_{i}(x)+\frac{\rho}{2}{\displaystyle \sum _{i=m+1}^{mt}ce{q}_{i}}{(x)}^{2},$$

where

The components

of the vector*λ*_{i}are nonnegative and are known as Lagrange multiplier estimates*λ*The elements

of the vector*s*_{i}are nonnegative shifts*s*is the positive penalty parameter.*ρ*

The algorithm begins by using an initial value for
the penalty parameter (`InitialPenalty`

).

The pattern search minimizes a sequence of subproblems, each
of which is an approximation of the original problem. Each subproblem
has a fixed value of * λ*,

`PenaltyFactor`

). This results
in a new subproblem formulation and minimization problem. These steps
are repeated until the stopping criteria are met.Each subproblem solution represents one iteration. The number of function evaluations per iteration is therefore much higher when using nonlinear constraints than otherwise.

For a complete description of the algorithm, see the following references:

[1] Kolda, Tamara G., Robert Michael Lewis, and Virginia Torczon. "A generating set direct search augmented Lagrangian algorithm for optimization with a combination of general and linear constraints." Technical Report SAND2006-5315, Sandia National Laboratories, August 2006.

[2] Conn, A. R., N. I. M. Gould, and Ph. L.
Toint. "A Globally Convergent Augmented Lagrangian Algorithm
for Optimization with General Constraints and Simple Bounds," *SIAM
Journal on Numerical Analysis*, Volume 28, Number 2, pages
545–572, 1991.

[3] Conn, A. R., N. I. M. Gould, and Ph. L.
Toint. "A Globally Convergent Augmented Lagrangian Barrier
Algorithm for Optimization with General Inequality Constraints and
Simple Bounds," *Mathematics of Computation*,
Volume 66, Number 217, pages 261–288, 1997.

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