coliny_direct

DIviding RECTangles method

Topics

package_scolib, package_coliny, global_optimization_methods

Specification

• Alias: None

• Arguments: None

Child Keywords:

Required/Optional	Description of Group	Dakota Keyword	Dakota Keyword Description
Optional		division	Determine how rectangles are subdivided
Optional		global_balance_parameter	Tolerance for whether a subregion is worth dividing
Optional		local_balance_parameter	Tolerance for whether a subregion is worth dividing
Optional		max_boxsize_limit	Stopping Criterion based on longest edge of hyperrectangle
Optional		min_boxsize_limit	Stopping Criterion based on shortest edge of hyperrectangle
Optional		constraint_penalty	Multiplier for the penalty function
Optional		solution_target	Stopping criteria based on objective function value
Optional		seed	Seed of the random number generator
Optional		show_misc_options	Show algorithm parameters not exposed in Dakota input
Optional		misc_options	Set method options not available through Dakota spec
Optional		max_iterations	Number of iterations allowed for optimizers and adaptive UQ methods
Optional		convergence_tolerance	Stopping criterion based on objective function or statistics convergence
Optional		max_function_evaluations	Number of function evaluations allowed for optimizers
Optional		scaling	Turn on scaling for variables, responses, and constraints
Optional		model_pointer	Identifier for model block to be used by a method

Description

The DIviding RECTangles (DIRECT) optimization algorithm is a derivative free global optimization method that balances local search in promising regions of the design space with global search in unexplored regions. As shown in Figure 5.1, DIRECT adaptively subdivides the space of feasible design points so as to guarantee that iterates are generated in the neighborhood of a global minimum in finitely many iterations.

image html direct1.jpg “Figure 5.1 Design space partitioning with DIRECT” image latex direct1.eps “Design space partitioning with DIRECT” width=10cm

In practice, DIRECT has proven an effective heuristic for engineering design applications, for which it is able to quickly identify candidate solutions that can be further refined with fast local optimizers.

See the page :ref:`topic-package_scolib` for important information regarding all SCOLIB methods

The DIRECT algorithm supports concurrency up to twice the number of variables being optimized.

DIRECT uses the solution_target, constraint_penalty and show_misc_options specifications that are described in Package: SCOLIB. Note, however, that DIRECT uses a fixed penalty value for constraint violations (i.e. it is not dynamically adapted as is done in coliny_pattern_search).

Search Parameters

The global_balance_parameter controls how much global search is performed by only allowing a subregion to be subdivided if the size of the subregion divided by the size of the largest subregion is at least global_balance_parameter. Intuitively, this forces large subregions to be subdivided before the smallest subregions are refined. The local_balance_parameter provides a tolerance for estimating whether the smallest subregion can provide a sufficient decrease to be worth subdividing; the default value is a small value that is suitable for most applications.

Stopping Critieria

DIRECT can be terminated with:

li max_function_evaluations li max_iterations li convergence_tolerance li solution_target li max_boxsize_limit li min_boxsize_limit - most effective in practice

Expected HDF5 Output

If Dakota was built with HDF5 support and run with the hdf5 keyword, this method writes the following results to HDF5:

• Best Parameters

• Best Objective Functions (when objective_functions) are specified)

• Best Nonlinear Constraints

• Calibration (when calibration_terms are specified)