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A comparison of design and model selection methods for supersaturated experiments

A comparison of design and model selection methods for supersaturated experiments
A comparison of design and model selection methods for supersaturated experiments
Various design and model selection methods are available for supersaturated designs having more factors than runs but little research is available on their comparison and evaluation. Simulated experiments are used to evaluate the use of E(s2)-optimal and Bayesian D-optimal designs and to compare three analysis strategies representing regression, shrinkage and a novel model-averaging procedure. Suggestions are made for choosing the values of the tuning constants for each approach. Findings include that (i) the preferred analysis is via shrinkage; (ii) designs with similar numbers of runs and factors can be effective for a considerable number of active effects of only moderate size; and (iii) unbalanced designs can perform well. Some comments are made on the performance of the design and analysis methods when effect sparsity does not hold.
bayesian D-optimal designs, E(s2)-optimal designs, effect sparsity, gauss–dantzig selector, main effects, screening, simulation
0167-9473
3158-3167
Marley, Christopher J.
cf0ba89e-7868-4df0-9bb4-31004497e2ae
Woods, David C.
ae21f7e2-29d9-4f55-98a2-639c5e44c79c
Marley, Christopher J.
cf0ba89e-7868-4df0-9bb4-31004497e2ae
Woods, David C.
ae21f7e2-29d9-4f55-98a2-639c5e44c79c

Marley, Christopher J. and Woods, David C. (2010) A comparison of design and model selection methods for supersaturated experiments. Computational Statistics & Data Analysis, 54 (12), 3158-3167. (doi:10.1016/j.csda.2010.02.017).

Record type: Article

Abstract

Various design and model selection methods are available for supersaturated designs having more factors than runs but little research is available on their comparison and evaluation. Simulated experiments are used to evaluate the use of E(s2)-optimal and Bayesian D-optimal designs and to compare three analysis strategies representing regression, shrinkage and a novel model-averaging procedure. Suggestions are made for choosing the values of the tuning constants for each approach. Findings include that (i) the preferred analysis is via shrinkage; (ii) designs with similar numbers of runs and factors can be effective for a considerable number of active effects of only moderate size; and (iii) unbalanced designs can perform well. Some comments are made on the performance of the design and analysis methods when effect sparsity does not hold.

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More information

e-pub ahead of print date: 2 March 2010
Published date: 1 December 2010
Keywords: bayesian D-optimal designs, E(s2)-optimal designs, effect sparsity, gauss–dantzig selector, main effects, screening, simulation
Organisations: Southampton Statistical Research Inst.

Identifiers

Local EPrints ID: 151259
URI: http://eprints.soton.ac.uk/id/eprint/151259
ISSN: 0167-9473
PURE UUID: 0cf59c04-b230-46af-a82d-898dfd3b8702
ORCID for David C. Woods: ORCID iD orcid.org/0000-0001-7648-429X

Catalogue record

Date deposited: 10 May 2010 09:23
Last modified: 14 Mar 2024 02:44

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Contributors

Author: Christopher J. Marley
Author: David C. Woods ORCID iD

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