Optimal blocked minimum-support designs for non-linear models
Optimal blocked minimum-support designs for non-linear models
Finding optimal designs for experiments for non-linear models and dependent data is a challenging task. We show how the problem simplifies when the search is restricted to designs that are minimally supported; that is, the number of distinct runs (treatments) is equal to the number of unknown parameters, p, in the model. Under this restriction, the problem of finding a locally or pseudo-Bayesian D-optimal design decomposes into two simpler problems that are more widely studied. The first is that of finding a minimum- support D-optimal design d1 with p runs for the corresponding model for the mean but assuming independent observations. The second problem is finding a D-optimal block design for assigning the treatments in d1 to the experimental units. We find and assess optimal minimum-support designs for three examples, each assuming a mean model from a different member of the exponential family: binomial, Poisson and normal. In each case, the efficiencies of the designs are compared to the optimal design where the restriction on the number of distinct support points is relaxed. The optimal minimum-support designs are found to often perform satisfactorily under both local and Bayesian D-optimality for concentrated prior distributions. The results are also relatively insensitive to the assumed degree of dependence in the data.
binary data, block designs, count data, D-optimality, generalized estimating equations, generalized linear models, michaelis menten model
152-159
van de Ven, P.M.
774197e8-dc76-4931-9d3c-1b16b2296713
Woods, D.C.
ae21f7e2-29d9-4f55-98a2-639c5e44c79c
2014
van de Ven, P.M.
774197e8-dc76-4931-9d3c-1b16b2296713
Woods, D.C.
ae21f7e2-29d9-4f55-98a2-639c5e44c79c
van de Ven, P.M. and Woods, D.C.
(2014)
Optimal blocked minimum-support designs for non-linear models.
Journal of Statistical Planning and Inference, 144, .
(doi:10.1016/j.jspi.2013.02.001).
Abstract
Finding optimal designs for experiments for non-linear models and dependent data is a challenging task. We show how the problem simplifies when the search is restricted to designs that are minimally supported; that is, the number of distinct runs (treatments) is equal to the number of unknown parameters, p, in the model. Under this restriction, the problem of finding a locally or pseudo-Bayesian D-optimal design decomposes into two simpler problems that are more widely studied. The first is that of finding a minimum- support D-optimal design d1 with p runs for the corresponding model for the mean but assuming independent observations. The second problem is finding a D-optimal block design for assigning the treatments in d1 to the experimental units. We find and assess optimal minimum-support designs for three examples, each assuming a mean model from a different member of the exponential family: binomial, Poisson and normal. In each case, the efficiencies of the designs are compared to the optimal design where the restriction on the number of distinct support points is relaxed. The optimal minimum-support designs are found to often perform satisfactorily under both local and Bayesian D-optimality for concentrated prior distributions. The results are also relatively insensitive to the assumed degree of dependence in the data.
More information
Published date: 2014
Keywords:
binary data, block designs, count data, D-optimality, generalized estimating equations, generalized linear models, michaelis menten model
Organisations:
Statistics, Statistical Sciences Research Institute
Identifiers
Local EPrints ID: 347912
URI: http://eprints.soton.ac.uk/id/eprint/347912
ISSN: 0378-3758
PURE UUID: 8507586c-422a-4244-a7fe-e2fcae6acc49
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Date deposited: 14 Feb 2013 13:43
Last modified: 15 Mar 2024 03:05
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Author:
P.M. van de Ven
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