Approximate optimal designs for multivariate polynomial regression

Yohann De Castro; Fabrice Gamboa; Didier Henrion; Roxana Hess; Jean Bernard Lasserre

doi:10.1214/18-AOS1683

Approximate optimal designs for multivariate polynomial regression

Yohann De Castro
, Fabrice Gamboa
, Didier Henrion
, Roxana Hess
, Jean Bernard Lasserre

Université Paris-Saclay
Université de Toulouse
Université Paul Sabatier

Research output: Contribution to journal › Article › peer-review

Abstract

We introduce a new approach aiming at computing approximate optimal designs for multivariate polynomial regressions on compact (semialgebraic) design spaces. We use the moment-sum-of-squares hierarchy of semidefinite programming problems to solve numerically the approximate optimal design problem. The geometry of the design is recovered via semidefinite programming duality theory. This article shows that the hierarchy converges to the approximate optimal design as the order of the hierarchy increases. Furthermore, we provide a dual certificate ensuring finite convergence of the hierarchy and showing that the approximate optimal design can be computed numerically with our method. As a byproduct, we revisit the equivalence theorem of the experimental design theory: it is linked to the Christoffel polynomial and it characterizes finite convergence of the moment-sum-of-square hierarchies.

Original language	English
Pages (from-to)	127-155
Number of pages	29
Journal	Annals of Statistics
Volume	47
Issue number	1
DOIs	https://doi.org/10.1214/18-AOS1683
Publication status	Published - 1 Feb 2019
Externally published	Yes

Keywords

Christoffel polynomial
Equivalence theorem
Experimental design
Linear model
Semidefinite programming

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10.1214/18-AOS1683

Cite this

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title = "Approximate optimal designs for multivariate polynomial regression",

abstract = "We introduce a new approach aiming at computing approximate optimal designs for multivariate polynomial regressions on compact (semialgebraic) design spaces. We use the moment-sum-of-squares hierarchy of semidefinite programming problems to solve numerically the approximate optimal design problem. The geometry of the design is recovered via semidefinite programming duality theory. This article shows that the hierarchy converges to the approximate optimal design as the order of the hierarchy increases. Furthermore, we provide a dual certificate ensuring finite convergence of the hierarchy and showing that the approximate optimal design can be computed numerically with our method. As a byproduct, we revisit the equivalence theorem of the experimental design theory: it is linked to the Christoffel polynomial and it characterizes finite convergence of the moment-sum-of-square hierarchies.",

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AU - De Castro, Yohann

AU - Gamboa, Fabrice

AU - Henrion, Didier

AU - Hess, Roxana

AU - Lasserre, Jean Bernard

N1 - Publisher Copyright: © Institute of Mathematical Statistics, 2019.

PY - 2019/2/1

Y1 - 2019/2/1

N2 - We introduce a new approach aiming at computing approximate optimal designs for multivariate polynomial regressions on compact (semialgebraic) design spaces. We use the moment-sum-of-squares hierarchy of semidefinite programming problems to solve numerically the approximate optimal design problem. The geometry of the design is recovered via semidefinite programming duality theory. This article shows that the hierarchy converges to the approximate optimal design as the order of the hierarchy increases. Furthermore, we provide a dual certificate ensuring finite convergence of the hierarchy and showing that the approximate optimal design can be computed numerically with our method. As a byproduct, we revisit the equivalence theorem of the experimental design theory: it is linked to the Christoffel polynomial and it characterizes finite convergence of the moment-sum-of-square hierarchies.

AB - We introduce a new approach aiming at computing approximate optimal designs for multivariate polynomial regressions on compact (semialgebraic) design spaces. We use the moment-sum-of-squares hierarchy of semidefinite programming problems to solve numerically the approximate optimal design problem. The geometry of the design is recovered via semidefinite programming duality theory. This article shows that the hierarchy converges to the approximate optimal design as the order of the hierarchy increases. Furthermore, we provide a dual certificate ensuring finite convergence of the hierarchy and showing that the approximate optimal design can be computed numerically with our method. As a byproduct, we revisit the equivalence theorem of the experimental design theory: it is linked to the Christoffel polynomial and it characterizes finite convergence of the moment-sum-of-square hierarchies.

KW - Christoffel polynomial

KW - Equivalence theorem

KW - Experimental design

KW - Linear model

KW - Semidefinite programming

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DO - 10.1214/18-AOS1683

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JO - Annals of Statistics

JF - Annals of Statistics

IS - 1

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Approximate optimal designs for multivariate polynomial regression

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Keywords

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