Random projections for quadratic programs

Claudia D’Ambrosio; Leo Liberti; Pierre Louis Poirion; Ky Vu

doi:10.1007/s10107-020-01517-x

Random projections for quadratic programs

Claudia D’Ambrosio
, Leo Liberti
, Pierre Louis Poirion
, Ky Vu

Laboratoire d'Informatique (LIX)
RIKEN AIP
FPT University

Résultats de recherche: Contribution à un journal › Article › Revue par des pairs

Résumé

Random projections map a set of points in a high dimensional space to a lower dimensional one while approximately preserving all pairwise Euclidean distances. Although random projections are usually applied to numerical data, we show in this paper that they can be successfully applied to quadratic programming formulations over a set of linear inequality constraints. Instead of solving the higher-dimensional original problem, we solve the projected problem more efficiently. This yields a feasible solution of the original problem. We prove lower and upper bounds of this feasible solution w.r.t. the optimal objective function value of the original problem. We then discuss some computational results on randomly generated instances, as well as a variant of Markowitz’ portfolio problem. It turns out that our method can find good feasible solutions of very large instances.

langue originale	Anglais
Pages (de - à)	619-647
Nombre de pages	29
journal	Mathematical Programming
Volume	183
Numéro de publication	1-2
Les DOIs	https://doi.org/10.1007/s10107-020-01517-x
état	Publié - 1 sept. 2020

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title = "Random projections for quadratic programs",

abstract = "Random projections map a set of points in a high dimensional space to a lower dimensional one while approximately preserving all pairwise Euclidean distances. Although random projections are usually applied to numerical data, we show in this paper that they can be successfully applied to quadratic programming formulations over a set of linear inequality constraints. Instead of solving the higher-dimensional original problem, we solve the projected problem more efficiently. This yields a feasible solution of the original problem. We prove lower and upper bounds of this feasible solution w.r.t. the optimal objective function value of the original problem. We then discuss some computational results on randomly generated instances, as well as a variant of Markowitz{\textquoteright} portfolio problem. It turns out that our method can find good feasible solutions of very large instances.",

keywords = "Approximation, Johnson–Lindenstrauss lemma, Large-scale optimization, Nonlinear programming, Polynomial optimization",

author = "Claudia D{\textquoteright}Ambrosio and Leo Liberti and Poirion, \{Pierre Louis\} and Ky Vu",

note = "Publisher Copyright: {\textcopyright} 2020, Springer-Verlag GmbH Germany, part of Springer Nature and Mathematical Optimization Society.",

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AU - Liberti, Leo

AU - Poirion, Pierre Louis

AU - Vu, Ky

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N2 - Random projections map a set of points in a high dimensional space to a lower dimensional one while approximately preserving all pairwise Euclidean distances. Although random projections are usually applied to numerical data, we show in this paper that they can be successfully applied to quadratic programming formulations over a set of linear inequality constraints. Instead of solving the higher-dimensional original problem, we solve the projected problem more efficiently. This yields a feasible solution of the original problem. We prove lower and upper bounds of this feasible solution w.r.t. the optimal objective function value of the original problem. We then discuss some computational results on randomly generated instances, as well as a variant of Markowitz’ portfolio problem. It turns out that our method can find good feasible solutions of very large instances.

AB - Random projections map a set of points in a high dimensional space to a lower dimensional one while approximately preserving all pairwise Euclidean distances. Although random projections are usually applied to numerical data, we show in this paper that they can be successfully applied to quadratic programming formulations over a set of linear inequality constraints. Instead of solving the higher-dimensional original problem, we solve the projected problem more efficiently. This yields a feasible solution of the original problem. We prove lower and upper bounds of this feasible solution w.r.t. the optimal objective function value of the original problem. We then discuss some computational results on randomly generated instances, as well as a variant of Markowitz’ portfolio problem. It turns out that our method can find good feasible solutions of very large instances.

KW - Approximation

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KW - Nonlinear programming

KW - Polynomial optimization

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Random projections for quadratic programs

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