The interval Branch-and-Prune algorithm for the discretizable molecular distance geometry problem with inexact distances

Carlile Lavor; Leo Liberti; Antonio Mucherino

doi:10.1007/s10898-011-9799-6

The interval Branch-and-Prune algorithm for the discretizable molecular distance geometry problem with inexact distances

Carlile Lavor
, Leo Liberti
, Antonio Mucherino

University of Campinas (UNICAMP)
University of Rennes

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

Résumé

The Distance Geometry Problem in three dimensions consists in finding an embedding in {\mathbb R³} of a given nonnegatively weighted simple undirected graph such that edge weights are equal to the corresponding Euclidean distances in the embedding. This is a continuous search problem that can be discretized under some assumptions on the minimum degree of the vertices. In this paper we discuss the case where we consider the full-atom representation of the protein backbone and some of the edge weights are subject to uncertainty within a given nonnegative interval. We show that a discretization is still possible and propose the iBP algorithm to solve the problem. The approach is validated by some computational experiments on a set of artificially generated instances.

langue originale	Anglais
Pages (de - à)	855-871
Nombre de pages	17
journal	Journal of Global Optimization
Volume	56
Numéro de publication	3
Les DOIs	https://doi.org/10.1007/s10898-011-9799-6
état	Publié - 1 juil. 2013

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10.1007/s10898-011-9799-6

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title = "The interval Branch-and-Prune algorithm for the discretizable molecular distance geometry problem with inexact distances",

abstract = "The Distance Geometry Problem in three dimensions consists in finding an embedding in \{\textbackslash{}mathbb R3\} of a given nonnegatively weighted simple undirected graph such that edge weights are equal to the corresponding Euclidean distances in the embedding. This is a continuous search problem that can be discretized under some assumptions on the minimum degree of the vertices. In this paper we discuss the case where we consider the full-atom representation of the protein backbone and some of the edge weights are subject to uncertainty within a given nonnegative interval. We show that a discretization is still possible and propose the iBP algorithm to solve the problem. The approach is validated by some computational experiments on a set of artificially generated instances.",

keywords = "Combinatorial optimization, Distance geometry, Interval Branch and Prune, NMR data, Protein conformations",

author = "Carlile Lavor and Leo Liberti and Antonio Mucherino",

year = "2013",

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AU - Mucherino, Antonio

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N2 - The Distance Geometry Problem in three dimensions consists in finding an embedding in {\mathbb R3} of a given nonnegatively weighted simple undirected graph such that edge weights are equal to the corresponding Euclidean distances in the embedding. This is a continuous search problem that can be discretized under some assumptions on the minimum degree of the vertices. In this paper we discuss the case where we consider the full-atom representation of the protein backbone and some of the edge weights are subject to uncertainty within a given nonnegative interval. We show that a discretization is still possible and propose the iBP algorithm to solve the problem. The approach is validated by some computational experiments on a set of artificially generated instances.

AB - The Distance Geometry Problem in three dimensions consists in finding an embedding in {\mathbb R3} of a given nonnegatively weighted simple undirected graph such that edge weights are equal to the corresponding Euclidean distances in the embedding. This is a continuous search problem that can be discretized under some assumptions on the minimum degree of the vertices. In this paper we discuss the case where we consider the full-atom representation of the protein backbone and some of the edge weights are subject to uncertainty within a given nonnegative interval. We show that a discretization is still possible and propose the iBP algorithm to solve the problem. The approach is validated by some computational experiments on a set of artificially generated instances.

KW - Combinatorial optimization

KW - Distance geometry

KW - Interval Branch and Prune

KW - NMR data

KW - Protein conformations

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JO - Journal of Global Optimization

JF - Journal of Global Optimization

IS - 3

ER -

The interval Branch-and-Prune algorithm for the discretizable molecular distance geometry problem with inexact distances

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