Please use this identifier to cite or link to this item: http://dspace.utpl.edu.ec/handle/123456789/18981
Title: Communications on quantum similarity (4): Collective distances computed by means of similarity matrices, as generators of intrinsic ordering among quantum multimolecular polyhedra
Authors: Barragan Guerrero, D.
Carbo Dorca, R.
Keywords: Geometry
Linear algebra
Matrix algebra
Quantum theory
Vectors Application examples
Arbitrary sets
Arbitrary vectors
Molecular contribution
Notion of distance
Quantitative structures
Quantum mechanical
Quantum similarity
Publisher: Wiley Interdisciplinary Reviews: Computational Molecular Science
Abstract: This study generalizes the notion of distance via defining an axiomatic collective distance, between arbitrary vector sets. A first part discusses conceptual tools, which can be later useful for general mathematical practice or as computational quantum similarity indices. After preliminary definitions, two elements, which can be associated with arbitrary sets of a vector space, are described: the centroid and the variance vectors. The Minkowski norm of the variance vector is shown to comply with the axioms of a collective distance. The role of the Gram matrix, associated with a vector set, is linked to the definition of numerical variance. Several simple application examples involving linear algebra and N-dimensional geometry are given. In a second part, all previous definitions are applied to quantum multimolecular polyhedra (QMP), where a set of molecular quantum mechanical density functions act as vertices. The numerical Minkowski norm of the variance vector in any QMP could be considered as a superposition of molecular contributions, corresponding to a new set of quantum similarity indices, which can generate intrinsic ordering among QMP vertices. In this way, the role of quantum similarity matrix elements is evidenced. Application to collections of molecular structures is analyzed as an illustrative practical exercise. The connection of the QMP framework with classical and quantum quantitative structure-properties relation (QSPR) becomes evident with the aid of numerical examples computed over several molecular sets acting as QMP. © 2015 John Wiley & Sons, Ltd.
URI: http://dspace.utpl.edu.ec/handle/123456789/18981
ISBN: 17590876
Other Identifiers: http://10.1002/wcms.1223
Appears in Collections:Artículos de revistas Científicas



Items in DSpace are protected by copyright, with all rights reserved, unless otherwise indicated.