On the surjectivity of shape fibrations
Q. Haxhibeqiri (1985)
Matematički Vesnik
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Q. Haxhibeqiri (1985)
Matematički Vesnik
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Szalay, I. (2003)
Acta Mathematica Academiae Paedagogicae Nyí regyháziensis. New Series [electronic only]
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Paulus Gerdes (2013)
Visual Mathematics
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Manuel Alonso Moron (1989)
Colloquium Mathematicae
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Segal, Jack
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M.A. Morón, F.R. Ruiz del Portal (1996)
Manuscripta mathematica
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Tao Liao, Hao-Chih Lee, Ge Yang, Yongjie Jessica Zhang (2015)
Molecular Based Mathematical Biology
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The functionality of biomolecules depends on their flexible structures, which can be characterized by their surface shapes. Tracking the deformation and comparing biomolecular shapes are essential in understanding their mechanisms. In this paper, a new spectral shape correspondence analysis method is introduced for biomolecules based on volumetric eigenfunctions. The eigenfunctions are computed from the joint graph of two given shapes, avoiding the sign flipping and confusion in the...
Joviša Žunić (2012)
Zbornik Radova
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G. Kozlowski, Jack Segal (1977)
Fundamenta Mathematicae
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Jerzy Dydak, Sławomir Nowak (2002)
Fundamenta Mathematicae
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The purpose of this paper is to provide a geometric explanation of strong shape theory and to give a fairly simple way of introducing the strong shape category formally. Generally speaking, it is useful to introduce a shape theory as a localization at some class of “equivalences”. We follow this principle and we extend the standard shape category Sh(HoTop) to Sh(pro-HoTop) by localizing pro-HoTop at shape equivalences. Similarly, we extend the strong shape category of Edwards-Hastings...