Directions and projective shapes

Directions and projective shapes

Kanti V. Mardia and Vic Patrangenaru

Source: Ann. Statist. Volume 33, Number 4 (2005), 1666-1699.

Abstract

This paper deals with projective shape analysis, which is a study of finite configurations of points modulo projective transformations. The topic has various applications in machine vision. We introduce a convenient projective shape space, as well as an appropriate coordinate system for this shape space. For generic configurations of k points in m dimensions, the resulting projective shape space is identified as a product of k−m−2 copies of axial spaces ℝP^m. This identification leads to the need for developing multivariate directional and multivariate axial analysis and we propose parametric models, as well as nonparametric methods, for these areas. In particular, we investigate the Frećhet extrinsic mean for the multivariate axial case. Asymptotic distributions of the appropriate parametric and nonparametric tests are derived. We illustrate our methodology with examples from machine vision.

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Primary Subjects: 62H11

Secondary Subjects: 62H10, 62H35

Keywords: Projective transformations; projective frame; projective shape space; equivariant embedding; extrinsic means; directional statistics; tangent approximation; bootstrapping; shape analysis; machine vision

Full-text: Open access

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Permanent link to this document: http://projecteuclid.org/euclid.aos/1123250226
Digital Object Identifier: doi:10.1214/009053605000000273
Mathematical Reviews number (MathSciNet): MR2166559
Zentralblatt MATH identifier: 1078.62068

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