Landmark-Constrained Elastic Shape Analysis of Planar Curves

Strait, Justin; Kurtek, Sebastian; Bartha, Emily; MacEachern, Steven N.

doi:10.1080/01621459.2016.1236726

Cited by 21 publications

(12 citation statements)

References 21 publications

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“…Landmark-constrained alignment, under a geometric, non-stochastic framework, was only recently studied (Strait et al, 2017;Bauer et al, 2017). In those methods, it is not possible to capture or model uncertainty in the optimal alignment.…”

Section: Motivation and Related Workmentioning

confidence: 99%

Distribution on Warp Maps for Alignment of Open and Closed Curves

Bharath

Kurtek

2019

Journal of the American Statistical Association

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Alignment of curve data is an integral part of their statistical analysis, and can be achieved using model-or optimization-based approaches. The parameter space is usually the set of monotone, continuous warp maps of a domain. Infinite-dimensional nature of the parameter space encourages sampling based approaches, which require a distribution on the set of warp maps. Moreover, the distribution should also enable sampling in the presence of important landmark information on the curves which constrain the warp maps. For alignment of closed and open curves in R d , d = 1, 2, 3, possibly with landmark information, we provide a constructive, point-process based definition of a distribution on the set of warp maps of [0, 1] and the unit circle S that is (1) simple to sample from, and (2) possesses the desiderata for decomposition of the alignment problem with landmark constraints into multiple unconstrained ones. For warp maps on [0, 1], the distribution is related to the Dirichlet process. We demonstrate its utility by using it as a prior distribution on warp maps in a Bayesian model for alignment of two univariate curves, and as a proposal distribution in a stochastic algorithm that optimizes a suitable alignment functional for higher-dimensional curves. Several examples from simulated and real datasets are provided.

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Section: Motivation and Related Workmentioning

confidence: 99%

Distribution on Warp Maps for Alignment of Open and Closed Curves

Bharath

Kurtek

2019

Journal of the American Statistical Association

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“…Some nonlinear flag manifolds have already appeared in the literature too. Landmark-constrained planar curves, for instance, have been used in a statistical elastic shape analysis framework in [ 26 ]. Landmark-constrained surfaces in the context of shape analysis are being discussed in [ 17 , Chapter 6].…”

Section: Introductionmentioning

confidence: 99%

Nonlinear flag manifolds as coadjoint orbits

Haller

Vizman

2020

Ann Glob Anal Geom

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“…A detailed description of this dataset (section 1.4.1), along with a thorough statistical analysis under the landmark-based representation, are given in Dryden and Mardia (2016). More recently, this data was also analyzed under different representations in Cheng, Dryden, and Huang (2016), Strait, Kurtek, Bartha, and MacEachern (2017) and Cho, Asiaee, and Kurtek (2019). The entire dataset is available in R as part of the shapes package.…”

Section: Introductionmentioning

confidence: 99%

Analysis of shape data: From landmarks to elastic curves

Bharath

Kurtek

2020

WIREs Computational Stats

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Proliferation of high-resolution imaging data in recent years has led to substantial improvements in the two popular approaches for analyzing shapes of data objects based on landmarks and/or continuous curves. We provide an expository account of elastic shape analysis of parametric planar curves representing shapes of two-dimensional (2D) objects by discussing its differences, and its commonalities, to the landmark-based approach. Particular attention is accorded to the role of reparameterization of a curve, which in addition to rotation, scaling and translation, represents an important shape-preserving transformation of a curve. The transition to the curve-based approach moves the mathematical setting of shape analysis from finite-dimensional non-Euclidean spaces to infinite-dimensional ones. We discuss some of the challenges associated with the infinite-dimensionality of the shape space, and illustrate the use of geometry-based methods in the computation of intrinsic statistical summaries and in the definition of statistical models on a 2D imaging dataset consisting of mouse vertebrae. We conclude with an overview of the current state-of-the-art in the field.

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Landmark-Constrained Elastic Shape Analysis of Planar Curves

Cited by 21 publications

References 21 publications

Distribution on Warp Maps for Alignment of Open and Closed Curves

Distribution on Warp Maps for Alignment of Open and Closed Curves

Nonlinear flag manifolds as coadjoint orbits

Analysis of shape data: From landmarks to elastic curves

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