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Reconstructing Planar Curves from Euclidean and Affine Curvatures


Temel Kavramlar
Practical algorithms for reconstructing planar curves from their Euclidean or affine curvatures, and estimates on the closeness of reconstructed curves with close curvatures.
Özet

The content discusses practical aspects of reconstructing planar curves with prescribed Euclidean or affine curvatures. These curvatures are invariant under the special Euclidean group and the special affine group, respectively, and play an important role in computer vision and shape analysis.

The key highlights and insights are:

  1. Rigid motions (compositions of translations, rotations, and reflections) make up the Euclidean group E(2), and the special Euclidean group SE(2) consists of orientation-preserving rigid motions (rotations and translations).
  2. The special affine group SA(2) consists of compositions of unimodular linear transformations and translations, and preserves areas but not distances or angles.
  3. Two sufficiently smooth planar curves are SE(2)-congruent if they have the same Euclidean curvature as a function of the Euclidean arc-length, and SA(2)-congruent if they have the same affine curvature as a function of the affine arc-length.
  4. The authors review and implement procedures for reconstructing curves from their Euclidean and affine curvatures, and provide estimates on how close reconstructed curves can be brought together by the relevant transformation group if their curvatures are close in appropriate metrics.
  5. The Euclidean reconstruction is based on successive integrations, while the affine reconstruction uses Picard iterations.
  6. Theorem 12 provides an upper bound on the Hausdorff distance between two curves with δ-close Euclidean curvatures, and Theorem 19 provides a similar result for the affine case.
  7. The content includes several illustrative examples and discusses the pedagogical value of the project for the undergraduate participants.
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Kaynak

İstatistikler
The Euclidean curvature function κ(s) is given by the formula: κ(s) = ±|γss|, where the sign depends on the orientation of the rotation from γs to γss. The affine curvature function µ(s) is given by the formula: µ(s) = 3κ(κss + 3κ3) - 5κ2s / 9κ8/3.
Alıntılar
"Rigid motions – compositions of translations, rotations and reflections – are fundamental transformations on the plane studied in a high-school geometry course." "Two sufficiently smooth planar curves are SE(2)-congruent if they have the same Euclidean curvature κ as a function of the Euclidean arc-length s." "Similarly to the Euclidean case, one can show that two sufficiently smooth planar curves are SA(2)-congruent if they have the same affine curvature µ as a function of the affine arc-length α."

Önemli Bilgiler Şuradan Elde Edildi

by Jose Agudelo... : arxiv.org 04-02-2024

https://arxiv.org/pdf/2201.09929.pdf
Euclidean and Affine Curve Reconstruction

Daha Derin Sorular

How can the reconstruction algorithms be extended to handle more general classes of curves, such as those with singularities or self-intersections

To extend the reconstruction algorithms to handle more general classes of curves, such as those with singularities or self-intersections, additional considerations and techniques need to be incorporated. For curves with singularities, special treatment may be required at these points to ensure the continuity and smoothness of the reconstructed curve. This could involve using specialized interpolation methods or curve fitting techniques that can accommodate abrupt changes in curvature. For curves with self-intersections, the reconstruction algorithm would need to detect and resolve these intersections to ensure a coherent and accurate reconstruction. This could involve segmenting the curve into non-intersecting components and reconstructing each segment separately before merging them back together. Advanced geometric algorithms for curve intersection detection and resolution would be essential in handling such cases.

What are some potential applications of curve reconstruction techniques in computer vision, shape analysis, or other fields beyond the planar case considered here

Curve reconstruction techniques have a wide range of applications beyond the planar case considered here. In computer vision, these techniques are crucial for shape analysis, object recognition, and image processing. By reconstructing curves from curvature information, it becomes possible to analyze and compare shapes in images, leading to applications in pattern recognition, object tracking, and scene understanding. In fields like robotics and autonomous navigation, curve reconstruction can be used to interpret sensor data, map environments, and plan motion trajectories. By reconstructing curves from sensor measurements, robots can navigate complex environments, avoid obstacles, and perform tasks with precision. In medical imaging, curve reconstruction techniques can be applied to analyze anatomical structures, track organ shapes and movements, and assist in surgical planning. By reconstructing curves from medical imaging data, doctors and researchers can gain insights into biological shapes and structures for diagnosis and treatment purposes.

Is there a deeper connection between the Euclidean and affine curvatures, and can insights from one geometry inform the understanding of the other

There is a deep connection between Euclidean and affine curvatures, stemming from their geometric interpretations and mathematical properties. While Euclidean curvature measures the rate at which a curve deviates from a straight line in Euclidean space, affine curvature captures the rate of change of the curve's tangent vector in affine space. Insights from one geometry can indeed inform the understanding of the other. For example, the concept of affine curvature can be seen as a generalization of Euclidean curvature that accounts for affine transformations and preserves area rather than distance. Understanding the relationship between these curvatures can lead to insights into the underlying geometric structures and transformations in different spaces. By studying the interplay between Euclidean and affine curvatures, researchers can develop more robust algorithms for curve reconstruction, shape analysis, and transformation estimation in various geometries. This deeper connection can also inspire new mathematical frameworks and applications in fields such as differential geometry, computer graphics, and geometric modeling.
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