Your search keyword '"Mataigne, Simon"' showing total 5 results

1. The eigenvalue decomposition of normal matrices by the decomposition of the skew-symmetric part with applications to orthogonal matrices

Author

Mataigne, Simon and Gallivan, Kyle A.

Subjects

Mathematics - Numerical Analysis, 65F15, 15B10, 15B57, 62R30

Abstract

We propose a fast method for computing the eigenvalue decomposition of a dense real normal matrix $A$. The method leverages algorithms that are known to be efficiently implemented, such as the bidiagonal singular value decomposition and the symmetric eigenvalue decomposition. For symmetric and skew-symmetric matrices, the method reduces to calling the latter, so that its advantages are for orthogonal matrices mostly and, potentially, any other normal matrix. The method relies on the real Schur decomposition of the skew-symmetric part of $A$. To obtain the eigenvalue decomposition of the normal matrix $A$, additional steps depending on the distribution of the eigenvalues are required. We provide a complexity analysis of the method and compare its numerical performance with existing algorithms. In most cases, the method is as fast as obtaining the Hessenberg factorization of a dense matrix. Finally, we evaluate the method's accuracy and provide experiments for the application of a Karcher mean on the special orthogonal group., Comment: 24 pages, 5 figures, 2 tables

Published

2024

2. Bounds on the geodesic distances on the Stiefel manifold for a family of Riemannian metrics

Author

Mataigne, Simon, Absil, P. -A., and Miolane, Nina

Subjects

Mathematics - Differential Geometry, Computer Science - Machine Learning, 15B10, 53Z50, 53C30, 14M17

Abstract

We give bounds on geodesic distances on the Stiefel manifold, derived from new geometric insights. The considered geodesic distances are induced by the one-parameter family of Riemannian metrics introduced by H\"uper et al. (2021), which contains the well-known Euclidean and canonical metrics. First, we give the best Lipschitz constants between the distances induced by any two members of the family of metrics. Then, we give a lower and an upper bound on the geodesic distance by the easily computable Frobenius distance. We give explicit families of pairs of matrices that depend on the parameter of the metric and the dimensions of the manifold, where the lower and the upper bound are attained. These bounds aim at improving the theoretical guarantees and performance of minimal geodesic computation algorithms by reducing the initial velocity search space. In addition, these findings contribute to advancing the understanding of geodesic distances on the Stiefel manifold and their applications., Comment: 27 pages, 11 figures

Published

2024

3. The Selective G-Bispectrum and its Inversion: Applications to G-Invariant Networks

Author

Mataigne, Simon, Mathe, Johan, Sanborn, Sophia, Hillar, Christopher, and Miolane, Nina

Subjects

Computer Science - Machine Learning, 68T01, 68T07, 68R01, 20K01

Abstract

An important problem in signal processing and deep learning is to achieve \textit{invariance} to nuisance factors not relevant for the task. Since many of these factors are describable as the action of a group $G$ (e.g. rotations, translations, scalings), we want methods to be $G$-invariant. The $G$-Bispectrum extracts every characteristic of a given signal up to group action: for example, the shape of an object in an image, but not its orientation. Consequently, the $G$-Bispectrum has been incorporated into deep neural network architectures as a computational primitive for $G$-invariance\textemdash akin to a pooling mechanism, but with greater selectivity and robustness. However, the computational cost of the $G$-Bispectrum ($\mathcal{O}(|G|^2)$, with $|G|$ the size of the group) has limited its widespread adoption. Here, we show that the $G$-Bispectrum computation contains redundancies that can be reduced into a \textit{selective $G$-Bispectrum} with $\mathcal{O}(|G|)$ complexity. We prove desirable mathematical properties of the selective $G$-Bispectrum and demonstrate how its integration in neural networks enhances accuracy and robustness compared to traditional approaches, while enjoying considerable speeds-up compared to the full $G$-Bispectrum., Comment: 10 pages

Published

2024

4. An efficient algorithm for the Riemannian logarithm on the Stiefel manifold for a family of Riemannian metrics

Author

Mataigne, Simon, Zimmermann, Ralf, and Miolane, Nina

Subjects

Mathematics - Numerical Analysis, Mathematics - Differential Geometry, 15B10, 15B57, 53Z50, 65B99, 15A16

Abstract

Since the popularization of the Stiefel manifold for numerical applications in 1998 in a seminal paper from Edelman et al., it has been exhibited to be a key to solve many problems from optimization, statistics and machine learning. In 2021, H\"uper et al. proposed a one-parameter family of Riemannian metrics on the Stiefel manifold, subsuming the well-known Euclidean and canonical metrics. Since then, several methods have been proposed to obtain a candidate for the Riemannian logarithm given any metric from the family. Most of these methods are based on the shooting method or rely on optimization approaches. For the canonical metric, Zimmermann proposed in 2017 a particularly efficient method based on a pure matrix-algebraic approach. In this paper, we derive a generalization of this algorithm that works for the one-parameter family of Riemannian metrics. The algorithm is proposed in two versions, termed backward and forward, for which we prove that it conserves the local linear convergence previously exhibited in Zimmermann's algorithm for the canonical metric., Comment: 20 pages, 6 figures, 3 tables

Published

2024

5. The ultimate upper bound on the injectivity radius of the Stiefel manifold

Author

Absil, P. -A. and Mataigne, Simon

Subjects

Mathematics - Differential Geometry, Mathematics - Optimization and Control

Abstract

We exhibit conjugate points on the Stiefel manifold endowed with any member of the family of Riemannian metrics introduced by H\"uper et al. (2021). This family contains the well-known canonical and Euclidean metrics. An upper bound on the injectivity radius of the Stiefel manifold in the considered metric is then obtained as the minimum between the length of the geodesic along which the points are conjugate and the length of certain geodesic loops. Numerical experiments support the conjecture that the obtained upper bound is in fact equal to the injectivity radius., Comment: v2: fixed MSC codes; fixed typo in the penultimate sentence of the proof of Theorem 6.1; added section 9 (Concluding remarks)

Published

2024