Chordal-NMF with Riemannian Multiplicative Update
Chordal-NMF with Riemannian Multiplicative Update
Nonnegative Matrix Factorization (NMF) is the problem of approximating a given nonnegative matrix M through the conic combination of two nonnegative low-rank matrices W and H. Traditionally NMF is tackled by optimizing a specific objective function evaluating the quality of the approximation. This assessment is often done based on the Frobenius norm. In this study, we argue that the Frobenius norm as the "point-to-point" distance may not always be appropriate. Due to the nonnegative combination resulting in a polyhedral cone, this conic perspective of NMF may not naturally align with conventional point-to-point distance measures. Hence, a ray-to-ray chordal distance is proposed as an alternative way of measuring the discrepancy between M and WH. This measure is related to the Euclidean distance on the unit sphere, motivating us to employ nonsmooth manifold optimization approaches.
We apply Riemannian optimization technique to solve chordal-NMF by casting it on a manifold. Unlike existing works on Riemannian optimization that require the manifold to be smooth, the nonnegativity in chordal-NMF is a non-differentiable manifold. We propose a Riemannian Multiplicative Update (RMU) that preserves the convergence properties of Riemannian gradient descent without breaking the smoothness condition on the manifold.
We showcase the effectiveness of the Chordal-NMF on synthetic datasets as well as real-world multispectral images.
Esposito, Flavia
8dc4f35b-400e-4260-82ae-4cd8fbe2e680
Ang, Andersen
ed509ecd-39a3-4887-a709-339fdaded867
23 May 2024
Esposito, Flavia
8dc4f35b-400e-4260-82ae-4cd8fbe2e680
Ang, Andersen
ed509ecd-39a3-4887-a709-339fdaded867
[Unknown type: UNSPECIFIED]
Abstract
Nonnegative Matrix Factorization (NMF) is the problem of approximating a given nonnegative matrix M through the conic combination of two nonnegative low-rank matrices W and H. Traditionally NMF is tackled by optimizing a specific objective function evaluating the quality of the approximation. This assessment is often done based on the Frobenius norm. In this study, we argue that the Frobenius norm as the "point-to-point" distance may not always be appropriate. Due to the nonnegative combination resulting in a polyhedral cone, this conic perspective of NMF may not naturally align with conventional point-to-point distance measures. Hence, a ray-to-ray chordal distance is proposed as an alternative way of measuring the discrepancy between M and WH. This measure is related to the Euclidean distance on the unit sphere, motivating us to employ nonsmooth manifold optimization approaches.
We apply Riemannian optimization technique to solve chordal-NMF by casting it on a manifold. Unlike existing works on Riemannian optimization that require the manifold to be smooth, the nonnegativity in chordal-NMF is a non-differentiable manifold. We propose a Riemannian Multiplicative Update (RMU) that preserves the convergence properties of Riemannian gradient descent without breaking the smoothness condition on the manifold.
We showcase the effectiveness of the Chordal-NMF on synthetic datasets as well as real-world multispectral images.
Text
2405.12823v2
- Author's Original
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Published date: 23 May 2024
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Local EPrints ID: 491060
URI: http://eprints.soton.ac.uk/id/eprint/491060
PURE UUID: 94fcc0a6-5042-4aed-aa78-723fb81b06c9
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Date deposited: 11 Jun 2024 16:50
Last modified: 12 Jun 2024 02:08
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Author:
Flavia Esposito
Author:
Andersen Ang
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