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Main Authors: Li, Qiang, Yu, Shujian, Ma, Liang, Ma, Chen, Liu, Jingyu, Adali, Tulay, Calhoun, Vince D.
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2601.00904
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author Li, Qiang
Yu, Shujian
Ma, Liang
Ma, Chen
Liu, Jingyu
Adali, Tulay
Calhoun, Vince D.
author_facet Li, Qiang
Yu, Shujian
Ma, Liang
Ma, Chen
Liu, Jingyu
Adali, Tulay
Calhoun, Vince D.
contents Blind source separation, particularly through independent component analysis (ICA), is widely utilized across various signal processing domains for disentangling underlying components from observed mixed signals, owing to its fully data-driven nature that minimizes reliance on prior assumptions. However, conventional ICA methods rely on an assumption of linear mixing, limiting their ability to capture complex nonlinear relationships and to maintain robustness in noisy environments. In this work, we present deep deterministic nonlinear independent component analysis (DDICA), a novel deep neural network-based framework designed to address these limitations. DDICA leverages a matrix-based entropy function to directly optimize the independence criterion via stochastic gradient descent, bypassing the need for variational approximations or adversarial schemes. This results in a streamlined training process and improved resilience to noise. We validated the effectiveness and generalizability of DDICA across a range of applications, including simulated signal mixtures, hyperspectral image unmixing, modeling of primary visual receptive fields, and resting-state functional magnetic resonance imaging (fMRI) data analysis. Experimental results demonstrate that DDICA effectively separates independent components with high accuracy across a range of applications. These findings suggest that DDICA offers a robust and versatile solution for blind source separation in diverse signal processing tasks.
format Preprint
id arxiv_https___arxiv_org_abs_2601_00904
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Deep Deterministic Nonlinear ICA via Total Correlation Minimization with Matrix-Based Entropy Functional
Li, Qiang
Yu, Shujian
Ma, Liang
Ma, Chen
Liu, Jingyu
Adali, Tulay
Calhoun, Vince D.
Methodology
Machine Learning
Blind source separation, particularly through independent component analysis (ICA), is widely utilized across various signal processing domains for disentangling underlying components from observed mixed signals, owing to its fully data-driven nature that minimizes reliance on prior assumptions. However, conventional ICA methods rely on an assumption of linear mixing, limiting their ability to capture complex nonlinear relationships and to maintain robustness in noisy environments. In this work, we present deep deterministic nonlinear independent component analysis (DDICA), a novel deep neural network-based framework designed to address these limitations. DDICA leverages a matrix-based entropy function to directly optimize the independence criterion via stochastic gradient descent, bypassing the need for variational approximations or adversarial schemes. This results in a streamlined training process and improved resilience to noise. We validated the effectiveness and generalizability of DDICA across a range of applications, including simulated signal mixtures, hyperspectral image unmixing, modeling of primary visual receptive fields, and resting-state functional magnetic resonance imaging (fMRI) data analysis. Experimental results demonstrate that DDICA effectively separates independent components with high accuracy across a range of applications. These findings suggest that DDICA offers a robust and versatile solution for blind source separation in diverse signal processing tasks.
title Deep Deterministic Nonlinear ICA via Total Correlation Minimization with Matrix-Based Entropy Functional
topic Methodology
Machine Learning
url https://arxiv.org/abs/2601.00904