Deep Unfolded Variable Projection Networks

Gergö Bognar; Manuel Feindert; Christian Huber; Michael Lunglmayr; Mario Huemer; Peter Kovacs

doi:10.1142/S0129065725500534

Deep Unfolded Variable Projection Networks

Gergö Bognar^*
, Manuel Feindert^*
, Christian Huber
, Michael Lunglmayr
, Mario Huemer
, Peter Kovacs

^*Corresponding author for this work

Institute of Signal Processing

Research output: Contribution to journal › Article › peer-review

Abstract

In this paper, we present a hybrid learning framework that integrates two model-driven AI paradigms: Deep unfolding and Variable Projections (VPs). The core idea is to unfold the iterations of VP solvers for separable nonlinear least squares (SNLLS) problems into trainable neural network layers. As a consequence, the network is capable of learning optimal nonlinear VP parameters during inference, which is a form of model-based meta-learning. Furthermore, the architecture incorporates prior knowledge of the underlying SNLLS problem, such as basis function expansions and signal structure, which enhance interpretability, reduce model size, and lower data requirements. As a case study, we adapt the proposed deep unfolded VPNet to learn ECG representations for the classification of five arrhythmias. Experimental results on the MIT-BIH Arrhythmia Database show that VPNet achieves performance comparable to state-of-the-art ECG classifiers, attaining 95% accuracy while maintaining a compact architecture. Its low computational complexity enables efficient training and inference, making it highly suitable for real-time, power-efficient edge computing applications. This is further validated through embedded implementation on STM32 microcontrollers.

Original language	English
Article number	2550053
Pages (from-to)	1
Number of pages	18
Journal	International Journal of Neural Systems
Issue number	13
DOIs	https://doi.org/10.1142/S0129065725500534
Publication status	Published - 27 Aug 2025

Fields of science

202017 Embedded systems
202015 Electronics
102019 Machine learning
202 Electrical Engineering, Electronics, Information Engineering
202041 Computer engineering
202037 Signal processing
202022 Information technology

JKU Focus areas

Digital Transformation

Access to Document

10.1142/S0129065725500534

Cite this

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title = "Deep Unfolded Variable Projection Networks",

abstract = "In this paper, we present a hybrid learning framework that integrates two model-driven AI paradigms: Deep unfolding and Variable Projections (VPs). The core idea is to unfold the iterations of VP solvers for separable nonlinear least squares (SNLLS) problems into trainable neural network layers. As a consequence, the network is capable of learning optimal nonlinear VP parameters during inference, which is a form of model-based meta-learning. Furthermore, the architecture incorporates prior knowledge of the underlying SNLLS problem, such as basis function expansions and signal structure, which enhance interpretability, reduce model size, and lower data requirements. As a case study, we adapt the proposed deep unfolded VPNet to learn ECG representations for the classification of five arrhythmias. Experimental results on the MIT-BIH Arrhythmia Database show that VPNet achieves performance comparable to state-of-the-art ECG classifiers, attaining 95\% accuracy while maintaining a compact architecture. Its low computational complexity enables efficient training and inference, making it highly suitable for real-time, power-efficient edge computing applications. This is further validated through embedded implementation on STM32 microcontrollers.",

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year = "2025",

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AU - Bognar, Gergö

AU - Feindert, Manuel

AU - Huber, Christian

AU - Lunglmayr, Michael

AU - Huemer, Mario

AU - Kovacs, Peter

PY - 2025/8/27

Y1 - 2025/8/27

N2 - In this paper, we present a hybrid learning framework that integrates two model-driven AI paradigms: Deep unfolding and Variable Projections (VPs). The core idea is to unfold the iterations of VP solvers for separable nonlinear least squares (SNLLS) problems into trainable neural network layers. As a consequence, the network is capable of learning optimal nonlinear VP parameters during inference, which is a form of model-based meta-learning. Furthermore, the architecture incorporates prior knowledge of the underlying SNLLS problem, such as basis function expansions and signal structure, which enhance interpretability, reduce model size, and lower data requirements. As a case study, we adapt the proposed deep unfolded VPNet to learn ECG representations for the classification of five arrhythmias. Experimental results on the MIT-BIH Arrhythmia Database show that VPNet achieves performance comparable to state-of-the-art ECG classifiers, attaining 95% accuracy while maintaining a compact architecture. Its low computational complexity enables efficient training and inference, making it highly suitable for real-time, power-efficient edge computing applications. This is further validated through embedded implementation on STM32 microcontrollers.

AB - In this paper, we present a hybrid learning framework that integrates two model-driven AI paradigms: Deep unfolding and Variable Projections (VPs). The core idea is to unfold the iterations of VP solvers for separable nonlinear least squares (SNLLS) problems into trainable neural network layers. As a consequence, the network is capable of learning optimal nonlinear VP parameters during inference, which is a form of model-based meta-learning. Furthermore, the architecture incorporates prior knowledge of the underlying SNLLS problem, such as basis function expansions and signal structure, which enhance interpretability, reduce model size, and lower data requirements. As a case study, we adapt the proposed deep unfolded VPNet to learn ECG representations for the classification of five arrhythmias. Experimental results on the MIT-BIH Arrhythmia Database show that VPNet achieves performance comparable to state-of-the-art ECG classifiers, attaining 95% accuracy while maintaining a compact architecture. Its low computational complexity enables efficient training and inference, making it highly suitable for real-time, power-efficient edge computing applications. This is further validated through embedded implementation on STM32 microcontrollers.

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Deep Unfolded Variable Projection Networks

Abstract

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LCM - Center for Symbiotic Mechatronics - Förderphase 2

Cite this

Deep Unfolded Variable Projection Networks

Abstract

Fields of science

JKU Focus areas

Access to Document

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LCM - Center for Symbiotic Mechatronics - Förderphase 2

Cite this