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Autori principali: Enzner, Gerald, Knaepper, Niklas, Chinaev, Aleksej
Natura: Preprint
Pubblicazione: 2025
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Accesso online:https://arxiv.org/abs/2507.03109
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author Enzner, Gerald
Knaepper, Niklas
Chinaev, Aleksej
author_facet Enzner, Gerald
Knaepper, Niklas
Chinaev, Aleksej
contents Inband full-duplex communication requires accurate modeling and cancellation of self-interference, specifically in the digital domain. Neural networks are presently candidate models for capturing nonlinearity of the self-interference path. This work utilizes synthetic and real data from different sources to evaluate and cross-compare performances of previously proposed neural self-interference models from different sources. The relevance of the analysis consists in the mutual assessment of methods on data they were not specifically designed for. We find that our previously proposed Hammerstein model represents the range of data sets well, while being significantly smaller in terms of the number of parameters. A new Wiener-Hammerstein model further enhances the generalization performance.
format Preprint
id arxiv_https___arxiv_org_abs_2507_03109
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Cross-Comparison of Neural Architectures and Data Sets for Digital Self-Interference Modeling
Enzner, Gerald
Knaepper, Niklas
Chinaev, Aleksej
Signal Processing
Inband full-duplex communication requires accurate modeling and cancellation of self-interference, specifically in the digital domain. Neural networks are presently candidate models for capturing nonlinearity of the self-interference path. This work utilizes synthetic and real data from different sources to evaluate and cross-compare performances of previously proposed neural self-interference models from different sources. The relevance of the analysis consists in the mutual assessment of methods on data they were not specifically designed for. We find that our previously proposed Hammerstein model represents the range of data sets well, while being significantly smaller in terms of the number of parameters. A new Wiener-Hammerstein model further enhances the generalization performance.
title Cross-Comparison of Neural Architectures and Data Sets for Digital Self-Interference Modeling
topic Signal Processing
url https://arxiv.org/abs/2507.03109