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Main Authors: Elfiky, Abdelrahman, Rezki, Zouheir, Cortez, Jorge, Boumhaout, Youssef, Xia, Anne, Celik, Abdulkadir, Kaddoum, Georges
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2603.12289
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author Elfiky, Abdelrahman
Rezki, Zouheir
Cortez, Jorge
Boumhaout, Youssef
Xia, Anne
Celik, Abdulkadir
Kaddoum, Georges
author_facet Elfiky, Abdelrahman
Rezki, Zouheir
Cortez, Jorge
Boumhaout, Youssef
Xia, Anne
Celik, Abdulkadir
Kaddoum, Georges
contents The physical layer (PHY) in wireless communication systems has traditionally relied on model-based methods that are often optimized individually as independent blocks to perform tasks such as modulation, coding, and channel estimation. However, these approaches face challenges when it comes to capturing real-world nonlinearities, hardware imperfections, and increasing complexity in modern networks. This paper surveys advancements in applying deep learning (DL) for end-to-end PHY optimization by incorporating the autoencoder (AE) model as a powerful end-to-end DL framework to enable joint transmitter and receiver optimization and address challenges like dynamic channel conditions and scalability. We review cutting-edge DL models; their applications in PHY tasks such as modulation, error correction, and channel estimation; and their deployment in real-world scenarios, including point-to-point communication, multiple access, and interference channels. This work highlights the benefits of learning-based approaches over traditional methods, offering a comprehensive resource for researchers and engineers looking to innovate in next-generation wireless systems. Key insights and future directions are discussed to bridge the gap between theory and practical implementation.
format Preprint
id arxiv_https___arxiv_org_abs_2603_12289
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle End-to-End Deep Learning in Wireless Communication Systems: A Tutorial Review
Elfiky, Abdelrahman
Rezki, Zouheir
Cortez, Jorge
Boumhaout, Youssef
Xia, Anne
Celik, Abdulkadir
Kaddoum, Georges
Information Theory
The physical layer (PHY) in wireless communication systems has traditionally relied on model-based methods that are often optimized individually as independent blocks to perform tasks such as modulation, coding, and channel estimation. However, these approaches face challenges when it comes to capturing real-world nonlinearities, hardware imperfections, and increasing complexity in modern networks. This paper surveys advancements in applying deep learning (DL) for end-to-end PHY optimization by incorporating the autoencoder (AE) model as a powerful end-to-end DL framework to enable joint transmitter and receiver optimization and address challenges like dynamic channel conditions and scalability. We review cutting-edge DL models; their applications in PHY tasks such as modulation, error correction, and channel estimation; and their deployment in real-world scenarios, including point-to-point communication, multiple access, and interference channels. This work highlights the benefits of learning-based approaches over traditional methods, offering a comprehensive resource for researchers and engineers looking to innovate in next-generation wireless systems. Key insights and future directions are discussed to bridge the gap between theory and practical implementation.
title End-to-End Deep Learning in Wireless Communication Systems: A Tutorial Review
topic Information Theory
url https://arxiv.org/abs/2603.12289