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Hauptverfasser: Zheng, Xufei, Xiao, Han, Jin, Shi, Wang, Zhiqin, Tian, Wenqiang, Liu, Wendong, Cao, Jianfei, Shen, Jia, Shi, Zhihua, Zhang, Zhi, Yang, Ning
Format: Preprint
Veröffentlicht: 2026
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Online-Zugang:https://arxiv.org/abs/2601.02827
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author Zheng, Xufei
Xiao, Han
Jin, Shi
Wang, Zhiqin
Tian, Wenqiang
Liu, Wendong
Cao, Jianfei
Shen, Jia
Shi, Zhihua
Zhang, Zhi
Yang, Ning
author_facet Zheng, Xufei
Xiao, Han
Jin, Shi
Wang, Zhiqin
Tian, Wenqiang
Liu, Wendong
Cao, Jianfei
Shen, Jia
Shi, Zhihua
Zhang, Zhi
Yang, Ning
contents In this article, a framework of AI-native cross-module optimized physical layer with cooperative control agents is proposed, which involves optimization across global AI/ML modules of the physical layer with innovative design of multiple enhancement mechanisms and control strategies. Specifically, it achieves simultaneous optimization across global modules of uplink AI/ML-based joint source-channel coding with modulation, and downlink AI/ML-based modulation with precoding and corresponding data detection, reducing traditional inter-module information barriers to facilitate end-to-end optimization toward global objectives. Moreover, multiple enhancement mechanisms are also proposed, including i) an AI/ML-based cross-layer modulation approach with theoretical analysis for downlink transmission that breaks the isolation of inter-layer features to expand the solution space for determining improved constellation, ii) a utility-oriented precoder construction method that shifts the role of the AI/ML-based CSI feedback decoder from recovering the original CSI to directly generating precoding matrices aiming to improve end-to-end performance, and iii) incorporating modulation into AI/ML-based CSI feedback to bypass bit-level bottlenecks that introduce quantization errors, non-differentiable gradients, and limitations in constellation solution spaces. Furthermore, AI/ML based control agents for optimized transmission schemes are proposed that leverage AI/ML to perform model switching according to channel state, thereby enabling integrated control for global throughput optimization. Finally, simulation results demonstrate the superiority of the proposed solutions in terms of BLER and throughput. These extensive simulations employ more practical assumptions that are aligned with the requirements of the 3GPP, which hopefully provides valuable insights for future standardization discussions.
format Preprint
id arxiv_https___arxiv_org_abs_2601_02827
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle AI-Native 6G Physical Layer with Cross-Module Optimization and Cooperative Control Agents
Zheng, Xufei
Xiao, Han
Jin, Shi
Wang, Zhiqin
Tian, Wenqiang
Liu, Wendong
Cao, Jianfei
Shen, Jia
Shi, Zhihua
Zhang, Zhi
Yang, Ning
Signal Processing
In this article, a framework of AI-native cross-module optimized physical layer with cooperative control agents is proposed, which involves optimization across global AI/ML modules of the physical layer with innovative design of multiple enhancement mechanisms and control strategies. Specifically, it achieves simultaneous optimization across global modules of uplink AI/ML-based joint source-channel coding with modulation, and downlink AI/ML-based modulation with precoding and corresponding data detection, reducing traditional inter-module information barriers to facilitate end-to-end optimization toward global objectives. Moreover, multiple enhancement mechanisms are also proposed, including i) an AI/ML-based cross-layer modulation approach with theoretical analysis for downlink transmission that breaks the isolation of inter-layer features to expand the solution space for determining improved constellation, ii) a utility-oriented precoder construction method that shifts the role of the AI/ML-based CSI feedback decoder from recovering the original CSI to directly generating precoding matrices aiming to improve end-to-end performance, and iii) incorporating modulation into AI/ML-based CSI feedback to bypass bit-level bottlenecks that introduce quantization errors, non-differentiable gradients, and limitations in constellation solution spaces. Furthermore, AI/ML based control agents for optimized transmission schemes are proposed that leverage AI/ML to perform model switching according to channel state, thereby enabling integrated control for global throughput optimization. Finally, simulation results demonstrate the superiority of the proposed solutions in terms of BLER and throughput. These extensive simulations employ more practical assumptions that are aligned with the requirements of the 3GPP, which hopefully provides valuable insights for future standardization discussions.
title AI-Native 6G Physical Layer with Cross-Module Optimization and Cooperative Control Agents
topic Signal Processing
url https://arxiv.org/abs/2601.02827