PINN and GNN-based RF Map Construction for Wireless Communication Systems
arXiv:2507.22513v2 Announce Type: replace Abstract: Radio frequency (RF) map is a promising technique for capturing the characteristics of multipath signal propagation, offering critical support for channel modeling, coverage analysis, and beamforming in wireless communication networks. This paper proposes a novel RF map construction method based on a combination of physics-informed neural network (PINN) and graph neural network (GNN). The PINN incorporates physical constraints derived from electromagnetic propagation laws to guide the learning process, while the GNN models spatial correlations among receiver locations. By parameterizing multipath signals into received power, delay, and angle of arrival (AoA), and integrating both physical priors and spatial dependencies, the proposed meth
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Abstract:Radio frequency (RF) map is a promising technique for capturing the characteristics of multipath signal propagation, offering critical support for channel modeling, coverage analysis, and beamforming in wireless communication networks. This paper proposes a novel RF map construction method based on a combination of physics-informed neural network (PINN) and graph neural network (GNN). The PINN incorporates physical constraints derived from electromagnetic propagation laws to guide the learning process, while the GNN models spatial correlations among receiver locations. By parameterizing multipath signals into received power, delay, and angle of arrival (AoA), and integrating both physical priors and spatial dependencies, the proposed method achieves accurate prediction of multipath parameters. Experimental results demonstrate that the method enables high-precision RF map construction under sparse sampling conditions and delivers robust performance in both indoor and complex outdoor environments, outperforming baseline methods in terms of generalization and accuracy.
Subjects:
Signal Processing (eess.SP)
Cite as: arXiv:2507.22513 [eess.SP]
(or arXiv:2507.22513v2 [eess.SP] for this version)
https://doi.org/10.48550/arXiv.2507.22513
arXiv-issued DOI via DataCite
Submission history
From: Lizhou Liu [view email] [v1] Wed, 30 Jul 2025 09:34:54 UTC (5,132 KB) [v2] Sun, 29 Mar 2026 13:58:56 UTC (5,066 KB)
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Google strongly implies the existence of large Gemma 4 models
In the huggingface card: Increased Context Window – The small models feature a 128K context window, while the medium models support 256K. Small and medium... implying at least one large model! 124B confirmed :P submitted by /u/coder543 [link] [comments]
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