BiSplat-WRF applies 2D planar Gaussians rendered on angular domains plus a bilinear spatial transformer to capture electromagnetic interactions, outperforming prior NeRF and GS methods on SSIM for wireless radiance field reconstruction.
Neural representation for wireless radiation field reconstruction: A 3D Gaussian splatting approach
3 Pith papers cite this work. Polarity classification is still indexing.
3
Pith papers citing it
years
2026 3verdicts
UNVERDICTED 3representative citing papers
RFIR framework embeds RF-aware BSDF into Gaussian splatting for decoupled RF scene modeling, generalizing RCS synthesis, RSSI prediction, and wireless scene editability with performance gains.
URF-GS creates a single radiation field from visual and wireless observations via 3D Gaussian splatting to predict radio signals at any location and configuration with higher accuracy and fewer samples than prior NeRF approaches.
citing papers explorer
-
Planar Gaussian Splatting with Bilinear Spatial Transformer for Wireless Radiance Field Reconstruction
BiSplat-WRF applies 2D planar Gaussians rendered on angular domains plus a bilinear spatial transformer to capture electromagnetic interactions, outperforming prior NeRF and GS methods on SSIM for wireless radiance field reconstruction.
-
Radio-Frequency Inverse Rendering for Wireless Environment Modeling
RFIR framework embeds RF-aware BSDF into Gaussian splatting for decoupled RF scene modeling, generalizing RCS synthesis, RSSI prediction, and wireless scene editability with performance gains.
-
Bridging Visual and Wireless Sensing via a Unified Radiation Field for 3D Radio Map Construction
URF-GS creates a single radiation field from visual and wireless observations via 3D Gaussian splatting to predict radio signals at any location and configuration with higher accuracy and fewer samples than prior NeRF approaches.