Differentiable Physics-Driven Human Representation for Millimeter-Wave Based Pose Estimation

While millimeter-wave (mmWave) presents advantages for Human Pose Estimation (HPE) through its non-intrusive sensing capabilities, current mmWave-based HPE methods face limitations in two predominant input paradigms: Heatmap and Point Cloud (PC). Heatmap represents dense multi-dimensional features derived from mmWave, but is significantly affected by multipath propagation and hardware modulation noise. PC, a set of 3D points, is obtained by applying the Constant False Alarm Rate algorithm to the Heatmap, which suppresses noise but results in sparse human-related features. To address these limitations, we study the feasibility of providing an alternative input paradigm: Differentiable Physics-driven Human Representation (DIPR), which represents humans as an ensemble of Gaussian distributions with kinematic and electromagnetic parameters. Inspired by Gaussian Splatting, DIPR leverages human kinematic priors and mmWave propagation physics to enhance human features while mitigating non-human noise through two strategies: 1) We incorporate prior kinematic knowledge to initialize DIPR based on the Heatmap and establish multi-faceted optimization objectives, ensuring biomechanical validity and enhancing motion features. 2) We simulate complete mmWave processing pipelines, re-render a new Heatmap from DIPR, and compare it with the original Heatmap, avoiding spurious noise generation due to kinematic constraints overfitting. Experimental results on three datasets with four methods demonstrate that existing mmWave-based HPE methods can easily integrate DIPR and achieve superior performance.