Data Fusion for Multipath-Based SLAM: Combining Information From Multiple Propagation Paths

Multipath-based simultaneous localization and mapping (SLAM) is an emerging paradigm for accurate indoor localization constrained by limited navigation resources. The goal of multipath-based SLAM is to support the estimation of time-varying positions of mobile agents by detecting and localizing radio-reflective surfaces in the environment. In existing Bayesian methods, a propagation surface is represented by the mirror image of each physical anchor (PA) across that surface - known as the corresponding virtual anchor (VA). Due to this VAs representation, each propagation path is mapped individually. Existing methods thus ignore inherent geometrical constraints across different paths that interact with the same surface, which limits accuracy and speed. In this paper, we introduce an improved statistical model and estimation method that enables data fusion in multipath-based SLAM. By directly representing each surface with a MVA, geometrical constraints across propagation paths are also modeled statistically. A key aspect of the proposed method based on MVAs is to check the availability of single-bounce and double-bounce propagation paths at potential agent positions by means of ray-tracing (RT). This availability check is directly integrated into the statistical model as detection probabilities for propagation paths. Estimation is performed by a sum-product algorithm (SPA) derived based on the factor graph that represents the new statistical model. Numerical results based on simulated and real data demonstrate significant improvements in estimation accuracy compared to state-of-the-art multipath-based SLAM methods.

Automated summary

Multipath-based SLAM is an emerging paradigm for accurate indoor localization. Existing methods have limitations in accuracy and speed due to ignoring geometric constraints between different paths. This paper introduces an improved statistical model and estimation method that utilize multiple virtual anchors (MVA) for statistical modeling and ray-tracing (RT) for checking path availability, resulting in significant improvements in estimation accuracy.