Fast Monte-Carlo Localization on Aerial Vehicles using Approximate Continuous Belief Representations
This addresses localization challenges for resource-constrained aerial vehicles, presenting an incremental improvement over existing methods.
The paper tackles the problem of fast localization on size, weight, and power constrained aerial vehicles by using Gaussian Mixture Model representations and a particle filter, achieving real-time performance that outperforms a state-of-the-art algorithm on desktop and embedded platforms.
Size, weight, and power constrained platforms impose constraints on computational resources that introduce unique challenges in implementing localization algorithms. We present a framework to perform fast localization on such platforms enabled by the compressive capabilities of Gaussian Mixture Model representations of point cloud data. Given raw structural data from a depth sensor and pitch and roll estimates from an on-board attitude reference system, a multi-hypothesis particle filter localizes the vehicle by exploiting the likelihood of the data originating from the mixture model. We demonstrate analysis of this likelihood in the vicinity of the ground truth pose and detail its utilization in a particle filter-based vehicle localization strategy, and later present results of real-time implementations on a desktop system and an off-the-shelf embedded platform that outperform localization results from running a state-of-the-art algorithm on the same environment.