Online Informative Path Planning for Active Information Gathering of a 3D Surface

This paper presents an online informative path planning approach for active information gathering on three-dimensional surfaces using aerial robots. Most existing works on surface inspection focus on planning a path offline that can provide full coverage of the surface, which inherently assumes the surface information is uniformly distributed hence ignoring potential spatial correlations of the information field. In this paper, we utilize manifold Gaussian processes (mGPs) with geodesic kernel functions for mapping surface information fields and plan informative paths online in a receding horizon manner. Our approach actively plans information-gathering paths based on recent observations that respect dynamic constraints of the vehicle and a total flight time budget. We provide planning results for simulated temperature modeling for simple and complex 3D surface geometries (a cylinder and an aircraft model). We demonstrate that our informative planning method outperforms traditional approaches such as 3D coverage planning and random exploration, both in reconstruction error and information-theoretic metrics. We also show that by taking spatial correlations of the information field into planning using mGPs, the information gathering efficiency is significantly improved.

Automated summary

This paper introduces an online informative path planning approach for active information gathering on three-dimensional surfaces using manifold Gaussian processes with geodesic kernel functions. The method plans information-gathering paths based on recent observations, respecting dynamic vehicle constraints and a total flight time budget. Results demonstrate that this approach outperforms traditional methods in reconstruction error and information-theoretic metrics, showing significant improvement in information gathering efficiency by taking spatial correlations into account.