English

Map Space Belief Prediction for Manipulation-Enhanced Mapping

Robotics 2025-06-19 v3 Machine Learning

Abstract

Searching for objects in cluttered environments requires selecting efficient viewpoints and manipulation actions to remove occlusions and reduce uncertainty in object locations, shapes, and categories. In this work, we address the problem of manipulation-enhanced semantic mapping, where a robot has to efficiently identify all objects in a cluttered shelf. Although Partially Observable Markov Decision Processes~(POMDPs) are standard for decision-making under uncertainty, representing unstructured interactive worlds remains challenging in this formalism. To tackle this, we define a POMDP whose belief is summarized by a metric-semantic grid map and propose a novel framework that uses neural networks to perform map-space belief updates to reason efficiently and simultaneously about object geometries, locations, categories, occlusions, and manipulation physics. Further, to enable accurate information gain analysis, the learned belief updates should maintain calibrated estimates of uncertainty. Therefore, we propose Calibrated Neural-Accelerated Belief Updates (CNABUs) to learn a belief propagation model that generalizes to novel scenarios and provides confidence-calibrated predictions for unknown areas. Our experiments show that our novel POMDP planner improves map completeness and accuracy over existing methods in challenging simulations and successfully transfers to real-world cluttered shelves in zero-shot fashion.

Keywords

Cite

@article{arxiv.2502.20606,
  title  = {Map Space Belief Prediction for Manipulation-Enhanced Mapping},
  author = {Joao Marcos Correia Marques and Nils Dengler and Tobias Zaenker and Jesper Mucke and Shenlong Wang and Maren Bennewitz and Kris Hauser},
  journal= {arXiv preprint arXiv:2502.20606},
  year   = {2025}
}

Comments

14 pages, 10 figures; Published at RSS 2025 - this version contains a small fix to figure 6 which was missing a plot in the original submission

R2 v1 2026-06-28T22:01:00.294Z