Robust Robotic Exploration and Mapping Using Generative Occupancy Map Synthesis
- URL: http://arxiv.org/abs/2506.20049v1
- Date: Tue, 24 Jun 2025 23:13:44 GMT
- Title: Robust Robotic Exploration and Mapping Using Generative Occupancy Map Synthesis
- Authors: Lorin Achey, Alec Reed, Brendan Crowe, Bradley Hayes, Christoffer Heckman,
- Abstract summary: We introduce SceneSense, a diffusion model designed and trained for predicting 3D occupancy maps.<n>Our proposed approach fuses these predictions into a running occupancy map in real-time, resulting in significant improvements in map quality and traversability.
- Score: 3.7014661122784025
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: We present a novel approach for enhancing robotic exploration by using generative occupancy mapping. We introduce SceneSense, a diffusion model designed and trained for predicting 3D occupancy maps given partial observations. Our proposed approach probabilistically fuses these predictions into a running occupancy map in real-time, resulting in significant improvements in map quality and traversability. We implement SceneSense onboard a quadruped robot and validate its performance with real-world experiments to demonstrate the effectiveness of the model. In these experiments, we show that occupancy maps enhanced with SceneSense predictions better represent our fully observed ground truth data (24.44% FID improvement around the robot and 75.59% improvement at range). We additionally show that integrating SceneSense-enhanced maps into our robotic exploration stack as a "drop-in" map improvement, utilizing an existing off-the-shelf planner, results in improvements in robustness and traversability time. Finally we show results of full exploration evaluations with our proposed system in two dissimilar environments and find that locally enhanced maps provide more consistent exploration results than maps constructed only from direct sensor measurements.
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