Spatial Attention: Adapting Execution Horizons for Diffusion Policies via Observation Sensitivity
2026-07-06 • Robotics
Robotics
AI summaryⓘ
The authors studied how robots follow learned actions by breaking them into chunks. Instead of always running these chunks for a fixed time, they change the length based on how sensitive the robot's actions are to what it sees, a concept they call Spatial Attention. When the robot needs to react quickly because things are changing a lot, the chunks are shorter; when things are stable, the chunks are longer. This adaptive approach helps robots succeed more often without taking more time overall, tested in both simulations and with a real robot.
robot learning from demonstrationaction chunkexecution horizonspatial attentionpolicy sensitivitygradient of log-likelihoodadaptive controlrobotic manipulationgenerative modelscomputational efficiency
Authors
Che-Sang Park, Junsu Ha, Jianlong Fu, Frank C. Park
Abstract
Sampling action chunks via generative models has become a widely adopted methodology for robotic learning from demonstration. However, existing methods often struggle to balance responsiveness and computational cost because they execute each action chunk for a fixed execution horizon. In this paper, we adaptively adjust the execution horizon of sampled action chunks, balancing responsiveness and computational efficiency. We introduce Spatial Attention -- defined as the expected squared norm of the gradient of the action log-likelihood with respect to the observation -- which indicates the sensitivity of the policy's action distribution to variations in the observation. We show that, under a fixed budget of chunk samplings, the execution horizon that minimizes the cumulative likelihood drop induced by disturbances decreases as Spatial Attention increases. By forecasting future Spatial Attention values alongside the action chunk, our framework dynamically assigns shorter execution horizons to phases with high Spatial Attention, and longer horizons to phases with low Spatial Attention. Experiments on standard and perturbed tasks, in both simulation and on a real robot, show that our method significantly improves success rates over fixed-horizon baselines while maintaining the average execution horizon.