The Speedup Paradox: Rethinking Inference Speed-Quality Trade-off in Embodied Tasks

Published June 30, 2026 · Category: Robotics

Overview

arXiv:2606.28529v1 Announce Type: new Abstract: Embodied foundation models have recently been widely used to improve robot generalization and task success rates. Previous works apply lossy efficient-inference techniques such as quantization, pruning, and asynchronous inference, accepting small action quality degradation in exchange for lower per-step computation cost and inter-action latency. However, unlike traditional static ML tasks, embodied tasks involve repeated interaction with the environment, and task-level performance is determined not only by per-step cost, but also by closed-loop effects unique to embodied execution, which remain insufficiently characterized in current efficient-inference studies. In this work, we propose TISED (\underline{T}ask-level \underline{I}nference \underline{S}peedup \underline{E}ffect \underline{D}ecomposition), an analytical framework that unifies diverse lossy inference optimization techniques and decomposes their effects on static and dynamic tasks, and uncovers some paradoxical effects on task-level performance: (1) on \textit{static tasks}, optimization sometimes can lengthen end-to-end per-task completion time even as per-step latency drops; (2) on \textit{dynamic tasks}, moderate lossy optimization can raise task success rate even above the baseline; and (3) the monotonicity and sweet-spot location of both effects can shift with hardware configuration. Together, our findings provide a new perspective on adapting inference optimization techniques to embodied tasks.

Source

Originally published at arxiv.org.

Related Articles

• You Only Touch Once: 6-DoF Object Pose Estimation from Single Tactile Contact
• X-Morph: Human Motion Priors for Scalable Robot Learning Across Morphologies
• AsyncMDE: Real-Time Monocular Depth Estimation via Asynchronous Spatial Memory