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arxiv: 2406.07767 · v2 · pith:U5SJQAPD · submitted 2024-06-11 · cs.RO · cs.LG

Conformalized Teleoperation: Confidently Mapping Human Inputs to High-Dimensional Robot Actions

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classification cs.RO cs.LG
keywords mappingassistivehigh-dimensionalinputsuncertaintyhumanlow-dimensionalrobot
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Assistive robotic arms often have more degrees-of-freedom than a human teleoperator can control with a low-dimensional input, like a joystick. To overcome this challenge, existing approaches use data-driven methods to learn a mapping from low-dimensional human inputs to high-dimensional robot actions. However, determining if such a black-box mapping can confidently infer a user's intended high-dimensional action from low-dimensional inputs remains an open problem. Our key idea is to adapt the assistive map at training time to additionally estimate high-dimensional action quantiles, and then calibrate these quantiles via rigorous uncertainty quantification methods. Specifically, we leverage adaptive conformal prediction which adjusts the intervals over time, reducing the uncertainty bounds when the mapping is performant and increasing the bounds when the mapping consistently mis-predicts. Furthermore, we propose an uncertainty-interval-based mechanism for detecting high-uncertainty user inputs and robot states. We evaluate the efficacy of our proposed approach in a 2D assistive navigation task and two 7DOF Kinova Jaco tasks involving assistive cup grasping and goal reaching. Our findings demonstrate that conformalized assistive teleoperation manages to detect (but not differentiate between) high uncertainty induced by diverse preferences and induced by low-precision trajectories in the mapping's training dataset. On the whole, we see this work as a key step towards enabling robots to quantify their own uncertainty and proactively seek intervention when needed.

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Cited by 3 Pith papers

Reviewed papers in the Pith corpus that reference this work. Sorted by Pith novelty score.

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    cs.AI 2025-11 unverdicted novelty 6.0

    QuickLAP fuses language and physical feedback in a Bayesian update to learn reward functions in real time for semi-autonomous systems, reducing error by over 70% versus physical-only and heuristic baselines.

  2. QuickLAP: Quick Language-Action Preference Learning for Semi-Autonomous Agents

    cs.AI 2025-11 unverdicted novelty 6.0

    QuickLAP fuses LLM-extracted language observations with physical feedback in a closed-form Bayesian update to cut reward learning error by over 70% in a driving simulator and improve user preference in a 15-person study.

  3. Adaptor: Advancing Assistive Teleoperation with Few-Shot Learning and Cross-Operator Generalization

    cs.RO 2026-04 unverdicted novelty 5.0

    Adaptor uses few-shot learning with trajectory perturbation and vision-language conditioning to achieve robust cross-operator intent recognition and higher success rates in assistive teleoperation.