Adaptive vs. Static Robot-to-Human Handover: A Study on Orientation and Approach Direction
Federico Biagi, Dario Onfiani, Simone Silenzi, Cristina Iani, Luigi Biagiotti
TLDR
A new adaptive framework dynamically adjusts robot handover poses based on human hand pose and task, reducing user workload and stress.
Key contributions
- Novel adaptive framework dynamically adjusts object delivery pose based on human hand pose and intended task.
- Integrates AI-based hand pose estimation with smooth, kinematically constrained trajectories for safe approaches.
- User study compares adaptive vs. static handovers, using NASA-TLX, Trust Scale, and physiological blink rate.
- Adaptive approach significantly reduces user cognitive workload, physiological stress, and increases trust.
Why it matters
This paper introduces a significant advancement in human-robot interaction by making robot handovers truly adaptive to human needs. By reducing user burden and increasing trust, it paves the way for more natural and efficient collaboration in various real-world applications.
Original Abstract
Robot-to-human handovers often rely on static, open-loop strategies (or, at best, approaches that adapt only the position), which generally do not consider how the object will be grasped by the human, thus requiring the user to adapt. This work presents a novel adaptive framework that dynamically adjusts the object's delivery pose in real time based on the user's hand pose and the intended downstream task. By integrating AI-based hand pose estimation with smooth, kinematically constrained trajectories, the system ensures a safe approach and an optimal handover orientation. A comprehensive user study compares the proposed adaptive approach against a static baseline across multiple tasks, evaluating both subjective metrics (NASA-TLX, Human-Robot Trust Scale) and objective physiological data (blink rate measured via wearable eye-trackers). The results demonstrate that dynamic alignment significantly reduces users' cognitive workload and physiological stress, while increasing perceived trust in the robot's reliability. These findings highlight the potential of task- and pose-aware systems for enabling fluid and ergonomic human-robot collaboration.
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