Transferrable Operative Difficulty Assessment in Robot-assisted Teleoperation: A Domain Adaptation Approach
Ziheng Wang, Cong Feng, Jie Zhang, Ann Majewicz Fey

TL;DR
This paper introduces a domain adaptation method that uses physiological and kinematic data to assess operative difficulty in robot teleoperation, enabling task-independent difficulty evaluation and interface design.
Contribution
It presents a novel unsupervised domain adaptation approach that generalizes difficulty assessment from simple to complex teleoperation tasks using user data.
Findings
Achieved 96.6% accuracy in predicting task difficulty in a Fitts' task.
Validated model effectiveness in robotic needle steering case study.
Detected significant difficulty differences across control algorithms and targets.
Abstract
Providing an accurate and efficient assessment of operative difficulty is important for designing robot-assisted teleoperation interfaces that are easy and natural for human operators to use. In this paper, we aim to develop a data-driven approach to numerically characterize the operative difficulty demand of complex teleoperation. In effort to provide an entirely task-independent assessment, we consider using only data collected from the human user including: (1) physiological response, and (2) movement kinematics. By leveraging an unsupervised domain adaptation technique, our approach learns the user information that defines task difficulty in a well-known source, namely, a Fitt's target reaching task, and generalizes that knowledge to a more complex human motor control scenario, namely, the teleoperation of a robotic system. Our approach consists of two main parts: (1) The first part…
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Taxonomy
TopicsSurgical Simulation and Training · Teleoperation and Haptic Systems · Virtual Reality Applications and Impacts
