Simulation of a Tilt-Rotor Uav with a Cable-Driven Gripper for High-Precision Physical Interaction

Simulation of a Tilt-Rotor Uav with a Cable-Driven Gripper for High-Precision Physical Interaction

2025 International Conference on Unmanned Aircraft Systems (ICUAS)

10.1109/ICUAS65942.2025.11007871

https://doi.org/10.1109/icuas65942.2025.11007871

Yun Ting Chen, Joshua Taylor, Nursultan Imanberdiyev, Efe Camci

Physical Interaction , Positive Control , Control Strategy , Simulation Software , Unmanned Aerial Vehicles , Force Control , Interaction Task , Vertical Surface , Elastic Component , Absolute Difference , Centroid , Target Object , Target Surface , Pitch Angle , Physical Experiments , Control Architecture , Yaw Angle , Easy Integration , Soft Constraints , Forward Motion , Finger Joints , Robot Operating System , Advanced Control Strategies , Inertia Values , Force Error , Correct Force , Real Vehicle , Body Frame , Physics Engine

27 May 2025

Chen, Y. T., Taylor, J., Imanberdiyev, N., & Camci, E. (2025). Simulation of a Tilt-Rotor Uav with a Cable-Driven Gripper for High-Precision Physical Interaction. 2025 International Conference on Unmanned Aircraft Systems (ICUAS), 332–339. https://doi.org/10.1109/icuas65942.2025.11007871

Performing tasks at high altitudes can be inconvenient and unsafe for humans. Unmanned aerial vehicles (UAVs) with physical interaction capabilities are on hand to address these issues. Our previous work introduced one such UAV: a multi-rotor with a pair of tilting rotors and a novel, cable-driven, front-mounted gripper, which improved position accuracy during interaction tasks. However, the UAV could only interact with vertical surfaces, and its control performance was limited by a simple pilot-assisted position controller during interaction. This paper advances that work by developing an improved version of our UAV. The modified design includes two pairs of tilt-rotors, which can tilt simultaneously to angle the drone body, allowing interaction with non-vertical targets at specific angles. We develop a simulation package that accurately replicates our new UAV design's physical characteristics and dynamics, including the cable-driven gripper. This simulation package provides a virtual testbed for designing and evaluating advanced interaction control algorithms, minimizing the risks, costs, and time of physical prototyping. We demonstrate its utility by safely testing autonomous control strategies, including force control, in a tree-grasping scenario. We also give insights into hyperparameter selections, challenges faced, and current limitations while developing such a versatile package that involves simulating elastic components such as cables, springs, and soft finger pads. We open-source our simulation package for the community's benefit at https://tinyurl.com/ypwzje2a.

Publisher Copyright

This research / project is supported by the National Research Foundation - Cities of Tomorrow R&D Programme
Grant Reference no. : CoT-V1-2023-2

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