Collision avoidance trajectory planning for a dual-robot system: using a modified APF method

Yang, Dong; Dong, Li; Dai, Jun Kang

doi:10.1017/s0263574723001807

Cited by 4 publications

(2 citation statements)

References 38 publications

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“…Additionally, future work will delve into control aspects, exploring impedance and admittance control for optimal robot-environment interaction, as proposed in works such as [29]. Attention will also be directed towards active learning of collision distance functionality, as suggested in [30] and [31].Furthermore, we aim to explore different end-effectors, such as grippers capable of manipulating not only food but also a wide range of objects, as proposed by Fu et al [32], Dong and Zhang [33], Carbone et al [34], and Yao et al [35]. Their collective work offers valuable insights into control strategies, motion planning, flexible grasping, grasp detection technology, and optimal design of robotic mechanisms, thereby opening multiple avenues for further enhancement of this research.…”

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confidence: 99%

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confidence: 99%

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Design of a Wheelchair-Mounted Robotic Arm for Feeding Assistance of Upper-Limb Impaired Patients

Leone,

Giunta,

Rino

et al. 2024

Robotics

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This paper delineates the design and realization of a Wheelchair-Mounted Robotic Arm (WMRA), envisioned as an autonomous assistance apparatus for individuals encountering motor difficulties and/or upper limb paralysis. The proposed design solution is based on employing a 3D printing process coupled with optimization design techniques to achieve a cost-oriented and user-friendly solution. The proposed design is based on utilizing commercial Arduino control hardware. The proposed device has been named Pick&Eat. The proposed device embodies reliability, functionality, and cost-effectiveness, and features a modular structure housing a 4-degrees-of-freedom robotic arm with a fixing frame that can be attached to commercial wheelchairs. The arm is integrated with an interchangeable end-effector facilitating the use of various tools such as spoons or forks tailored to different food types. Electrical and sensor components were meticulously designed, incorporating sensors to ensure user safety throughout operations. Smooth and secure operations are achieved through a sequential procedure that is depicted in a specific flowchart. Experimental tests have been carried out to demonstrate the engineering feasibility and effectiveness of the proposed design solution as an innovative assistive solution for individuals grappling with upper limb impairment. Its capacity to aid patients during the eating process holds promise for enhancing their quality of life, particularly among the elderly and those with disabilities.

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confidence: 99%

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confidence: 99%

Design of a Wheelchair-Mounted Robotic Arm for Feeding Assistance of Upper-Limb Impaired Patients

Leone,

Giunta,

Rino

et al. 2024

Robotics

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Improved SLTV-MPC for Epidemic Prevention Robots Based on Artificial Potential Field

Wu,

Shen,

Fan

2024

Lecture Notes in Electrical Engineering

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Hybrid learning-based visual path following for an industrial robot

Bingol,

Aydogmus

2024

Robotica

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This study proposes a novel hybrid learning approach for developing a visual path-following algorithm for industrial robots. The process involves three steps: data collection from a simulation environment, network training, and testing on a real robot. The actor network is trained using supervised learning for 500 epochs. A semitrained network is then obtained at the $250^{th}$ epoch. This network is further trained for another 250 epochs using reinforcement learning methods within the simulation environment. Networks trained with supervised learning (500 epochs) and the proposed hybrid learning method (250 epochs each of supervised and reinforcement learning) are compared. The hybrid learning approach achieves a significantly lower average error (30.9 mm) compared with supervised learning (39.3 mm) on real-world images. Additionally, the hybrid approach exhibits faster processing times (31.7 s) compared with supervised learning (35.0 s). The proposed method is implemented on a KUKA Agilus KR6 R900 six-axis robot, demonstrating its effectiveness. Furthermore, the hybrid approach reduces the total power consumption of the robot’s motors compared with the supervised learning method. These results suggest that the hybrid learning approach offers a more effective and efficient solution for visual path following in industrial robots compared with traditional supervised learning.

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Collision avoidance trajectory planning for a dual-robot system: using a modified APF method

Cited by 4 publications

References 38 publications

Design of a Wheelchair-Mounted Robotic Arm for Feeding Assistance of Upper-Limb Impaired Patients

Design of a Wheelchair-Mounted Robotic Arm for Feeding Assistance of Upper-Limb Impaired Patients

Improved SLTV-MPC for Epidemic Prevention Robots Based on Artificial Potential Field

Hybrid learning-based visual path following for an industrial robot

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