Teleoperation Control Design with Virtual Force Feedback for the Cable-Driven Hyper-Redundant Continuum Manipulator

Qin, Long; Huang, Fanghao; Zheng, Chao; Song, Wei; Zhu, Shiqiang

doi:10.3390/app10228031

Cited by 8 publications

(4 citation statements)

References 36 publications

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“…During this process, the spring serves as an elastic element and generates force against the direction of motion from the virtual handle. Moreover, the damper system, in combination with the spring, helps control robot stability and reduce robot velocity when the magnitude of the force increases abruptly [30,31]. The formula for computing the elastic force is as follows:…”

Section: Haptic Algorithmmentioning

confidence: 99%

Development of a Hardware-in-the-Loop Platform for a Teleoperation Flexibility Robotic System

Tran,

Nguyen,

Tran

et al. 2024

Applied Sciences

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A control method for a cable-driven robot in a teleoperation system is proposed using the hardware-in-the-loop (HIL) simulation technique. The main components of the teleoperated robotic system are a haptic device, also called a delta robot, and a cable-driven hyper-redundant (CDHR) robot. The CDHR manipulator has higher flexibility and multiple degrees of freedom (DOF), and, therefore, its inverse kinematics are complex. For this reason, the Jacobian method is used in place of the conventional method to calculate the inverse kinematics. Moreover, the two robots constituting the telerobotic system are different in terms of their mechanical structures and workspaces. Therefore, the position mapping method is applied to ensure that the two workspaces are utilized together. However, a singularity area appears when the mapping parameter is adjusted to expand the workspace. Therefore, a haptic algorithm is proposed to prevent the robot from moving into the singularity region and generate force feedback at the end-effector of the haptic device to warn the operator. Because experimental verification of this control strategy is difficult, the HIL technique is used for demonstration in this study to ensure stability and safety before implementation of the method at the experiment scale. The CDHR robot is designed using SolidWorks 2021. Then, the Simscape model is used to simulate the telerobotic system. In addition, the protocol between the haptic device and the laptop is programmed using C/C++ language to facilitate communication with the CDHR robot in MATLAB Simulink 2022a. A few trials are conducted to evaluate and demonstrate the effectiveness of the proposed method.

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Section: Haptic Algorithmmentioning

confidence: 99%

Development of a Hardware-in-the-Loop Platform for a Teleoperation Flexibility Robotic System

Tran,

Nguyen,

Tran

et al. 2024

Applied Sciences

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“…Qin et el. [40] proposed a wave variable based control scheme with a virtual force feedback. However, most of them are computationally expensive and have complex mathematical formulations.…”

Section: Introductionmentioning

confidence: 99%

A Study on Position Control of a Continuum Arm Using MAML (Model-Agnostic Meta-Learning) for Adapting Different Loading Conditions

Sahoo

Chakraborty

2022

IEEE Access

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Predicting tip positions of a spring based continuum manipulator is highly challenging due to its nonlinear deformations. External loading on the tip further deteriorates the accuracy. Model-less control has shown great success in the tip positioning. However, the model less control strategies require a large data set and considerable amount of time for the training. Performance of these controllers also deteriorates with external loads. To address these problems, this paper presents a MAML(Model-Agnostic Meta-Learning) based closed loop controller for the continuum manipulators. This controller requires relatively small amount of data to achieve the state-of-art positioning accuracy. It can also adapt to the changes due to the external loads with less than 2.5 percent of the original data. Two algorithms for the offline adaptation of the known and unknown external loading are proposed. This technique is also helpful for automatic stiffness tuning of the spring based continuum manipulators. The experimental validations have been done on the simulation environment and on the real prototype. The continuum arm used for the experimentation is a tendon based non constant curvature spring-based manipulator. The average relative positioning error for the zero loading case was found to be 3.83% on the spring based prototype . The controller was successful in bringing down the relative tip positioning error of the manipulator from 5.42% to 2.7% in the simulation environment. It also showed success in bringing down the relative tip positioning error from 7.8% to 3.96% on the real prototype. Average relative tip positioning errors below 4.27% and 4.89% have been achieved in the trajectory following tasks for the known and unknown external loading cases respectively.

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“…Hua et al [30] investigated the effect of different parameters on the vibration of a dynamic model by controlling for variables. Qin et al [31] proposed a virtual force feedback algorithm to improve SAMs' perception and assistance capabilities in remote operations. Ma et al [32] applied the perturbation method to a dynamic model of SAM, derived a vibration control Appl.…”

Section: Introductionmentioning

confidence: 99%

Equivalent Dynamic Analysis of a Cable-Driven Snake Arm Maintainer

Qin

2022

Applied Sciences

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In this paper, we investigate a design method for a cable-driven snake arm maintainer (SAM) and its dynamics modelling. A SAM can provide redundant degrees of freedom and high structural stiffness, as well as high load capacity and a simplified structure ideal for various narrow and extreme working environments, such as nuclear power plants. However, their serial-parallel configuration and cable drive system make the dynamics of a SAM strongly coupled, which is not conducive to accurate control. In this paper, we propose an equivalent dynamics modelling method for the strongly coupled dynamic characteristics of each joint cable. The cable traction dynamics are forcibly decoupled using force analysis and joint torque equivalent transformation. Then, the forcibly equivalent dynamic model is obtained based on traditional series robot dynamic modelling methods (Lagrangian method, etc.). To verify the correctness of the equivalent dynamics, a simple model-based controller is established. In addition, a SAM prototype is produced to collect joint angles and cable forces at different trajectories. Finally, the results of the equivalent dynamics control simulation and the prototype tests demonstrate the validity of the SAM structural design and the equivalent dynamics model.

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Teleoperation Control Design with Virtual Force Feedback for the Cable-Driven Hyper-Redundant Continuum Manipulator

Cited by 8 publications

References 36 publications

Development of a Hardware-in-the-Loop Platform for a Teleoperation Flexibility Robotic System

Development of a Hardware-in-the-Loop Platform for a Teleoperation Flexibility Robotic System

A Study on Position Control of a Continuum Arm Using MAML (Model-Agnostic Meta-Learning) for Adapting Different Loading Conditions

Equivalent Dynamic Analysis of a Cable-Driven Snake Arm Maintainer

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