Design and Control of a Deformable Trees-Pruning Aerial Robot

, , , , , , &
Complexity 2020:1-19 (2020)
  Copy   BIBTEX

Abstract

Tree branches near the electric power transmission lines are of great threat to the electricity supply. Nowadays, the tasks of clearing threatening tree branches are still mostly operated by hand and simple tools. Traditional structures of the multirotor aerial robot have the problem of fixed structure and limited performance, which affects the stability and efficiency of pruning operation. In this article, in order to obtain better environmental adaptability, an active deformable trees-pruning aerial robot is presented. The deformation of the aerial robot is implemented through two ways, arm telescopic and folding. In order to suppress the influence of internal and external disturbances on the system, Active Disturbance Rejection Control technology is adopted to build the flight controller. Firstly, active deformation aerial robot structure is given, followed by system dynamic model establishment under wind disturbance using the Newton–Euler method. Also, the analysis of the gusts influence on the system is considered. Then, the active deformation aerial robot system is decoupled into a combination of six SISO systems, so that a disturbance rejection controller is designed. Finally, the expanded state observer and the nonlinear state error feedback law are used to inspect and compensate the disturbance. Simulation results of attitude and position tracking as well as the antidisturbance capability show that the active deformation aerial robot with the ADRC flight controller designed in this paper has excellent attitude control capabilities during flight and trees-pruning operation.

Categories

Keywords

Reprint years

DOI

10.1155/2020/6627339

Links

PhilArchive



    Upload a copy of this work     Papers currently archived: 91,349

External links

Setup an account with your affiliations in order to access resources via your University's proxy server

Through your library

My notes

Similar books and articles

Disturbance-Observer-Based Fuzzy Control for a Robot Manipulator Using an EMG-Driven Neuromusculoskeletal Model.Longbin Zhang, Wen Qi, Yingbai Hu & Yue Chen - 2020 - Complexity 2020:1-10.
Adaptive Visually Servoed Tracking Control for Wheeled Mobile Robot with Uncertain Model Parameters in Complex Environment.Fujie Wang, Yi Qin, Fang Guo, Bin Ren & John T. W. Yeow - 2020 - Complexity 2020:1-13.
A Compound Controller of an Aerial Manipulator Based on Maxout Fuzzy Neural Network.Xinchen Qi, Jianwei Wu & Jiansheng Pan - 2020 - Complexity 2020:1-10.
Load Parameter Identification for Parallel Robot Manipulator Based on Extended Kalman Filter.Shijie Song, Xiaolin Dai, Zhangchao Huang & Dawei Gong - 2020 - Complexity 2020:1-12.
Wind and Payload Disturbance Rejection Control Based on Adaptive Neural Estimators: Application on Quadrotors.Jesús Enrique Sierra & Matilde Santos - 2019 - Complexity 2019:1-20.
Fuzzy Adaptation Algorithms’ Control for Robot Manipulators with Uncertainty Modelling Errors.Yongqing Fan, Keyi Xing & Xiangkui Jiang - 2018 - Complexity 2018:1-8.
Optimization and Realization of the Continuous Reactor with Improved Automatic Disturbance Rejection Control.Mingsan Ouyang & Yunlong Wang - 2020 - Complexity 2020:1-14.
Comparison of H∞ and μ-synthesis Control Design for Quarter Car Active Suspension System using Simulink.Mustefa Jibril - 2020 - International Journal of Scientific Research and Engineering Development 3 (1):596-607.
Acceleration Level Control of Redundant Manipulators with Physical Constraints Compliance and Disturbance Rejection under Complex Environment.Jinglun Liang, Yisheng Rong, Guoliang Ye, Xiaoxiao Li, Jianwen Guo & Zhenzhen He - 2020 - Complexity 2020:1-14.
Nonlinear Trajectory Controller with Improved Performances for Waveriders.LiuQing Yang, YanBin Liu & Yong Zhang - 2019 - Complexity 2019:1-16.
Design to Implementation of A Line Follower Robot Using 5 Sensors.Anupoju Sai Vamsi, Badana Manasa, Kocherla Rama Krishna, Tarigoppula Venu & A. N. V. N. Shashank - 2019 - International Journal of Engineering and Information Systems (IJEAIS) 3 (1):42-47.
Decentralized fuzzy linguistic control of multiple robotic manipulators with guaranteed global stability.Yongqing Fan, Wenqing Wang, Xiangkui Jiang & Zhen Li - 2019 - Interaction Studies 20 (1):185-204.
Robust Stabilization of Extended Nonholonomic Chained-Form Systems with Dynamic Nonlinear Uncertain Terms by Using Active Disturbance Rejection Control.Hua Chen, Xiaoying Sun, Shen Xu & Yuxuan Wang - 2019 - Complexity 2019:1-12.
Humanoid Robot Navigation: Getting Localization Information from Vision.Fabien Moutarde, Arnaud de La Fortelle, Silvère Bonnabel & Emilie Wirbel - 2014 - Journal of Intelligent Systems 23 (2):113-132.
Quarter car active suspension system design using optimal and robust control method.Mustefa Jibril - 2020 - International Research Journal of Modernization in Engineering Technology and Science 2 (3):197-207.

Analytics

Added to PP
2020-12-29

Downloads
10 (#1,165,120)

6 months
5 (#629,136)

Historical graph of downloads
How can I increase my downloads?

Author Profiles

Yang Zhong
University of Wisconsin, Madison
Zhao Zhang

Citations of this work

No citations found.

Add more citations

References found in this work

Add more references