A Pesticide Spraying Mission Allocation and Path Planning With Multicopters

被引：1

作者：

Huang, Jing ^{[1
,2
]}

Du, Baihui ^{[3
]}

Zhang, Youmin ^{[4
]}

Quan, Quan ^{[5
]}

Wang, Ban ^{[6
]}

Mu, Lingxia ^{[1
]}

机构：

[1] Xian Univ Technol, Dept Automat & Informat Engn, Xian 710048, Peoples R China

[2] Jiujiang Precis Test Technol Res Inst, Jiujiang 332000, Peoples R China

[3] China Elect Corp, Beijing 100081, Peoples R China

[4] Concordia Univ, Dept Mech Ind & Aerosp Engn, Montreal, PQ H3G 1M8, Canada

[5] Beihang Univ, Sch Automat Sci & Elect Engn, Beijing 100191, Peoples R China

[6] Northwestern Polytech Univ, Sch Aeronaut, Xian 710072, Peoples R China

来源：

IEEE TRANSACTIONS ON AEROSPACE AND ELECTRONIC SYSTEMS | 2024年 / 60卷 / 02期

基金：

中国国家自然科学基金;

关键词：

Spraying; Pesticides; Optimization; Task analysis; Resource management; Path planning; Genetic algorithms; Mission assignment; multicopters; multiple traveling salesman problem (mTSP); path planning; point cloud; precision spraying; TRAVELING SALESMAN PROBLEM; UNMANNED AERIAL VEHICLES; ALGORITHM; DEPOT; OPTIMIZATION; FORMULATIONS; TECHNOLOGIES; ASSIGNMENT; SEARCH; SOLVE;

D O I：

10.1109/TAES.2024.3355028

中图分类号：

V [航空、航天];

学科分类号：

08 ; 0825 ;

摘要：

This article presents a mission allocation and path-planning solution for the pesticide spraying mission of dense trees in hilly terrains using cooperative multicopters. The problem is formulated as a single-depot single-end multiple traveling salesman problem (mTSP). Three different algorithms, namely classical mTSP algorithm, Grouping-TSP combined algorithm, and Grouping-TSP decoupled algorithm, are developed to solve the proposed mTSP. Simulation results indicate that the classical mTSP algorithm provides an evenly distributed task allocation while the Grouping-TSP combined algorithm delivers the optimal solution. In addition, the Grouping-TSP decoupled algorithm minimizes computational complexity. Both Grouping-TSP algorithms integrate a subregions segmentation process to guarantee collision avoidance between the multicopters.

引用

页码：2277 / 2291

页数：15

共 50 条

[21] Path Planning for Heterogeneous UAVs With Radar Sensors
Yan, Zining
Yin, Guisheng
Li, Sizhao
Sikdar, Biplab
IEEE INTERNET OF THINGS JOURNAL, 2024, 11 (06) : 9979 - 9994
[22] Dynamic Mission Planning Algorithm for UAV Formation in Battlefield Environment
Zhang, Jing
Cui, Yani
Ren, Jia
IEEE TRANSACTIONS ON AEROSPACE AND ELECTRONIC SYSTEMS, 2023, 59 (04) : 3750 - 3765
[23] Obstacle avoidance and path planning for carrier aircraft launching
Wu Yu
Qu Xiangju
CHINESE JOURNAL OF AERONAUTICS, 2015, 28 (03) : 695 - 703
[24] Application of metamorphic testing on UAV path planning software✩
Wu, Lvyuan
Xi, Zhiyu
Zheng, Zheng
Li, Xiaoli
JOURNAL OF SYSTEMS AND SOFTWARE, 2023, 204
[25] Path-Planning for an Unmanned Aerial Vehicle with Energy Constraint in a Search and Coverage Mission
Gramajo, German
Shankar, Praveen
2016 IEEE GREEN ENERGY AND SYSTEMS CONFERENCE (IGSEC), 2016,
[26] Task Allocation and Path Planning for Collaborative Swarm Guidance in Support of Artillery Mission
Pinon, N.
Strub, G.
Changey, S.
Basset, M.
2022 INTERNATIONAL CONFERENCE ON UNMANNED AIRCRAFT SYSTEMS (ICUAS), 2022, : 1006 - 1015
[27] Multiregional Coverage Path Planning for Multiple Energy Constrained UAVs
Xie, Junfei
Chen, Jun
IEEE TRANSACTIONS ON INTELLIGENT TRANSPORTATION SYSTEMS, 2022, 23 (10) : 17366 - 17381
[28] Automatic Path Planning for Spraying Drones Based on Deep Q-Learning
Huang, Ya-Yu
Li, Zi-Wen
Yang, Chun-Hao
Huang, Yueh-Min
JOURNAL OF INTERNET TECHNOLOGY, 2023, 24 (03): : 565 - 575
[29] Mission-based PTR triangle for multi-UAV systems flight planning
El-Basioni, Basma M. Mohammad
Abd El-Kader, Sherine M.
AD HOC NETWORKS, 2023, 142
[30] Path Planning for UAV Communication Networks: Related Technologies, Solutions, and Opportunities
Luo, Junhai
Wang, Zhiyan
Xia, Ming
Wu, Linyong
Tian, Yuxin
Chen, Yu
ACM COMPUTING SURVEYS, 2023, 55 (09)

← 1 2 3 4 5 →