计算机科学
瓶颈
稳健性(进化)
调度(生产过程)
任务(项目管理)
分布式计算
机器人
任务分析
最优化问题
背景(考古学)
数学优化
算法设计
资源配置
机器学习
人工智能
算法
自适应系统
资源管理(计算)
过程(计算)
编码(内存)
进化算法
强化学习
计算复杂性理论
高效能源利用
健身景观
灵活性(工程)
线性规划
作者
Peng Chen,Jing Liang,Kangjia Qiao,Hui Song,Cai-Tong Yue,Tianlei Ma,Kunjie Yu,Ponnuthurai Nagaratnam Suganthan,Witold Pedrycz
标识
DOI:10.1109/tevc.2026.3659072
摘要
In smart farming, the development of multi-robot systems is essential for improving harvesting efficiency and addressing labor shortages, yet achieving optimal coordination presents significant scheduling complexities. This paper investigates a critical multi-robot task allocation problem in the context of orchard harvesting, focusing on multi-objective optimization (makespan and energy consumption) while considering task divisibility, robot re-utilization for multiple routes, and load-dependent energy consumption. Balancing these conflicting objectives across transport and operations, while managing the immensely expanded decision space due to task splitting, poses severe challenges to algorithm efficiency. To deal with these issues, we propose an adaptive multi-objective task splitting algorithm (AMTSA), which employs a hybrid encoding method to clearly demonstrate robot-route assignments and task-splitting information. Regarding the search modes, AMTSA adopts an adaptive strategy: the early phase emphasizes diverse exploration through route structural optimization, while the later phase shifts computational resources towards in-depth task splitting optimization (TSO) to accelerate convergence. Furthermore, the TSO process integrates two coordinated splitting mechanisms to collaboratively optimize the spatial layout and temporal balance of the task allocation by targeting the bottleneck robot, thereby addressing multi-objective conflicts. The effectiveness and robustness of AMTSA have been validated through comparative experiments on one real-world case study and 15 newly constructed test instances. Generally, this research advances the theoretical comprehension of multi-robot coordination and provides practical insights relevant to agricultural automation.
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