Development of a bionic hexapod robot with adaptive gait and clearance for enhanced agricultural field scouting.

IF 2.9 Q2 ROBOTICS
Frontiers in Robotics and AI Pub Date : 2024-09-18 eCollection Date: 2024-01-01 DOI:10.3389/frobt.2024.1426269
Zhenghua Zhang, Weilong He, Fan Wu, Lina Quesada, Lirong Xiang
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Abstract

High agility, maneuverability, and payload capacity, combined with small footprints, make legged robots well-suited for precision agriculture applications. In this study, we introduce a novel bionic hexapod robot designed for agricultural applications to address the limitations of traditional wheeled and aerial robots. The robot features a terrain-adaptive gait and adjustable clearance to ensure stability and robustness over various terrains and obstacles. Equipped with a high-precision Inertial Measurement Unit (IMU), the robot is able to monitor its attitude in real time to maintain balance. To enhance obstacle detection and self-navigation capabilities, we have designed an advanced version of the robot equipped with an optional advanced sensing system. This advanced version includes LiDAR, stereo cameras, and distance sensors to enable obstacle detection and self-navigation capabilities. We have tested the standard version of the robot under different ground conditions, including hard concrete floors, rugged grass, slopes, and uneven field with obstacles. The robot maintains good stability with pitch angle fluctuations ranging from -11.5° to 8.6° in all conditions and can walk on slopes with gradients up to 17°. These trials demonstrated the robot's adaptability to complex field environments and validated its ability to maintain stability and efficiency. In addition, the terrain-adaptive algorithm is more energy efficient than traditional obstacle avoidance algorithms, reducing energy consumption by 14.4% for each obstacle crossed. Combined with its flexible and lightweight design, our robot shows significant potential in improving agricultural practices by increasing efficiency, lowering labor costs, and enhancing sustainability. In our future work, we will further develop the robot's energy efficiency, durability in various environmental conditions, and compatibility with different crops and farming methods.

开发具有自适应步态和间隙的仿生六足机器人,以增强农田侦察能力。
高灵活性、机动性和有效载荷能力,再加上占地面积小,使腿部机器人非常适合精准农业应用。在本研究中,我们介绍了一种专为农业应用设计的新型仿生六足机器人,以解决传统轮式机器人和空中机器人的局限性。该机器人具有地形适应性步态和可调间隙,可确保在各种地形和障碍物上的稳定性和鲁棒性。该机器人配备了高精度惯性测量单元(IMU),能够实时监测其姿态以保持平衡。为了增强障碍物探测和自导航能力,我们设计了一种配备可选高级传感系统的高级版机器人。这种高级版本包括激光雷达、立体摄像机和距离传感器,可实现障碍物探测和自导航功能。我们在不同的地面条件下对标准版机器人进行了测试,包括坚硬的混凝土地面、崎岖的草地、斜坡和有障碍物的不平整场地。在所有条件下,机器人都能保持良好的稳定性,俯仰角波动范围从-11.5°到8.6°不等,并能在坡度高达17°的斜坡上行走。这些试验证明了机器人对复杂野外环境的适应能力,并验证了其保持稳定性和效率的能力。此外,与传统的避障算法相比,地形适应算法更加节能,每越过一个障碍物,能耗可降低 14.4%。结合其灵活轻便的设计,我们的机器人在提高效率、降低劳动力成本和增强可持续性等方面显示出改善农业实践的巨大潜力。在未来的工作中,我们将进一步提高机器人的能效、在各种环境条件下的耐用性以及与不同作物和耕作方法的兼容性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
CiteScore
6.50
自引率
5.90%
发文量
355
审稿时长
14 weeks
期刊介绍: Frontiers in Robotics and AI publishes rigorously peer-reviewed research covering all theory and applications of robotics, technology, and artificial intelligence, from biomedical to space robotics.
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