Learning to Model and Plan for Wheeled Mobility on Vertically Challenging Terrain

IF 4.6 2区计算机科学 Q2 ROBOTICS

IEEE Robotics and Automation Letters Pub Date : 2024-12-23 DOI:10.1109/LRA.2024.3520919

Aniket Datar;Chenhui Pan;Xuesu Xiao

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引用次数: 0

Abstract

Most autonomous navigation systems assume wheeled robots are rigid bodies and their 2D planar workspaces can be divided into free spaces and obstacles. However, recent wheeled mobility research, showing that wheeled platforms have the potential of moving over vertically challenging terrain (e.g., rocky outcroppings, rugged boulders, and fallen tree trunks), invalidate both assumptions. Navigating off-road vehicle chassis with long suspension travel and low tire pressure in places where the boundary between obstacles and free spaces is blurry requires precise 3D modeling of the interaction between the chassis and the terrain, which is complicated by suspension and tire deformation, varying tire-terrain friction, vehicle weight distribution and momentum, etc. In this letter, we present a learning approach to model wheeled mobility, i.e., in terms of vehicle-terrain forward dynamics, and plan feasible, stable, and efficient motion to drive over vertically challenging terrain without rolling over or getting stuck. We present physical experiments on two wheeled robots and show that planning using our learned model can achieve up to 60% improvement in navigation success rate and 46% reduction in unstable chassis roll and pitch angles.

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学习模型和计划在垂直挑战地形轮式移动

大多数自主导航系统假设轮式机器人为刚体，其二维平面工作空间可分为自由空间和障碍物。然而，最近的轮式移动研究表明，轮式平台具有在垂直挑战性地形上移动的潜力（例如，裸露的岩石、崎岖的巨石和倒下的树干），这两种假设都无效。在障碍物与自由空间边界模糊的地方，对长悬架行程、低胎压的越野车底盘进行导航，需要对底盘与地形的相互作用进行精确的三维建模，而悬架与轮胎的变形、胎地摩擦的变化、车辆的重量分布和动量等因素使底盘与地形的相互作用变得复杂。在这封信中，我们提出了一种学习方法来模拟轮式机动性，即从车辆-地形前向动力学的角度出发，并规划可行、稳定和有效的运动，以在垂直挑战性地形上行驶，而不会翻车或卡住。我们在两个轮式机器人上进行了物理实验，并表明使用我们学习的模型进行规划可以使导航成功率提高60%，减少46%的不稳定底盘横摇和俯仰角。

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来源期刊

IEEE Robotics and Automation Letters Computer Science-Computer Science Applications

CiteScore

9.60

自引率

15.40%

发文量

1428

期刊介绍： The scope of this journal is to publish peer-reviewed articles that provide a timely and concise account of innovative research ideas and application results, reporting significant theoretical findings and application case studies in areas of robotics and automation.