This paper presents a novel analytical formulation for identifying the closest pair of points lying on two arbitrary cylinders in space, and subsequently the distance between them. Each cylinder is decomposed into four geometric primitives. It is shown that the original problem reduces to the computation of the shortest distance between five distinct combinations of these primitives. Four of these subproblems are solved in closed form, while the remaining one requires the solution of an eight-degree polynomial equation. The analytical nature of the formulation and solution allows the identification of all the special cases, e.g., positive-dimensional solutions, and the curve of intersection when the cylinders interfere. The symbolic precomputation of the results leads to a fast numerical implementation, capable of solving the problem in about 50 mu s (averaged over 1 x 10(6) random instances of the most general case) on a standard PC. The numerical results are verified by repeating all the calculations in a general-purpose commercial CAD software. The algorithm has significant potential for applications in the various aspects of robotics and mechanisms, as their links can be modeled easily and compactly as cylinders. This makes tasks such as path planning, determination of the collision-free workspace, etc., computationally easier.
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机译:本文提出了一种新颖的分析公式,用于识别空间中两个任意圆柱上最接近的点对,并确定它们之间的距离。每个圆柱体被分解为四个几何图元。结果表明,原始问题简化为这些图元的五个不同组合之间最短距离的计算。这些子问题中的四个以闭合形式求解,而其余一个则需要八次多项式方程的解。制剂和溶液的分析性质允许识别所有特殊情况,例如正维溶液,以及圆柱体干涉时的相交曲线。结果的符号预计算导致快速的数值实现,能够在标准PC上以大约50毫秒(在最一般情况下的1 x 10(6)个随机实例中平均)解决问题。通过在通用商用CAD软件中重复所有计算,可以验证数值结果。该算法在机器人技术和机构的各个方面都具有巨大的应用潜力,因为它们的链接可以像圆柱一样轻松而紧凑地建模。这使诸如路径规划,确定无碰撞工作区等任务的计算更加容易。
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