CURE: Simulation-Augmented Autotuning in Robotics

IF 9.4 1区计算机科学 Q1 ROBOTICS

IEEE Transactions on Robotics Pub Date : 2025-03-06 DOI:10.1109/TRO.2025.3548546

Md Abir Hossen;Sonam Kharade;Jason M. O'Kane;Bradley Schmerl;David Garlan;Pooyan Jamshidi

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引用次数: 0

Abstract

Robotic systems are typically composed of various subsystems, such as localization and navigation, each encompassing numerous configurable components (e.g., selecting different planning algorithms). Once an algorithm has been selected for a component, its associated configuration options must be set to the appropriate values. Configuration options across the system stack interact nontrivially. Finding optimal configurations for highly configurable robots to achieve desired performance poses a significant challenge due to the interactions between configuration options across software and hardware that result in an exponentially large and complex configuration space. These challenges are further compounded by the need for transferability between different environments and robotic platforms. Data efficient optimization algorithms (e.g., Bayesian optimization) have been increasingly employed to automate the tuning of configurable parameters in cyber-physical systems. However, such optimization algorithms converge at later stages, often after exhausting the allocated budget (e.g., optimization steps, allotted time) and lacking transferability. This article proposes causal understanding and remediation for enhancing robot performance (CURE)—a method that identifies causally relevant configuration options, enabling the optimization process to operate in a reduced search space, thereby enabling faster optimization of robot performance. CURE abstracts the causal relationships between various configuration options and the robot performance objectives by learning a causal model in the source (a low-cost environment such as the Gazebo simulator) and applying the learned knowledge to perform optimization in the target (e.g., Turtlebot 3 physical robot). We demonstrate the effectiveness and transferability of CURE by conducting experiments that involve varying degrees of deployment changes in both physical robots and simulation.

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CURE：机器人中的仿真-增强自动调谐

机器人系统通常由各种子系统组成，例如定位和导航，每个子系统都包含许多可配置的组件（例如，选择不同的规划算法）。一旦为组件选择了算法，就必须将其相关的配置选项设置为适当的值。跨系统堆栈的配置选项相互作用非常重要。为高度可配置的机器人寻找最佳配置以实现期望的性能是一个重大的挑战，因为跨软件和硬件的配置选项之间的相互作用会导致指数级大和复杂的配置空间。这些挑战由于需要在不同环境和机器人平台之间进行转移而进一步复杂化。数据高效优化算法（例如，贝叶斯优化）已越来越多地用于自动调整网络物理系统中的可配置参数。然而，这种优化算法在后期往往在耗尽分配的预算（例如，优化步骤，分配的时间）和缺乏可转移性之后收敛。本文提出了提高机器人性能的因果理解和补救方法（CURE）——一种识别因果相关配置选项的方法，使优化过程能够在减少的搜索空间中操作，从而实现机器人性能的更快优化。CURE通过在源（低成本环境，如Gazebo模拟器）中学习因果模型，将各种配置选项与机器人性能目标之间的因果关系抽象出来，并将学习到的知识应用于目标（如Turtlebot 3物理机器人）中进行优化。我们通过在物理机器人和模拟中进行不同程度的部署变化的实验来证明CURE的有效性和可转移性。

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

IEEE Transactions on Robotics 工程技术-机器人学

CiteScore

14.90

自引率

5.10%

发文量

259

审稿时长

6.0 months

期刊介绍： The IEEE Transactions on Robotics (T-RO) is dedicated to publishing fundamental papers covering all facets of robotics, drawing on interdisciplinary approaches from computer science, control systems, electrical engineering, mathematics, mechanical engineering, and beyond. From industrial applications to service and personal assistants, surgical operations to space, underwater, and remote exploration, robots and intelligent machines play pivotal roles across various domains, including entertainment, safety, search and rescue, military applications, agriculture, and intelligent vehicles. Special emphasis is placed on intelligent machines and systems designed for unstructured environments, where a significant portion of the environment remains unknown and beyond direct sensing or control.