惯性辅助系统的连续规划

IF 3.7 3区计算机科学 Q2 COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE

Autonomous Robots Pub Date : 2024-10-12 DOI:10.1007/s10514-024-10180-6

Mitchell Usayiwevu, Fouad Sukkar, Chanyeol Yoo, Robert Fitch, Teresa Vidal-Calleja

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引用次数: 0

摘要

惯性辅助系统需要持续的运动激励，以确定测量偏差的特征，从而实现定位框架所需的精确整合。本文提出使用信息路径规划来寻找最佳轨迹，以最大限度地减少 IMU 偏差的不确定性，并提出一种自适应轨迹方法，以引导规划者找到有助于收敛的轨迹。该方法的主要贡献是基于高斯过程（GP）的新型回归方法，以强制执行 \(\hbox {RRT}^*\)规划算法变体的航点之间的连续性和可区分性。我们采用应用于 GP 核函数的线性算子，不仅能推断连续的位置轨迹，还能推断速度和加速度。通过使用线性函数，可以将 IMU 测量给出的速度和加速度约束施加到位置 GP 模型上。模拟和实际实验的结果表明，对 IMU 偏差收敛进行规划有助于最大限度地减少状态估计框架中的定位误差。

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Continuous planning for inertial-aided systems

Inertial-aided systems require continuous motion excitation among other reasons to characterize the measurement biases that will enable accurate integration required for localization frameworks. This paper proposes the use of informative path planning to find the best trajectory for minimizing the uncertainty of IMU biases and an adaptive traces method to guide the planner towards trajectories that aid convergence. The key contribution is a novel regression method based on Gaussian Process (GP) to enforce continuity and differentiability between waypoints from a variant of the \(\hbox {RRT}^*\) planning algorithm. We employ linear operators applied to the GP kernel function to infer not only continuous position trajectories, but also velocities and accelerations. The use of linear functionals enable velocity and acceleration constraints given by the IMU measurements to be imposed on the position GP model. The results from both simulation and real-world experiments show that planning for IMU bias convergence helps minimize localization errors in state estimation frameworks.

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来源期刊

Autonomous Robots 工程技术-机器人学

CiteScore

7.90

自引率

5.70%

发文量

审稿时长

3 months

期刊介绍： Autonomous Robots reports on the theory and applications of robotic systems capable of some degree of self-sufficiency. It features papers that include performance data on actual robots in the real world. Coverage includes: control of autonomous robots · real-time vision · autonomous wheeled and tracked vehicles · legged vehicles · computational architectures for autonomous systems · distributed architectures for learning, control and adaptation · studies of autonomous robot systems · sensor fusion · theory of autonomous systems · terrain mapping and recognition · self-calibration and self-repair for robots · self-reproducing intelligent structures · genetic algorithms as models for robot development. The focus is on the ability to move and be self-sufficient, not on whether the system is an imitation of biology. Of course, biological models for robotic systems are of major interest to the journal since living systems are prototypes for autonomous behavior.