This paper presents a method for efficient extrinsic self-calibration of multiple inertial measurement units (IMUs) by selecting informative measurement subsets. The key insights are:
Extrinsic calibration of multiple IMUs is crucial for realizing the benefits of enhanced measurement accuracy, bandwidth, and fault tolerance. Self-calibration methods that rely solely on IMU measurements offer significant advantages, especially in scenarios requiring recalibration due to changes in sensor configuration.
The authors hypothesize that the measure of utility, a function of the parameter estimates, is largely insensitive to the specific choice of parameters. This allows evaluating utility at an initial guess, eliminating the need for frequent recalibrations and significantly reducing computation time.
The paper introduces two algorithms for selecting informative measurement subsets: the original greedy algorithm and a modified version that evaluates utility at the initial calibration parameters. The modified algorithm demonstrates a significant reduction in runtime, from minutes to roughly a quarter minute, without sacrificing accuracy in both simulation and real-world experiments.
The authors provide a theoretical analysis showing the computational complexity reduction of the modified greedy algorithm compared to the original. They also conduct a sensitivity analysis to support the validity of their hypothesis regarding the insensitivity of utility to parameter estimates.
The results show that the proposed efficient greedy algorithm with utility evaluation at initial parameters can achieve sub-centimeter and sub-degree precision in extrinsic calibration while using less than 3% of the total measurements, making it suitable for resource-limited platforms.
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by Jongwon Lee,... kl. arxiv.org 09-12-2024
https://arxiv.org/pdf/2407.02232.pdfDybere Forespørgsler