UAS Edge Computing of Energy Infrastructure Damage Assessment

Photogrammetric Engineering & Remote Sensing Pub Date : 2023-02-01 DOI:10.14358/pers.22-00087r2

Jordan Bowman, Lexie Yang, O. Thomas, Jerry Kirk, Andrew M. Duncan, D. Hughes, Shannon Meade

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Abstract

Energy infrastructure assessments are needed within 72 hours of natural disasters, and previous data collection methods have proven too slow. We demonstrate a scalable end-to-end solution using a prototype unmanned aerial system that performs on-the-edge detection, classification (i.e., damaged or undamaged), and geo-location of utility poles. The prototype is suitable for disaster response because it requires no local communication infrastructure and is capable of autonomous missions. Collections before, during, and after Hurricane Ida in 2021 were used to test the system. The system delivered an F1 score of 0.65 operating with a 2.7 s/frame processing speed with the YOLOv5 large model and an F1 score of 0.55 with a 0.48 s/frame with the YOLOv5 small model. Geo-location uncertainty in the bottom half of the frame was ∼8 m, mostly driven by error in camera pointing measurement. With additional training data to improve performance and detect additional types of features, a fleet of similar drones could autonomously collect actionable post-disaster data.

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能源基础设施损害评估的UAS边缘计算

需要在自然灾害发生后72小时内对能源基础设施进行评估，而以前的数据收集方法被证明太慢。我们展示了一个可扩展的端到端解决方案，使用一个原型无人机系统，执行边缘检测、分类(即损坏或未损坏)和电线杆的地理定位。原型机适用于灾难响应，因为它不需要本地通信基础设施，并且能够自主执行任务。在2021年飓风艾达之前、期间和之后收集的数据被用来测试该系统。在YOLOv5大模型下，系统的F1分数为0.65，处理速度为2.7 s/帧;在YOLOv5小模型下，F1分数为0.55，处理速度为0.48 s/帧。帧下半部分的地理定位不确定性为~ 8 m，主要由相机指向测量误差引起。通过额外的训练数据来提高性能并检测其他类型的特征，一组类似的无人机可以自主收集可操作的灾后数据。

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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Photogrammetric Engineering & Remote Sensing

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