Understanding Bounding Functions in Safety-Critical UAV Software

2021 IEEE/ACM 43rd International Conference on Software Engineering (ICSE) Pub Date : 2021-02-13 DOI:10.1109/ICSE43902.2021.00119

Xiaozhou Liang, John Henry Burns, Joseph Sanchez, Karthik Dantu, Lukasz Ziarek, Yu David Liu

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引用次数: 1

Abstract

Unmanned Aerial Vehicles (UAVs) are an emerging computation platform known for their safety-critical need. In this paper, we conduct an empirical study on a widely used open-source UAV software framework, Paparazzi, with the goal of understanding the safety-critical concerns of UAV software from a bottom-up developer-in-the-field perspective. We set our focus on the use of Bounding Functions (BFs), the runtime checks injected by Paparazzi developers on the range of variables. Through an in-depth analysis on BFs in the Paparazzi autopilot software, we found a large number of them (109 instances) are used to bound safety-critical variables essential to the cyber-physical nature of the UAV, such as its thrust, its speed, and its sensor values. The novel contributions of this study are two fold. First, we take a static approach to classify all BF instances, presenting a novel datatype-based 5-category taxonomy with fine-grained insight on the role of BFs in ensuring the safety of UAV systems. Second, we dynamically evaluate the impact of the BF uses through a differential approach, establishing the UAV behavioral difference with and without BFs. The two-pronged static and dynamic approach together illuminates a rarely studied design space of safety-critical UAV software systems.

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理解安全关键型无人机软件中的边界函数

无人驾驶飞行器(uav)是一种新兴的计算平台，以其安全需求而闻名。在本文中，我们对广泛使用的开源无人机软件框架Paparazzi进行了实证研究，目的是从自下而上的开发人员在现场的角度理解无人机软件的安全关键问题。我们将重点放在边界函数(Bounding Functions, BFs)的使用上，即狗仔队开发人员在变量范围上注入的运行时检查。通过对Paparazzi自动驾驶软件中的BFs进行深入分析，我们发现大量BFs(109个实例)用于绑定对无人机网络物理性质至关重要的安全关键变量，例如其推力，速度和传感器值。这项研究的新贡献有两个方面。首先，我们采用静态方法对所有BF实例进行分类，提出了一种新的基于数据类型的5类分类法，并对BF在确保无人机系统安全方面的作用进行了细粒度的洞察。其次，通过差分方法动态评估BF使用的影响，建立有BF和无BF的无人机行为差异。静态和动态双管齐下的方法共同阐明了一个很少研究安全关键型无人机软件系统的设计空间。

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

2021 IEEE/ACM 43rd International Conference on Software Engineering (ICSE)

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