Combinatorial Coverage for Assured Autonomy

2022 IEEE International Symposium on Software Reliability Engineering Workshops (ISSREW) Pub Date : 2022-10-01 DOI:10.1109/ISSREW55968.2022.00092

D. Kuhn, M. Raunak, R. Kacker

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Abstract

With the advancement of Artificial Intelligence and Ma-chine Learning (AI/ML), we are observing a rapid increase of autonomous systems in safety-critical domains, such as smart medical equipment, self-driving vehicles, and unmanned aircraft. These systems are required to be made ultra reliable using state of the art verification and validation methodologies. Existing verification, validation, and assurance efforts, such as DO-178C guidance for avionics software, depend on structural coverage based testing, such as MC/DC coverage. Such structural coverage criteria require that test cases are chosen to ensure that a specified level of statements, decisions, and paths are systematically exercised. Neural network and other machine learning based systems, however, are not well suited to be tested with such structural coverage dependent criteria [1], [2]. This is because the performance of machine learning functions such as neural networks depends on the data used to train and test the model, rather than in specifically coded behavior. Behaviors of such systems will change depending on inputs used in the training.

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保证自治的组合覆盖

随着人工智能和机器学习(AI/ML)的进步，我们看到在安全关键领域(如智能医疗设备、自动驾驶汽车和无人驾驶飞机)的自主系统迅速增加。这些系统需要使用最先进的验证和验证方法来实现超可靠。现有的验证、确认和保证工作，例如航空电子软件的DO-178C指导，依赖于基于测试的结构覆盖，例如MC/DC覆盖。这种结构覆盖标准要求选择测试用例，以确保系统地执行指定级别的语句、决策和路径。然而，神经网络和其他基于机器学习的系统并不适合用这种结构覆盖依赖标准进行测试[1]，[2]。这是因为神经网络等机器学习功能的性能取决于用于训练和测试模型的数据，而不是特定编码的行为。这种系统的行为将根据训练中使用的输入而改变。

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2022 IEEE International Symposium on Software Reliability Engineering Workshops (ISSREW)

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