An explainable hybrid deep learning-enabled intelligent fault detection and diagnosis approach for automotive software systems validation

TL;DR

This paper presents an explainable hybrid deep learning model for fault detection in automotive software systems, enhancing interpretability and aiding root cause analysis during real-time validation.

Contribution

It introduces a novel hybrid 1dCNN-GRU model combined with explainable AI techniques for fault diagnosis in automotive systems, improving transparency and adaptability.

Findings

Effective fault detection and localization in real-time data

Enhanced interpretability through explainable AI methods

Facilitated root cause analysis in automotive validation

Abstract

Advancements in data-driven machine learning have emerged as a pivotal element in supporting automotive software systems (ASSs) engineering across various levels of the V-development process. Duringsystemverificationandvalidation,theintegrationofanintelligent fault detection anddiagnosis (FDD) model with test recordings analysis process serves as a powerful tool for efficiency ensuring functional safety. However, the lack of interpretability of the black-box FDD models developed not only hinders understanding of the cause underlying the prediction, but also prevents the model from being adapted based on the prediction result. This, in turn, increases the computational cost required for developingacomplexFDDmodelandlimitsconfidenceinreal-timesafety-criticalapplications.To address this challenge, a novel explainable method for fault detection, identification, and localization is proposed in this article with the aim of providing a clear understanding of the logic behind the prediction outcome. To this end, a hybrid 1dCNN-GRU-based intelligent model was developed to analyze the recordings from the real-time validation process of ASSs. The employment of explainable AI techniques, i.e., IGs, DeepLIFT, Gradient SHAP, and DeepLIFT SHAP, was instrumental in enabling model adaptation and facilitating the root cause analysis (RCA). The proposed approach is applied to the real time dataset collected during a virtual test drive performed by the user on hardware in the loop system.