Security Challenges of Vehicular Cloud Computing

Jaydeep Thakker
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Abstract

In the realm of Industry 4.0, the utilization of artificial intelligence (AI) and machine learning for anomaly detection faces challenges due to significant computational demands and associated environmental consequences. This study aims to tackle the need for high-performance machine learning models while promoting environmental sustainability, contributing to the emerging concept of 'Green AI.' We meticulously assessed a wide range of machine learning algorithms, combined with various Multilayer Perceptron (MLP) configurations. Our evaluation encompassed a comprehensive set of performance metrics, including Accuracy, Area Under the Curve (AUC), Recall, Precision, F1 Score, Kappa Statistic, Matthews Correlation Coefficient (MCC), and F1 Macro. Concurrently, we evaluated the environmental footprint of these models by considering factors such as time duration, CO2 emissions, and energy consumption during training, cross-validation, and inference phases.   While traditional machine learning algorithms like Decision Trees and Random Forests exhibited robust efficiency and performance, optimized MLP configurations yielded superior results, albeit with a proportional increase in resource consumption. To address the trade-offs between model performance and environmental impact, we employed a multi-objective optimization approach based on Pareto optimality principles. The insights gleaned emphasize the importance of striking a balance between model performance, complexity, and environmental considerations, offering valuable guidance for future endeavors in developing environmentally conscious machine learning models for industrial applications.
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在工业 4.0 领域,利用人工智能(AI)和机器学习进行异常检测面临着巨大的计算需求和相关环境后果的挑战。本研究旨在满足对高性能机器学习模型的需求,同时促进环境的可持续发展,为新兴的 "绿色人工智能 "概念做出贡献。我们结合各种多层感知器(MLP)配置,对各种机器学习算法进行了细致的评估。我们的评估涵盖了一整套性能指标,包括准确度、曲线下面积(AUC)、召回率、精确度、F1 分数、Kappa 统计量、马修斯相关系数(MCC)和 F1 宏。与此同时,我们还通过考虑训练、交叉验证和推理阶段的时间长度、二氧化碳排放量和能源消耗等因素,评估了这些模型的环境足迹。 虽然决策树和随机森林等传统机器学习算法表现出了强大的效率和性能,但优化的 MLP 配置却产生了更优越的结果,尽管资源消耗会成正比增加。为了解决模型性能与环境影响之间的权衡问题,我们采用了基于帕累托最优原则的多目标优化方法。我们所获得的启示强调了在模型性能、复杂性和环境因素之间取得平衡的重要性,为今后为工业应用开发具有环保意识的机器学习模型提供了宝贵的指导。
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