A semantic model based on ensemble learning and attribute-based encryption to increase security of smart buildings in fog computing

Ronita Rezapour, Parvaneh Asghari, Hamid Haj Seyyed Javadi, Shamsollah Ghanbari
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Abstract

Fog computing is a revolutionary technology that, by expanding the cloud computing paradigm to the network edge, brings a significant achievement in the resource-constrained IoT applications in intelligent environments. However, security matters still challenge the extensive deployment of fog computing infrastructure. Ciphertext policy attribute-based encryption prepares a solution for data sharing and security preservation issues in fog-enhanced intelligent environments. Nevertheless, the lack of an effective mechanism to moderate the execution time of CP-ABE schemes due to the diversity of attributes used in secret key and access structure, as well as ensuring data security, practically restricts the deployment of such schemes. In this regard, a collaborative semantic model, including an outsourced CP-ABE scheme with the attribute revocation ability, together with an impressive AES algorithm relying on an ensemble learning system, was proposed in this study. The ensemble learning model uses multiple classifiers, including the GMDH, SVM, and KNN, to specify attributes corresponding to CP-ABE. The Dragonfly algorithm with a semantic leveling method generates outstanding and practical feature subsets. The experimental results on five smart building datasets indicate that the recommended model performs more accurately than existing methods. Also, the encryption, decryption, and attribute revocation execution time are significantly modified with the average time of 1.95, 2.11, and 14.64 ms, respectively, compared to existing works and conducted the scheme’s security.

Abstract Image

基于集合学习和属性加密的语义模型,提高雾计算中智能建筑的安全性
雾计算是一项革命性技术,它将云计算模式扩展到网络边缘,为智能环境中资源受限的物联网应用带来了重大成就。然而,安全问题仍然是广泛部署雾计算基础设施所面临的挑战。基于密文策略属性的加密为雾增强智能环境中的数据共享和安全保护问题提供了解决方案。然而,由于密钥和访问结构中使用的属性多种多样,CP-ABE 方案缺乏有效的机制来控制执行时间,同时也无法确保数据安全,这实际上限制了此类方案的部署。为此,本研究提出了一种协作语义模型,包括一种具有属性撤销能力的外包 CP-ABE 方案,以及一种依赖于集合学习系统的令人印象深刻的 AES 算法。集合学习模型使用多个分类器,包括 GMDH、SVM 和 KNN,来指定与 CP-ABE 相对应的属性。采用语义分层方法的蜻蜓算法可生成优秀实用的特征子集。在五个智能建筑数据集上的实验结果表明,推荐模型的性能比现有方法更精确。同时,与现有方法相比,加密、解密和属性撤销的执行时间也有了明显改善,平均时间分别为 1.95、2.11 和 14.64 毫秒,并保证了方案的安全性。
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