BLOCK CHAIN-ENABLED DEEP LEARNING FRAMEWORK FOR CYBERSECURITY AND SECURE IOT DATA ANALYTICS

Swagatika Lenka; Sanjay Bajpai; Virendra Kumar Tiwari; Kavita Kanathey

doi:10.48047/rw0z6h06

Authors

Swagatika Lenka LNCT University, JK Town Sarvadharam C Sector, Kolar Road, Bhopal, Madhya Pradesh India-462024 Author
Dr. Sanjay Bajpai Lakshmi Narain College of Technology (MCA), LNCT Campus, Kalchuri Nagar, Raisen Road, P.O. Kolua, Bhopal, Madhya Pradesh, India-462022 Author
Dr. Virendra Kumar Tiwari Lakshmi Narain College of Technology (MCA), LNCT Campus, Kalchuri Nagar, Raisen Road, P.O. Kolua, Bhopal, Madhya Pradesh, India-462022 Author
Dr. Kavita Kanathey Lakshmi Narain College of Technology Excellence, Khajuri Khurd, Raisen Road, Bhopal, Madhya Pradesh, India -462022 Author

DOI:

https://doi.org/10.48047/rw0z6h06

Keywords:

Blockchain, Deep Learning, Cybersecurity, Internet of Things (IoT), Data Integrity, Federated Learning

Abstract

The proliferation of Internet of Things (IoT) devices has precipitated an unprecedented expansion of the digital attack surface, rendering traditional cybersecurity paradigms increasingly inadequate. The voluminous, high-velocity data generated by IoT ecosystems necessitates robust, intelligent analytics, yet it simultaneously introduces profound vulnerabilities related to data integrity, privacy, and single points of failure. This paper proposes a novel, integrated framework that synergizes the immutable, decentralized trust architecture of blockchain with the potent predictive capabilities of deep learning (DL) to fortify cybersecurity and secure IoT data analytics. The proposed framework leverages blockchain to establish a tamper-proof ledger for recording IoT data transactions and model parameters, thereby ensuring data provenance and auditability. Concurrently, advanced DL models, trained on this verified data stream, are deployed for real-time anomaly detection, intrusion classification, and predictive threat intelligence. This symbiosis not only enhances the security and reliability of the data fueling the analytical models but also facilitates decentralized, collaborative learning—such as federated learning—where model updates are securely aggregated and recorded on the blockchain to preserve data privacy. Our analysis delineates the architectural components, security threat mitigation mechanisms, and performance benchmarks of this hybrid paradigm, arguing that it represents a critical evolution towards resilient, transparent, and trustworthy intelligent systems for the next-generation IoT landscape.

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