Privacy-Preserving Federated Learning for Distributed Financial IoT: A Blockchain-Based Framework for Secure Cryptocurrency Market Analytics
Kuznetsov O. Adilzhanova S. Florov S. Bushkov V. Peremetchyk D.
December 2025Multidisciplinary Digital Publishing Institute (MDPI)
IoT
2025#6Issue 4
The proliferation of Internet of Things (IoT) devices in financial markets has created distributed ecosystems where cryptocurrency exchanges, trading platforms, and market data providers operate as autonomous edge nodes generating massive volumes of sensitive financial data. Collaborative machine learning across these distributed financial IoT nodes faces fundamental challenges: institutions possess valuable proprietary data but cannot share it directly due to competitive concerns, regulatory constraints, and trust management requirements in decentralized networks. This study presents a privacy-preserving federated learning framework tailored for distributed financial IoT systems, combining differential privacy with Shamir secret sharing to enable secure collaborative intelligence across blockchain-based cryptocurrency trading networks. We implement per-layer gradient clipping and Rényi differential privacy composition to minimize utility loss while maintaining formal privacy guarantees in edge computing scenarios. Using 5.6 million orderbook observations from 11 cryptocurrency pairs collected across distributed exchange nodes, we evaluate three data partitioning strategies simulating realistic heterogeneity patterns in financial IoT deployments. Our experiments reveal that federated edge learning imposes 9–15 percentage point accuracy degradation compared to centralized cloud processing, driven primarily by data distribution heterogeneity across autonomous nodes. Critically, adding differential privacy (ε = 3.0) and cryptographic secret sharing increases this degradation by less than 0.3 percentage points when mechanisms are calibrated appropriately for edge devices. The framework achieves 62–66.5% direction accuracy on cryptocurrency price movements, with confidence-based execution generating 71–137 basis points average profit per trade. These results demonstrate the practical viability of privacy-preserving collaborative intelligence for distributed financial IoT while identifying that the federated optimization gap dominates privacy mechanism costs. Our findings offer architectural insights for designing trustworthy distributed systems in blockchain-enabled financial IoT ecosystems.
Blockchain , cryptocurrency , decentralized finance , differential privacy , distributed systems , federated learning , financial IoT , internet of things , privacy-preserving computing , secure aggregation , trust management
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Department of Theoretical and Applied Sciences, eCampus University, Via Isimbardi 10, CO, Novedrate, 22060, Italy
Department of Intelligent Software Systems and Technologies, School of Computer Science and Artificial Intelligence, Karazin Kharkiv National University, 4 Svobody Sq., V.N, Kharkiv, 61022, Ukraine
Department of Cybersecurity and Cryptology, Al-Farabi Kazakh National University, 71 Al-Farabi Ave., Almaty, 050040, Kazakhstan
Department of Cybersecurity and Information Technologies, University of Customs and Finance, Vernadskogo str., 2/4, Dnipro, 49000, Ukraine
Department of Software Engineering and Cybersecurity, State University of Trade and Economics, 19 Kyoto str., Kyiv, 02156, Ukraine
Department of Theoretical and Applied Sciences
Department of Intelligent Software Systems and Technologies
Department of Cybersecurity and Cryptology
Department of Cybersecurity and Information Technologies
Department of Software Engineering and Cybersecurity
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