Game Theory Empowered Carbon-Intelligent Federated Multi-Edge Caching for Industrial Internet of Things

Liang, Jie and Yu, Zhengxin and Pervaiz, Haris and Zheng, Guhan and Suri, Neeraj (2025) Game Theory Empowered Carbon-Intelligent Federated Multi-Edge Caching for Industrial Internet of Things. IEEE Internet of Things Journal, 12 (17). pp. 34875-34889. ISSN 2327-4662

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Abstract

To navigate the carbon emission and functional challenges associated with edge caching within heterogeneous Industrial Internet of Things (IIoT) spanning energy use, cache hit rate, and bandwidth usage, this paper proposes a novel Game Theory Empowered Carbon-Intelligent Federated Multi-Edge Caching framework (GT-FMC). The proposed framework enables distributed collaborative caching by intelligently coordinating edge nodes to optimize content decisions while efficiently integrating content providers (CPs), edge nodes, and users with energy-aware strategies. In GT-FMC, a lightweight federated content popularity prediction method based on Temporal Convolutional Networks (TCN) is introduced to collaboratively learn global content popularity while reducing prediction energy cost. The energy-aware utilities of the three involved parties are jointly formulated as a coupled non-linear optimization problem. To address this challenge, a two-stage game-theoretic algorithm is designed. Experimental results on a real-world testbed show that GT-FMC achieves up to 77.9% of Oracle in cache hit rate and 10.6%–32.4% reduction in transmission energy consumption compared to baseline methods. Complementary evaluations also validate the game-theoretic design’s effectiveness.