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dc.contributor.authorDogani, Javad 
dc.contributor.authorNamvar, Reza 
dc.contributor.authorKhodarahmi, Masoumeh 
dc.contributor.authorKhunjush, Farshad
dc.contributor.authorLaoutaris, Nikolaos 
dc.date.accessioned2026-07-15T12:20:23Z
dc.date.available2026-07-15T12:20:23Z
dc.date.issued2026-07-06
dc.identifier.citationhttps://ieeexplore.ieee.org/abstract/document/11595484es
dc.identifier.issn1536-1233es
dc.identifier.urihttps://hdl.handle.net/20.500.12761/2053
dc.description.abstractFederated Learning (FL) enables collaborative model training across edge devices but faces challenges balancing energy consumption, heterogeneous resources, and accuracy in IoT ecosystems. Existing solutions often overlook adaptive coordination of computation and communication or depend on hardware-level adjustments unavailable on constrained devices. We propose FLEAT (Federated Learning Energy and Accuracy Tuning), a framework that jointly optimizes energy efficiency and model accuracy via dynamic local update adaptation and gradient-informed layer-wise pruning. FLEAT introduces a theoretical error bound for synchronous FL under these mechanisms and employs an energy-aware optimization loop to allocate per-device computation/communication time. By scaling local updates to device capabilities and pruning redundant layers based on parameter importance, FLEAT mitigates stragglers, reduces communication overhead, and stabilizes convergence via normalized gradient aggregation. We evaluate FLEAT in both real-world IoT deployments and simulated edge networks. At a fixed wall-clock budget, FLEAT achieves a higher convergence rate-reaching higher accuracy earlier-than FedAvg, FedProx, and FedNova; when all methods train to completion, it remains within 1.2-3.1% of FedAvg's final accuracy while cutting total energy by 16.2%. Relative to existing studies, FLEAT matches or surpasses their accuracy while strictly lowering energy, owing to its joint tuning of local steps and pruning under an energyaware objective. This work bridges model- and system-level optimizations, offering a scalable solution for energy-accuracy equilibrium in heterogeneous FL deployments.es
dc.language.isoenges
dc.publisherIEEEes
dc.titleFLEAT: Energy-Accuracy Trade-off in Federated Learning over Heterogeneous Edge Deviceses
dc.typejournal articlees
dc.journal.titleIEEE Transactions on Mobile Computinges
dc.type.hasVersionAMes
dc.rights.accessRightsopen accesses
dc.identifier.doi10.1109/TMC.2026.3710334es
dc.page.initial1-14es
dc.subject.keywordFederated Learninges
dc.subject.keywordInternet of Things (IoT)es
dc.subject.keywordEnergy-Accuracy Equilibriumes
dc.description.refereedTRUEes
dc.description.statuspubes


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