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Main Authors: Papanikolaou, Athanasios, Tziouvaras, Athanasios, Stoikos, Pavlos, Xenakis, Apostolos, Parambath, Shameem A Puthiya, Floros, George, Zereik, Enrica, Petrovic, Ivan, Bonsignorio, Fabio
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2605.08121
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author Papanikolaou, Athanasios
Tziouvaras, Athanasios
Stoikos, Pavlos
Xenakis, Apostolos
Parambath, Shameem A Puthiya
Floros, George
Zereik, Enrica
Petrovic, Ivan
Bonsignorio, Fabio
author_facet Papanikolaou, Athanasios
Tziouvaras, Athanasios
Stoikos, Pavlos
Xenakis, Apostolos
Parambath, Shameem A Puthiya
Floros, George
Zereik, Enrica
Petrovic, Ivan
Bonsignorio, Fabio
contents Early detection of plant diseases is critical for improving crop productivity, while it also facilitates the foundations of precision agriculture. Recent advances in distributed deep learning have enabled plant disease classification models to be trained across geographically distributed agricultural sensing infrastructures. However, deploying such systems in large-scale Internet of Things (IoT) environments, introduces significant challenges related to computational cost, energy consumption, and system efficiency. In this paper, we present a design-space exploration of hierarchical federated learning architectures for plant disease classification, with a particular focus on the trade-offs between predictive performance and energy efficiency. We further introduce a power- and energy-aware optimization framework that enables the systematic evaluation and selection of model-aggregator configurations under varying deployment constraints. The hierarchical federated architecture organizes distributed clients through intermediate aggregation layers, reducing communication and computational overhead. We evaluate multiple convolutional neural network architectures, including EfficientNet-B0, ResNet-50, and MobileNetV3-Large, in combination with different federated aggregation strategies such as FedAvg, FedProx, and FedAvgM. Experimental results demonstrate that different model-aggregator combinations exhibit distinct performance-energy trade-offs. Consequently, we highlight configurations that achieve competitive diagnostic accuracy and significantly reduce system resource requirements.
format Preprint
id arxiv_https___arxiv_org_abs_2605_08121
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Performance and Energy Trade-Off Analysis of Hierarchical Federated Learning for Plant Disease Classification
Papanikolaou, Athanasios
Tziouvaras, Athanasios
Stoikos, Pavlos
Xenakis, Apostolos
Parambath, Shameem A Puthiya
Floros, George
Zereik, Enrica
Petrovic, Ivan
Bonsignorio, Fabio
Distributed, Parallel, and Cluster Computing
Machine Learning
Early detection of plant diseases is critical for improving crop productivity, while it also facilitates the foundations of precision agriculture. Recent advances in distributed deep learning have enabled plant disease classification models to be trained across geographically distributed agricultural sensing infrastructures. However, deploying such systems in large-scale Internet of Things (IoT) environments, introduces significant challenges related to computational cost, energy consumption, and system efficiency. In this paper, we present a design-space exploration of hierarchical federated learning architectures for plant disease classification, with a particular focus on the trade-offs between predictive performance and energy efficiency. We further introduce a power- and energy-aware optimization framework that enables the systematic evaluation and selection of model-aggregator configurations under varying deployment constraints. The hierarchical federated architecture organizes distributed clients through intermediate aggregation layers, reducing communication and computational overhead. We evaluate multiple convolutional neural network architectures, including EfficientNet-B0, ResNet-50, and MobileNetV3-Large, in combination with different federated aggregation strategies such as FedAvg, FedProx, and FedAvgM. Experimental results demonstrate that different model-aggregator combinations exhibit distinct performance-energy trade-offs. Consequently, we highlight configurations that achieve competitive diagnostic accuracy and significantly reduce system resource requirements.
title Performance and Energy Trade-Off Analysis of Hierarchical Federated Learning for Plant Disease Classification
topic Distributed, Parallel, and Cluster Computing
Machine Learning
url https://arxiv.org/abs/2605.08121