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Autores principales: Singh, Anshika, Borkotoky, Siddhartha S.
Formato: Preprint
Publicado: 2025
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Acceso en línea:https://arxiv.org/abs/2508.10574
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author Singh, Anshika
Borkotoky, Siddhartha S.
author_facet Singh, Anshika
Borkotoky, Siddhartha S.
contents Federated learning (FL) over long-range (LoRa) low-power wide area networks faces unique challenges due to limited bandwidth, interference, and strict duty-cycle constraints. We develop a Python-based simulator that integrates and extends the Flower and LoRaSim frameworks to evaluate centralized FL over LoRa networks. The simulator employs a detailed link-level model for FL update transfer over LoRa channels, capturing LoRa's receiver sensitivity, interference characteristics, block-fading effects, and constraints on the maximum transmission unit. It supports update sparsification, quantization, compression, forward frame-erasure correction (FEC), and duty cycling. Numerical results illustrate the impact of transmission parameters (spreading factor, FEC rate) and interference on FL performance. Demonstrating the critical role of FEC in enabling FL over LoRa networks, we perform an in-depth evaluation of the impact of FEC on FL convergence and device airtime, providing insights for communication protocol design for FL over LoRa networks.
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institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Federated Learning Over LoRa Networks: Simulator Design and Performance Evaluation
Singh, Anshika
Borkotoky, Siddhartha S.
Networking and Internet Architecture
Federated learning (FL) over long-range (LoRa) low-power wide area networks faces unique challenges due to limited bandwidth, interference, and strict duty-cycle constraints. We develop a Python-based simulator that integrates and extends the Flower and LoRaSim frameworks to evaluate centralized FL over LoRa networks. The simulator employs a detailed link-level model for FL update transfer over LoRa channels, capturing LoRa's receiver sensitivity, interference characteristics, block-fading effects, and constraints on the maximum transmission unit. It supports update sparsification, quantization, compression, forward frame-erasure correction (FEC), and duty cycling. Numerical results illustrate the impact of transmission parameters (spreading factor, FEC rate) and interference on FL performance. Demonstrating the critical role of FEC in enabling FL over LoRa networks, we perform an in-depth evaluation of the impact of FEC on FL convergence and device airtime, providing insights for communication protocol design for FL over LoRa networks.
title Federated Learning Over LoRa Networks: Simulator Design and Performance Evaluation
topic Networking and Internet Architecture
url https://arxiv.org/abs/2508.10574