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Autori principali: Corlay, Vincent, Nakazato, Tatsuya, Yamaguchi, Kanako, Nakajima, Akinori
Natura: Preprint
Pubblicazione: 2024
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Accesso online:https://arxiv.org/abs/2412.00328
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author Corlay, Vincent
Nakazato, Tatsuya
Yamaguchi, Kanako
Nakajima, Akinori
author_facet Corlay, Vincent
Nakazato, Tatsuya
Yamaguchi, Kanako
Nakajima, Akinori
contents The advent of deep learning and recurrent neural networks revolutionized the field of time-series processing. Therefore, recent research on spectrum prediction has focused on the use of these tools. However, spectrum prediction, which involves forecasting wireless spectrum availability, is an older field where many "classical" tools were considered around the 2010s, such as Markov models. This work revisits high-order Markov models for spectrum prediction in dynamic wireless environments. We introduce a framework to address mismatches between sensing length and model order as well as state-space complexity arising with large order. Furthermore, we extend this Markov framework by enabling fine-tuning of the probability transition matrix through gradient-based supervised learning, offering a hybrid approach that bridges probabilistic modeling and modern machine learning. Simulations on real-world Wi-Fi traffic demonstrate the competitive performance of high-order Markov models compared to deep learning methods, particularly in scenarios with constrained datasets containing outliers.
format Preprint
id arxiv_https___arxiv_org_abs_2412_00328
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Differentiable High-Order Markov Models for Spectrum Prediction
Corlay, Vincent
Nakazato, Tatsuya
Yamaguchi, Kanako
Nakajima, Akinori
Signal Processing
Machine Learning
The advent of deep learning and recurrent neural networks revolutionized the field of time-series processing. Therefore, recent research on spectrum prediction has focused on the use of these tools. However, spectrum prediction, which involves forecasting wireless spectrum availability, is an older field where many "classical" tools were considered around the 2010s, such as Markov models. This work revisits high-order Markov models for spectrum prediction in dynamic wireless environments. We introduce a framework to address mismatches between sensing length and model order as well as state-space complexity arising with large order. Furthermore, we extend this Markov framework by enabling fine-tuning of the probability transition matrix through gradient-based supervised learning, offering a hybrid approach that bridges probabilistic modeling and modern machine learning. Simulations on real-world Wi-Fi traffic demonstrate the competitive performance of high-order Markov models compared to deep learning methods, particularly in scenarios with constrained datasets containing outliers.
title Differentiable High-Order Markov Models for Spectrum Prediction
topic Signal Processing
Machine Learning
url https://arxiv.org/abs/2412.00328