利用 LSTM 模型为认知无线电应用预测频谱占用率。

IF 1.1 3区计算机科学 Q4 COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE

Network-Computation in Neural Systems Pub Date : 2024-09-30 DOI:10.1080/0954898X.2024.2393245

Tamizhelakkiya Kolangiyappan, Sabitha Gauni, Prabhu Chandhar

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引用次数: 0

摘要

近年来，移动流量预测已成为认知无线电（CR）应用中下一代蜂窝网络频谱管理相关操作的一个重要解决方案。为此，我们通过监测九个不同的长期演进（LTE）频率信道的频谱活动，从捕获的数据中创建了二进制数据集。我们提出了一种基于长短期记忆（LSTM）的频谱占用预测（SOP）方法，用于模拟基于基础设施的蜂窝通信系统。通过离线训练生成了不同类型的 LSTM 模型，如卷积模型、卷积神经网络（CNN）模型、堆叠模型和双向模型，并对创建的二进制数据集进行了测试。此外，还使用平均绝对误差（MAE）计算了生成的 LSTM 模型的预测性能评估。所生成的基于 LSTM 的 SOP 模型的预测准确率比自回归整合移动平均（ARIMA）统计模型高出 2.5%，准确地将交通趋势与实际样本相一致。

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Spectrum occupancy prediction using LSTM models for cognitive radio applications.

In recent days, mobile traffic prediction has become a prominent solution for spectrum management-related operations for the next-generation cellular networks in Cognitive Radio (CR) applications. To achieve this, the binary dataset has been created from the captured data by monitoring the spectrum activities of nine different Long Term Evolution (LTE) frequency channels. We propose a Long Short Term Memory (LSTM) based Spectrum Occupancy Prediction (SOP) approach for modelling infrastructure-based cellular traffic systems. The different types of LSTM models, such as Convolutional, Convolutional Neural Network (CNN), Stacked, and Bidirectional have been generated via offline training and tested for the created binary datasets. Moreover, the prediction performance evaluation of the generated LSTM models has been calculated using Mean Absolute Error (MAE). The pro- posed LSTM-based SOP model has achieved 2.5% higher prediction accuracy than the Auto-Regressive Integrated Moving Average (ARIMA) statistical model, accurately aligning the traffic trend with the actual samples.

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来源期刊

Network-Computation in Neural Systems 工程技术-工程：电子与电气

CiteScore

3.70

自引率

1.30%

发文量

审稿时长

>12 weeks

期刊介绍： Network: Computation in Neural Systems welcomes submissions of research papers that integrate theoretical neuroscience with experimental data, emphasizing the utilization of cutting-edge technologies. We invite authors and researchers to contribute their work in the following areas: Theoretical Neuroscience: This section encompasses neural network modeling approaches that elucidate brain function. Neural Networks in Data Analysis and Pattern Recognition: We encourage submissions exploring the use of neural networks for data analysis and pattern recognition, including but not limited to image analysis and speech processing applications. Neural Networks in Control Systems: This category encompasses the utilization of neural networks in control systems, including robotics, state estimation, fault detection, and diagnosis. Analysis of Neurophysiological Data: We invite submissions focusing on the analysis of neurophysiology data obtained from experimental studies involving animals. Analysis of Experimental Data on the Human Brain: This section includes papers analyzing experimental data from studies on the human brain, utilizing imaging techniques such as MRI, fMRI, EEG, and PET. Neurobiological Foundations of Consciousness: We encourage submissions exploring the neural bases of consciousness in the brain and its simulation in machines.