利用递归神经模糊模型实现认知集成系统中卫星-地面混合网络的流量卸载和资源分配

IF 0.9 4区 计算机科学 Q3 ENGINEERING, AEROSPACE International Journal of Satellite Communications and Networking Pub Date : 2024-07-04 DOI:10.1002/sat.1530
Manish Kumar Mishra, Ritesh Kumar Mishra
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引用次数: 0

摘要

摘要近年来,对高速、可靠通信网络的需求急剧增长。为满足这一需求,研究人员和工程师们一直在探索结合卫星和地面网络优势的创新解决方案。精确建模和预测动态网络条件以优化资源分配和保持无缝连接的复杂性。这项工作的目标是开发和实施一个循环神经模糊模型(RNFM),用于优化认知集成系统中卫星-地面混合网络的流量卸载和资源分配。这项工作从采用频谱共享技术的认知集成混合卫星-地面网络开始。这些技术与软件定义网络(SDN)相结合,促进了混合星地网络(H-STN)中的流量卸载。该过程采用第二价格密封投标拍卖机制来有效分配资源。然后使用两种凸优化方法对联合资源分配进行优化。这种分配反过来又为资源分配策略提供依据。该系统还进一步结合了用户行为分析,并采用了带有深度前馈神经网络的循环神经模糊模型,以提高整个流程的准确性和效率。MATLAB 仿真结合了自适应学习算法和模糊逻辑,可动态管理网络资源并提高系统效率。研究结果表明,所提出的技术优于一步预测算法和多步预测算法,准确率提高了 99.23%。这项研究的未来发展方向是将强化学习等先进的机器学习算法与递归神经模糊模型相结合,在日益复杂和异构的卫星-地面网络环境中进一步加强动态流量卸载和资源分配。
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Traffic offloading and resource allocation enabled hybrid satellite-terrestrial networks in cognitive integrated systems using a recurrent neuro-fuzzy model

In recent years, the demand for high-speed and reliable communication networks has grown exponentially. To meet this demand, researchers and engineers have been exploring innovative solutions that combine the benefits of both satellite and terrestrial networks. The complexity of accurately modeling and predicting dynamic network conditions to optimize resource distribution and maintain seamless connectivity. The objective of this work is to develop and implement a recurrent neuro-fuzzy model (RNFM)for optimizing traffic offloading and resource allocation in hybrid satellite-terrestrial networks within cognitive integrated systems. This work, begins with cognitive integrated hybrid satellite-terrestrial networks employing spectrum-sharing techniques. These techniques integrate with software-defined networks (SDN) to facilitate traffic offloading in hybrid satellite-terrestrial networks (H-STN). The process incorporates a second-price sealed-bid auction mechanism to efficiently allocate resources. Joint resource allocation is then optimized using two convex optimization methods. This allocation, in turn, informs the resource allocation strategy. The system further incorporates user behavior analysis and employs a recurrent neuro-fuzzy model with deep feed-forward neural networks to enhance the accuracy and efficiency of the entire process. MATLAB simulation that incorporates adaptive learning algorithms and fuzzy logic to dynamically manage network resources and improve system efficiency. The findings show that the proposed technique outperforms both one-step and multi-step prediction algorithms with an accuracy increase of 99.23%. The future scope for this research is to integrate advanced machine learning algorithms, such as reinforcement learning, with the recurrent neuro-fuzzy model to further enhance dynamic traffic offloading and resource allocation in increasingly complex and heterogeneous satellite-terrestrial network environments.

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来源期刊
CiteScore
4.10
自引率
5.90%
发文量
31
审稿时长
>12 weeks
期刊介绍: The journal covers all aspects of the theory, practice and operation of satellite systems and networks. Papers must address some aspect of satellite systems or their applications. Topics covered include: -Satellite communication and broadcast systems- Satellite navigation and positioning systems- Satellite networks and networking- Hybrid systems- Equipment-earth stations/terminals, payloads, launchers and components- Description of new systems, operations and trials- Planning and operations- Performance analysis- Interoperability- Propagation and interference- Enabling technologies-coding/modulation/signal processing, etc.- Mobile/Broadcast/Navigation/fixed services- Service provision, marketing, economics and business aspects- Standards and regulation- Network protocols
期刊最新文献
Issue Information Design and Implementation of Transparent Cross-Polarization Interference Compensation in a Wideband Dual-Polarization Satellite Receiver Deeper dive into interoperability and its implications for LunaNet communications and navigation services Issue Information A decade of EHF scientific research: Unveiling insights from Alphasat Q/V‐band satellite communication experiments
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