数字全波技术在电信信道建模中的可行性

IF 0.6 Q4 COMPUTER SCIENCE, INFORMATION SYSTEMS Journal of Communications Software and Systems Pub Date : 2020-10-08 DOI:10.24138/jcomss.v16i4.1041
Roman Novak
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引用次数: 1

摘要

在电信信道建模中,波长与感兴趣的物理特征相比很小,因此确定性光线追踪技术提供的解决方案比当前的数值全波技术更有效、更快,而且仍然在时间限制内。求解基本的麦克斯韦方程组是计算电动力学的核心,最适合于模拟与物理对象的电场相互作用,其中计算域的特征尺寸在几个波长的量级上。然而,极端的通信速度、更接近用户的无线接入点以及更小的pico和femto单元将需要更高的预测和规划无线信号的准确性,从而测试光线追踪方法的精度极限。计算能力的提高和对跨越较小地理区域的通信信道的更好表征的需求使得数字全波技术即使对于更大的问题也具有吸引力。本文探讨了克服数值全波技术对时间要求过高的方法,同时为最小的无线电单元和可能更宽的无线电单元提供可接受的信道建模精度。我们确定了几种可能导致改进通道建模的研究路径,包括适用于大规模问题的数值算法,替代有限差分方法,如无网格方法,以及专用并行硬件,可能作为数据流机器的实现。
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Viability of Numerical Full-Wave Techniques in Telecommunication Channel Modelling
In telecommunication channel modelling the wavelength is small compared to the physical features of interest, therefore deterministic ray tracing techniques provide solutions that are more efficient, faster and still within time constraints than current numerical full-wave techniques. Solving fundamental Maxwell's equations is at the core of computational electrodynamics and best suited for modelling electrical field interactions with physical objects where characteristic dimensions of a computing domain is on the order of a few wavelengths in size. However, extreme communication speeds, wireless access points closer to the user and smaller pico and femto cells will require increased accuracy in predicting and planning wireless signals, testing the accuracy limits of the ray tracing methods. The increased computing capabilities and the demand for better characterization of communication channels that span smaller geographical areas make numerical full-wave techniques attractive alternative even for larger problems. The paper surveys ways of overcoming excessive time requirements of numerical full-wave techniques while providing acceptable channel modelling accuracy for the smallest radio cells and possibly wider. We identify several research paths that could lead to improved channel modelling, including numerical algorithm adaptations for large-scale problems, alternative finite-difference approaches, such as meshless methods, and dedicated parallel hardware, possibly as a realization of a dataflow machine.
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来源期刊
Journal of Communications Software and Systems
Journal of Communications Software and Systems Engineering-Electrical and Electronic Engineering
CiteScore
2.00
自引率
14.30%
发文量
28
审稿时长
8 weeks
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