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引用次数: 0
摘要
系统性能分析是第五代(5G)及以后无线通信领域的一个重要问题,被广泛用于无线通信系统部署前的设计和估算。为此,可在各种条件下使用的通用系统性能表达式具有重要意义。本文研究了广义κ - μ和η - μ衰减信道上的符号错误率(SER)性能,在这种情况下,SER表达式具有多样性,可以表征各种无线信道模型下的性能。为了解决与高阶三角积分相关的计算复杂性问题,我们提出了具有任意小误差的闭式 SER 表达式。基于蒙特卡罗的仿真证明了我们的推导和分析的有效性。模拟结果还表明1) 我们推导出的 SER 闭式解在截断因子 T 变化时误差最小,计算效率更高,其中 T 可设置为最小值以获得精确结果,或根据信道参数进行优化选择;2) 提高参数 κ、μ 和 η 的值会降低 SER,其中 μ 比 κ 和 η 的影响更大;3) 与之前的估计表达式相比,我们的近似表达式具有更高的精确度。
SER performance analysis of generalized κ — μ and η — μ fading channels
System performance analysis is a vital issue in the fifth generation (5G) and beyond wireless communications, which is widely adopted for the design and estimation of wireless communication systems before deployments. To this end, the versatile system performance expressions that can be used under various conditions are of significant importance. This paper investigates the symbol error rate (SER) performance over the generalized κ — μ and η — μ fading channels, whereby the SER expressions in this case are versatile and can characterize the performance under various wireless channel models. To address the computational complexity associated with high-order trigonometric integration, we present the closed-form SER expressions with arbitrary small errors. Monte Carlo-based simulations demonstrate the validity of our derivation and analysis. Simulation results also show that: 1) the closed-form solutions we derived for SER yield minimal errors upon variations in the truncation factor T and are computationally more efficient, in which T can be set to a minimal value to attain precise outcomes or be optimally chosen contingent on the channel parameters; 2) elevating the values of parameters κ, μ and η results in decreased SER, with μ exerting a more significant impact than κ and η; and 3) our approximate expressions have superior accuracy compared to the previous estimated expressions.
期刊介绍:
The JOURNAL OF COMMUNICATIONS AND NETWORKS is published six times per year, and is committed to publishing high-quality papers that advance the state-of-the-art and practical applications of communications and information networks. Theoretical research contributions presenting new techniques, concepts, or analyses, applied contributions reporting on experiences and experiments, and tutorial expositions of permanent reference value are welcome. The subjects covered by this journal include all topics in communication theory and techniques, communication systems, and information networks. COMMUNICATION THEORY AND SYSTEMS WIRELESS COMMUNICATIONS NETWORKS AND SERVICES.