Time domain self-correlation Nakagami-m fading complex channel simulation method

A simulation method and autocorrelation technology, applied in transmission monitoring, electrical components, transmission systems, etc., can solve the problem that the probability density distribution, cumulative distribution function and second-order statistical characteristics of the first-order statistical characteristics cannot be satisfied at the same time. Fading time, time domain autocorrelation function, etc., to achieve the effect of good scalability and low complexity

Active Publication Date: 2016-08-10
XIDIAN UNIV
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Problems solved by technology

[0003] The purpose of the present invention is to provide a time-domain autocorrelation Nakagami-m fading complex channel simulation method, aiming to solve the problem that the existing simulation method cannot satisfy the first-order statistical characteristic probability density distribution, cumulative distribution function and second-order statistical statistics at the same time Problems with characteristic level pass rate, average fading time, and time-domain autocorrelation function

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  • Time domain self-correlation Nakagami-m fading complex channel simulation method
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  • Time domain self-correlation Nakagami-m fading complex channel simulation method

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[0040] In order to make the object, technical solution and advantages of the present invention more clear, the present invention will be further described in detail below in conjunction with the examples. It should be understood that the specific embodiments described here are only used to explain the present invention, not to limit the present invention.

[0041] The application principle of the present invention will be described in detail below in conjunction with the accompanying drawings.

[0042] Such as figure 1 As shown, given m=5, Ω=1, N=10 6 The specific implementation scheme of the time-domain autocorrelation Nakagami-m fading complex channel simulation is as follows:

[0043] S1 uses superposition of sinusoids (SoS) model to generate autocorrelation Rayleigh sequence R Ray1 (k) and The root sequence sum R of the autocorrelation Rayleigh sum of squares Ray2 (k); The specific implementation of the embodiment of the present invention is as follows:

[0044] S1....

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Abstract

The invention discloses a time domain self-correlation Nakagami-m fading complex channel simulation method, which comprises the steps of: firstly, carrying out independent simulation on envelope distribution, so that a probability density function and a cumulative distribution function of envelopes are consistent with theoretical values; secondly, carrying out independent simulation on phase distribution, so that statistical indexes of a probability density function and a cumulative distribution function of phases are consistent with theoretical values; then ranking an envelope sequence and a phase sequence, so that a self-correlation function and a power spectral density are consistent with theoretical values; and finally, superposing the ranked envelope sequence and phase sequence to obtain a time domain self-correlation Nakagami-m fading complex channel random sequence satisfying all simulation performance evaluation statistics. The time domain self-correlation Nakagami-m fading complex channel simulation method realizes good self-correlation characteristic fading simulation and fast fading simulation of a time domain self-correlation Nakagami-m fading complex channel, has good extensibility, and brings convenience for subsequent adoption of a more efficient module simulation algorithm.

Description

technical field [0001] The invention belongs to the technical field of wireless communication channel modeling and simulation, in particular to a time-domain autocorrelation Nakagami-m fading complex channel simulation method. Background technique [0002] In the wireless mobile communication environment, Nakagami-m fading can characterize small-scale fading better and more widely than traditional Rayleigh distribution or Rice distribution. Nakagami-m fading is obtained by fitting the experimental data with the density function of the variable parameter gamma distribution, and its main parameters are the shape factor m and the average power Ω of the received signal. By changing the shape factor m, the channel environment from severe, moderate, slight to no fading can be simulated, including Rayleigh distribution and Rice distribution. Time-domain autocorrelation channel simulation needs to consider the correlation characteristics of the channel, and pay attention to the pro...

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Application Information

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Patent Type & Authority Applications(China)
IPC IPC(8): H04B17/391
CPCH04B17/3911H04B17/3912
Inventor 石磊边志耀刘彦明郭振李小平
Owner XIDIAN UNIV
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