CORRELATION FUNCTIONS AND QUASI-DETERMINISTIC SIGNALS

Nadezhda Cheremska
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Abstract

When processing data on random functions, they are most often limited to constructing an empirical correlation function. In this regard, the problem arises of constructing a random function (a quasi-deterministic signal) determined by a finite set of random variables and having a given correlation function. Moreover, a random function can often be considered Gaussian, since in many cases a random signal is obtained at the output of the system, which is fairly well approximated by a Gaussian. For stationary random processes and for random fields, this problem has been considered. For random sequences and discrete random fields, as well as for non-stationary random signals, the problem remained open. The article considers the problem of restoring a random sequence from known mathematical expectation and correlation function. Such a model random sequence is constructed, in which the mathematical expectation and correlation function coincide with the given ones. The mathematical expectation and the correlation function are the simplest probabilistic numerical characteristics, but they do not uniquely determine the corresponding set of probability distribution densities that satisfy the conditions of normalization and consistency, provided that for each fixed integer value of the parameter, the random sequence is a continuous random variable. The article considers the restoration of a quasi-deterministic signal in stationary and non-stationary cases. For the stationary case, three examples are given for constructing a quasi-deterministic discrete signal EMBED Equation.DSMT4 , provided that the spectral density has three different forms. For the non-stationary case, the corresponding quasi-deterministic signal was obtained for various cases of the spectrum. The use of a random function model determined by a finite number of parameters makes it possible to significantly simplify the analysis of applied problems, the solution of which is associated with differential equations with random coefficients, which are such quasi-deterministic signals. In this case, there is no need to use a complex apparatus of stochastic differential equations, since the solution of such an equation simply depends on random variables as on parameters.
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相关函数与准确定性信号
当处理随机函数上的数据时,它们通常仅限于构造经验相关函数。在这方面,问题出现了构造一个随机函数(准确定性信号)由一组有限的随机变量决定,并具有给定的相关函数。此外,随机函数通常可以被认为是高斯函数,因为在许多情况下,在系统的输出处获得随机信号,这可以很好地近似于高斯函数。对于平稳随机过程和随机场,我们考虑了这个问题。对于随机序列和离散随机场,以及非平稳随机信号,这个问题仍然没有解决。本文研究了从已知的数学期望和相关函数中恢复随机序列的问题。构造了一个数学期望和相关函数与给定的数学期望和相关函数一致的模型随机序列。数学期望和相关函数是最简单的概率数值特征,但它们并不能唯一地确定相应的满足归一化和一致性条件的概率分布密度集合,前提是对于参数的每一个固定整数值,随机序列是连续随机变量。本文研究了准确定性信号在平稳和非平稳情况下的恢复问题。对于平稳情况,给出了拟确定离散信号嵌入方程的三个构造实例。DSMT4,假设谱密度有三种不同的形式。对于非平稳情况,得到了各种情况下的准确定性信号。使用由有限数量的参数决定的随机函数模型,可以大大简化应用问题的分析,这些问题的解与具有随机系数的微分方程有关,这些微分方程是准确定性信号。在这种情况下,没有必要使用复杂的随机微分方程装置,因为这种方程的解只取决于随机变量,而不是参数。
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