RU201281U1 - Device for estimating the parameters of superposition of two exponential distributions - Google Patents

Abstract

The proposed technical solution relates to devices for determining the characteristics of random processes. It is advisable to use it when studying the characteristics of gas-discharge matrix indicators. The proposed device contains a memory unit, a unit for calculating moments, a unit for calculating distribution parameters, an indication unit, and a control unit. The distribution parameters are estimated by solving a system of three equations representing the equalities of the first, second and third initial or central moments of a random variable described by the sum of two exponential distributions, and the corresponding experimental estimates of these moments. distributions that uniquely characterize the process under study with the required accuracy.

Description

The proposed technical solution relates to devices for determining the characteristics of random processes and is designed to calculate the parameters of the superposition of two exponential distributions. It is advisable to use it when studying the characteristics of gas-discharge matrix indicators.

Known devices for evaluating the parameters of gas-discharge indicators, which allow you to measure (register) random values of the ignition delay time of display elements, store these values in memory and then calculate the necessary characteristics (for example, Sviyazov A.A., Soldatov V.V. Automated scientific research devices parameters of gas-discharge sign-synthesizing indicators of direct current.Vestnik RGRTU, Issue 24, Ryazan. 2008; SI Lavrentyev, Shesterkin AN Device for determining the densities of determining the ignition delay time of display elements of gas-discharge indicators.Electronic engineering, Series 4 - Electrovacuum and gas-discharge devices, Issue 3 (98), 1983). The structure of these devices assumes that the random values of the delay times are distributed according to the exponential law and therefore only a single distribution parameter is required to be determined, i.e. devices have limited capabilities. This is a disadvantage of analogs.

Closest to the claimed technical solution is a device (USSR author's certificate No. 1520545 Device for determining the distribution law, prototype), in which the distribution parameters are assessed on the basis of moments. This device contains a memory unit, a unit for calculating distribution moments, a unit for calculating distribution parameters, an indication unit, a synchronizer (hereinafter referred to as a control unit), the first and second outputs of which are connected, respectively, to the control input of the memory unit and the first control input of the unit for calculating distribution parameters, its second the control input is connected to the input of the device.

In the device adopted as a prototype, the calculation of the distribution parameters is performed in two stages. At the first stage, two distribution parameters are calculated from a system of equations containing estimates of the moments of the distribution of a random variable, a set of a priori (assumed) probability values that determine a certain distribution, and the coordinates of the midpoints of the approximation intervals for the corresponding values of a priori probabilities (system of equations 10 of the prototype). For this, on the basis of preliminary research, it is necessary to establish the permissible minimum and maximum values for both sought parameters. At the second stage, on the basis of two previously found parameters, a set of a priori values of the probabilities and coordinates of the midpoints of the approximation intervals for the corresponding values of a priori probabilities, the third parameter is calculated. Thus, to determine the distribution parameters, in addition to the array of random values, on the basis of which the distribution moments are calculated, knowledge of the set of a priori distribution probabilities and the domain of determination of the distribution parameters is required. The equations for determining the distribution parameters include a set of values of a priori probabilities and, accordingly, the same number of coordinates of the midpoints of the approximation intervals. Since the reliable assignment of the a priori distribution requires a large number (up to several tens) of the values of a priori probabilities, and, as indicated in the prototype, the accuracy of their assignment significantly affects the error of the determined parameters, the procedure for calculating the distribution parameters in the known device is rather complicated and cumbersome.

In addition, the purpose of statistical processing of random values is to identify influencing factors, relationships between them and patterns that govern random events, etc. In the known device (prototype), the calculated distribution parameters are summed up, and the result is used as some exponent. It is practically impossible to interpret each calculated distribution parameter and evaluate its influence on the process under study, especially for nonparametric statistics (free from distributions), in the known device.

To describe the distribution of the delay time of the discharge of gas-discharge matrix indicators in a number of cases (Shesterkin A.N. Determination of the ignition reliability of the display element of a gas-discharge matrix indicator. Bulletin of the RGRTU. Issue 61. Ryazan. 2017) use the superposition of two exponential distributions (hyperexponential distribution)

- математическое ожидание времени запаздывания зажигания. Коэффициенты с_1; с₂ характеризуют вклад каждого из эффектов в зажигание элемента отображения. В дальнейшем с_г будем обозначать как с₁ а с₂ - 1-с. Суперпозиция экспоненциальных распределений используется также в теории надежности при описании времени возникновения отказов.Here, τ is a random variable (the delay time of the discharge occurrence), λ ₁ is the ignition intensity due to the self-ignition of the display element (without "illumination"), λ ₂ is the ignition intensity of the element due to the influence of its combustion in the previous excitation cycle (due to the "illumination "). Ignition intensity

is the mathematical expectation of the ignition delay time. Odds from _1; c ₂ characterize the contribution of each of the effects to the ignition of the display element. In what follows, _c will be denoted as c ₁ a c ₂ - 1-c. The superposition of exponential distributions is also used in reliability theory to describe the time of failure.

Calculation of reliability indicators based on distribution (1) assumes knowledge of distribution parameters λ ₁ , λ ₂ , p. The author is not aware of the methods and devices for determining these parameters based on some theoretical premises or on the basis of experimental random values. Calculation of distribution parameters is possible by solving a system of equations containing these (unknown) parameters and some characteristics of the distribution, which should be determined based on measured random values (for example, lag time).

The determination of three unknown parameters is possible by solving a system of three equations. Such systems of equations can be composed of the equalities of the first, second and third initial or central moments corresponding to the estimates of these moments:

- оценка первого начального (центрального) момента, оценка математического ожидания;

- оценки второго и третьего начальных моментов;

- оценки второго и третьего центральных моментов,

- оценка дисперсии. Левые части уравнений (2) - начальные, а уравнений (3) - центральные моменты суперпозиции двух экспоненциальных распределений.In these equations:

- evaluation of the first initial (central) moment, evaluation of the mathematical expectation;

- estimates of the second and third initial moments;

- estimates of the second and third central moments,

- variance estimation. The left-hand sides of equations (2) are initial, and equations (3) are the central moments of the superposition of two exponential distributions.

If the random variable takes values τ _i (i = 1, 2,… n), then the estimates of the moments are calculated by the formulas:

The solution of the systems of equations (2) or (3) makes it possible to find the parameters of the superposition of two exponential distributions, which uniquely characterize random processes, in particular, those occurring during the ignition of display elements in gas-discharge indicators. The accuracy of the calculation of these parameters is mainly determined by the error in the estimates of the moments of distribution, which depends, first of all, on the number of elements of the sample, on the basis of which the estimates are determined.

The purpose of the proposed technical solution is to determine the set of parameters of the superposition of two exponential distributions that characterize the investigated random process.

For this purpose, in the proposed device, the information inputs of the device are connected to the information inputs of the memory unit, and its outputs to the input of the control unit and the information input of the moment calculation unit, the outputs of the calculation results of the first, second and third moments of which are connected to the corresponding inputs of the distribution parameters calculation unit, which decides a system of three equations representing the equalities of the first, second, and third initial or central moments of a random variable described by the sum of two exponential distributions, and the corresponding experimental estimates of these moments. The outputs of the block for calculating the distribution parameters are connected to the information inputs of the display unit. The third and fourth outputs of the control unit are connected, respectively, to the control inputs of the torque calculation unit and the display unit. The input of the control unit is the control input of the device.

A functional diagram of a device for estimating the parameters of the superposition of two exponential distributions is shown in Fig. The device contains memory blocks 1, calculation of distribution moments 2, calculation of distribution parameters 3, indication 4 and control 5.

The device operates sequentially in three modes: registering random values of the process under study, calculating estimates of the initial or central moments and determining the distribution parameters and displaying them. A sequential change in operating modes is carried out by signals of the control unit 5, arriving at the control inputs of memory units 1, calculating distribution moments 2, calculating distribution parameters 3 and displaying 4.

Registration of random values of the process under study begins when the "Start" signal is generated. In this case, a signal is sent to the control input of the memory unit 1 from the control unit 5, which sets the memory unit 1 to its initial state and allows the recording of random values supplied to the information inputs of the device. Since the frequency of receipt of random values, their number can differ significantly from study to study, i.e. the time of writing data to the memory unit 1 can vary significantly, then in the proposed device at the additional output of the memory unit 1 a signal is generated indicating the end of data recording. On its basis, the control unit 6 generates a signal that transfers the device to the second mode: the calculation by unit 2 of the estimates of the initial or central moments.

The device switches to the third mode of operation when a signal is generated at the second output of the control unit 6, which arrives at the first control input of block 3. By this time, the estimates of the moments are calculated, and at the second control input of block 3, the initial values are set, which may be required to solve the systems of equations (2) or (3). The need for these settings is due to the fact that for solving equations, as a rule, by iterative methods, it is required to set the initial values of the parameters, the calculation accuracy or the number of iterations. The time for calculating the estimates of the distribution moments by block 2, as well as the distribution parameters by block 3, are practically constant and can be set in advance, therefore the operating time of these blocks is determined by the control signals of the control unit 5 (without feedback).

At the end of the calculations, the found values of the distribution parameters are reproduced by the display unit 5. The absence of a control signal at the input of this unit until the end of the calculations does not allow displaying the values of the parameters that change during the calculations.

Blocks 1-4 can be implemented according to any of the known structures. The control unit 5 is a classic timing circuit.

The reliability of calculating the parameters of the superposition of two exponential distributions using the proposed technical solution was verified by modeling in the MathCAD environment. For some initial distribution parameters λ ₁ , λ ₂ , s, an array of random values was generated, the elements of which correspond to the superposition of two exponential distributions, the numerical characteristics of the distribution were calculated: estimates of the first, second, and third initial and central moments. Further, from the systems of equations (2) or (3), estimates of the distribution parameters were found

The studies were carried out at different ignition intensities λ ₁ λ ₂ , coefficient c, different sample sizes n.

The table shows the research results for the characteristic values of the probability of self-ignition of the display element ≅0.2, the probability of ignition of the "highlighted" element ≅0.95, c = 0.2. This corresponds to the intensity of ignition of display elements λ ₁ = 0.003 1 / μs, λ ₂ = 0.04 1 / μs. Sample size n = 4000 elements. The process of modeling and calculating parameters was repeated 50 times.

Results of estimation of distribution parameters.

Analysis of the simulation results shows that the average values of all calculated parameters practically coincide with the initial ones. Increasing the sample size to 50,000 elements provides a more accurate estimate of the moments and, accordingly, a more accurate calculation of the distribution parameters. If the number of sample elements is set small, for example, 500, then the error in determining the distribution parameters and the spread of the found values increase significantly. Note that even when using the estimates of the moments calculated on the basis of the corresponding formulas for the superposition of two exponential distributions (i.e., ideal values), the estimates of the distribution parameters are calculated with insignificant error.

Thus, the proposed technical solution makes it possible to calculate the estimates of the distribution parameters of a random variable characterized by a superposition of two exponential distributions with a sufficiently high accuracy.

Claims (1)

A device for estimating the parameters of the superposition of two exponential distributions, comprising a memory unit, a unit for calculating distribution moments, a unit for calculating distribution parameters, an indication unit, a control unit, the first and second outputs of which are connected, respectively, to the control input of the memory unit and the first control input of the unit for calculating the distribution parameters, its second control input is connected to the input of the device, characterized in that the information inputs of the device are connected to the information inputs of the memory unit, and its outputs are connected to the information inputs of the moment calculation unit, the outputs of the calculation results of the first, second and third moments of which are connected to the corresponding inputs of the calculation unit distribution parameters solving a system of three equations representing the equalities of the first, second and third initial or central moments of a random variable described by the sum of two exponential distributions, and the corresponding experiment of these moments, the outputs of the block for determining the distribution parameters are connected to the information inputs of the display unit, the third and fourth outputs of the control unit are connected, respectively, to the control inputs of the moments calculation unit and the display unit, the input of the control unit is the control input of the device.

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