RU181880U1 - Device for evaluating the parameters of the distribution of the delay time of the occurrence of the discharge - Google Patents

Abstract

The proposed technical solution relates to the indicator technique and can be used to study the characteristics of gas-discharge indicators. The proposed device for evaluating the parameters of the distribution of the delay time of the occurrence of the discharge contains a memory unit, a register, an adder, a control unit, a shaper of a single code, a counter and a calculation and indication unit. To estimate the average delay time, the proposed utility model implements the formula, where n is the number of values that fall into the first differential corridor; A is the width of the differential corridor. The proposed device for evaluating the distribution parameters provides a reduction in the computation time of the numerical estimates of the distribution parameters of the delay time of the occurrence of the discharge.

Description

The proposed technical solution relates to indicator technology and can be used to study the characteristics of gas-discharge matrix indicators.

Known devices for evaluating the parameters of gas-discharge indicators that allow you to measure (register) random values of the ignition delay time of display elements, enter these values into the computer memory and then calculate the necessary characteristics (Sviyazov A.A., Soldatov V.V. Automated devices for scientific research of parameters gas-discharge sign-synthesizing indicators of direct current. Vestnik RGRTU, Issue 24, Ryazan. 2008; Sviyazov AA, Soldatov VV Experimental studies of factors, ow yayuschih on the parameters of the gas-discharge display panels. RSREU Bulletin, Issue 27, Ryazan. 2009). Since the number of measurements necessary to construct the distribution density is inversely proportional to the cube of the error in determining it (Orlov, Yu.N. Optimal partition of the histogram for estimating the sample density of the distribution function of the unsteady time series // Keldysh Institute Preprints. 2013. No. 14. 26 pp. URL: http://library.keldysh.ru/preprint.asp?id=2013-14) and can be several thousand, then to implement these devices requires a computer, and cumbersome statistical processing of measurement results increases the research time . This is a disadvantage of analogues.

Closest to the claimed technical solution is a device for evaluating the parameters of the distribution of the delay time for the occurrence of a discharge (S.I. Lavrentiev, Shesterkin A.N. A device for determining the densities for determining the delay time of ignition of the display elements of gas discharge indicators. Electronic Technology, Series 4 - Electric and gas instruments, Issue 3 (98), 1983, prototype) containing a memory unit, a register, an adder, a control unit, a unit of code generator and a counter, the outputs of which are connected They are with address inputs of the memory block, its data inputs are connected to the outputs of the adder, the inputs of which are connected to the outputs of the register and the unit of the unit code. The outputs of the memory unit are connected to the output of the device and the information inputs of the register, the first and second outputs of the control unit are connected respectively to the control input of the register and the data recording input of the memory unit, the information and clock inputs of the counter and the clock input of the control unit are connected to the inputs of the device.

при использовании традиционного метода максимального правдоподобия следует воспользоваться формулой:The distribution density in this device is built at the measurement rate (data received from the measuring device), however, to determine the numerical characteristics, the found numbers of random values falling into each differential corridor (although a smaller number of values compared to analogues, since the histogram has already been constructed data processing) must be further processed. In particular, to estimate the mathematical expectation of the delay time of the occurrence of a discharge

when using the traditional maximum likelihood method, you should use the formula:

where N is the number of measurements (sample size), n _i is the number of random values entered in the i-th differential corridor (i = 1, 2, ..., k), τ _i is the value of the delay time for the occurrence of the discharge, corresponding to the i-th differential corridor, k is the number of corridors.

Thus, to evaluate the numerical values of the delay time of the occurrence of a discharge in the traditional way, the prototype must be supplemented with a rather complicated computing device that will ensure the implementation of formula (1), which significantly complicates the device and increases the research time.

, m - математическое ожидание времени запаздывания зажигания, равное τ_ср. Очевидно, при τ=0 ƒ(0)=λ, т.е. для оценки интенсивности зажигания элемента отображения достаточно определить значение плотности распределения при t=0. Для экспериментальной оценки плотности распределения - гистограмме - начальное значение соответствует относительной частоте попадания случайной величины в первый дифференциальный коридор. Так как это значение зависит от ширины (числа) дифференциальных коридоров, то найденную относительную частоту следует скорректировать на ширину дифференциального коридора. Таким образом, оценку среднего времени запаздывания

(интенсивности) зажигания можно вычислить на основе первого значения гистограммы и она равнаFor the exponential distribution, which in most cases can be used to describe the distribution of the delay time of the discharge of gas-discharge indicators (Shesterkin AN Determination of the reliability of information display on gas-discharge matrix indicators. Vestnik RGRTU. Issue 39. Part 2. Ryazan. 2012), density distribution ƒ (τ) = λ exp (-λ⋅τ). Here, τ is a random variable (delay time for the occurrence of a discharge), λ is the ignition intensity, which is equal to

, m is the mathematical expectation of the ignition delay time equal to τ _cf. Obviously, for τ = 0, ƒ (0) = λ, i.e. To estimate the ignition intensity of the display element, it is sufficient to determine the value of the distribution density at t = 0. For an experimental estimation of the distribution density — the histogram — the initial value corresponds to the relative frequency of the random variable entering the first differential corridor. Since this value depends on the width (number) of differential corridors, the found relative frequency should be adjusted to the width of the differential corridor. Thus, an estimate of the average delay time

(intensities) of ignition can be calculated based on the first histogram value and it is equal to

Here n ₁ is the number of values that fell into the first differential corridor; Δ is the width of the differential corridor equal to the difference between the maximum and minimum values of the measured delay time divided by the number of differential corridors k. When conducting research, the number of differential corridors and their width are determined on the basis of the expected range of changes and the required accuracy of building a histogram (sample size). These parameters are chosen before the start of research, therefore, for calculating the estimates according to formula (2), it is necessary to determine only n ₁ .

Obviously, the calculation of numerical estimates of the average delay time of the occurrence of a discharge using formula (2) is much simpler, and, therefore, faster than using formula (1).

The delay time for the occurrence of a discharge of display elements in different operating modes, for example, during autonomous excitation and during “illumination” of previously burning or burning elements, differs significantly, therefore, when conducting studies for the measurement unit, a certain range of variation of the delay time is established, which is equivalent to setting some scale, in which the measurement results are recorded. Thus, to obtain absolute numerical estimates, this scale should be taken into account.

.The purpose of the invention is to reduce the calculation time of numerical estimates of the delay time of occurrence of a discharge of the display elements of gas discharge indicators. To this end, the device additionally includes a calculation and indication unit, the information inputs of which are connected to the outputs of the memory unit, the third output of the control unit is connected to the inputs of the counter code setting, the control inputs of the device are connected to the input of the mode selection of the control unit, the zero setting of the memory unit, and the inputs of the installation of the coefficients of the calculation and display unit, which implements the formula

.

A functional diagram of a device for estimating the parameters of the distribution of the delay time of the occurrence of a discharge is shown in FIG. The device comprises a memory unit 1, a register 2, an adder 3, a control unit 4, a unit shaper 5, a counter 6, and a calculation and indication unit 7.

The device operates in two modes: measuring-recording the delay time of the discharge (building a histogram) and calculating estimates of the numerical characteristics of random values of the delay time (average value or intensity of ignition).

Histogram construction mode. The choice of the operating mode is carried out by the signal received at the input of the choice of the mode of the control unit 4. Before starting the construction of the histogram, all cells of the memory unit 1 are set to the state “0”. The input code received at the information inputs of counter 6 and corresponding to a randomly measured ignition delay time, with a synchronizing pulse accompanying the input code, is recorded in counter 6. A synchronizing pulse is also fed to the synchronizing input of control unit 4, which determines the operation sequence of the device units. The output code of the counter 6, arriving at the address inputs of the memory unit 1, provides a selection of its cells corresponding to the input code. The code of memory unit 1, stored at the selected address, is supplied to the information inputs of register 2. A synchronizing pulse is also supplied to the synchronizing input of control unit 4, which determines the sequence of operation of the device nodes. After the processes of writing the input code to the counter 1, setting the address, generating the output code of the memory unit 1 and installing it on the information inputs of the register 2 by the signal from the first output of the control unit 4, the output code of the memory unit 1 is written into register 2. The adder 3 adds the current value of the output code of the memory block 1 recorded in register 2 with a single code of the shaper 5, i.e. at the output of the adder 3 is formed increased by one value of the output code of the memory block 1, at the address determined by the input code. The output code of adder 3 is fed to the data inputs of memory unit 1 and after the transients are completed by the output signal from the second output of control unit 4, this code is recorded at the same address in memory unit 1. Thus, the output code of memory unit 1, at the address corresponding to the input code will be increased by one.

Such a cycle of the device will be repeated upon receipt of each next value of the input code and the accompanying synchronizing pulse. Obviously, at the end of the measurements, i.e. after N input codes are received at the input of the device at each address in the memory unit 1, the code value corresponding to the number of occurrences of the corresponding input code will be recorded, i.e. a histogram will be generated.

Grade calculation mode. In the absence of a control signal at the input of the mode selection of the control unit 4, the device operates in the mode of calculating numerical estimates of the delay time of the occurrence of the discharge. To evaluate the numerical characteristics according to formula (2), counter 5 should be set to the state corresponding to the first differential corridor, i.e. 000 ... 01. In this case, the output code of the memory block 1 will be equal to the number of hits of random values in this differential corridor. In addition, at the inputs of the coefficients of the calculation and indication unit 7, it is necessary to set the width of the differential corridor and the sample size, which are known in advance. Based on these values, block 7 will determine and display the values found.

The reliability of the calculation of numerical estimates of the ignition delay time of the proposed device was checked by statistical modeling. For this, an array of random values was generated, the elements of which corresponded to the exponential distribution, a histogram was formed, and an estimate of the average value was calculated by formula (2). The studies were conducted at various ignition delay times, sample sizes, and numbers of differential corridors. In particular, with an average ignition delay time of 50 μs, a sample size of 2000, the number of differential corridors of 50 and repeating the simulation process 50 times, the average value varied from 47.2 to 55.1 μs (average value of 52.2 μs) i.e., the maximum error of determination the estimate was about 10%. A slight excess of the estimates compared to the true values is due to the fact that not only the values corresponding to the zero value of the distribution density, but also smaller ones fall into the first differential corridor. With an increase in the sample size to 10,000 elements and the number of differential corridors to 100, the average value was 50.85 μs.

Thus, the proposed device for estimating the parameters of the distribution of the delay time of the occurrence of the discharge provides a significantly simpler and faster calculation of the numerical estimates of the delay time of the occurrence of the discharge of the display elements of gas-discharge indicators with sufficiently high accuracy.

Claims (1)

A device for evaluating the parameters of the distribution of the delay time of the occurrence of a discharge, containing a memory unit, a register, an adder, a control unit, a unit of code and a counter whose outputs are connected to the address inputs of the memory unit, its data inputs are connected to the outputs of the adder, the inputs of which are connected to the outputs of the register and a shaper of a single code, the outputs of the memory unit are connected to the output of the device and the information inputs of the register, the first and second outputs of the control unit are connected respectively to the control The input of the register and the data recording input of the memory unit, the information and synchronizing inputs of the counter and the synchronizing input of the control unit are connected to the inputs of the device, characterized in that, in order to reduce the calculation time of numerical estimates, the device additionally includes a calculation and indication unit, the information inputs of which connected to the outputs of the memory unit, the third output of the control unit is connected to the inputs of the installation of the counter code, the control inputs of the device are connected to the input of the choice of the mode of the control unit ni, zeroing the memory block, as well as inputs for setting the coefficients of the calculation and indication block, which implements the formula

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