SU1200231A1 - Meter of duration of transient process - Google Patents

Abstract

TRANSMITTED PROCESS DURATION, containing serially connected reference pulse generator, splitter and first pulse shaper, as well as a comparison element, a reference level setting unit, a bandpass filter and an indicator, the input of the first pulse shaper connected to the comparison element output, the first input of which is connected to the output of the unit setting the reference level as well. A second input is connected to an input bus, characterized in that, in order to increase accuracy, a controllable delay element, a second pulse shaper, a regulator and a clock generator are introduced into it, the output of the first pulse shaper being connected to the first input of the second shaper pulses directly, and with the second input through a controlled delay element, the output of the second pulse shaper is connected to the input of a bandpass filter, the output of which (L through the regulator is connected to the input of the clock pulses, the first output of which is connected to the input of the indicator, and the second - to the control input of the controlled delay element. ic N9 CO

Description

The invention relates to a pulse technique. The aim of the invention is to improve the accuracy. Figure 1 shows the functional diagram of the transient process duration meter4. Fig 2, a temporary p, kagrvasch his work. The meter contains generator 1. EDA pulses, splitter 2 comparison element 3, unit 4 for setting the reference level first pulse shaper 5, controllable delay element 6, second pulse shaper 7, band-pass filter 8, regulator 9, generator 10 clock pulses, indicator 11, input 12 and output 13 of the meter bus, Generator 1 reference pulses through a splitter 2 is connected to the output bus 13 of the meter and the first input of the first pulse shaper 5, the second input of which is connected to the output of the comparison element 3 the first and second inputs of which are connected respectively to the output of the unit 4 for setting the reference level and the input bus 12 of the meter, the output of the driver 5 is connected to the first input of the driver 7 directly, and to the second through a controllable delay element 6. The output of the imaging unit 7 is connected via a series-connected bandpass filter 8 and a regulator 9 connected to the generator input 10 clock pulses, the first output of which is connected to the input of the indicator 11, and the second output to the controllable input of the controlled delay element 6. Measuring the duration of transient processes as follows. The generator 1 of the reference pulses generates a reference sequence of rectangular pulses (FIG. 2A). The duration of the output pulses of the generator 1 is determined by the inertia of the object under study, the further the transient process in the object under study the longer the generator pulses must be. The repetition period of these pulses Tp determines the bandwidth of the band-pass filter 8 and the required accuracy of measuring the duration of the transition process under study. 31 From the generator output 1, the reference pulses through the splitter 2 are fed through the output bus 13 to the input of the object under study and the first input of the imaging unit 5 pulses. On the leading edge of the pulse generator 1, the leading edge of the output pulse is formed at the output of the shaper 5. When a pulse of the generator 1 arrives at the input of the object under study, in the latter there is a transient process, the duration of which should not exceed the duration of the input pulse. When the output voltage level of the object under study reaches 0.9 of its maximum value, the output pulse is formed by the comparison element 3 (FIG. 2). The formation of this pulse is carried out by comparing the level of the pulse arriving at the second input of the comparison element 3 from the output of the object under study with the value of the reference voltage equal to 0.9 of the maximum value of the output voltage of the object under study, coming from the output of the reference level setting unit 4 (Fig .2 B). The pulse formed by the element of comparison 3, is fed to the second input of the driver 5. The leading edge of the pulse from the output of the element 3 of the comparison by the driver 5 forms the trailing edge g of the output pulse (Fig. 2). Thus, the pulse duration at the output of the imaging unit 5 is determined by the duration of the transient process in the object under study, and their follow-up period remains unchanged and equal to the follow-up period of the reference frequency impulses. The pulse from the output of the imaging unit 5 is fed to the input of the adjustable delay element 6 and to the first input of the second imaging unit 7. In the second imaging unit 7, two pulses are added to the first and second inputs of the imaging unit 7, respectively, from the outputs of the imaging unit 5 and the controlled delay element 6 (FIG. 2 C). Thus, at the output of the second generator 7, a pulse is formed, the duration of which is determined by the time of passage of the signal through the object under study and the delay time nAf in the adjustable delay line 6 (FIG. 2-3) + h-ui-3 8, where Hi is the pulse duration, formed by the second pulse shaper; d1g is the duration of the pulse generated by the first pulse shaper; and n is the number of counting pulses that have arrived at the controllable delay element; the change in the value of the delay in the arrival of one of them., the pulse to the input of the controlled delay element. The operation of the adjustable element 6 of the delay is controlled via a controllable input, a generator of 10 clock pulses, the clock pulse following period Td Tjj being substantially longer than the period: the pulse of the generator 1 of the reference pulses. This ensures the input to the input of the bandpass filter 8 of the steady-state spectrum of the waveform h eliminates the influence of the inertia of the response of the band-pass filter 8 and the regulator 9 on the measurement process. Band-pass filter 8 has sufficient bandwidth And "-. In the low frequency range compared to the frequency of the Nth harmonic (zero mark of the spectrum under study, A. Due to this, one of the harmonics of the spectrum under study (Figure 2 A, B) is extracted at the output of the band-pass filter 8, which then enters the control input torus 9. At the output of regulator 9, a resolving potential is formed at the afterclock of the clock pulse generator 10. From the generator output of 10 clock pulses, the generated clock pulse (FIG. 2 D) goes to adjustable delay element 6 and to the input indicator 11. As a result, output element That 6 delay (Fig. 2E) the periodic pulse sequence will be delayed by time. Thus, with the arrival of the next clock pulse to the input of the adjustable delay element 6, the pulse duration at the output of the second driver 7 will increase by an amount each time. until the duration of the generated pulses becomes such that the frequency of the Nth harmonic falls in the passband of the band-pass filter 8 (the zero point of the spectrum of the investigated Pulse duration, Fig. 2 B) fdr-fh - nif, where fq, is the average tuning frequency of the bandpass filter: f is the frequency of the zero harmonic of the non-delayed pulse train; Af is the constant frequency interval by which the pulse sequence is delayed each time the next clock pulse arrives, and n is the number of clock pulses received. With the appearance at the output of the bandpass filter 8 zero (below the threshold level) of the reaction, the regulator 9 forms a prohibiting level entering the input of the generator 10, as a result of which the formation of clock pulses by the generator 10 ceases. Know the frequency f to which the band-pass filter B is tuned, and determine the value of the time delay of the pulses according to the indication of the indicator 11, you can uniquely determine the zero mark fi, unused pulses, and hence the duration of the transition process of the object under study G - f ,,

Claims (1)

TRANSITION DURATION METER, comprising in series a reference pulse generator, a splitter and a first pulse shaper, as well as a comparison element, a reference level setting unit, a bandpass filter and an indicator, the input of the first pulse shaper is connected to the output of the comparison element, the first input of which is connected to the output of the block setting the reference level, a. the second input is connected to the input bus, characterized in that, in order to improve accuracy, a controlled delay element is introduced into it. · ki, a second pulse shaper, · a regulator and a clock pulse generator, the output of the first pulse shaper connected to the first input of the second shaper pulses directly to the second input of a- - via a controllable delay element, a second pulse shaper output is connected to _a row vho- bandpass filter output kotoro- ® th through the regulator is connected to the input of the clock generator pulses. whose first output is connected to the indicator input, and the second to the control input of the controlled delay element. Fig / SU „» 1200231 ί 1200231