SU1272260A1 - Controlled device for determining moments of occurences of extrema - Google Patents

Abstract

The invention relates to the field. electrical measuring instruments and can be used to determine the moments of occurrence of an extremum of both single and periodic or non-periodic sequences of signals of positive and negative polarities. The aim of the invention is to increase the determination of accuracy over a wide range of frequencies and to expand the functionality by registering different extremes. The goal is achieved by introducing into the device an additional diode 5, an adjustable resistor 3 and Q 9 of a resistor 2. The device also contains a comparator 1, a diode and a capacitor 5, (L When the comparator is adjusted using an adjustable resistor 3

Description

Due to the output signal, the device frequency is about 500 kHz with input signal amplitudes from 0.1 to + 15 V. A small input signal at which the device is able to work is provided by a high comparator input resistance substantially exceeding the resistance of the diode at close to zero. direct voltage values. 2 Il.

Claims (1)

The invention relates to electrical measuring equipment and can be used to determine the moments of occurrence of an extremum, both single and periodic or non-periodically, the sequence of signals (noi) .viTO., UbHou and negative voltage. The purpose of the invention is to increase the accuracy in a wide range of frequencies and to expand the functional possibilities: by means of ensuring the registration of different extremes. i. FIG. 1 is a schematic diagram of the device in FIG. 2 voltage plots that show his work. The device contains a comparator 1 to the inverting input of which the first terminal of the resistor 2 is connected, the first output of the adjustable resistor 3, the second terminal of which is connected to the first electrodes of the diodes 4 and 5 connected counter-parallel and the second terminal of the parallel-parallel diodes 4 to the input terminal of the device. and 5 are connected to the first capacitor plate 6 and to the inverting input of the comparator 1, whose output is connected to the output terminals of the device, the second capacitor cover and the second terminal of the resistor 2 are connected to the common busbars device. The device works as follows. Consider the case when positive voltage impulses arrive at the device input. Suppose that the resistance value of the adjustable resistor 3 is set equal to the bullet. When the input pulse starts to increase at the non-inverting input of the comparator 1, the voltage A (Fig. 2) increases with the input increasing speed, and the voltage B increases the inverting input of the comparator because of partial voltage drop across diode 4, which is open for a positive pulse (diode 5 is closed), and also due to the capacitor 6 capacitance. As a result, the comparator output voltage is equal to a high level (at time t). When the input pulse reaches a maximum value (time moment tg), the capacitor 6 is charged to a certain value U, which is less than the maximum value of the input pulse voltage. When the voltage drop of the input pulse starts, diode 4 turns off-. The SI is already non-conducting, while diode 5 is not yet turned on. Therefore, the voltage on the capacitor and, therefore, on the inverting input of the comparator 1 immediately after the storage of the maximum remains unchanged and equals U {, while the feces on the inverting input of the comparator continue to decrease. When reversed by sign1; the difference between the inputs of the comparator reaches the threshold (the 5th sensitivity U 5 which is almost less} the threshold voltage of the opening of diode 5, the output voltage of the comparator switches from the upper level to the lower - negative differential, look that it is positive, The proton pulse is responsible for the input pulse through the maximum of its value, lags behind the time when it actually occurs. This lag is due to the finite value i of the sensitivity of the computer and the fact that the maximum voltage on the capacitor 6 is much less than the maximum 3.V. values of the input pulse voltage due to a partial voltage drop on the open diode 4. After the comparative output voltage of the comparator has already occurred, the difference between the voltages A and B due to the continued decay of the input voltage A increases with to the value when diode 5 opens. A fast discharge of capacitor 6 begins through the open diode 5, diode 4 is closed (time t); When the next input pulse arrives, the processes described are repeated. The voltage on the capacitor 6, lagging in phase, rotates the input voltage in frequency, since the time constant of the charging circuit is equal to the constant time of the discharge circuit and is determined by the capacitance of the capacitor 6 and the resistance of the alternately open diodes 4 and 5. Thus, taking into account the insignificance of the magnitude of the resistance of open diodes and their equality, we have a wide range of operating frequencies. In addition, the width of the operating frequency range is not related to the possible accuracy of the device. If we now increase the value of the adjustable resistance on the resistor 3, then the voltage on the non-inverting input of the comparator will decrease due to the division of the input signal by the divider formed from the resistance on the resistors 3 and 2 (FIG. 2, curve A). Pa figs. 2. It is obvious that in this case the point of intersection of the case of curves A and B, where the polarity difference of the voltage difference at the comparator inputs changes, and, accordingly, the negative differential at the output, moved forward in time (to the left in Fig. 2) relative to the moment of reaching the maximum by the input pulse (time tj). Thus, by adjusting the magnitude of the resistance 3, it is possible to vary the amplitude of voltage A and thereby move the moment of the negative output differential voltage of the comparator (device) relative to the maximum of the input pulse up to 604 to match them to any desired extent. In this case, the frequency range of the device operation does not expand only because the constant charging and discharging times of the capacitor are equal. It is possible to further expand the operating range towards higher frequencies by compensating (by adjusting the resistor 3) the delay of the output signal inherent to the comparator used, which begins to affect the higher frequencies. When negative pulses are input to the device, all processes remain the same, only negative in sign, i.e. all diagrams for example, shown in FIG. 2, rotate 180 relative to the zero horizontal axis. In this case, the charge current flows through diode 5, and the discharge current of capacitor 6 passes through diode 4. The actual output signal in this case is the positive voltage drop of the comparator. Claims of the Invention An adjustable device for determining the moments of occurrence of an extremum, comprising a comparator, the output of which is connected to the output bus of the device, a diode and a capacitor, the first plate of which is connected to the common bus of the device, the second plate of the capacitor is connected to the inverting input of the comparator and the cathode of the diode whose anode is connected with an input bus device, characterized in that, in order to improve the determination of accuracy in a wide frequency range and to extend the functionality by providing Registration of different extremes, an additional diode and a series-connected adjustable resistor and a resistor are inserted into it, the common terminal of which is connected to the non-inverting input of a comparator, the second output of the adjustable resistor is connected to the input bus of the device, the second output of the resistor is connected to the common bus of the device, and the additional diode on-back diode.