SU785773A1 - Pulse converter - Google Patents

Description

(54) PULSE CONVERTER

The invention relates to a measurement technique and can be used to measure the amplitude value of periodic sequences of voltage pulses. A pulsed transducer is known for measuring peak values of periodic pulse signals, in which the automatic discharge of a memory capacitor to inter-face by successive pulses is carried out using a resistor 1 parallel to the capacitor connected. when operating at low frequencies RX repetition. The closest technical solution to the invention is an impulse converter containing a capacitor included in the grid circuit of a cathode follower, in which a circuit consisting of a normally closed circuit with a diode in the anode circuit 2 is connected in parallel with the capacitor. a diode and to the anode of the second diode, connected in series with the diode - triode circuit. The accuracy of the converter is its complexity caused by the need to use the active element — the triode and its source of power. The aim of the invention is to increase the speed of the pulse converter,. . This is achieved by the fact that an impulse converter containing a series-connected charge diode and a storage capacitor, the other lining of which is connected to a common bus, as well as a discharge resistor connected in parallel to the memory capacitor, are connected to a coupling diode with a threshold current-voltage characteristic and a cell comparison with a constant discharge time, a shorter discharge time of the storage capacitor: made as a series of connected diode and capacitor, the other of which is connected and s; catering bus and razradnym resistor: a capacitor connected in parallel, the diode connection is connected to the storage capacitor and a capacitor cell of comparison, entry

the comparison cells are connected to the converter input, the polarity including the NIN of the comparison cell diode coincides with the inclusion of the diode in the storage capacitor circuit, and the communication diode is connected to the diode of the comparison cell with the same electrodes,

Fig. 1 shows the principle electrical circuit of the proposed pulse converter; Fig. 2 shows time diagrams of voltages at the output of the pulse converter with positive polarity of the input pulses.

The pulse converter (see Fig. 1) contains a charging diode 1, a discharge resistor 3 connected to a storage capacitor 2f, connected in parallel with an e-capacitor capacitor, a charging diode of a comparison cell 4, a capacitor of a comparison cell 5, a discharge resistor B and a diode connection 7 with a threshold current-voltage characteristic, connected between the converter and the output. comparison cells, the communication diode 7 being connected to the charging diode of the comparison cell 4 with the same electrodes.

Pulse Converter works as follows

When a pulse arrives at the converter input, the capacitors 2 and 5 through diodes 1 and 4 are charged to a voltage equal to the peak value of the pulse. After the end of the pulse, capacitor 2 is discharged into resistor 3 with RS time constant, where C is capacitor 2 capacity, R is resistor 3 resistance, and capacitor 5 is discharged into resistor 6 with time constant, where C is capacitor 5 EM , R is the resistance of the resistor 6. If the time constant is less than the RC time constant, then due to the faster discharge of the capacitor 5 compared to the capacitor 2, the voltage on it tends to be lower than the voltage on the capacitor 2. At the same time d capacitors occur independently of each other. However, due to the presence of a threshold voltage-current characteristic of the diode 7., the capacitors 2 and 5 are discharged independently of each other only until the voltage difference between them changes the threshold voltage of the communication diode 7, Therefore, if the threshold voltage diode 7 is chosen to be equal to or greater than the voltage difference across capacitors 2 and 5 and the end of the pulse repetition period, then at a constant level of input pulses, the converter works as known converters with a constant discharge time of the storage capacitor on a resistor equal to RC. When the level of input pulses decreases, the voltage on capacitors 2 and 5 decreases. As a result of their discharge, but because the constant RjC time is less. Of RC time, the voltage on capacitor 5 decreases faster than on capacitor 2, which leads to an increase the voltage differences across the capacitors until this difference reaches the threshold of the communication diode 7. From this moment on, the capacitors 2, 5 and resistors 3,6 come through the communication diode

7 connected in parallel, in connection with which a further reduction in the voltage at the output of the converter occurs at a rate determined by the time constant of the parallel-connected capacitors and resistors,

The difference in the voltage across the condensate during the discharge process is kept constant and equal to the magnitude of the voltage drop across the diode LED 7.

After the voltage on the capacitor 5 decreases to the level corresponding to the new peak value of the input pulses, the voltage change on it stops.

At the same time, the capacitor 2 continues to discharge, the voltage difference across the capacitors 2 and 5 decreases and the threshold voltage of the communication diode 7 becomes lower, as a result of which the capacitor 2 is disconnected from

. capacitor 5 and its further discharge through resistor 3 with a constant time RC occurs regardless of the capacitor 5 discharge. The terminal of capacitor 2 is discharged until the voltage at the output of the converter reaches the level corresponding to the new peak the value of the input pulses, after which the operation of the converter does not differ from the operation of the known converters with the storage capacitor across the resistor with a constant time equal to RC.

Thus, due to the fact that after a decrease in the level of the input voltage pulses, the capacitor 2 is discharged from a small time constant, smaller than RC, and then the discharge of capacitor 2 occurs from a constant RC time, but by a small amount not exceeding the threshold voltage of the communication diode, the speed of the proposed pulse converter is higher than that of the known converters with automatic storage of the storage capacitor on the resistor with the same storage accuracy of the IN formation.

Claims (2)

Invention Formula Pulse transducer holding in series The charge diode and the storage capacitor, the other lining of which is connected to the common bus, and the discharge resistor connected in parallel to the storage capacitor, are distinguished by the fact that, in order to increase the speed, the coupling diode with the threshold voltage-current characteristic and A comparison cell with a constant discharge time, a shorter discharge capacitor discharge time, is made in the form of a series-connected diode and a capacitor, the other of which is connected to the common bus and to the discharge resistor stories, connected parallel with a capacitor, and diode connection is connected to the capacitor 2 zapomiHanpflineHue Condenser loading 5 V with a capacitor and a comparison cell, the input of the comparison cell is connected to the input of the converter, the polarity of the diode of the comparison cell coincides with the polarity of the diode in the memory of the capacitor, and the superconnection diode is connected with the comparison cell with a single name electrode. Sources of information taken into account in the examination 1, Netrebenko K.A., Compensation schemes of amplitude voltmeters and extremum indicators, - M. Energie, 1967, p.4. 2. USSR author's certificate No. 143565, cl. G 11 C 27/00, 1960 (prototype), 1