SU499660A1 - Pulse selector by frequency - Google Patents

Description

one

The invention relates to a pulse technique and is intended for the selection of periodic pulse sequences with pulse repetition frequencies lower than a certain fixed fanichnogo frequency, especially in those cases when, under the conditions of operation, the limiting selection frequency can be adjusted during operation of the device.

The following pulse frequency selector is known, which contains a single junction transistor, the emitter of which is connected via a capacitor to a common selector bus, and the first base is connected to a power source, a key stage made on a bipolar transistor, the emitter of which is connected to a power source, and the collector is connected through serially connected the resistor and the thyristor are connected to the common bus, a differentiating circuit, the input of which is connected to the input of the key stage.

However, the known selector does not provide a wide adjustment of the values of the boundary frequency selection.

The aim of the invention is to expand the range of adjustment of the cutoff frequency values.

This is achieved by the fact that two diodes are introduced into the proposed selector, the anode of one of which is connected to the output of the differentiating circuit, and the anode of the other through a resistor

the second base of the unijunction transistor, the KOTOiporo emitter is connected via an adjustable resistor to the collector of the key bipolar transistor, and the cathodes of the diodes are connected to the control input of the thyristor.

The drawing shows the principal circuit diagram of the proposed selector. The selector includes a bipolar transistor 1, resistors 2-8, capacitors 9-11, thyristor 12, diodes 13-15, single junction transistor 16, terminal 17 of the input source, terminal 18 of the power supply. The selector works as follows. After turning on the power supply (terminal 18), the voltage on the capacitor 10 remains zero and the single junction transistor 16 is turned off. There are no 12 positive pulses on the control electrode of the thyristor. Therefore, the thyristor 12 is also turned off (the resistor has a low resistance and the voltage created on it due to the passage of current through the interbase circuit of the single junction transistor 16 is not enough to turn on the thyristor 12). The emitter junction of the bipolar T1 transistor 1 is biased in the forward direction, and a current flows in its base circuit, the magnitude of which is set by resistor 4. The magnitude of the base current of bipolar transistor 1 is sufficient to saturate it. Through the saturated bipolar transistor 1, the top output of the adjustable resistor 3 will be connected to terminal 18. The capacitor 10 starts charging through the resistor 3 and the saturated bipolar transistor 1. When the voltage on the capacitor 10 reaches the turn-on level of the single junction transistor 16 through the emitter, the last included. The capacitor 10 is quickly discharged through the emitter junction of the unijunction transistor 16, creating a positive polarity pulse on the load resistor 5 connected in the circuit of the first base of the single junction transistor 16. The specified pulse from the first base of the single junction transistor 16 through the resistor 8 and the diode 14 is also fed to the control thyristor electrode 12 and causes the inclusion of this thyristor. After turning on the thyristor 12, the capacitor 10 is discharged not only through the emitter circuit of the unijunction transistor 16, but also through the diode 13 and the thyristor 12. When the voltage on the capacitor 10 decreases to turn off the voltage of the unijunction transistor 16, the latter closes and the further discharge of the capacitor 10 goes only through diode 13 and thyristor 12. After a fast discharge of capacitor 10, the circuit goes into a long-steady state in which the bipolar transistor 1 is saturated, the thyristor 12 and diode 13 are turned on, the single junction transistor 16 Off Trigger pulse. positive polarity goes to terminal 17 and causes the following switch in the circuit: it closes the bipolar transistor 1, i.e. it breaks the connection of the thyristor anode 12 to terminal 18, in addition, the input pulse is differentiated by a circuit consisting of a capacitor 11 and a resistor 7. A short positive pulse corresponding to the leading edge of the input signal from resistor 7 through the diode 15 is fed to the control electrode of the thyristor 12 and keeps it open. Since the main circuit of the anode current of the thyristor 12 is opened by the bipolar transistor 1, the remaining voltage on the anode of the thyristor 12 decreases, and the capacitor 10 during the action of the input signal is slightly discharged. When the discharge current of the capacitor 10 reaches the thyristor turn-on current, the thyristor 12 is turned off. Upon termination of the input signal, bipolar transistor 1 becomes saturated again and connects resistors 2 and 3 to terminal 18, however, thyristor 12 remains off because the positive pulse on its control electrode, resulting from differentiating the input signal, ends much earlier than the input signal itself. When the input signal ends, the capacitor 10 begins to charge. After a time, the voltage across the capacitor 10 and the emitter of the unijunction transistor 16 reaches the on-voltage value. A single junction transistor 16 is turned on, the capacitor 10 discharging through its emitter circuit. During the discharge process, a pulse is generated at the first base of the single junction transistor 16, which includes the thyristor 12 and the output of the device. Thus, the response of the circuit to a single trigger pulse is a short pulse of positive polarity generated at the first base of a single junction transistor with a delay of time t relative to the start one. The processes in the device are repeated at a pulse repetition rate with a period, or at a repetition rate. In the case of a repetition frequency of the triggering signals g - after the arrival of the first triggering pulse of the sequence, the capacitor 10 starts charging. However, the voltage across it does not have time to increase before the voltage to turn on the unijunction transistor 16 when the second input pulse arrives. By its leading edge, this pulse turns on the thyristor 12 across the control electrode. The capacitor 10 is each time discharged through the diode 13 and the thyristor 12 earlier than the turn-on level of the unijunction transistor 16 is reached. The single-junction transistor remains switched on and there are no pulses on its first base. Thus, at the output of the selector, there are positive pulses shifted by time t with respect to the starting ones, and at pulses at the output of the selector, Formula of the Invention Pulse selector with respect to the tracking frequency, which contains a Single junction transistor whose emitter is connected through a capacitor to the common selector bus, and the first - power supply, key cascade performed on a bipolar transistor, the emitter of which is connected to the power source, the collector is connected through a series-connected resistor and thyristor to In addition, a differentiating circuit, the input is connected to the input of a key stage, different from the fact that, in order to expand the range of adjustment of the values of the selected selection frequency, two iodines are inserted in it, the anode of one of which is connected to the output of the differentiating circuit, and through a resistor with the second base of a single-pass transistor, the emitter of which is connected through an adjustable resistor with the collector of a key bipolar transistor, the cathodes of the diodes are connected to the control input of the thyristor.