SU1718377A1 - High-frequency signal commutator - Google Patents

Abstract

The invention relates to a pulse technique and can be used in diopole and antenna devices for switching input signals. The purpose of the invention is to reduce the switching time by reducing the impulse noise on the load at the time of switching channels. At the moment of switching to the closed state, the common-mode components of the interference occurring in the control circuit are supplied simultaneously through the primary and secondary windings of the transformer 21 (23) to the equivalent input resistance of the generator (load) and resistors 19 (20) whose resistance is equal to the equivalent resistance generator (load). Due to the same loads on the first (second) outputs of the windings of the transformer 21 (23), the common-mode currents in the windings are compensated. 3 il. h y

Description

00

s

Xi xi

Yu

The invention relates to a pulse technique, can be used in radio receiving and antenna devices for switching input signals, and is an improvement of the commutator switch. St. No. 1651370.

Known switch high-frequency signals, containing in each channel 1-1 ... 1-n six diodes, two capacitors, three drosellers, four resistors, an input transformer, which is made on the basis of a long line, as well as a common choke and output transformer, which is made based on a long line, the first terminal of the first resistor being connected to the anodes of the first and second diodes and to the first terminal of the first capacitor, the second terminal of which is connected to the cathode of the third diode and the first terminal of the second resistor, the second terminal of which connected to the second output of the first resistor and through the first choke to the power bus; the cathode of the first diode is connected via the second choke to the anode of the third diode and the common bus; the cathodes of the second diodes of all channels are connected to the first common return lead, and the first output of the third resistor is connected to the fourth anode and 5th diodes and the first output of the second capacitor, the second output of which is connected to the cathode of the sixth diode and the first output of the fourth resistor, the second output of which is connected to the second output of the third resistor and through t This choke with the power bus, the cathode of the first diode through the primary winding of the input transformer is connected to the input bus, the cathode of the fourth diode is connected via the secondary winding of the input transformer to the common bus, the anode of the sixth diode and the second output of the common throttle, the first output of which is through the primary winding of the output transformer connected to the output bus; cathodes of the fifth diodes of all channels are connected to the first output of the secondary winding of the output transformer, the second output of which is connected to the common bus.

The disadvantage of such a high-frequency switch is the large switching time of the switch from the open (closed) state to the closed (open), due to the high level of impulse noise arising on the switch load at the moments of channel switching, and, consequently, a large transient time. This drawback of the device arises due to the presence of load asymmetry for the in-phase components of the impulse noise current flowing through the transformer windings at the moments of switching channels of the switch.

The purpose of the invention is to reduce the time

nor switch switching due to reduction of impulse noise on the load at the moment of switching channels.

This goal is achieved by the fact that the switch of high-frequency signals, containing in each channel six diodes, two capacitors, three chokes, four resistors, an input transformer, which is made on the basis of a long line, as well as a common choke and output transformer, the long line, the first output of the first resistor is connected to the anodes of the first and second diodes and to the first output of the first capacitor, the second output of which is connected to the cathode of the third diode and the first output of the second resistor, the second output of which is connected to the second output of the first resistor and through the first choke to the power bus, the cathode of the first diode through

5, the second choke is connected to the anode of the third diode and the common bus, the cathodes of the second diodes of all channels are connected to the first common ground lead, the first lead of the third resistor is connected to the fourth and fifth diodes and the first lead of the second capacitor, the second lead of which is connected to the sixth cathode the diode and the first output of the fourth resistor, the second output of which is connected to the second output of the third resistor and through the third choke to the power bus, the cathode of the first diode through the primary winding of the input transformer. Connected to the input bus, the cathode of the fourth diode is connected to the second output of the secondary winding of the input transformer, the anode of the sixth diode is connected to the common bus and the second output of the common droplet, the first output of which is connected to the output bus through the primary winding of the output transformer of the fifth transformer channels are connected to the first output of the secondary winding of the output transformer, two additional diodes and two resistors are introduced, the second

The pins of which are connected to the common bus, and the first pins of the additional first diode and resistor are connected to the first terminal of the secondary winding of the input transformer, and the first pins of the additional second diode and resistor are connected to the second terminal of the secondary winding of the output transformer.

A comparison of the proposed solution with other technical solutions in the field of radio engineering shows that diodes and resistors, when introduced into these links with the rest of the circuit elements, increase the symmetry of the switch channels for the in-phase components of the impulse noise currents in the transformer windings, which leads to suppression impulse noise at the moments of switching the switch from the open (closed) state to the closed (open) state.

FIG. 1 is an electrical circuit diagram of a switch of high frequency signals; in fig. 2 - oscillogram of transients of a switch of high-frequency signals according to the scheme of a known switch; in fig. 3 - oscillogram of transients of the switch of high-frequency signals according to the scheme of the proposed switch.

The switch of high-frequency signals (Fig. 1) contains - in each channel 1-1 ... 1-p eight diodes 2-9, two capacitors 10 and 11, three drossel 12-14, six resistors 15-20, input transformer 21, which is made on the basis of a long line, as well as a common choke 22 and an output transformer 23, which is made on the basis of a long line, with the first output of the first resistor connected to the anodes of the first 2 and second 3 diodes and to the first output of the first capacitor 10, the second output of which is connected with the cathode of the third diode 4 and the first output of the second resistor 16, sec whose output is connected to the second output of the first resistor 15 and through the first choke 12 to the bus 24-1 ... 24-n power, the cathode of the first diode 2 is connected through the second choke 13 to the anode of the third-diode 4 and the common bus 25, the second cathodes Diodes 3 of all channels 1-1 ... 1-p are connected to the first output of common throttle 22, the first output of the third resistor 17 is connected to the anodes of the fourth 5 and fifth 6 diodes and the first output of the second capacitor 11, the second output of which is connected to the cathode of the sixth diode 7 and the first output of the fourth resistor 18, the second output of which it is uniform with the second output of the third resistor 17 and through the third choke 14 with the bus 24-1 .., 24-. l power, the cathode of the first diode 2 through the primary winding of the input transformer 21 is connected to the input bus 26-1 ... 26-p, the cathode of the fourth diode 5 through the secondary winding of the input transformer 21 is connected to the first pins of the additional first diode 8 and resistor 19, the second the pins of which are connected to the common bus 25, the anode of the sixth diode 7 and the second output of the common cable 22, the first terminal of which through the primary winding of the output transformer 23 is connected to the output

bus 27, the cathodes of the fifth diodes 6 of all channels 1-1 ... 1-n through the secondary winding of the output transformer 23 are connected to the first terminals of the additional second 5 diode 9 and the resistor 20, the second terminals of which are connected to the common bus 25.

Switch high-frequency signals as follows.

At the moment the switch switches to

0 closed state, the in-phase interference components appearing in the control circuit are fed simultaneously through the primary and secondary windings of the input (output) transformer 21 (23) to the equivalent input resistance of the generator (load) and additional resistors 19 (20) whose resistance is selected equal to the equivalent input impedance of the generator (load).

0 Due to identical loads on the first (second) outputs of the windings of the input (output) transformer 21 (23), the common-mode currents in the transformer windings are compensated, which leads to a decrease in the level of impulse noise on the switch load and, consequently, to a decrease in switching time, V closed Channels 1–1. “1 – n, direct current flows through diodes 4, 7, their differential resistance is low, and diodes 2, 3,5,6 and additional diodes 8, 9 are closed by control voltage, and therefore, have low conductivity. At this time, the first output winding output

5 of the transformer 21 and the second output of the secondary winding of the output transformer 23 are connected to the common bus 25 via the respective resistors 19 and 20, which contribute to additional attenuation

0 spurious signals penetrating from the input to the output bus of the closed switch.

At the moment of switching the switch to the open state due to the transitional processes due to the stored energy in the inductance of the windings of transformers 2.1, 23 and chokes 12-14 and 22, there are impulse noise in the switch circuits, which are current surges and but neither. Moreover, the additional diodes 8, 9 periodically transition from the open to the closed state. At the moment of the closed state of the diodes 8, 9, due to identical loads on the first (second) terminals, the current of the input (output) transformer 21 (23) is ignited and the common-mode currents in the transformer windings are compensated, which leads to a decrease in impulse noise on the switch load and, therefore, to reduce switching time. In the open

a switch current flows through the diodes 2, 3, 5, 6, 8 and 9 through the chokes 13. 22, the secondary windings of transformers 21, 23. The diodes 8, 9 shunt resistors 19 and 20, respectively, connecting the first output terminal of the secondary winding of the input transformer 21 and the second output of the secondary winding of the output transformer 23 with a common bus 25. The input signal in the open channel 1-1 ... 1-p through the input bus 26-1 ... 26-p goes to the primary winding of the input transformer 21. For the account of the presence of electromagnetic induction between the windings from the terminals of the windings of the input tr The source 21 input signal oscillations: in-phase input from the primary winding output and anti-phase input from the secondary winding output — through open diodes 2, 3 and 5, 6 are supplied to the windings of the output transformer 23. On the primary winding of the output transformer 23, the in-phase and anti-phase composition The oscillations of the signal are added up, and the output signal is fed to the output bus 27. Thus, the operation of an open switch according to the scheme of the claimed invention is equivalent to the work of an open switch according to known switch.

The switch of high-frequency signals is implemented using modern element base, and semiconductor diodes KD 522B, ninth diodes KA 507A, etc. can be used as diodes. Experimental studies of the claimed switch of high-frequency signals with transformers made on M 400NN ferrite ring cores 4 and M ZOOVNS-1 size K 20 x 12 x 6 showed that compared with the known switch. The proposed switch provides greater suppression of impulse noise on the load during switch switching instants, as illustrated by the waveforms in FIG. 2 and 3, where indicated: At is the amplitude of the signal, t is the time. A comparison of the oscillograms of the transients of the switches proposed (Fig. 3) and the known (Fig. 2) shows that the time of switching the switch from the open (closed) state to the closed (open) To (tzo) to

the proposed switch is reduced by at least 2 times.

Thus, the proposed switch of high-frequency signals allows to increase the speed of radio receiving

and antenna devices using switching nodes, and. therefore, improve the quality of functioning of radio systems.

Claims (1)

Invention Formula Switch high-frequency signals on aut. St. No. 1651370, characterized in that, in order to reduce the switching time of the switch, in each channel the first output of the secondary winding of the input transformer is connected to the common bus through an additional first diode and resistor, which are connected in parallel, the second output of the secondary winding of the output The transformer is connected to the common bus through an additional second diode and a resistor, which are connected in parallel. Fig.Z