SU1406672A1 - Differential attenuator - Google Patents

Abstract

The invention relates to the field of radio engineering and m. B. used in radio receivers and radio transmitters. The purpose of the invention is the expansion of the working frequency band. The differential attenuator (YES) contains a segment of 1 transmission line (LC) with a length of 3/4 of the working wavelength, one end of which is the INPUT and the other is the output YES, diodes 2 and 3, one electrodes of which are connected at distances of 1 / 4 working wavelengths from the ends of the segment 1, and the others are connected to a common 1pina, a segment 4 LP of a length of 1/4 of the working wavelength, to the ends of which pin-diodes 5 and 6 are connected, segments 7 and 8 L11. The wave resistances of segments 1, 4, 7, and 8 are the same and equal to the characteristic resistance of the path. Phases the transmissions of YES in both states with low attenuation differ by 180 °, which makes it possible to use it as a phase manipulator. Segments 7 and 8 equalize the energy accumulated in both channels. At the center frequency, these segments do not affect the matching. 1 il. c & cl

Description

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. I h:; t; ini- fires to radio technicians and can be used in radio receivers and radio transmitters.

The purpose of the invention is to expand the working frequency band.

The drawing shows a circuit diagram of a differential attenuator.

The device contains the first segment 1 of the transmission line with a length of 3/4 of the working wavelength, one end of which is the input and the other the output of the differential attenuator and to which, at distances in I 4, the working wavelength from its ends 1) ) h (m1y alone with their like pc dumps, respectively, the first and second pin 14 i ii and 3,; ipyiHi to the country, of which ((. Gsnu with uU and | chi |||), the second segment 4 .1 ney ne - pc.1 and a length of 1/4 of the working wavelength, to the ends of which are connected by one pusimous electrodes of the same third and fourth) 111 diodes 5 and 6, respectively etstvenno, the third line segment 7 nere- cottages d.tinoy 1/4 working length vo.shy and fourth transmission line segment 8, which among its ends connected to second ends of |) ezka 4 respectively. The other electrode of the third pin diode 5 is connected to the input, and the other electrode of the fourth pin diode 6 is connected to the output of the differential attenuator, the other ends of the third and fourth segments 7 and 8 are connected in alternating current to o6uj, eii through a capacitor 9, the length of the fourth segment 8 is chosen equal to 1/4 of the working wavelength, and wave resistances. The n-nor nepBoi o, second, third, and fourth stubs 1, 4, 7, and 8 are the same and equal to the characteristic impedance of the path into which the differential is included: the 1st attenuator.

The device works in a consistent manner.

The first segment 1 with pin diodes 2 and 3 1 the second segment 4 with pin diodes 5 and 6 form two cnrfia passage channels, iiocTyiiinunei o to the input of the differential attenuator. Since the electrical lengths of the side channels differ by 1/2 of the working L.1INY wave, the signals that pass through the channel, 1y, turn out to be pro- во ivof:;., E and dim each other. If the control, tk) 1cc signal is zero, then the first one. the second, third, and fourth pin diodes .1Ы 2, 3, 5, and 6 are closed. In this case, the transmission coefficient of the channel, which includes segment 1, is close to unity, the other | -o channel is zero, and the entire signal with a small attenuation arrives at the output. An increase in gamma of the sending signal leads to (nerve, second, third, and fourth pin diodes 2, i, 3 and 6 are coupled), which entails partial compensation of output signals passed through different channels. The damping of the tis: functional attenuator increases At a certain value of control voltage, the transmission coefficients of both channels will become the same at the output

there will be a complete mutual compensation of the two signals transmitted through different channels. The attenuation of the differential attenuator reaches its maximum value, the value of which is limited only by the influence of parasitic signals.

parameters of schema elements. A further increase in the control voltage leads to an increase in the transmission coefficient of the channel, which includes segment 4, and the attenuation of the differential attenuator again gradually decreases to the minimum value.

 15az of differential attenuator transfer coefficients in both states with low attenuation differ by 180 °, which allows using it in

as a phase manipulator.

Segments 7 and 8 with a length of 1/4 of the working wavelength equalize the energy accumulated in both channels. This allows for the same phase dependency.

the transmission coefficients of both channels from the DI. CHY waves in the vicinity of the working wavelength and keep the phase shift between the channels constant. This reduces the attenuation dependence introduced by the differential attenuator when changing

wavelength.

Coordination of the differential attenuator over the entire range of the introduced attenuations is provided at the center frequency of the operating range by selecting the wave impedances nepi oin n of the second segment 1 and 4, equal to 1.1 x characteristic resistance TJIHI. ha, which includes differentials; G1 attenuator, and the choice of the length of the region:, r () in 1 and 4, equal to an odd number of the fourth working wavelength. In this (agonizing coordination has

the place is equal to: no resistances of the first, second, third | .-) i of the fourth pin diodes 2, 3, 5 and 6, 1 MCH is provided automatically at any values of the control voltage, as the same control currents flow through them. The third and fourth segments 7 and 8 at the central operating frequency do not affect the matching.

The minimum dimensions of the differential ateptor are achieved by selecting

the length of the segment 4, equal to 1/4, and the first segment 1 - 3/4 of the working wavelength.

Claims (1)

Invention Formula The differential 1utenator containing the first segment of the transmission line D.P1IOY 3/4 of the working wavelength, one i Oiiin I is an input, and the other is the output of the differential attenuator and to which is 1/4 the working wavelength from its ends the first and second pin diodes are connected by their same electrodes respectively, the other electrodes of which are connected to the busbar, the bus, the second segment of the transmission line with a length of 1/4 of the working wavelength, the ends of which are connected by their third electrodes with the same and fourth piri-th diodes, respectively, a third transmission line segment of length of 1/4 of the operating wavelength, and a fourth transmission line segment, which alone their ends Con to the ends of the second segment of the transmission line, respectively, while the BO.IHO resistances of the first, second, third and fourth segments of the transmission line are the same, characterized in that, in order to expand the working frequency band, another electrode of the third pin diode connected to the input, and another electrode of the fourth pin-dio. the output of the differential attenuator, the other ends of the third and fourth ribs of the AC transmission line are connected to a common bus, and the length of the fourth segment of the transmission line is equal to 1/4 of the working wavelength.