RU2691762C1 - M-channel frequency-selective device - Google Patents

Abstract

FIELD: radio equipment and communications.SUBSTANCE: invention relates to the radio communication, and can be used in the decameter wave band radio receivers. M-channel frequency selective device has a common bus, an input potential terminal to which the input broadband filter input is connected, an amplifying element, a group comprising M output narrow-band filters. Input broadband filter includes inputs of input differential amplifier, in which to first output is connected first subgroup containing M / 2 output tunable filters with odd serial numbers, and to second output is connected second subgroup containing M / 2 output filters with even serial numbers, in each group, inputs of all filters are connected in series, output of each output tunable filter is simultaneously output of device. Input broadband filter having a large steep characteristic in the transition regions comprises a common bus and an input potential terminal connected to the input potential terminal of the frequency selective device, to which is connected first input of input coupling coil of inductance coil, in which first output is connected to first outputs of first capacitor, as well as first and second two-terminal devices, second leads of the communication winding, the input inductance coil and the first capacitor are connected to the common bus, the second outputs of the first and second two-terminal devices are connected to the first and second inputs of the input differential amplifier, respectively, first and second dipoles contain parallel connected capacitor and two two-terminal devices, each of which is made in the form of series-connected inductance coil and capacitor.EFFECT: improved functional and technical capabilities, namely obtaining of M channels with increased level of attenuation in stopping bands at each channel.1 cl, 8 dwg

Description

The invention relates to radio communications and can be used in receiving devices of a decameter wave range.

A frequency selective device is known, comprising a serially connected input, a broadband filter, a first switch, a group of narrow band filters, a second switch, and an output. This device plays the role of a single channel preselector in the WI 8888 receiving <Watkins Johnson radio receiver [1].

This device can be taken as a prototype.

The objective of the invention is the expansion of the arsenal of technical tools in the field of M-channel frequency-selective systems ..

The technical result is an increase in the functional and technical capabilities, namely, obtaining M channels with an increased level of attenuation in the delay bands in each channel.

The technical result is achieved in that the M channel frequency selective device comprising a common bus, an input potential terminal to which the input of the input wideband filter is connected, an amplifying element, a group containing M output narrowband filters according to the invention,

the broadband filter includes the inputs of a differential amplifier, in which the first subgroup is connected to the first output, containing M / 2 output tunable filters with odd sequence numbers, and the second subgroup, containing the M / 2 output filters with even serial numbers, is connected to the second output in each group the inputs of all filters are connected in series, the output of each filter is simultaneously the output of the device, while

The wideband input filter contains a common bus and an input potential terminal connected to the input potential terminal of a frequency selective device to which the first terminal of the connection winding of the input inductor is connected, in which the first terminal is connected to the first terminals of the first capacitor, as well as the first and second double poles , the second terminals of the coupling winding, the input inductor and the first capacitor are connected to a common bus; the second terminals of the first and second two-pole devices are connected to the first and second strokes input differential amplifier, respectively, the first and second two-pole comprise a capacitor connected in parallel and two two-terminal network, each of which is in the form soedinennyz series inductor and a capacitor,

each output tunable filter contains a common bus, the first and second potential input terminals to which the terminals of the connection winding of the input inductor are connected, in which the first terminal is connected to the first terminals of the first, second and third capacitors, the second terminals of the input inductor and the first capacitor are connected to A common bus, the second terminals of the second and third kondesatoroy connected to the first and second inputs of the output differential amplifier, respectively, at the output differential force The first output of the fourth capacitor is connected to the first output, and the first output of the fifth capacitor is connected to the second output, the second terminals of the fourth and fifth capacitors are connected to the first terminals of the sixth capacitor and the output inductor, the second terminals of which are connected to the common bus, the output inductor is wired connection, the conclusions of which are connected to the output terminals of the filter, the first and sixth capacitors are made in the form of a store of discrete capacitors.

The essence of the invention lies in the fact that the M channel frequency-selective device containing a common bus, an input potential terminal to which the input of the input wideband filter is connected, an amplifying element, a group containing M output narrowband filters,

the broadband filter includes the inputs of a differential amplifier, in which the first subgroup is connected to the first output, containing M / 2 output tunable filters with odd sequence numbers, and the second subgroup, containing the M / 2 output filters with even serial numbers, is connected to the second output in each group the inputs of all filters are connected in series, the output of each filter is simultaneously the output of the device, while

The wideband input filter contains a common bus and an input potential terminal connected to the input potential terminal of a frequency selective device to which the first terminal of the connection winding of the input inductor is connected, in which the first terminal is connected to the first terminals of the first capacitor, as well as the first and second double poles , the second terminals of the coupling winding, the input inductor and the first capacitor are connected to a common bus; the second terminals of the first and second two-pole devices are connected to the first and second strokes input differential amplifier, respectively, the first and second two-pole comprise a capacitor connected in parallel and two two-terminal network, each of which is designed as a series-connected inductor and condenser,

each output tunable filter contains a common bus, the first and second potential input terminals to which the terminals of the connection winding of the input inductor are connected, in which the first terminal is connected to the first terminals of the first, second and third capacitors, the second terminals of the input inductor and the first capacitor are connected to A common bus, the second terminals of the second and third condensers are connected to the first and second inputs of the output differential amplifier, respectively, at the output differential force The first output of the fourth capacitor is connected to the first output, and the first output of the fifth capacitor is connected to the second output, the second terminals of the fourth and fifth capacitors are connected to the first terminals of the sixth capacitor and the output inductor, the second terminals of which are connected to the common bus, the output inductor is wired connection, the conclusions of which are connected to the output terminals of the filter, the first and sixth capacitors are made in the form of a store of discrete capacitors.

FIG. 1 is a circuit diagram of an M channel frequency selective device; FIG. 2 shows the electrical circuit of the input broadband filter; FIG. 3 shows the electrical circuit output tunable bandpass filter.

M channel frequency-selective device (see Fig. 1) contains a common bus 1, an input potential terminal 2, an input wideband filter 3, which includes the input part of the differential amplifier 4. The first subgroup 5 of the output tunable is connected to the first output of the differential amplifier 4 band-pass filters 6, containing m / 2 filters with odd-numbered numbers. To the second output of the differential amplifier 4 is connected the second subgroup 7, containing M / 2 output tunable bandpass filters 8 with even serial numbers. The output terminals 9 and 10 of each filter is simultaneously the output of the device.

FIG. 2 shows a diagram of the input broadband filter 3.

The wideband input filter 3 contains a common bus 1, an input potential terminal 2 connected to the first terminal of the communication winding 11 of the input coil 12, the second terminal of which is connected to the common bus. In parallel with the terminals of the inductor 12, a capacitor 13 is connected. For the inductor 12 and the capacitor 13, the first terminals are connected to the first terminals of the two-terminal 14 and 15, and the second to the common bus. The two-port 14 contains a parallel-connected capacitor 16 and two-pole 17 and 18, each of which contains a series-connected inductor and a capacitor. The second terminal of the two-terminal 14 is connected to the first input of the differential amplifier 4. The two-terminal 15 contains a parallel-connected capacitor 19 and two-terminal 20 and 21, each of which contains an inductance coil connected in series and a capacitor. The second output of the two-port 15 is connected to the second input of the differential amplifier 4. Figure 3 shows the equivalent differential bridge circuit of the input filter. The circuit contains in each arm a multi-element two-port network, containing an inductance coil connected in parallel, a capacitor and two two-port circuits, each of which contains an inductance coil connected in series and a capacitor. Figure 4 shows the conditional distribution of the resonant frequencies of the shoulders of the differential-bridge filter. The filter circuit has a fourth class in characteristic impedance and a fifth class in working attenuation. The presence of two poles of the working attenuation provides a large steepness characteristic of the working attenuation in the transition regions.

FIG. 5 shows the electrical circuit subgroups output tunable bandpass filters, the inputs of which are connected in series. In each subgroup, the first input terminal at the first tunable bandpass filter is connected to the corresponding output of the differential amplifier. The second input terminal is connected to the first input terminal of the subsequent filter, etc ... At the last filter in the group, the second input terminal is connected to the common bus.

At the output tunable bandpass filter (see Fig. 6), the terminals of the coil of connection 24 of the inductor 25 are connected to the input terminals; the first terminals of the capacitors 26, 27 28 are connected to the first terminal. The second terminals of the inductor 25 and the capacitor 26 are connected to the common bus . The second output of the capacitor 27 is connected to the first input of the differential amplifier 29. The second output of the capacitor 28 is connected to the second input of the differential amplifier 29, in which the first output is connected to the first output of the capacitor 30, and the second output is connected to the first output of the capacitor 31. The second terminals of the capacitors 30 and 31 is connected to the first terminals of the capacitor 32 and the inductor 33, in which the second terminals are connected to a common bus. The inductor 33 is provided with a communication winding 34, the terminals of which are connected to the output terminals of the device 9 and 10. The capacitors 26 and 32 are made in the form of a store of discrete capacitors. Figure 7 shows the main and equivalent circuits of the input and output link of the output tunable bandpass filter. Each arm of each link contains parallel inductors and a variable capacitor. FIG. 8 shows the conditional distributions of the resonant frequencies of the shoulders of a differential bridge filter.

The scheme of each link has the first class in characteristic attenuation and the second class in characteristic impedance. All variable capacitors change the capacitance value synchronously. The device works as follows.

The group signal is fed to the input of an input wideband filter, which allocates a frequency spectrum equal to the bandwidth of the input filter. This amplified spectrum is fed to the outputs of the differential amplifier. Each output tunable filter allocates its own frequency spectrum, which is determined by the bandwidth of this filter. This spectrum is fed to the output of the filter. An analog-to-digital converter can be connected to the output of each channel.

The frequency-selective device can be made with a gap between adjacent bandwidths and adjacent ones.

Information sources

1. O.V. Golovin. Professional radio receivers of the decametre range. -M..Radio and Communications, 1985, p. 271, fig. 9.22

Claims (4)

M channel frequency selective device containing a common bus, a potential input terminal to which the input of the wideband filter input is connected, an amplifying element, a group containing M output narrowband filters, characterized in that wideband input filter includes inputs of an input differential amplifier, in which a first subgroup is connected to the first output, containing M / 2 output tunable filters with odd-numbered numbers, and a second subgroup, containing M / 2 output filters with even-numbered numbers, is connected to the second output to each group, the inputs of all filters are connected in series, the output of each output tunable filter is simultaneously the output of the device, while The wideband input filter contains a common bus and an input potential terminal connected to the input potential terminal of a frequency selective device to which the first terminal of the connection winding of the input inductor is connected, in which the first terminal is connected to the first terminals of the first capacitor, as well as the first and second double poles, the second terminals of the coupling winding, the input inductor and the first capacitor are connected to a common bus; the second terminals of the first and second two-pole devices are connected to the first and second the inputs of the input differential amplifier, respectively, the first and second two-terminal contain a parallel-connected capacitor and two two-terminal, each of which is made in the form of inductors and a capacitor connected in series, each output tunable filter contains a common bus, the first and second potential input terminals to which the terminals of the connection winding of the input inductor are connected, in which the first terminal is connected to the first terminals of the first, second and third capacitors, the second terminals of the input inductor and the first capacitor are connected to A common bus, the second terminals of the second and third capacitors are connected to the first and second inputs of the output differential amplifier, respectively, at the output differential amplifier The first output of the fourth capacitor is connected to the first output, and the first output of the fifth capacitor is connected to the second output, the second terminals of the fourth and fifth capacitors are connected to the first terminals of the sixth capacitor and the output inductor, the second terminals of which are connected to the common bus, the output inductor is wired connection, the conclusions of which are connected to the output terminals of the filter, the first and sixth capacitors are made in the form of a store of discrete capacitors.

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