RU2431920C1 - Frequency selective device - Google Patents

Abstract

FIELD: radio engineering.

SUBSTANCE: to frequency selective device including band-pass filter tunable in frequency band by means of variable capacitors and containing M band-pass double-circuit links with inductive coupling between circuits, as well as input and output matching links there introduced are additional band-pass tunable filters (BTF) and (2M×N)+2N three-contact switches, where N - number of BTF (frequency subrange). In each of BTF the band-pass links are the same and contain two L-shaped semi-links with inductance coil in longitudinal arm and capacitor in transverse arm. Inductance coils of L-shaped semi-links are connected to each other, and to their connection point there connected is one communication inductance output, the second output of which is connected to common bus.

EFFECT: enlarging the range of working frequencies of frequency selective device and minimising the changes of its parameters at tuning.

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Description

The invention relates to the field of radio engineering and can be used as a tunable preselector of radio receivers or a frequency selector in the causative agents of wide-range radio transmitters.

A frequency-selective device is known in the form of a set of switched sub-octave filters [1, p. 112, Fig. 2.45]. This device provides minimal parameter changes in a wide frequency range, but does not have sufficient selectivity. And to increase the number of filters to several tens and at the same time complicate them to meet the increased requirements for selectivity (for example, when tuning by ± 10% of the frequency of the input signal) it is practically impractical. Therefore, in the input circuits of radio receivers, various circuits or filters are used that are tunable with variable capacitors [2, Fig. 46, Fig. 65]. However, single- and dual-circuit frequency-selective devices do not provide the necessary "range" - one of the main quality indicators of the input device of a radio receiver tunable in the frequency range [3, p. 73]. Changes in the parameters of three-band bandpass filters during tuning in a wide range of frequencies are much smaller than in two-band filters [4].

A frequency-selective device is known, which is a band-pass filter, tunable in the frequency range 30 ... 60 MHz using variable capacitors [5, p. 82.,. 86, Fig.5.7a]. Figure 1 shows a diagram of this frequency-selective device, which is closest to the proposed one, since it contains capacitors of variable capacitance and four strip links 1 connected in series, input 2 and output 3 matching links included respectively at input 4 and output 5 tunable band-pass filter, with each band-link contains two connected oscillatory circuit 6, each of which contains an inductor and a capacitor. A coupling inductance 7 is connected between the circuits.

This device has the following disadvantages. Firstly, the tuning range with the overlap coefficient equal to two in frequency is insufficient, and its expansion will lead to a deterioration in the parameters of the frequency-selective device at the edges of the frequency range. Secondly, the prototype has a complex structure, characterized by the presence of taps on the inductance coils of the circuits and matching links, which does not provide high-quality transformation at a high frequency due to the small coupling coefficient between the parts of the windings and the influence of secondary parameters. As a result, the connection between the circuits becomes frequency-dependent, which leads to significant changes in the parameters of the known device when it is tuned in a wide frequency range.

The objective of the invention is to expand the range of operating frequencies of a frequency-selective device and minimize changes in its parameters during tuning.

This problem is solved in that in a frequency-selective device containing variable capacitors and a tunable bandpass filter, which contains M band links connected in series, input and output matching links included respectively at the input and output of a tunable bandpass filter, with each bandpass The link contains two oscillatory circuits, each of which contains an inductor and a capacitor, and the coupling inductance is connected between the circuits, additional specifically, N-1 tunable bandpass filters, where N = 1, 2, 3, ... is the number of frequency subbands, and each tunable bandpass filter contains M band links connected in series, where M = 1, 2, 3, ..., input and output matching links included respectively at the input and output of a tunable bandpass filter, with each oscillating circuit in each band link made in the form of a L-shaped half link with an inductor in the longitudinal arm and a capacitor in the transverse arm, and the inductor coils the characteristics of the L-shaped half links are connected to each other, and one connection inductance terminal is connected to the connection point, the second terminal of which is connected to the common bus, in addition, additional (2M × N) + 2N three-contact switches are introduced, each capacitor of variable capacitance has the ability to connect in parallel to the transverse arm capacitor of the L-shaped half link of the corresponding band link of one of the N band tunable filters through the corresponding three-pin switch and is common to these x L-shaped half-links, with the input of each band-pass tunable filter connected to the input of the frequency selective device through the corresponding input three-pin switch, and the output of each band-tunable filter connected to the output of the frequency-selective device through the corresponding output three-pin switch, in each band tunable filter, all input and output matching links are made in the form of a double-winding transformer, and all strip links are made s are the same, and the capacitance of each capacitor of variable capacitance is determined by the formula:

C = C ₀ [(F _max / F) ² -1],

where F _max - the maximum frequency of the included frequency sub-band;

F is the tuning frequency of the frequency selective device;

With ₀ - the minimum total capacity of each oscillatory circuit at F = F _max .

Figure 2 shows a diagram of the claimed device. The frequency-selective device contains capacitors 8 of variable capacity and N tunable bandpass filters, where N = 1, 2, 3, ... is the number of frequency subbands. Each of the tunable bandpass filters contains M band links 1 connected in series, input 2 and output 3 matching links included respectively at the input and output of the tunable bandpass filter, while in each band link 1 each oscillatory circuit 4 is made in the form of a L-shaped half link with an inductor 5 in the longitudinal arm and a capacitor 6 in the transverse arm, and the inductors of the 5 L-shaped half links are connected to each other, and one terminal ind ktivnosti connection 7, the second terminal of which is connected to the common bus. In addition, an additional (2M × N) + 2N three-pin switch is introduced into the frequency selective device, and each variable capacitor 8 has the ability to connect in parallel to the capacitor 6 of the L-shaped half link of the corresponding band-link 1 of one of the N tunable bandpass filters through the corresponding three-pin switch 9 and is common to these L-shaped half links, with the input of each band-pass tunable filter connected to the input 10 of the frequency selective device through Resp input switch 11 and the output of each bandpass tunable filter 12 is connected to the output of the frequency-selective device via the respective output switch 13.

All input 2 and output 3 matching links of the frequency selective device are made in the form of a double winding transformer.

In each band-pass tunable filter of the frequency-selective device, all band-links 1 are made identical, while the capacitance of each variable capacitor 8 is determined by the formula:

C = C ₀ [(F _max / F) ² -1],

where F _max - the maximum frequency of the included frequency sub-band;

F is the tuning frequency of the frequency selective device;

With ₀ - the minimum total capacity of each oscillatory circuit at F = F _max .

To increase the tuning speed of the frequency-selective device, variable capacitors 8 are made in the form of a discrete variable capacitor (DKPE), which is a set of binary-switched capacitors that are switched according to the binary law.

Frequency-selective device operates as follows.

In the initial state, the movable contacts of all switches 9, 11 and 13 are closed with fixed contacts connected to a common bus. When tuning the frequency-selective device to a given frequency of the input signal, the capacitance of the variable capacitors 8 is set equal to the calculated one (see formula) and the corresponding tunable bandpass filter is switched on, in the tuning frequency range of which there is the frequency of the input signal. In this case, the movable contacts of the switches 9, 11 and 13, corresponding to the included tunable bandpass filter, are transferred to a different position and the input signal passes to the output of the frequency-selective device.

The proposed frequency-selective device has a wide tuning range due to the presence of N tunable bandpass filters. Small changes in the parameters of the frequency-selective device are achieved by the fact that, firstly, in each band link, the interconnection is made in the form of a coupling inductance connecting the connection point of the inductances of the L-shaped half links with a common bus. The magnitude of the inductive coupling between the circuits in the claimed device does not depend on the frequency, in contrast to the prototype, where the practical feasibility of the coupling inductance, which is excessively large in narrow-band filters, requires its transformation.

Secondly, the input and output matching links in the claimed device are made in the form of a double winding transformer with a coupling coefficient close to unity, which ensures the necessary transformation of the high input and output impedances of each bandpass tunable filter with virtually no loss. Thirdly, due to the fact that in the claimed device all the band links in each tunable bandpass filter are made identical, the exact initial tuning of all loops to the given input signal frequencies is provided, which, in turn, provides small changes in the parameters of the claimed frequency-selective device when its tuning in the frequency range.

Information sources

1. Red E. Reference manual on high-frequency circuitry: Circuits, blocks, 50-ohm technology: TRANS. with him. - M .: 1990.

2. Golovin OV Systems for automatic tuning of radio receivers of trunk communication. - M.: Communication, 1980.

3. Zavarin G. D., Martynov V. A., Fedortsov B. F. Radio receivers - M .: Military Publishing House, 1973.

4. A.G. Zinoviev, Analysis of tunable bandpass filters on coupled circuits. - Communication technology, ser. TRS, 1992, issue 9, p. 42-55.

5. Naroditsky A.I. Band antenna filters. - M.: Communication, 1978.

Claims (3)

1. Frequency-selective device containing variable capacitors and a tunable bandpass filter, which contains M band links connected in series, input and output matching links included respectively at the input and output of a tunable bandpass filter, with each band link containing two oscillatory circuits , each of which contains an inductor and a capacitor, and a coupling inductance is included between the circuits, characterized in that an additional N-1 floor is introduced tunable filters, where N = 1, 2, 3, ... is the number of frequency subbands, and each tunable bandpass filter contains M band links connected in series, where M = 1, 2, 3, ..., input and output matching links, included respectively at the input and output of a tunable bandpass filter, with each oscillating circuit in each band link made in the form of a L-shaped half link with an inductance coil in the longitudinal arm and a capacitor in the transverse arm, and the G-shaped inductance coils of the half-links are connected to each other, and one connection inductance terminal is connected to the connection point, the second terminal of which is connected to the common bus, in addition, additional (2M · N) + 2N three-contact switches are introduced, and each capacitor of variable capacitance has the ability to connect parallel to the transverse shoulder capacitor of the L-shaped half-link of the corresponding band-link of one of the N tunable band-pass filters through the corresponding three-pin switch and is common to these L-shaped all the links, and the input of each band-pass tunable filter is connected to the input of the frequency selective device through the corresponding input three-pin switch, and the output of each band-tunable filter is connected to the output of the frequency-selective device through the corresponding output three-pin switch. 2. The frequency-selective device according to claim 1, characterized in that all input and output matching links are made in the form of a double winding transformer. 3. The frequency-selective device according to claim 1, characterized in that in each tunable band-pass filter, all band-pass links are made the same, while the capacitance of each variable capacitor is determined by the formula: C = C ₀ [(F _max / F) ² - 1], where F _max is the maximum frequency of the included frequency sub-band; F is the tuning frequency of the frequency selective device; With ₀ - the minimum total capacity of each oscillatory circuit at F = F _max .

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