RU2722340C1 - M-channel frequency-selective device - Google Patents

Abstract

FIELD: radio engineering and communication.

SUBSTANCE: invention relates to radio communication and can be used in decameter range radio receivers. M-channel frequency-selective device has common bus (1) and an input potential terminal (2), as well as a frequency-selective system comprising M channels (1_k…3_k). Each channel has separate output (terminals 4 and 5). All channels by input (terminals 6 and 7) are connected in series. Each channel comprises an input tunable band-pass filter formed by elements 8, 9, 13, 14 and an input circuit of the differential amplifier, and having coupling coil (10), and an output tunable band-pass filter formed by elements 16, 17, 18, 19 and the output circuit of differential amplifier (15) and having coupling coil (20).

EFFECT: wider range of equipment in the field of frequency-selective systems.

1 cl, 4 dwg

Description

The invention relates to radio communications and can be used in radio receivers decameter wavelength range.

The input device of a multi-channel radio receiving system is known, comprising an antenna input, a spark gap, an anti-radar filter, a protection circuit, a selection device, connected in series. amplification and signal conversion, including M-channel broadband frequency selective device containing one input connected to the output of the protection device, and M outputs, to each output of which a sub-band radio channel is connected.

As a prototype, a device can be taken as part of the input device, namely, the M-channel broadband frequency selective device contains M bandpass filters, the inputs of which are connected to the input of the device, each filter having a separate output 1.

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

EFFECT: obtaining a circuit of a channel two-tune tunable band-pass filter.

This is achieved by the fact that in the M-channel frequency selective device containing a common bus and input potential terminal, as well as a frequency selective system including M channels, each channel has a separate output, according to the invention,

each channel contains the first and second input terminals, a common bus, an input oscillating circuit containing parallel connected input element of variable capacitance and an inductor equipped with a coupling winding, the conclusions of which are connected to the input terminals, respectively, the first output of the oscillating circuit is connected to a common bus, the second output the oscillatory circuit is connected to the first conclusions of the first and second two-terminal, the second conclusions of which are connected to the first and second inputs of the differential amplifier, respectively, the first and second two-terminal are made in the form of capacitors, the first conclusions of the third and fourth two-terminal are connected to the first and second outputs of the differential amplifier, the second conclusions which are connected to the first output of the output oscillating circuit, containing a parallel connected output capacitive element and an inductor equipped with a coupling winding, the conclusions of which are connected to the output terminals, the second output of the output oscillatory the circuit is connected to a common bus, the third and fourth two-terminal devices are made in the form of capacitors, the input and output capacitive elements are made in the form of a capacitor and a varicap connected in series, at the first channel the first input terminal is connected to the input potential terminal of the device, the second input terminal is connected to the first input terminal of the second channel, in which the second input terminal is connected to the first input terminal of the subsequent channel, etc., the second input terminal M of the channel is connected to a common bus.

The essence of the invention lies in the fact that in the M-channel frequency-selective device containing a common bus and input potential terminal, as well as a frequency-selective system, including M channels, while

each channel contains the first and second input terminals, a common bus, an input oscillating circuit containing parallel connected input element of variable capacitance and an inductor equipped with a coupling winding, the conclusions of which are connected to the input terminals, respectively, the first output of the oscillating circuit is connected to a common bus, the second output the oscillatory circuit is connected to the first conclusions of the first and second two-terminal, the second conclusions of which are connected to the first and second inputs of the differential amplifier, respectively, the first and second two-terminal are made in the form of capacitors, the first conclusions of the third and fourth two-terminal are connected to the first and second outputs of the differential amplifier, the second conclusions which are connected to the first output of the output oscillating circuit, containing a parallel connected output capacitive element and an inductor equipped with a coupling winding, the conclusions of which are connected to the output terminals, the second output of the output oscillatory the circuit is connected to a common bus, the third and fourth two-terminal devices are made in the form of capacitors, the input and output capacitive elements are made in the form of a capacitor and a varicap connected in series, at the first channel the first input terminal is connected to the input potential terminal of the device, the second input terminal is connected to the first input terminal of the second channel, in which the second input terminal is connected to the first input terminal of the subsequent channel, etc., the second input terminal M of the channel is connected to a common bus.

In FIG. 1 is an electrical diagram of an M-channel frequency selective device. FIG. 2 is an electrical diagram of a channel bandpass filter; FIG. 3 shows the main and equivalent differential bridge circuit of the input link; in FIG. 4 shows the main and equivalent differential bridge circuit of the output link,

The frequency-selective device contains a common bus 1, input potential terminal 2, M channels 3, each of which contains input and output tunable narrow-band filters, the output of which is connected to output potential terminals of channel 4 and 5. Each channel has input terminals 6 and 7, at the first channel, terminal 6 is connected to input terminal 2, and terminal 7 is connected to terminal 6 of the second channel. For channel M, terminal 6 is connected to terminal 7 of the previous channel, and terminal 7 is connected to terminal 1 (common bus) of the frequency selective device. Thus, all input channels are consequently switched on.

In FIG. 2 is an electrical diagram of a channel tunable two-link bandpass filter. The filter contains input terminals 6 and 7, the input oscillating circuit, contains parallel connected input element of variable capacitance 8 and an inductor 9, which is equipped with a coupling winding 10, in which the terminals are connected to input terminals 6 and 7. The input element of variable capacitance 8 contains connected in series the capacitor 11 and the varicap 12. The connection point of the capacitor 11 and the varicap 12 is connected to the control unit. The first output of the oscillating circuit is connected to a common bus, the second to the first terminals of the capacitors 13 and 14, the second terminals of which are connected to the inputs of the differential amplifier 15. The outputs of the differential amplifier 15 are connected to the first terminals of the capacitors 16 and 17, the second terminals of which are connected to the first output terminal an oscillating circuit comprising a parallel connected output capacitive element 18 and an inductor 19, which is equipped with a coupling winding 20, the terminals of which are connected to the output terminals 4 and 5. The second output of the output oscillating circuit is connected to a common bus. The output capacitive element 18 is made in the form of a capacitor 21 and a varicap 22 connected in series. The connection point of the capacitor 21 and the varicap 22 is connected to the control unit.

The input elements 8-14, together with the input part of the differential amplifier 15 form a circuit (see Fig. 3), which is equivalent to a differential bridge circuit containing in each arm an inductance coil, a variable capacitor and a constant capacitor connected in parallel. The indicated circuit is an input tunable band-pass filter having a second class in characteristic impedance and a first class in characteristic hatching.

The output part of the differential amplifier 15 together with the elements 16-22 form a circuit (see Fig. 4), which is equivalent to a differential bridge circuit containing in each arm an inductance coil, a variable capacitor and a constant capacitor connected in parallel. This circuit is an output tunable bandpass filter having a second class in characteristic impedance and a first class in characteristic attenuation. Tuning the average frequency of the passband is performed using varicaps 12 and 22.

Thus, in general, the channel device performs the function of a two-link tunable bandpass filter.

Sources of information

RF patent No. 116724, Cl. ⁷ Н04В 1/06, publ. 05/25/2012.

Claims (1)

M-channel frequency selective device containing a common bus and input potential terminal, as well as a frequency selective system including M channels, each channel having a separate output, characterized in that each channel contains the first and second input terminals, a common bus , an input oscillating circuit comprising a parallel connected input element of variable capacitance and an inductor equipped with a coupling winding whose terminals are connected to input terminals, respectively, the first output of the oscillating circuit is connected to a common bus, the second output of the oscillating circuit is connected to the first terminals of the first and second two-terminal, the second terminals of which are connected to the first and second inputs of the differential amplifier, respectively, the first and second two-terminal devices are made in the form of capacitors, the first conclusions of the third and fourth two-terminal devices are connected to the first and second outputs of the differential amplifier, the second conclusions of which are connected to the first output terminal ohm oscillatory circuit comprising a parallel connected output capacitive element and an inductor equipped with a coupling winding, the terminals of which are connected to the output terminals, the second output of the output oscillating circuit is connected to a common bus, the third and fourth two-terminal circuits are made in the form of capacitors, the input and output capacitive elements are made in the form of a capacitor and a varicap connected in series, at the first channel, the first input terminal is connected to the input potential terminal of the device, the second input terminal is connected to the first input terminal of the second channel, in which the second input terminal is connected to the first input terminal of the subsequent channel, etc. , the second input terminal M of the channel is connected to a common bus.

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