RU2629960C2 - Multirange device for selecting, amplifying and converting signals - Google Patents

Abstract

FIELD: radio engineering, communication.

SUBSTANCE: multichannel device for selecting, amplifying and converting signals comprises M subrange channels. Each channel input is connected to the input of device, and the output is the output for both channel and device. Each channel comprises a series-connected input, an input subrange bandpass filter, a first controllable attenuator, a first radio frequency amplifier, a subrange tunable bandpass filter, a second radiofrequency amplifier, a second controllable attenuator, an analog-to-digital converter, and an output. The subrange bandpass filter includes the first inductor in which the first terminal is connected to an input potential terminal of the device, and the second terminal is connected to the first terminal of the first capacitor whose second terminal is connected to the first terminals of the second and third capacitors, the second terminal of the second capacitor is connected to the common bus, the second terminal of the third capacitor is connected to the first terminal of the second inductor, in which the second terminal is connected to the first terminals of the fourth and fifth capacitors, the second terminal of the fourth capacitor is connected to the common bus, the second terminal of the fifth capacitor is connected to the first terminal of the third inductor, in which the second terminal is connected to the first terminal of the sixth capacitor and to the output potential terminal, the second terminal of the sixth capacitor is connected to the common bus. The subrange tunable bandpass filter contains a common bus, input and output potential terminals, first and second coils.

EFFECT: increasing the sensitivity in each radio channel.

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Description

The invention relates to radio communications and can be used in receiving centers in the decameter wavelength range in order to increase the reception noise immunity.

It is known that at radio centers the standard mode of operation is used when the required number of channels is received from one antenna.

To connect multiple receivers to one antenna, multiple-use receiving antennas are used [1].

The equipment includes devices that distribute the energy of signals taken from the antenna along the receiving paths.

The simplest case of multiple use of the antenna is the inclusion of several receivers on one antenna through decoupling resistances. In this case, the power transfer coefficient of such a circuit is much less than unity.

Obviously, the use of this distribution circuit will inevitably cause a deterioration in the sensitivity of the receiving channel. An increase in the number of receivers leads to a decrease in the sensitivity of each channel.

To connect N receivers to one antenna, an antenna amplifier is used - an AUR distributor. The main elements of the AUR are a multiplexer amplifier and a multi-stage transformer hybrid power splitter MTGR. Each stage of the MTGR introduces attenuation of about 3.5 dB [2, 3].

The number of single-channel radios that can be connected to the AUR is determined by the expression P = 2n, where n is the number of MTGR stages.

The gain of the amplifiers is selected from the MTGR attenuation compensation condition. An increase in the gain of a high-frequency amplifier with a large number of receiving paths is provided in the MTGR by cascading the amplification cells, which negatively affects the linearity of the AUR. It is known [2] that with an increase in the number of receivers to eight, the dynamic range of the AUR decreases significantly due to the concentration of amplification in one place, and it is impossible to distribute the gain between the cascades introducing attenuation, since the splitter is common for all receiving paths.

The second disadvantage of AUR is the wide passband of the receive gain channel. As a result, this AUR is unsuitable for operation at combined transmitting and receiving radio centers of the PPRC.

Obviously, the use of isolation resistors will lead to an unacceptable increase in attenuation of the input circuit, and the inclusion of electronic devices directly at the input of the receiver will increase the level of intermodulation noise. The development trend of modern stationary radio centers is reduced to the replacement of single-channel radios with multi-channel ones. This is especially true when using the receiver structure with direct analog-to-digital conversion.

Radio-frequency analog-to-digital receivers have significant advantages over superheterodyne receivers.

It is known that in superheterodyne receivers, the noise of a frequency synthesizer affects all its main parameters. They reduce the sensitivity and dynamic range for intermodulation distortion, impair the effective selectivity of the receiver. The noise of the local oscillator is especially affected when there is concentrated interference at the input of the receiver [4].

A multi-channel radio receiving device is known which is used in receiving centers, which acts as a multi-channel radio receiving system. A description of this device is given in RF patent No. 2308149, class. H04B 1/06, publ. 10/10/2007, bull. No. 28 [5].

A multichannel radio receiving device comprises a series-connected antenna input, a matching device, M devices for selecting, amplifying and converting signals, digital signal processing modules, and signal demodulation and decoding devices. Each of the M devices for signal selection, amplification and conversion is a single-channel multi-band radio receiving device for receiving signals in the decameter wavelength range of 2-30 MHz. Each radio receiver contains analog and digital parts. Digital signal processing is carried out at the second intermediate frequency, see RF patent No. 2308149.

A disadvantage of the known radio receiving device is the presence of a matching device on the M outputs, which leads to a significant decrease in the signal transmission coefficient in each receiving path. The presence of M multi-band radio receivers significantly increases the dimensions of the entire device.

A multi-channel radio receiver is known, the description of which is given in the patent for utility model of the Russian Federation No. 116724, publ. 05/27/2012, bull. No. 15 [6].

A known radio receiving device comprises, in series, an antenna input, a spark gap, an anti-radar filter, a protection circuit, a signal receiving and processing device, including a multi-pole broadband frequency selective device containing one input and M outputs, to each output of which a subband radio channel is connected, containing connected in series controlled attenuator, high-frequency amplifier and sub-band frequency-selective system, as well as an analog-to-digital converter.

A signal receiving and processing device may be adopted as a prototype.

The objective of the invention is to expand the arsenal of technical means in the field of input devices of multi-channel radio receiving systems.

EFFECT: increased sensitivity in each radio receiving channel.

The technical result is achieved in that in a multi-band device for selecting, amplifying and converting signals containing M subband channels, with each channel, the input is connected to the input of the device, and the output is simultaneously the output of both the channel and the device, according to the invention, each channel contains serially connected input, input subband bandpass filter, first controlled attenuator, first radio frequency amplifier, subband tunable bandpass filter, second amplifier dio frequency, second controlled attenuator, analog-to-digital converter and output,

the sub-bandpass filter contains a first inductor in which the first terminal is connected to the input potential terminal of the device, and the second terminal is connected to the first terminal of the first capacitor, the second terminal of which is connected to the first terminals of the second and third capacitors, the second terminal of the second capacitor is connected to a common bus, the second terminal of the third capacitor is connected to the first terminal of the second inductor, in which the second terminal is connected to the first terminals of the fourth and fifth capacitors, the second the water of the fourth capacitor is connected to a common bus, the second terminal of the fifth capacitor is connected to the first terminal of the third inductor, in which the second terminal is connected to the first terminal of the sixth capacitor and to the output potential terminal, the second terminal of the sixth capacitor is connected to the common bus,

tunable band-pass filter contains a common bus, input and output potential terminals, the first and second inductors, in which the first terminal is connected to the input potential terminal, the second terminal at the first inductor is connected to the common bus, the second terminal of the second inductor is connected to the first terminal the first store of discrete capacitors and with the first output of the third inductor, the second output of the first store of discrete capacitors connected to a common bus, the second output of the tre of the second inductor connected to the first terminals of the fourth and fifth inductors, the second terminal of the fourth inductor connected to the common bus, the second terminal of the fifth inductor connected to the first terminal of the second discrete capacitor magazine and the first terminal of the sixth inductor, the second terminal of the second discrete capacitor magazine with a common bus, the second terminal of the sixth inductor is connected to the output potential terminal of the filter and with the first terminal of the seventh inductor A, the second terminal of the seventh inductor is connected to a common bus,

parallel to the input of the device includes a correction element containing parallel connected inductance coil, capacitor, first and second bipolar, each of which is made in the form of series-connected inductors and capacitors.

The essence of the invention lies in the fact that in a multi-band device for selection, amplification and conversion of signals containing M subband channels, each channel contains a series-connected input, an input subband bandpass filter, a first controlled attenuator, a first radio frequency amplifier, a subband tunable bandpass filter, a second amplifier radio frequencies, second controlled attenuator, analog-to-digital converter and output,

the sub-bandpass filter contains a first inductor in which the first terminal is connected to the input potential terminal of the device, and the second terminal is connected to the first terminal of the first capacitor, the second terminal of which is connected to the first terminals of the second and third capacitors, the second terminal of the second capacitor is connected to a common bus, the second terminal of the third capacitor is connected to the first terminal of the second inductor, in which the second terminal is connected to the first terminals of the fourth and fifth capacitors, the second the water of the fourth capacitor is connected to a common bus, the second terminal of the fifth capacitor is connected to the first terminal of the third inductor, in which the second terminal is connected to the first terminal of the sixth capacitor and to the output potential terminal, the second terminal of the sixth capacitor is connected to the common bus,

tunable band-pass filter contains a common bus, input and output potential terminals, the first and second inductors, in which the first terminal is connected to the input potential terminal, the second terminal at the first inductor is connected to the common bus, the second terminal of the second inductor is connected to the first terminal the first store of discrete capacitors and with the first output of the third inductor, the second output of the first store of discrete capacitors connected to a common bus, the second output of the tre of the second inductor connected to the first terminals of the fourth and fifth inductors, the second terminal of the fourth inductor connected to the common bus, the second terminal of the fifth inductor connected to the first terminal of the second discrete capacitor magazine and the first terminal of the sixth inductor, the second terminal of the second discrete capacitor magazine with a common bus, the second terminal of the sixth inductor is connected to the output potential terminal of the filter and with the first terminal of the seventh inductor A, the second terminal of the seventh inductor is connected to a common bus,

parallel to the input of the device includes a correction element containing parallel connected inductance coil, capacitor, first and second bipolar, each of which is made in the form of series-connected inductors and capacitors.

In FIG. 1 is a functional diagram of a radio receiving device; FIG. 2. shows a circuit diagram of a sub-bandpass filter, FIG. 3 is a circuit diagram of a subband tunable band-pass filter; FIG. 4 shows the electrical circuit of the correction element.

The proposed multi-band device for selection, amplification and conversion of signals (see Fig. 1) contains an input 1 to which the inputs of the device for selection, amplification and conversion of signals 2 and correction element 3 are connected. The device for selection and amplification of signals 2 contains M subband channels 4. Each subband channel 4 contains a serially connected subband bandpass filter 5, a first controlled attenuator 6, a first radio frequency amplifier 7, a tunable subband filter 8, and a second radio frequency amplifier you are 9, the second controlled attenuator 10, the analog-to-digital converter 11 and the output 12. The input of the first controlled attenuator 6 is connected to the output of the frequency-selective device 5. The control input of the attenuator 10 is connected to the control output of the analog-to-digital converter 11.

The input device of a multi-channel radio receiving system includes a control unit. The device is powered by a separate power source.

In FIG. 2 is an electrical diagram of a sub-band pass filter 5. The sub-band pass filter 5 comprises a common bus 13 and an input potential terminal 14 to which a first output of the inductor 15 is connected. A second output of the inductor 15 is connected to a first output of the capacitor 16, the second output of which is connected to the first the terminals of the capacitors 17 and 18, the second terminal of the capacitor 17 is connected to a common bus, the second terminal of the capacitor 18 is connected to the first terminal of the inductor 19, the second terminal of the inductor 19 is connected connected to the first terminals of the capacitors 20 and 21. The second terminal of the capacitor 20 is connected to a common bus, the second terminal of the capacitor 21 is connected to the first terminal of the inductor 22, in which the second terminal is connected to the first terminal of the capacitor 23 and to the output potential terminal 24. The second terminal of the capacitor 23 is connected to a common bus.

In FIG. 3 shows an electric circuit of a sub-band tunable band-pass filter 8. The filter contains, in a common bus 25, an input potential terminal 26 to which a first terminal of inductors 27 and 28 is connected. At an inductor 27, a second terminal is connected to a common bus. At the inductor 28, the second terminal is connected to the first terminal of the discrete capacitor store 29 and the first terminal of the inductor 30, in which the second terminal is connected to the first terminals of the inductors 31 and 32. The second terminals of the discrete capacitor store 28 and the inductor 31 are connected to a common bus. The second terminal of the inductor 32 is connected to the first terminal of the discrete capacitor store 33 and to the first terminal of the inductance coil 34. The second terminal of the discrete capacitor store 33 is connected to a common bus. The second terminal of the inductor 34 is connected to the output potential terminal of the filter 35 and to the first terminal of the inductor 36.

In FIG. 4 shows the electrical circuit of element 3. Element 3 contains a potential terminal 37 and a common bus 38. The first terminals of the capacitor 39 and inductors 40, 41 and 42 are connected to the potential terminal 37. The second terminals of the capacitor 39 and inductors 40 are connected to the common bus. The second output of the inductor 41 by means of a capacitor 43 is connected to a common bus. The second output of the inductor 42 by means of a capacitor 44 is connected to a common bus.

In the device, the potential terminal 37 is connected to the input terminal of the device 1. A multi-band device for selecting, amplifying and converting signals operates as follows.

The group signal from input 1 in the frequency range 1-30 MHz is fed to the inputs of subband channels 4. The working range of the received frequencies of the decameter range 1-30 MHz is divided into M subbands. The frequency overlap coefficient of each subband is not more than 2. In each subband, the working passband is allocated by a broadband filter. Next, the signals are fed to the input of the controlled attenuator 6, and then to the input of the input amplifier of the radio frequency 7. The attenuator 6 is controlled from the input by its control element. In case of overload by noise or signals, a signal is applied to the control input of the attenuator 6 to reduce the transmission coefficient. From the output of the radio frequency amplifier 7, the signals are fed to the input of a sub-band tunable band-pass filter 8. The filter is tuned to the desired frequency using discrete capacitors 29 and 33. The capacitors 39 and 33 are changed synchronously from the control panel. The passband of the narrow-band filter 8 may be equal to 3-10% of the nominal frequency. From the output of the bandpass filter 8, the signals are fed to the input of the radio frequency amplifier 9, and then to the input of the controlled attenuator 10. From the output of the attenuator 10, the signals are fed to the input of the analog-to-digital converter 11, and then to the output of the device 12 in digital form. At the attenuator 10, the control input is connected to the control output of the analog-to-digital converter 11. In the event of an overload of the analog-to-digital converter 11 with a signal or interference, a signal is supplied to the control input of the attenuator 10 from the control output of the analog-to-digital converter and the attenuator 10 gain is reduced, excluding the analog overload -digital converter.

The inputs of the digital signal processing unit, etc., can be connected to the outputs of the input device of the multichannel radio receiving system.

Compared with the prototype of the proposed multi-band radio receiving device, each receiving channel has a higher sensitivity with higher selectivity compared to the prototype.

Information sources

1. B.K. Baranovsky Equipment for multiple use of receiving antennas of the short-wave range. M .: Communication. 1966

2. Mikhailov B.C., Shemetov I.S. Noise-resistant equipment for multiple use of the receiving HF antenna // Telecommunication. - 1981. - No. 1. S. 51-58.

3. Chelyshev V.D. Reception radio centers. - M .: Communication. - 1975.S. 205.

4. V.A. Berezovsky et al. Modern decameter communication // Radio Engineering. M. 2011.S. 94-163.

5. Bannikov I.M. et al. A new generation of digital receivers of the KB range for modern complexes of radio reception and radio monitoring // Transactions of the 13th international scientific and technical conference “Radar, Navigation, Communication”. - Voronezh. 2007. - T. 2. - S. 1270-1276.

6. RF patent №2308149, cl. H04B 1/06, publ. 10/10/2007, bull. No. 28.

7. RF patent No. 116724, publ. 05/27/2013, bull. No. 15.

Claims (6)

A multi-band device for selecting, amplifying and converting signals containing M sub-band channels, with each channel having an input connected to the input of the device, and the output simultaneously being the output of both the channel and the device, characterized in that each channel contains a series-connected input, an input subband bandpass filter, a first controlled attenuator, a first radio frequency amplifier, a subband tunable bandpass filter, a second radio frequency amplifier, a second controlled attenuator, an analog-to-digital converter, and an output the sub-bandpass filter contains a first inductor in which the first terminal is connected to the input potential terminal of the device, and the second terminal is connected to the first terminal of the first capacitor, the second terminal of which is connected to the first terminals of the second and third capacitors, the second terminal of the second capacitor is connected to a common bus, the second terminal of the third capacitor is connected to the first terminal of the second inductor, in which the second terminal is connected to the first terminals of the fourth and fifth capacitors, the second the water of the fourth capacitor is connected to a common bus, the second terminal of the fifth capacitor is connected to the first terminal of the third inductor, in which the second terminal is connected to the first terminal of the sixth capacitor and to the output potential terminal, the second terminal of the sixth capacitor is connected to the common bus, tunable band-pass filter contains a common bus, input and output potential terminals, the first and second inductors, in which the first terminal is connected to the input potential terminal, the second terminal at the first inductor is connected to the common bus, the second terminal of the second inductor is connected to the first terminal the first store of discrete capacitors and with the first output of the third inductor, the second  the output of the first discrete capacitor store is connected to a common bus, the second output of the third inductance coil is connected to the first terminals of the fourth and fifth inductors, the second output of the fourth inductance coil is connected to the common bus, the second output of the fifth inductance coil is connected to the first output of the second discrete capacitor store and the first the output of the sixth inductor, the second output of the second discrete capacitor store is connected to a common bus, the second output of the sixth inductor is connected ene with potential output terminal of the filter and a first terminal of the seventh inductor, the second terminal of the seventh inductor connected to a common bus, parallel to the input of the device includes a correction element containing parallel connected inductance coil, capacitor, first and second bipolar, each of which is made in the form of series-connected inductors and capacitors.

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