RU2632818C1 - Broadband radiocommunication system with frequency duplex - Google Patents

Abstract

FIELD: radio engineering, communication.

SUBSTANCE: creation of a broadband radiocommunication system with a frequency duplex (with increased noise immunity) and with a reduced negative effect of the transmission path of the system on the receiving path of the system by suppressing the combinational frequencies of the transmission path, as well as with a reduced negative effect of the transmission path of the system on the receiving paths of other radiocommunication systems being in close proximity (in order to improve the electromagnetic compatibility), by including electronic tunable bandpass filter (ETBF) 306 in the composition of a transmitter-receiver 302.

EFFECT: improving the quality of communication.

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Description

The invention relates to the field of radio communications, and in particular to broadband frequency duplex radio communication systems using Code Division Multiple Access (CDMA) and multi-frequency code division multiplexing (MultiCarrier CDMA - MC-CDMA) for direct and reverse channel separation by Frequency Division Duplexing The claimed invention can be used in data transmission systems.

Closest to the claimed invention is a broadband radio communication system with frequency duplex, described in patent US 5886987 A ("FDD / CDMA transmission / reception system"), which contains a transceiver, antenna and digital modem connected to the transceiver with two intermediate frequency cables, and the transceiver connected to the antenna with one high-frequency cable (Fig. 1). The transceiver consists of:

- a transmitting converter (CVD), which transfers the intermediate frequency to a high frequency power amplifier (PA), which amplifies the signal power to the required level of the first bandpass filter (PPF), which provides filtering of spectral components lying outside the working frequency band. KNV PRM, UM and PPF form the transmitting path of the transceiver;

- a second band-pass filter (PPF), which provides filtering of interference signals lying outside the working frequency band of a low-noise amplifier (LNA), which amplifies the high-frequency signal supplied from the antenna, the receiving converter (PRF КНВ), which carries out the transfer of high-frequency to an intermediate frequency , while PPF, LNA and PF Knv form the receiving path of the transceiver;

- a controller (KONTR), which controls the KNV and KNV PWM;

- a circulator (C), which provides frequency isolation between the receiving and transmitting paths of the transceiver. This radio communication system is selected as a prototype of the claimed invention.

The disadvantage of the radio communication system of the prototype is that when converting signals in a transmitting converter (KNV PRD), the operations of adding and subtracting frequencies using signal mixers are used, and at the output of the mixers, due to non-linear processes, along with useful signals, a number of combinational components are formed, being parasitic. This phenomenon, firstly, leads to a deterioration in the quality of communication when combinational frequencies fall into the passband of the receiver and, secondly, it can be a source of interference for other radio systems. FIG. 2 illustrates the disadvantages of the radio communication system of the prototype. In FIG. Figure 2 shows that the Raman frequency f2 falls into the passband of the receiver, which can degrade the quality of communication, and the Raman frequency f1 is outside the operating range of the system and can be a source of interference for other radio systems.

The objective of the invention is the creation of a broadband radio communication system with frequency duplex with improved radio quality (with improved noise immunity) and with a reduced negative effect of the transmission path of the system on the reception path of the system by suppressing the combination frequencies of the transmission path, as well as with a reduced negative effect of the transmission path of the system on the reception paths other radio communication systems in close proximity (to improve electromagnetic compatibility), due to the inclusion in aB transceiver 302 (FIG. 3) of the electronic tunable bandpass filter (EPPF) 306.

The problem is solved by creating a broadband radio communication system with a frequency duplex containing a digital modem 301 (Fig. 3), which is connected by two intermediate frequency cables to a transceiver 302, which is connected to the antenna by one high-frequency cable, and the transceiver 302 includes a transmit path, a receive a path, a circulator 312 and a controller 305, wherein the transmit path is formed by a transmit converter 304, which is connected to a digital modem 301 and to a power amplifier 307, which is connected to the first strip filter 308, and the receiving path is formed by a receiving converter 309, which is connected to a digital modem 301 and to a low-noise amplifier 310, which is connected to a second band-pass filter 311, which is connected to a circulator 312, which is connected to the first band-pass filter 308 and to the antenna 303, and the controller 305 is connected to a transmitting converter 304, a receiving converter 309 and a digital modem 301, characterized in that the transmitting converter 304 is connected to a power amplifier 307 through an electronic tunable bandpass filter 306, which is connected to the control ler 305, while

- the transmitting converter 304 is configured to transfer the intermediate frequency to the high frequency of the power amplifier 307, which is configured to amplify the signal power to the desired level of the bandpass filter 306, configured to filter spectral components lying outside the operating frequency band;

- the second band-pass filter 308 is configured to filter interference signals lying outside the working frequency band of the low-noise amplifier 310, configured to amplify the high-frequency signal supplied from the antenna 303, the receiving converter 309 is configured to transfer high-frequency to an intermediate frequency;

- electronic tunable band-pass filter 306 is configured to filter spurious combination components;

- the controller 305 is configured to control a transmitting converter 304, a receiving converter 309, as well as an electronic tunable band-pass filter 306, while generating a control code for tuning the tunable band-pass filter 306 to an appropriate frequency;

- the circulator 312 is configured to perform frequency isolation between the receiving and transmitting paths of the transceiver 302.

In a preferred embodiment of a broadband duplex radio frequency communication system, the electronic tunable bandpass filter 306 consists of two parallel tunable oscillatory circuits 401, 402 (FIG. 4) connected by a tunable communication element 403, and the controller 305 comprises a digital-to-analog converter 404, the outputs of which are connected with inputs of tunable oscillatory circuits 401, 402 and tunable communication element 403, and parallel tunable circuits 401, 402 are formed by varactors VD1, VD2 and and by inductances L1, L2, the digital-to-analog converter 404 is capable of converting the control code of the controller 305 into control voltages V1 and V2 for an electronic tunable band-pass filter 306, configured to be tuned by changing the capacitance of the varactors VD1, VD2, by applying a control voltage to them V1, as well as by changing the capacity of the tunable communication element 403 by applying to it a control voltage V2.

In a preferred embodiment of a broadband radio communication system with a frequency duplex, the electronic tunable band-pass filter 306 is configured to self-diagnose when the operating frequency changes and when the communication quality deteriorates (a large number of bit errors or code recovery of information at the far end), and in the self-diagnosis mode of the electronic tunable band-pass filter 306 decreases the output power of the first power amplifier 307 of the transmitting path, and the bandpass filter 311 , the low-noise amplifier 310 and the receiving path converter 309 are turned on at the frequency of the transmitting path (the so-called "radio frequency loop"), and the digital modem 301 is configured to digitally process the signal, while determining changes in the amplitude-frequency characteristic (AFC) of the working signal which introduces an electronic tunable band-pass filter 306, and transmitting to the controller 305 the necessary information to correct the control voltages V1 and V2 in order to reduce the influence of the electronic tunable band-pass This filter 306 to an operation signal.

For a better understanding of the claimed invention the following is a detailed description with the corresponding graphic materials.

FIG. 1. The block diagram of a broadband radio communication system with frequency duplex, made according to the prototype.

FIG. 2. The frequency response of the electronic tunable band-pass filter of a radio communication system with a frequency duplex, made according to the prototype.

Items:

Prd - bandwidth of the transmitter;

Prm - receiver bandwidth;

f0 is the central frequency of the transmitter;

fн, fв - lower and upper frequencies of the operating range of the system;

f1, f2 - Raman frequencies.

FIG. 3. The block diagram of a broadband radio communication system with frequency duplex, made according to the invention.

Items:

301 - digital modem

302 — transceiver;

303 - antenna;

304 - transmitting converter (KNV PRD);

305 - controller;

306 - electronic tunable bandpass filter (EPPF);

307 - power amplifier (PA);

308 - the first band-pass filter (PPF);

309 - receiving converter (PFP КНВ);

310 - low noise amplifier (LNA);

311 - second band-pass filter (PPF);

312 - circulator (C).

FIG. 4. The block diagram of the electronic tunable bandpass filter of a broadband radio communication system with frequency duplex, made according to the invention.

Items:

401, 402 - tunable oscillatory circuits;

403 - tunable communication element;

404 - digital-to-analog converter;

VD1, VD2 - varactors;

L1, L2 - inductance;

V1, V2 - control voltage;

DAC - Digital-to-Analog Converter.

Let us consider in more detail the functioning of the claimed broadband radio communication system with frequency duplex (Fig. 3, 4).

A broadband frequency duplex radio communication system comprises a digital modem 301, which is connected by two intermediate frequency cables to a transceiver 302, which is connected to the antenna by a single high-frequency cable. The transceiver 302 includes a transmit path, a receive path, a circulator 312, and a controller 305. The transmit path is formed by a transmit converter 304, which is connected to a digital modem 301, and to a power amplifier 307, which is connected to a first band-pass filter 308. The receive path is formed by a receive converter 309, which is connected to a digital modem 301 and to a low noise amplifier 310, which is connected to a second band-pass filter 311. A circulator 312 is connected to the first band-pass filter 308 with a second band-pass filter 311 and with an antenna 303. Control eF 305 is connected to the transmitting converter 304, the converter 309 and the receiving modem digital converter 301. A transmitter 304 is coupled to power amplifier 307 via the electronic tunable bandpass filter 306, which is connected to the controller 305.

The objective of the claimed invention is solved by the inclusion in the transceiver 302 (Fig. 3) of an electronic tunable bandpass filter (EPPF) 306. In FIG. 3 is a block diagram of an EPPF 306. An EPPF 306 consists of two parallel tunable oscillatory circuits 401, 402 connected by a tunable coupling 403. Parallel tunable circuits 401, 402 are formed by varactors VD1, VD2 and inductors L1, L2. EPPF 306 is designed to filter spurious combination components. The controller 305, which is part of the transceiver 302, generates a control code for tuning the EPPF 306 to the appropriate frequency. The control code is converted by a digital-to-analog converter (DAC) 404, which is part of the controller 305, into control voltages V1 and V2. The restructuring of the EPPF 306 occurs due to a change in the capacitance of the varactors VD1, VD2, which are part of the tunable oscillatory circuits 401, 402, by supplying them with a control voltage V1, and also by changing the capacitance of the tunable coupling element 403 by applying a control voltage V2 to it.

In FIG. Figure 3 shows a block diagram of a radio communication system equipped with an EPPF 306. To prevent possible distortion of the emitted signal, an EPPF 306 self-diagnosis mode is provided. This mode is used when changing the operating frequency and when determining the deterioration of communication quality (a large number of bit errors or code recovery of information at the far end). In the EPPF self-diagnosis mode, the output power of the power amplifier 307 of the transmitting path is reduced, and the bandpass filter 311, LNA 310 and the converter of the receiving path 309 are turned on at the frequency of the transmitting path (the so-called "radio frequency loop"). Using digital signal processing by a digital modem 301, it is determined which change in the amplitude-frequency characteristic (AFC) of the working signal is made by the EPPF 306, and the necessary information is transmitted to the controller 305 to correct the control voltages V1 and V2 in order to reduce the influence of the EPPF 306 on working signal.

The invention can be carried out on the corresponding elemental base for standard technologies.

Although the above-described embodiment of the invention has been set forth to illustrate the present invention, it is clear to those skilled in the art that various modifications, additions and substitutions are possible without departing from the scope and meaning of the present invention disclosed in the attached claims.

Claims (8)

1. A broadband frequency duplex radio communication system comprising a digital modem 301, which is connected by two intermediate frequency cables to a transceiver 302, which is connected to the antenna by a single high-frequency cable, the transceiver 302 including a transmit path, a receive path, a circulator 312, and a controller 305, wherein the transmit path is constituted by the transmit converter 304, which is connected to the digital modem 301 and to the power amplifier 307, which is connected to the first band-pass filter 308, and the receive path is formed by receiving a converter 309, which is connected to a digital modem 301 and to a low noise amplifier 310, which is connected to a second bandpass filter 311, which is connected to a circulator 312, which is connected to a first bandpass filter 308 and to an antenna 303, and a controller 305 is connected to a transmitting converter 304 , a receiving converter 309 and a digital modem 301, characterized in that the transmitting converter 304 is connected to the power amplifier 307 through an electronic tunable bandpass filter 306, which is connected to the controller 305, - the transmitting converter 304 is configured to transfer the intermediate frequency to the high frequency of the power amplifier 307, which is configured to amplify the signal power to the desired level of the bandpass filter 306, configured to filter spectral components lying outside the operating frequency band; - the second band-pass filter 308 is configured to filter interference signals lying outside the working frequency band of the low-noise amplifier 310, configured to amplify the high-frequency signal supplied from the antenna 303, the receiving converter 309 is configured to transfer high-frequency to an intermediate frequency; - electronic tunable band-pass filter 306 is configured to filter spurious combination components; - the controller 305 is configured to control a transmitting converter 304, a receiving converter 309, as well as an electronic tunable band-pass filter 306, while generating a control code for tuning the tunable band-pass filter 306 to an appropriate frequency; - the circulator 312 is configured to perform frequency isolation between the receiving and transmitting paths of the transceiver 302. 2. Broadband radio communication system with frequency duplex according to claim 1, characterized in that the electronic tunable bandpass filter 306 consists of two parallel tunable oscillatory circuits 401, 402 (Fig. 4) connected by a tunable communication element 403, and the controller 305 contains a digital analog converter 404, the outputs of which are connected to the inputs of tunable oscillatory circuits 401, 402 and tunable communication element 403, and parallel tunable circuits 401, 402 are formed by varactors VD1, VD2 and inductance and L1, L2, the digital-to-analog converter 404 is configured to convert the control code of the controller 305 to the control voltages V1 and V2 for the electronic tunable bandpass filter 306, configured to be tuned by changing the capacitance of the varactors VD1, VD2, by applying a control voltage to them V1, as well as by changing the capacity of the tunable communication element 403 by applying to it a control voltage V2. 3. A broadband radio communication system with a frequency duplex according to claim 2, characterized in that the electronic tunable band-pass filter 306 is configured to self-diagnose when the operating frequency changes and when the quality of communication deteriorates (a large number of bit errors or code recovery of information at the far end), in the self-diagnosis mode of the tunable electronic bandpass filter 306, the output power of the first power amplifier 307 of the transmitting path decreases, and the bandpass filter 311, low noise the amplifier 310 and the receiving converter 309 of the receiving path are turned on at the frequency of the transmitting path (the so-called "radio frequency loop"), and the digital modem 301 is configured to digitally process the signal, while determining changes in the amplitude-frequency characteristic (AFC) of the working signal, which introduces an electronic tunable bandpass filter 306, and transmitting to the controller 305 the necessary information to correct the control voltages V1 and V2 in order to reduce the effect of the electronic tunable bandpass filter 306 on p Signal.

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