RU2157051C1 - Wide-band transmitter-receiver system - Google Patents

Abstract

FIELD: radio engineering, digital information transmission. SUBSTANCE: device uses pseudorandom retuning of working frequency. Transmitting part of device has first and second phase modulators, first and second high-frequency switches, NOT gate, adders, mixer, frequency synthesizer, pseudorandom sequence generator. Receiving part of device has mixer intermediate frequency amplifier, demodulator, synchronization unit, pseudorandom sequence generator, frequency synthesizer, first and second phase detectors, first and second gates, NOT gate, OR gate. Goal of invention is achieved by added units to achieve additional information channel using phase manipulation of frequency-shift signal of main information channel. EFFECT: increased throughput capacity. 6 dwg

Description

 The invention relates to the field of radio communications, in particular to broadband transceivers with pseudo-random tuning of the operating frequency (PFRCH) and can find application in radio lines for transmitting discrete messages.

Known broadband transceivers [1, 2, 3], transmitting messages in the frequency hopping mode. In these devices, the message is divided into information blocks, each of which is transmitted at one of the operating frequencies f _pi selected from a set of n frequencies allocated for communication f _p1 , f _p2 , ..., f _pi , ..., f _pn with adjustment speed V _per . In this case, the restructuring of the transmitter and receiver, transmitting message blocks with frequency-shift keying signals (FSK), is performed synchronously using a pseudo-random program. A common disadvantage of these devices is the limited bandwidth.

 The closest in technical essence to the proposed device is a radio "Jaguar - V" [4], operating in the frequency hopping mode and transmitting message blocks in the mode (FMN). This radio tool is selected as a prototype. The transmitting part of the device contains: a mixer, the first input of which is a frequency-manipulated signal of the transmitted message block, and the second input is connected to the output of the frequency synthesizer, the input of which is connected to the output of the pseudo-random sequence generator (GPS), and the output of the mixer is connected to the antenna. The receiving part of the device contains: an antenna connected to the first input of the mixer, the output of the latter is connected to the input of the intermediate frequency amplifier (OPC), the output of which is connected to the input of the demodulator. The output of the demodulator is the output of the receiving part of the device and is simultaneously connected to the second input of the mixer through serially connected synchronization blocks, GPS and frequency synthesizer.

 This radio facility allows the transmission and reception of messages in conditions of both stationary and deliberate interference with a given quality.

 The disadvantage of the prototype is the low bandwidth due to a single-channel mode of operation.

 The aim of the invention is to develop a broadband transceiver with frequency hopping, providing increased throughput by forming an additional information channel due to phase shift keying carrier frequency-manipulated signal of the main information channel.

To achieve a technical result, a broadband transceiver device containing a mixer on the transmitting side, the control input and output of which is connected respectively to the output of the frequency synthesizer and transmitting antenna, the input of the frequency synthesizer is connected to the GPS output, and in the receiving part, a receiving antenna connected to information input of the mixer, the control input of which is connected to the output of the frequency synthesizer, and its output is connected to the input of the amplifier, the output of which is connected to the input of the demodulator, info the radiation output of which is connected to the synchronization block and is the information output of the first channel of the device, the output of the synchronization block is connected to the GPS input, the output of which is connected to the input of the frequency synthesizer, are additionally introduced:
in the transmitting part of the device, the first and second phase manipulators, the inputs of which are combined and are the information input of the second channel of the device, and the outputs of the first and second phase manipulators are connected to the first inputs of the first and second high-frequency keys, the outputs of which are connected respectively to the first and second inputs of the adder and the output of the adder is connected to the information input of the mixer, the element is NOT, the input of which is combined with the second input of the first high-frequency key and is information input of the first unit duct and the output of NOT circuit connected to the second input of the second high frequency switch;
in the receiving part of the device, the second and third outputs of the demodulator connected to the inputs of the first and second phase detectors, respectively, the outputs of which are connected to the first inputs of the first and second keys, respectively, the information output of the demodulator is connected to the second input of the first key and, through the element NOT, to the second the input of the second key, an OR element, the first and second inputs of which are connected to the outputs of the first and second keys, respectively, and its output is the information output of the second channel.

 Thanks to the new set of essential features, due to the introduction of new units, it becomes possible to increase the transmission capacity of the transceiver by organizing a second (additional) channel, due to phase-shift keying of the carrier of the frequency-manipulated signal of the main information channel.

The analysis of the prior art made it possible to establish that analogues that are characterized by a combination of features that are identical to all the features of the claimed technical solution are absent, which indicates the compliance of the claimed device with the patentability condition of "novelty". The results of the search for known solutions in this and related fields of technology in order to identify features that match the distinctive features of the claimed object from the prototype have shown that they do not follow explicitly from the prior art. The prior art also did not reveal the popularity of the impact provided by the essential features of the claimed invention transformations to achieve the specified technical result. Therefore, the claimed invention meets the condition of patentability "inventive step",
The claimed device is illustrated by diagrams and drawings:
FIG. 1 is a block diagram of a device;
FIG. 2 is a structural diagram of a demodulator;
FIG. 3 - spectra of OFM signals;
FIG. 4 - signal spectrum OFM / FMN;
FIG. 5 - signal spectra OFM / FMN - PPRCH;
FIG. 6 is a diagram of the adder.

 The claimed device, a block diagram is shown in FIG. 1, consists of: in the transmitting part - the first 1 and second 2 phase manipulators, the first 3 and second 4 high-frequency keys, element NOT 5, adder 6, mixer 7, frequency synthesizer 8, GPSP 9, antenna 22. Inputs of phase modulators 1 and 2 combined and are the information input of the second (additional) channel, and their outputs are connected to the first and second inputs of the adder 6 through the first 3 and second 4 high-frequency keys, respectively. The input of the first information channel is connected to the second input of the first high-frequency key 3 and through the element 5 to the second input of the second high-frequency key 4, the output of the adder 6 is connected to the first input of the mixer 7, the second input of which is connected to the output of the frequency synthesizer 8, the input of which is connected to the output GPSSP 9, and the mixer output is connected to the antenna 22.

 In the receiving part of the device is an antenna 23, a mixer 10, an amplifier 11, a demodulator 12, a synchronization unit 13, GPSSP 14, a frequency synthesizer 15, the first 16 and second 17 phase detectors, the first 18 and second 19 keys, the element NOT 20 and the element OR 21 .

 The receiving part of the device contains: an antenna 23 connected to the first input of the mixer 10, the output of the latter is connected to the input of the amplifier UPCH 11, the output of which is connected to the input of the demodulator 12. The first output of the demodulator 12 is the information output of the first channel of the receiving part of the device and is simultaneously connected to the second input mixer 10 through serially connected synchronization blocks 13, GPSSP 14 and frequency synthesizer 15, and is also connected to the second input of the first key 18 and, through the element NOT 20, to the second input of the second key 19, missing in the prototype of the second and third outputs of the demodulator 12 are connected to inputs of the first 16 and second 17 phase detectors, the outputs of which are connected to first and second inputs of the adder 21 through the first 18 and second 19 switch, respectively, an output of OR 21 is the data output of the second information channel.

 In the claimed device, phase manipulators 1 and 2 are intended for the formation of two phase-modulated signals (OFM), shifted relative to each other in the carrier frequency. Phase manipulators 1 and 2 are known and, in particular, can be implemented according to the scheme of the relative phase modulator described in [6, p. 119, fig. 4.25].

 High-frequency keys 3 and 4 are designed for alternately connecting one of the independent paths (outputs of phase manipulators 1 and 2) to the adder 6 according to the law of changing the information signal in the first channel.

 Element NOT 5 is designed to invert the signal of the first information channel in order to provide antiphase control of keys 3 and 4, respectively.

The adder 6 is designed to combine the signals of two independent paths. It can be implemented in the simplest case on the conventional resistive adder shown in FIG. 6. The adder consists of a resistor R ₁ , the output of which is the first input of the adder and connected to the output of block 3, and its second output is connected to the resistor R ₂ , R ₃ and is the output of the adder and connected to block 7, the second output of the resistor R ₂ is the second input of the adder and connected to the output of block 4, the second output of the resistor R _{3 is} grounded. The calculation of the denominations of these elements can be made by known methods specified in [8, p. 104-124].

 The demodulator 12 is designed to isolate the signals of the FSK of the first channel and the separation of the signals of the OFM of the second channel along two independent paths. It can be implemented according to known schemes, in particular, according to a frequency detector with two detuned circuits shown in FIG. 2. The demodulator 12 consists of the first and second band-pass filters 12.1 and 12.2, the first and second detecting element 12.3 and 12.4, the first and second integrators 12.5 and 12.6, as well as the addition circuit 12.7. The inputs of the bandpass filters 12.1 and 12.2 are combined and are the input of the demodulator 12. The outputs of the first 12.1 and second 12.2 bandpass filters are connected to the inputs of the first 12.3 and second 12.4 detection elements, respectively, and are the second and third output of the demodulator 12 and simultaneously connected to the inputs of the first 16 and second 17 phase detectors. The outputs of the first 12.3 and second 12.4 detecting elements are connected to the inputs of the first 12.5 and second 12.6 integrators, the outputs of which are connected to the first and second inputs of the addition circuit 12.7. The output of the addition circuit 12.7 is the first output of the demodulator 12 and is the information output of the first channel. The described demodulator circuit can be implemented according to one of the known schemes, for example, given in [6, Fig. 5.17, p. 159].

 The first and second phase detectors 16 and 17 are designed to detect phase-shifted signals corresponding to the first and second paths of the second channel. You can execute them in any known manner, for example, as shown in [6, Fig. 5.19, p. 162].

 The keys 18 and 19 are designed to select the path for receiving demodulated signals from phase detectors 16 and 17 to the corresponding inputs of element 21. They can be made on the basis of the transistor in the key mode presented in [7, Fig. 3.4.9, p. 93].

 Element NOT 20 is designed to invert the signal of the first information channel in order to provide antiphase control of keys 18 and 19, respectively, it is similar to element NOT 5.

 The OR element 21 is designed to form a single sequence of information symbols, the second channel.

Used in the claimed device elements and their circuits are described in the following sources of information:
- high-frequency keys 3 and 4 in [5, p. 376];
- elements NOT 5 and 20 in [5, p. 59];
- element OR 21 in [5, p. 74].

The device of FIG. 1 works as follows. The discrete signals of the second (additional) channel are simultaneously fed to the information inputs of the first 1 and second 2 phase manipulators, at the output of which two OFM signals are formed, differing in carrier frequencies F ₁ and F ₂ , shifted relative to each other in frequency by ΔF = F ₂ - F ₁ as shown in FIG. 3. The signals of the OFM of the second channel with carriers F ₁ and F ₂ are used as the frequencies of "pressing" (F ₁ ) and "squeezed" (F ₂ ) when transmitting a message on the first channel. Thus, on the second channel, messages are transmitted using OFM signals.

The discrete signals of the first channel are simultaneously fed to the second control input of the first key 3 and, through the element 5, to the second control input of the second key 4, and the first channel inputs receive the OFM signals of the second channel from the outputs of the first 1 and second 2 phase manipulators, respectively . Moreover, the discrete signal of the first channel closes (opens) one of the two keys 3 or 4. This will ensure that one of the two OFM signals with a carrier frequency F ₁ or F ₂ appears on one of the inputs and the output of the adder 6. Thus, on the first channel, the message is transmitted using OFM / FSK signals, as shown in FIG. 4.

This signal from the OFM / FMN is fed to the first input of mixer 7. The second oscillator 7 feeds a reference oscillation of the operating frequency f _pi , tunable according to the pseudo-random program, from the output of the frequency synthesizer 8, controlled by GPSSP 9. In this case, the frequency synthesizer 8 forms the reference oscillation operating transmission frequency f _pi , with a given tuning speed according to a pseudo-random program from a set of n frequencies allocated for communication. Thus, at the output of the mixer 7, a signal with OFM / FMN is generated at the i-th working frequency f _pi , i = l ... n, which is emitted by the antenna towards the correspondent of FIG. 5. The received signal OFM / FMN - frequency hopping at a frequency f _pi goes to the first signal input of the mixer 10, the second input of which is tuned according to a pseudo-random program, the reference oscillation f _i from the output of the frequency synthesizer 15.

As a result of the conversion of the received and reference signals in the mixer 10, OFM / FSK intermediate frequency signals are generated at its output, which are amplified in the amplifier 11 and supplied to the input of the demodulator 12. At the first output of the demodulator 12, a discrete signal of the first channel is generated, which is received by the message recipient and simultaneously to the synchronization unit 13, which ensures the formation of the next operating frequency number by the generator 14 and synchronous tuning of the frequency synthesizer 15. At the second and third output of the demodulator 12 are allocated FMR signals on one of the carrier frequencies F ₁ and F ₂ which are coupled to respective inputs of the phase detector 16 or 17. Digital signals from the outputs of the second channel 16 of the first or second phase detectors 17 are supplied to first control inputs of first 18 and second 19 keys, respectively, . The second control input of the key 18 and through the element NOT, the second control input of the key 19 receives discrete signals from the first output of the demodulator 12, which ensures the input of the element OR 21 of the discrete signal of the second channel from the corresponding output of the phase detector. The output of the OR element 21 discrete signal of the second channel is received by the message recipient.

 Compared with the prototype, the proposed technical solution allows to increase the throughput of radio links with frequency hopping when transmitting discrete messages.

Sources of information
1. Dickson R.K. Broadband systems. Per. from English - M.: Communication, 1979. - 304 p.

 2. Gorshkov VV and other military communication systems using frequency hopping. Foreign electronics, 1986. N 3, - p. 9-13.

 3. Klimenko N.N. VHF radio station: state, development prospects, features of applying the frequency hopping mode. Foreign Radio Electronics, 1990, N 7, - p. 36-44.

 4. Ribchester E. The Jaguar V Frequency - hopping radio. Electronics and Rower, 1981, 27, No. 9, September, p. 627 - 629.

 5. Integrated circuits. Directory. Ed. Tarablina B.V. - M: Radio and communications, 1984. - 528 p.

 6. Gorelov G.V., Volkov A.A., Shelukhin V.I. Channel-forming devices of railway telemechanics and communications. - M .: Transport, 1994 .-- 240 p.

 7. Korolev A. I. Automation, telemechanics and communications in railway transport. - M .: Military Publishing House, 1985 .-- 488 p.

 8. Atabekov G. I. Theoretical foundations of electrical engineering. Part 1. - M .: Energy, 1970. - 592 p.

Claims (1)

 A broadband transceiver containing a mixer in the transmitting part, whose control input and output are connected respectively to the output of the frequency synthesizer and the transmitting antenna, the input of the frequency synthesizer is connected to the output of the pseudo-random sequence generator, and in the receiving part, the receiving antenna connected to the information input mixer, the control input of which is connected to the output of the frequency synthesizer, and its output is connected to the input of the intermediate frequency amplifier, the output of which is connected with the input of the demodulator, the information output of which is connected to the synchronization unit and is the information output of the first channel of the device, the output of the synchronization unit is connected to the input of the pseudo-random sequence generator, the output of which is connected to the input of the frequency synthesizer, characterized in that the first and the second phase manipulators, the inputs of which are combined and are the information input of the second channel of the device, and the outputs of the first and second phase manipulators tori are connected to the first inputs of the first and second high-frequency keys, respectively, the outputs of which are connected respectively to the first and second inputs of the adder, and the output of the adder is connected to the information input of the mixer, the element is NOT, the input of which is combined with the second input of the first high-frequency key and is the information input of the first channel devices, and the output of the element is NOT connected to the second input of the second high-frequency key, in the receiving part of the device - the second and third outputs of the demodulator connected to the input given respectively the first and second phase detectors, the outputs of which are connected to the first inputs of the first and second keys, respectively, the information output of the demodulator is connected to the second input of the first key, and through the element NOT to the second input of the second key, the OR element, the first and second inputs of which are connected to the outputs of the first and second keys, respectively, and its output is the information output of the second channel.

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