RU2178237C2 - Method and device for transmitting digital information in radio link using pseudorandom operating-frequency control - Google Patents

Abstract

FIELD: radio communications. SUBSTANCE: method includes following procedures: bursts are shaped on sending end from information signal and used for modulating signals of respective frequencies emitted into environment. Frequency selection is controlled from receiving end of radio link using results of noise situation analysis at frequencies set up by pseudorandom train generator. Reception is made at all frequencies on receiving end. EFFECT: enhanced noise immunity of long radio links. 2 cl, 4 dwg

Description

 The invention relates to radio communications, namely to the transmission of discrete information by signals with pseudo-random tuning of the operating frequencies (MHF), and are combined by a single inventive concept.

 The proposed method can be used in duplex radio links with frequency hopping of various lengths, operating in the common frequency band with radio facilities of various affiliations and with different principles of operation.

 The proposed device for transmitting information with frequency hopping signals can be used in duplex radio communication lines of various lengths in conditions of shortage of radio frequency resource and in the area of mutual electromagnetic accessibility of various electronic devices operating in the common frequency band with radio frequency hopping devices and operating at fixed frequencies.

 A known method of transmitting information described in the literature: E. RIBCHESTER. THE JAGUAR-V FREQUENCY-HOPPING RADIO. Electronics and Power, 1981, September; IEEE Trans, 1988, COM-289, p. 1561; Gorshkov V.V., Kuksin O.V., Rubtsov S.A., Sukhov A.V. Military communication systems with pseudo-random tuning of the operating frequency. Foreign electronics 3, 1986, p. 3-13. The reasons that impede the achievement of the result indicated below include the fact that when the frequencies of the subscriber’s reception coincide with the frequencies of the interfering stations, the probability of an erroneous signal reception at this frequency will be close to 0.5, and an increase in the number of affected frequencies will lead to communication failure.

 A known method of transmitting information described in the official bulletin "Inventions (applications and patents)" 35 for 1997, a description of the invention to the patent of the Russian Federation 2099886 "Method for transmitting information in radio lines with pseudo-random tuning of operating frequencies and a device that implements it." The reasons that impede the achievement of the technical result indicated below when using this method of transmitting information include the fact that it can be used only in short-haul radio links, the interference situation at the ends of which is identical. For long-distance radio links, the interference environment at the receiving and transmitting ends will be different, which can lead to the choice of the transmission frequency affected by the interference at the receiving end and communication failure.

 Known devices of a mobile communication system designed for signal communication with frequency hopping JAGUAR-V, SCHMITAR-A, most fully described in articles: E. RIBCHESTER. THE JAGUAR-V FREQUENCY-HOPPING RADIO. Electronics and Power, 1981, September. ; IEEE Trans. 1988. COM-287, 9, p. 1561.; Gorshkov V.V., Kuksin O.V., Rubtsov S.A., Sukhov A.V. Military communication systems with pseudo-random tuning of the operating frequency. Foreign electronics 3, 1986, p. 3-13. The reasons that impede the achievement of the technical result indicated below when using these devices include the fact that, having a strict frequency tuning program, they are not able to adapt to a changing interference environment, that is, automatically exclude frequencies affected by interference during communication.

 A radio communication device is known for communicating with frequency hopping signals, described in the official bulletin "Inventions (applications and patents)" 35 for 1997, a description of the invention to the patent of the Russian Federation 2099886 "Method for transmitting information in radio lines with pseudo-random tuning of operating frequencies and the device, its realizing ". The reasons that impede the achievement of the technical result indicated below when using this device include the fact that it cannot be used for communication over long distances, when the interference situation at the ends of the radio line will differ, since the control of the interference situation and the choice of transmission frequency are carried out by monitoring receivers at the transmitting end of the radio link, which can lead to the choice of the operating frequency of the transmitter, optimal for the transmitting end, but affected by interference at the receiving end, which when goes to a breakdown of communication.

 The closest in essence to the claimed method of transmitting discrete information by signals with frequency hopping is a known method described in the official bulletin "Inventions (applications and patents)" 35 for 1997, a description of the invention to the patent of the Russian Federation 2099886 "Method for transmitting information in a radio line with a pseudo-random the restructuring of the working frequencies and the device that implements it. " The prototype method is that at the transmitting end of the information signal form packets that modulate the respective carrier frequencies and emit into space. The carrier frequency is selected based on the best interference environment at the frequencies specified by the pseudo-random sequence generators. Reception of the signal, its conversion to an intermediate frequency, demodulation is performed on all K channels. The conclusion on which of the channels the information was transmitted is made based on the analysis of the address of the received packet.

 The reasons that impede the achievement of the technical result indicated below when using the prototype of the claimed method for transmitting discrete information by frequency hopping signals include the fact that the difference in the interference environment at the transmitting and receiving ends of the radio line, which is typical for long-distance radio lines, will lead to the choice of the operating transmission frequency affected interference at the receiving end, which will lead to a deterioration in the quality of communication below acceptable.

 The closest in technical essence to the claimed communication device signals with frequency hopping is the device described in the official bulletin "Inventions (applications and patents)" 35 for 1997, a description of the invention to the patent of the Russian Federation 2099886 "Method for transmitting information in radio lines with pseudo-random tuning of operating frequencies and a device that implements it. " The known prototype device includes: a source of information (AI), first, second, third, fourth and fifth frequency synthesizers (MF1, MF2, MF3, MF4, MF5), a modulator (M), the first and second antenna devices (A1, A2), PSP1 (GPSP1) generator with outputs of the current value and value of the next clock, PSP2 generator (GPSP2) with output of the current value and value of the next clock, switch (K), packet forming and decoding device (UVDP), first, second, third and fourth converters frequency (IF1, IF2, FC3, FC4), the first and second intermediate amplifiers frequency (UPCH1, UPCH2), the first and second demodulators (D1, D2), the first and second amplitude detectors (AD1, AD2), the first and second threshold devices (PU1, PU2), a comparison circuit (SS) and an information receiver (PI ) The AI output is connected to the first input of the UFDP, the first output of which is connected to the second input M, the output of the current GPS value 1 is connected to the first input K and the input MF2, the output of the next clock GPS1 is connected to the input MF4, the output of the current GPS value 2 is connected to the second input K and the input MF3, the output of the next HRSP2 clock is connected to the MF5 input, A2 output is connected to the first inputs of the MF1, MF2, MF3, MF4. The MF2 output is connected to the second input of the inverter1, the output of which is connected to the input of the UHF1, the output of the UHF1 is connected to the input D1, the output of which is connected to the second input of the UFDP and the first input of the SG, the MF3 output is connected to the second input of the UHF2, the output of which is connected to the input of the UHF2. The output of UCH2 is connected to the input D2, the outputs of which are connected to the third input of the UFDP and the second input of the SG, the output of MF4 is connected to the second input of the frequency converter3, the output of which is connected to the input of AD1, the output of which is connected to the input of PU1. MF5 output to the second input of MF4, the output of which is connected to the input of AD2, the output of which is connected to the input of PU2. The outputs PU1 and PU2 are connected respectively to the first and second inputs of the SS, the output of which is connected to the third input K and the fourth input of the UVDP, the output of the SG is connected to the third input of the SS, the input of the GPS1 and the input of the GPS2, the second output of the UVDP is connected to the input of the PI. From the incoming information signal to the UVDP, information packets are formed, which are supplied to the second input M, the corresponding carrier frequencies are modulated, which radiate into space. The carrier frequency generated by MF1 and supplied to the first input M is determined by the current code value of either GPSP1 or GPSSP2. The choice of code is determined by K, controlled by the SS, which generates control information for switching the GPSS in the presence of interference at a frequency specified by the operating memory bandwidth and in the absence of interference at the frequency specified by the backup memory bandwidth. In the absence of interference at the frequency specified by the operating memory bandwidth, or in the presence of interference at the frequencies specified by both PSPs, the switching of the GPSS is not performed. To analyze the interference environment, two identical receive channels are used, including IF3, MF4, AD1, PU1 - the first channel and IF4, MF5, AD2, PU2 - the second channel. In them, the radio signal received from A2 is converted to an intermediate frequency in the inverter, detected by the amplitude in the AM and by the value of the constant voltage at the output of the AM, the PU determines whether there is interference at this frequency or not. At the receiving end, the signal is received at two frequencies according to the current values of GPSP1 and GPSSP2. The first receiver contains IF1, MF2, UPCH1, D1, the second receiver - IF2, MF3, UPCH2, D2. The signal processing in them is carried out similarly: the signal coming from A2 to the IF is transferred to the intermediate frequency, amplified in the IF and demodulated. Further, by the presence of a signal, the SG controls the operation of GPSP1 and GPSP2. According to the results of the signal processing, based on the decoding of the packet address in the UVDP, it is determined by which of the branches the signal is received, the packet is decoded and an information signal is supplied to the PI.

 The reasons that impede the achievement of the technical result indicated below when using a prototype of a device for transmitting discrete information include the fact that the prototype cannot be used for communication over long distances, since the control of the interference environment and the choice of the transmission frequency are carried out by control receivers at the transmitting end of the radio line, which in the presence of various interference conditions at the transmitting and receiving ends, characteristic of long-distance radio links, can lead to the choice of the operating part from the transmitter, which is optimal for the transmitting end, but is affected by interference at the receiving end, which will lead to communication failure.

 SUMMARY OF THE INVENTION

 One of the ways to increase the noise immunity, and therefore the reliability of communication, is to use the well-known method of transmitting information in radio links with frequency hopping, which consists in simultaneously transmitting information on several radio links with orthogonal programs with the choice of one frequency channel from several offered by these radio links, according to the criterion lack of interference. It is assumed that the interference environment at both ends of the radio link is identical, which is true for short-haul radio links. In cases where the interference situation at the transmitting and receiving ends of the radio link is different, which is typical for long-distance radio links, this will lead to the choice of a frequency channel for transmission that is optimal for the transmitting end, but is affected by interference at the receiving end, which will lead to a deterioration in communication quality below the acceptable and loss of credibility. Thus, a contradiction arises between the requirement to increase the reliability of communication and an increase in the length of radio links.

 The technical result of the claimed method for transmitting discrete information in a radio frequency hopper radio frequency transmission system is an increase in the noise immunity of a radio frequency long-frequency hopping radio frequency channel.

 The specified technical result is achieved by the fact that in the known method for transmitting discrete information in a radio line with pseudo-random tuning of operating frequencies, including dividing the input signal into blocks at the transmitting end, tuning the transmitter carrier frequency in accordance with the code of one of two or more pseudorandom sequences, modulating the transmitter carrier appropriate package and its subsequent radiation into space, receiving a signal at the receiving end of the radio link simultaneously at all frequencies, according to odes of pseudorandom sequences, the choice of the frequency channel through which the signal was transmitted, the signal was converted to an intermediate frequency, amplification, demodulation, packet decoding, and the supply of an information signal to the terminal device, simultaneously with the reception of the information signal, the receiving end of the radio link receives signals at all frequencies corresponding to subsequent ticks of codes of pseudorandom sequences, monitoring the level of interference at these frequencies and, in the case of interference at the controlled The frequency of the working program, they form the control information for tuning the correspondent transmitter to the frequency with the least interference level, form information packets by connecting control information to the information signal blocks, modulate the carrier of their transmitter with the corresponding information package, emit the modulated carrier into space at the transmitting end simultaneously with the radiation modulated carrier into space, receive an information signal simultaneously at all frequencies, according to the codes of pseudorandom sequences, selecting the frequency channel through which the signal was converted, converting the signal to an intermediate frequency, followed by its amplification and demodulation, decoding the packet with the allocation of an information signal block arriving at the terminal device and a block containing information on controlling its transmitter, for its subsequent tuning to the frequency with the lowest noise level, optimal for the receiving end.

 The use of prototype of the claimed device for transmitting information by signals from the frequency hopper in radio communication lines improves the noise immunity of the radio line. It is assumed that the interference environment at both ends of the radio link is identical, which is true for short-haul radio links. However, when organizing radio links with long-range frequency hopping radios, this device cannot be used, since the jamming environment and the choice of transmission frequency are monitored by control receivers at the transmitting end of the radio link, which, in the presence of different jamming conditions at the transmitting and receiving ends, characteristic of long-distance radio links, can lead to the choice of the operating frequency of the transmitter, optimal for the transmitting end, but affected by interference at the receiving end, which will increase the probability of errors and disruption of communication.

 The technical result of the claimed device that implements a method of transmitting discrete information in a radio frequency hopping radio frequency transmission system is to increase the reliability of transmitting information in a long-distance radio frequency hopping radio frequency channel under the influence of interference by adapting the operating frequency at the transmitting end to the noise situation at the receiving end.

 The specified technical result is achieved by the fact that in a known device for transmitting information, including: an information source (AI), first, second, third, fourth and fifth frequency synthesizers (MF1, MF2, MF3, MF4, MF5), modulator (M), the first and the second antenna device (A1, A2), the generator PSP1 (GPSP1) with the outputs of the current value and the value of the next clock, the generator PSP2 (GPSP2) with the output of the current value and the value of the next clock, the switch (K), the device for forming and decoding packets (UVDP ), the first, second, third and fourth transformation frequency indexes (ПЧ1, ПЧ2, ПЧ3, ПЧ4), the first and second intermediate frequency amplifiers (UPCH1, UPCh2), the first and second demodulators (D1, D2), the first and second amplitude detectors (АД1, АД2), the first and second threshold devices (PU1, PU2), a comparison circuit (SS), an information receiver (PI), the AI output being connected to the first input of the UFDP, the first output of which is connected to the second input M, the output of the current GPS value 1 is connected to the first input K and the input of MF2, the output the next clock of GPSP1 is connected to the input MF4, the output of the current value of GPSSP2 is connected to the second input K and MF3, the output of the next GPSP2 clock cycle is connected to MF5 input, A2 output is connected to the first inputs of MF1, MF2, MF3, MF4, MF2 output is connected to the second input of MF1, the output of which is connected to MF1 input, MF1 output is connected to input D1, whose output connected to the second input of the UFDP and the first input of the SG, the MF3 output is connected to the second input of the IF2, the output of which is connected to the input of the UHF2, the output of the UHF2 is connected to the input D2, the outputs of which are connected to the third input of the UFDP and the second input of the SG, the MF4 output is connected to the second input FC3, the output of which is connected to the input of AD1, the output of which It is connected to input ПУ1, the output СЧ5 is connected to the second input ПЧ4, the output of which is connected to input АД2, the output of which is connected to input ПУ2, the outputs ПУ1 and ПУ2 are connected respectively to the first and second inputs of SS, the output of SG is connected to the third input of SS, input GPSSP1 and GPSSP2 input, the second output of the UVDP is connected to the input of the PI, a third output to the UVDP, which is connected to the third control input K, is additionally introduced, and the SS output is connected only to the fourth input of the UVDP.

 In the UVDP, information packets are formed by attaching service information to the blocks of the information signal, as well as control information received from the SS and containing a command to select one of the GPSPS correspondents. The generated packets are fed to the second input M, the transmitter carrier is modulated with the corresponding information packet, and the modulated carrier is emitted into space. The carrier frequency generated by MF1 and supplied to the first input M is determined by the current code value of either GPS1 or GPS2. The choice of the GPSSP determines K by the control information received from the UVDP. The signal is received at two frequencies, according to the current values of the codes GPSP1 and GPSSP2. The first receiver contains IF1, MF2, UPCH1, D1. The second receiver - IF2, MF3, UPCH2, D2. The signal coming from A2 to the IF is transferred to the intermediate frequency, amplified in the IF and demodulated in D. Further, by the presence of the signal, the SG controls the operation of GPSS1 and GPSSP2. According to the results of signal processing, based on the decoding of the packet address in the UVDP, it is determined by which branch the signal is received, the packet is decoded and its part containing the information signal block is fed to the PI, the other part containing the control information to K. To control the transmitter the correspondent in the device assesses the presence of interference at frequencies at which a radio link can be tuned to a subsequent clock cycle in accordance with GPS codes 1 and GPS codes 2. To do this, use two identical receive channels, including IF3, MF4, AD1, PU1 - the first channel and IF4, MF5, AD2, PU2 - the second channel. In them, the radio signal received from A2 is converted to an intermediate frequency in the inverter, detected by the amplitude in the AM and by the value of the constant voltage at the output of the AM, the control unit determines whether there is interference at this frequency or not. Information from PU1 and PU2 is fed to the SS, which generates control information for switching the GPS of the correspondent transmitter in the presence of interference at a frequency specified by the operating SRP and in the absence of interference at the frequency specified by the backup SRP. In the absence of interference at the frequency specified by the operating memory bandwidth, or in the presence of interference at the frequencies specified by both the memory bandwidth, the GPS switching command is not transmitted. The control information generated in the SS is fed to the UVDP for further transmission to the third, control input K.

 The specified new structure of the claimed device for transmitting information with frequency hopping signals improves the reliability of communication in long-distance radio lines, due to the choice of the frequency of the correspondent transmitter based on the analysis of the jamming situation at the receiving end of the radio line.

 The claimed objects of the invention are illustrated by drawings, where in FIG. 1 is a structural diagram of a transceiver device explaining the claimed method of transmitting information in the frequency hopping mode; in FIG. 2 is a structural diagram explaining the essence of the claimed information transmission device in the frequency hopping mode; in FIG. 3 is a structural diagram of an option for constructing threshold devices 6.1.1 and 6.2.1 using PU1 6.1.1 as an example; in FIG. 4 is a structural diagram of a variant of constructing a comparison scheme 5.

 The implementation of the claimed method is as follows.

 The transmission of information simultaneously on several radio links with orthogonal programs significantly increases noise immunity and reduces the number of required frequencies. However, the simultaneous operation of several transmitting devices in one object worsens the internal EMC of electronic means. More effective from this point of view is the algorithm for selecting one frequency channel from several offered by radio links with their own tuning programs, in which there is currently the least interference level. Such an algorithm for the operation of a radio frequency hopping system can be implemented when the transceiver devices operate in several, in particular in two, orthogonal programs with carrier control and consists in the fact that the transmitter operates in one of several programs, and reception is carried out immediately for all. In addition, the presence of interference at frequencies that will be set by each program after several jumps from the current frequency is monitored, and if there is interference at the controlled frequency of the work program, the transmitter tunes to the frequency specified by the backup program. For radio links with long-range frequency hopping, interference level control is carried out at the receiving end of the radio link. Based on the control results, control information is generated, which is transmitted to the transmitting end in order to adapt the transmission frequency to the interference situation at the receiving end. The receiver of the correspondent, which includes receivers operating according to the same programs, emits a useful signal according to the feature contained in the service part of the packets transmitted by one of the programs.

 The information transmission devices at both ends of the radio link are the same (Fig. 1) and comprise a GPS unit 1, transmitter 2, a device for generating and decoding packets 3, K receivers 4.1-4. K, comparison scheme 5, K control receivers 6.1-6. K. At the transmitting end of the radio link, the GPS unit 1 generates K pseudo-random sequences. On a command from the packet forming and decoding device 3, the GPS unit 1 connects the necessary memory bandwidth to the transmitter 2 and it transmits a packet formed by the packet forming and decoding device 3. At the same time as transmitting the packet, receivers 4.1-4. To receive the radio signal simultaneously on all To the frequency channels, transfer to an intermediate frequency, amplify and demodulate. The demodulated signals are fed to a packet forming and decoding device 3, in which it is concluded which channel is being transmitted and a packet is decoded, moreover, one part of the packet constituting the information signal block is supplied to the output of the device and the other part containing control information to the input of GPS 1 to control the restructuring of the transmitter at a frequency specified by one of the K programs of GPS 1.

 At the receiving end of the radio link simultaneously with receivers 4.1-4. To, carrying out the reception of an information signal, control receivers 6.1-6. To analyze the presence of interference on the frequency channels corresponding to the codes of subsequent clock ticks. According to the results of the analysis, the comparison circuit 5 evaluates the presence of interference at the inputs of the control receivers 6.1-6. To and in the presence of interference at the frequency specified by the work program of GPS 1, generates control information for tuning the correspondent transmitter to the frequency specified by one of the backup programs of GPS 1, free from interference. If there is no interference on the working frequency channel, or if all of the proposed GPS 1 frequency channels are interfered with, then the frequency bandwidth at the transmitting end is not changed. The control information is supplied to the packet forming and decoding device 3, where information packets are formed by attaching control information to the information signal blocks, the carrier of the transmitter 2 is modulated with the corresponding information packet, and the modulated carrier is emitted into the space.

 Thus, the claimed method implements a frequency hopping radio frequency transmission using frequency diversity with automatic selection of the operating frequency at the transmitting end according to the results of the analysis of the jamming situation at the receiving end of the radio line, and improves the reliability of the transmitted information without compromising the electromagnetic environment.

 An information transmission device implementing the inventive method is represented by a block diagram in FIG. 2. It consists of: GPS unit 1, transmitter 2, UVDP 3, first receiver 4.1, second receiver 4.2, comparison circuit 5, first control receiver 6.1, second control receiver 6.2, first antenna 7, information source 8, information receiver 9, the second antenna 10, the clock generator 11. In turn, the GPS unit 1 consists of a generator of the first SRP 1.01 with outputs n and n + x clock, a generator of the second SRP 1.03 with outputs n and n + x clock, switch 1.02. The transmitter 2 consists of a first frequency synthesizer 2.01 and a modulator 2.02. The first receiver consists of the first demodulator 4.1.1, the first intermediate frequency amplifier 4.1.2, the first frequency converter 4.1.3, the second frequency synthesizer 4.1.4. The second receiver consists of a second demodulator 4.2.1, a second intermediate frequency amplifier 4.2.2, a second frequency converter 4.2.3, a third frequency synthesizer 4.2.4. The first control receiver consists of a first threshold device 6.1.1, a first amplitude detector 6.1.2, a third frequency converter 6.1.3, and a fourth frequency synthesizer 6.1.4. The second control receiver consists of a second threshold device 6.2.1, a second amplitude detector 6.2.2, a fourth frequency converter 6.2.3, and a fifth frequency synthesizer 6.2.4. Moreover, the AI output is connected to the first input of the UFDP, the first output of which is connected to the second input (M) of the transmitter, the first output of the GPS unit from the output of the switch is connected to the first input of the transmitter (input MF1). The second output of the GPS unit (output of the current cycle of GPS1) is connected to the second input of the first receiver (input CCH2) and the first input K. The third output of the GPS unit (output of the subsequent cycle of GPS1) is connected to the second input of the first control receiver (input MF4). The fourth output of the GPS unit (output of the current cycle of GPS2) is connected to the second input K and the second input of the second receiver (input MF3). The fifth output of the GPS unit (output of the subsequent cycle of GPS2) is connected to the second input of the second control receiver (input MF5). The output of the transmitter (output M) is connected to input A1. Output A2 is connected to the first inputs of the receivers and control receivers (to the first inputs, respectively, inverters 1, inverters 2, inverters 3, inverters 4). The output of the first receiver (output D1) is connected to the second input of the UVDP and the first input of the SG. The output of the second receiver (output D2) is connected to the third input of the UVDP and the second input of the SG. The output of the first control receiver (output PU1) and the output of the second control receiver (output PU2) are connected respectively to the first and second inputs of the SS, the output of which is connected to the fourth input of the UVDP. The SG output is connected to the inputs of the SS, the GPS unit (the inputs of GPS 1 and GPS 2). The second output of the UVDP is connected to the input of the PI, and the third output of the UVDP is connected to the first input of the GPS unit (control input K). The MF2 output of the first receiver is connected to the second MF1 input. The output of the inverter 1 of the first receiver is connected to the input of the inverter 1. Output UPCH1 is connected to input D1. The MF3 output of the second receiver is connected to the second input of the MF2, the output of which is connected to the input of the MFC2. Output UPCH2 is connected to input D2. The MF4 output of the first control receiver is connected to the second MF3 input, the output of which is connected to the AD1 input. The output of AD1 is connected to the input of PU1. The MF5 output of the second control receiver is connected to the second input of the MF4, the output of which is connected to the input of AD2, the output of which is connected to the input of the M2.

 An embodiment of threshold devices (6.1.1, 6.2.1) is presented in FIG. 3 by the example of PU1 6.1.1. It consists of a comparator (6.1.1.1) and a voltage reference source (6.1.1.2). Moreover, the output of the reference voltage source is connected to the second input of the comparator. The input of the control unit is connected to the first input of the comparator. The output of the comparator is connected to the output of the threshold device.

 An embodiment of CC 5 is shown in FIG. 4. It consists of an RS trigger. The first input of the SS is connected to the R input, the second input to the input S, the third input to the clock input C. The output Y of the trigger is connected to the output of the SS.

 Switch 1.02 can be implemented using relays or on microcircuits that perform the functions of switches with the required number of switched channels. See the manual: Digital and analog integrated circuits. - M.: Radio and communications, 1989, p. 47-139.

 UVDP 3 is most appropriate to build using microprocessor technology. One of the options for its construction is considered in the literature: Computing networks with packet radio communications. Kiev: Technique, 1989, p. 192-206.

 The remaining elements of the device can be built according to well-known schemes considered in the literature: Digital radio receiving systems. Ed. M.I. Zhodzinsky. - M.: Radio and communications, 1990, p. 53-54, 68-80, 173-182. K.M. Pavlov. Radio receivers of trunk communication KB. - M.: Communication, 1980, p. 54-57. V.P. Serkov. Radio wave propagation and antenna devices. - L.: YOU, 1981, p. 280-312. R.K. Dixon. Broadband systems. Per. from English L.F. Zhigulina. Ed. V.I. Zhuravleva. - M.: Communication, 1979, p. 60-82.

 The claimed device operates as follows.

The choice of the number of the subsequent GSTP clock (n + x), on which the presence of interference will be assessed, depends on the operating conditions of the claimed device and will be determined by the number of clock cycles x, by which the control receiver will be ahead of the working receiver, and which should not be less than the reaction time of the system correspondent transmitter control
x ≥ int [t _p / t _psp ],
where t _p is the response time of the correspondent transmitter control system;
t _PSP - the time of one clock cycle.

The response time of the correspondent transmitter control system depends on the analysis time for the presence of interference, the algorithm for generating and decoding packets, the length of the radio line, the transmitter tuning time, and is determined by the expression
t _p = t ₁ + t ₂ + t ₃ + t ₄ ,
where t ₁ - time analysis of the presence of interference at the receiving end of the radio line;
t ₂ — packet formation time;
t ₃ is the transit time of the signal from the modulator at the receiving end, through the propagation medium, to the demodulator at the transmitting end;
t ₄ is the decoding time of the packet at the transmitting end and the execution of the transmitter tuning command.

 The generators of the first 1.01 and second 1.03 PSP with their output codes from the outputs of the current clock through switch 1.02 control the oscillation frequency generated by SCh1 2.01. The resulting oscillation is fed to the first input M 2.02.

 The information signal from AI 8 is fed to the first input of the UVDP 3. In it form information packets. The sequentially incoming information signal is divided into blocks of a given length, to which the "address" of the correspondents is added, control information for controlling the correspondent transmitter coming from the SS 5, if necessary, the packet route and, if possible, perform noise-resistant coding.

 The packet thus formed is fed to the second input M 2.02 and transferred to the radio frequency. The radio signal through A1 7 emit into space. Each packet of information is emitted at a frequency according to the code PSP1 or PSP2.

 The reception of the information signal is carried out simultaneously by both programs PSP receivers 4.1 and 4.2. In A2 10, the electromagnetic oscillation is converted into electrical oscillation and fed to the inputs of both receivers. The operation of the receivers is similar. Consider the principle of their action on the example of the first receiver 4.1. The frequency code from the output of the current clock GPS1 1.01 is fed to the input SCH2.1.4, which generates the fluctuation of the required frequency. The oscillation is fed to the second input of the inverter 4.1.3. The signal allocated at the intermediate frequency is amplified by UPCH1 4.1.2 and demodulate D1 4.1.1.

 The demodulation results of both receivers are fed to the second and third inputs of the UVDP 3. The device selects the channel on which the signal was transmitted at the address recorded in the packet, decodes the packet and supplies the received information signal to PI 9, and the control information to K 1.02, which controls the operation of the GPS 1.01 and 1.03. In addition, based on the analysis of clock pulses, the SG 11 controls the operation of the GPS 1.01 and 1.03.

 To select the frequency of the correspondent transmitter, unoccupied by interference, in the inventive device using control receivers 6.1 and 6.2. An assessment is made of the presence of interference at frequencies at which a radio link can be tuned into one of the following clock cycles in accordance with GPS codes 1.01 and GPS 1.03. Consider their work on the example of the receiver 6.1.

 The frequency code of the subsequent clock cycle of the first SRP from the output n + x of the GPS 1.01 is fed to the input of MF4 6.1.4. The synthesizer produces an oscillation of the required frequency, which is fed to the second input of the frequency converter 6.1.3. The first input of the inverter 6.1.3 receives interference received by A2 10. As a result of the conversion, the output voltage of the inverter 3 produces an interference voltage at the corresponding receive frequency. It is detected in AD1 6.1.2 and, based on the output voltage 6.1.2, ПУ1 6.1.1 makes a conclusion about the presence or absence of interference at the analyzed frequency. The result of the analysis is fed to the input of the SS 5.

 Similarly measure the level of interference at the subsequent frequency of the second SRP. Comparison scheme in the presence of interference at the frequency specified by the operating frequency bandwidth and the absence of interference at the frequency specified by the backup frequency bandwidth, generates control information for K 1.02 correspondent at the choice of the required frequency bandwidth and feeds it to the fourth input of the UFDP 3 for transmission to the transmitting end of the radio link. In the absence of interference at the frequency specified by the operating memory bandwidth, or in the presence of interference at frequencies specified by both PSPs, the switching of the GPSS is not performed.

 The use of the claimed device for transmitting information in the frequency hopping mode will reduce the likelihood of errors in the transmitted information in radio links with frequency hopping long distance.

Claims (1)

 A method for transmitting information in a long-distance duplex radio line with pseudo-random tuning of operating frequencies, including the formation of information packets at the transmitting end by dividing the information signal from the information source into blocks of a given length, to which the correspondent’s “address” and service information are added, the transmitter carrier frequency is tuned to the frequency corresponding to the code of the current measure of one of two or more pseudo-random sequences, which for this measure is At the end, modulation of the carrier frequency of the transmitter with the generated information packet and subsequent radiation of the received radio signal to the receiving end of the radio line, at the receiving end of the radio line, receiving the radio signal transmitted from the transmitting end at the same time at all frequencies corresponding to the codes of the current clock of all pseudorandom sequences, converting to an intermediate frequency, amplification, demodulation, decoding of the received information packet at the "address" recorded in the packet, supply of an information signal to an information receiver, characterized in that at the receiving end of the radio line, simultaneously with the reception of the radio signal, the control receivers monitor the presence of interference at frequencies corresponding to the codes of the subsequent clock of all pseudorandom sequences, and in the case of interference at a controlled frequency corresponding to the code of the subsequent clock of the working pseudorandom sequence of the transmitting end, form control information on the restructuring of the transmitter located on the transmitting end of the radio line, on frequent from the corresponding code of the subsequent clock cycle of one of the monitored pseudo-random sequences, in which there is no interference, by changing the pseudo-random sequence at the transmitting end, information packets are formed, to which control information is added to the tuning of the transmitter located at the transmitting end of the radio line, the carrier frequency of the transmitter located at the receiving end of the radio link, at a frequency corresponding to the code of the current measure of one of two or more pseudorandom sequences functions, modulate the carrier frequency of the transmitter located at the receiving end, formed by the information packet, emit the received radio signal to the transmitting end of the radio line, at the transmitting end simultaneously with the radiation of the radio signal receive the transmitted radio signal from the receiving end simultaneously at all frequencies corresponding to the codes of the current clock of all pseudorandom sequences, convert to an intermediate frequency, amplify, demodulate, decode the received information packet at the "address" recorded in the packet, control information is extracted for tuning the transmitter located on the transmitting end of the radio line, the received control information is supplied to the transmitter of the transmitting end of the radio line for tuning to a frequency corresponding to a subsequent clock code of that of the pseudorandom sequences at which there is no interference, in the absence of interference at a controlled frequency corresponding to the code of the subsequent clock of the working pseudo-random sequence of the transmitting end or the presence of interference at all monitored frequencies x, the control information and do not form a shift of the pseudorandom sequence at the transmitting end is not produced.

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