RU2185706C1 - Multichannel repeater - Google Patents

Abstract

FIELD: radio communications; ultrashort-wave repeaters. SUBSTANCE: newly introduced in repeater are several receiving units and comparison unit which function to ensure selection of best receiving signal with minimal percentage of telegraph distortions and also several control units and several controlled splitters used to select one or more channels for repeated message transmission. Provision is made for selection of receiving channel (direction) and also for selection of one or more repeated-message transmitting channels (directions) under varying communication conditions. EFFECT: enlarged functional capabilities. 2 cl, 10 dwg

Description

 The invention relates to radio communications technology and can be used to create remote multi-channel KB, as well as VHF transponders.

 A known repeater (see and.with. 944127, H 04 V 7/15, bull. 26 from 07/15/82), containing a receiver, transmitter, decoder service signals, adder, memory unit service signals, signal-to-noise ratio meter, element I. It provides a reduction in relay time delays by reducing transmission time.

 A repeater is also known (see A.S. 1378071, H 04 V 7/15, bull. 8 from 02.29.88), comprising a receiver, transmitter, service signal decoder, signal-to-noise ratio meter, service signal memory block, control unit radiated power of the transmitter, adders, AND elements, trigger, elements NOT. The known device allows you to relay the signal and control the transmitter power in order to reduce the influence of its out-of-band and spurious emissions on the receiver.

 The disadvantage of analogues is the impossibility of selecting communication directions during relaying, as well as simultaneously ensuring relaying to several correspondents in various directions.

 The closest both in the number of similar features and in the achieved technical result to the claimed device is a repeater (see AS 1243144, N 04 V 7/185, bull. 25 from 07.07.86). It contains a receiving unit including a radio receiver, a transmitting unit including a radio transmitter and a control unit including a delay element, service signal decoder, address decoder, L triggers, where L≥2, L output elements And, adder, memory element, signal / signal ratio meter noise, an OR element, and an NAND element. In this case, the information output of the radio receiver is connected to the information input of the radio transmitter, as well as to the input of the signal-to-noise ratio meter, to the input of the delay element and to the input of the address decoder. The output of the signal-to-noise ratio meter is connected to the second inputs of all elements I. The output of the delay element is connected to the input of the service signal decoder, the output of which is connected to the first input of the adder. The outputs of the address decoder are connected to the second inputs of the corresponding triggers. The output of the adder is connected to the third inputs of all the AND elements and the input of the AND element. The outputs of the triggers are connected to the first inputs of the corresponding elements I. The output of the AND-NOT element is connected to the first inputs of all the triggers. The outputs of the AND elements are connected to the control inputs of the transmitter and to the inputs of the OR element. The output of the OR element is connected to one of the control inputs of the radio transmitter and to the input of the memory block, the output of which is connected to the second input of the adder. This device provides the selection of the channel (direction) of transmission during relaying. We will take this device as a prototype.

 The disadvantage of the prototype is the inability to select a channel for receiving a repeater, as well as several transmission channels (directions) for a relayed message, which is necessary under constantly changing communication conditions.

 The aim of the invention is the development of a repeater, providing the ability to select the channel (direction) of reception, as well as one or more channels (directions) of transmission for relaying messages under changing communication conditions.

 This goal is achieved in that in a known device containing a first receiving unit including a radio receiver with an antenna, a first transmitting unit including a radio transmitter with an antenna, and a first control unit containing a delay element, the output of which is connected to the input of the service signal decoder, an address decoder, L flip-flops, where L≥2, L output elements AND, first adder, memory element and NAND element, L outputs of the address decoder are connected to the second inputs of the corresponding triggers, the outputs of which are connected to the second m inputs of the corresponding output elements AND, additionally introduced L-1 transmitting units, L-1 receiving blocks, L-1 control units, a comparison unit and L controlled splitters.

 In each receiving unit, a controlled key, a delay element, and an instruction encoder are additionally introduced. The first service, information and second service outputs of the radio are connected respectively to the first, second and third inputs of the managed key. The first control and second control inputs of the managed key are connected respectively to the first and second inputs of the command encoder and are the second and first inputs of the receiving unit. The output of the command encoder is connected to the service input of the radio receiver. The first and second outputs of the managed key are connected respectively to the output and input of the delay element, and the first and second outputs of the managed key are respectively the third and first outputs of the receiving unit. The third output of the managed key is the second output of the receiving unit.

 In each transmitting unit, a frequency code decoder and a delay element are additionally introduced. Moreover, the first input of the radio transmitter is connected to the output of the delay element, the input of which is connected to the input of the frequency code decoder and is the input of the transmitting unit. The output of the frequency code decoder is connected to the second input of the radio transmitter.

 In addition to each control unit, a channel occupation time decoder, a second delay element, a control element, L-1 AND-NOT elements, L-1 memory elements, L-1 adders, L enable elements I. are added. The input of the second delay element is connected to the decoder input channel occupation time and is the input of the control unit. The output of the second delay element is connected to the inputs of the first delay element and the address decoder. The output of the channel occupation time decoder is connected to the second inputs L of the enabling elements AND, the outputs of which are connected to the inputs of the corresponding memory elements. The outputs of the L memory elements are connected to the second inputs of the respective adders, the outputs of which are connected to the first inputs of the corresponding output elements I. The outputs of the L output elements AND are connected to the first inputs of the corresponding enable elements And are the corresponding L switched outputs of the control unit. The first inputs of the adders are combined and connected to the output of the decoder service signals. The outputs of L memory elements are combined and connected to the input of the control element, the output of which is the control output of the control unit.

 The third output of the i-th receiving unit, where i = l, 2, ..., L, is connected to the information input of the i-th controlled splitter. The first output of the i-th receiving unit is connected to the input of the i-th control unit. The first control input of the i-th receiving unit is connected to the control output of the i-th control unit, and the second control input of the i-th receiving unit is connected to the i-th output of the comparison unit. The second output of the i-th receiving unit is connected to the i-th input of the comparison unit. The input of the i-th transmitting unit is connected to the i-th outputs of L controlled splitters. The L switching inputs of the i-th controlled splitter are connected to the corresponding L switching outputs of the i-th control unit.

The comparison block consists of: L analog-to-digital converters, the inputs of which are the corresponding L inputs of the block, k steps of the comparison elements, where k = 1g ₂ (L) -l, the digital comparator and L elements I. The outputs of the elements AND are the corresponding L outputs of the block . Each gth step of the comparison elements, where g = 1, 2, .., k, includes p _g comparison elements, where p _g = 2 ^g . The outputs of the j-th and (j + 1) -th analog-to-digital converters, where j = 1, 3, 5, .., L-1, are connected respectively to the first and second inputs [(j + 1) / 2] - th comparison element of the kth step of the comparison elements. The third outputs of the nth and (n + 1) -th comparison elements of the gth stage of the comparison elements, except for the stage with the number g = 1, where n = 1, 3, 5, .., (p _g -1), are connected respectively, to the first and second inputs of the (n + 1) / 2 comparison element belonging to the (g-1) -th stage of the comparison elements. The third outputs of the first and second comparison elements of the first stage of the comparison elements are connected respectively to the first and second inputs of the digital comparator. The first and second outputs of the t-th comparison element, where t = 1, 2, 3, .., p _{g = k} , belonging to the k-th stage of the comparison elements, are connected to the first inputs, respectively (2t-1) -go and 2t- g elements I. The first and second outputs of the m-th comparison element, where m = l, 2, 3, .., p _g , belonging to the g-th stage of the comparison elements, except the stage with the number g = k, are connected to [(kg ) +1] -th inputs respectively from 4b (m-1) +1 to 2b (2m-1) and from 2b (2m-1) +1 to 4bm elements And, where b = 2 ^(kg-1) , and the first and second outputs of the digital comparator are connected to the (k + 1) -th inputs of AND elements with numbers, respectively, from 1 to L / 2 and from (L / 2) +1 d about L.

 Thanks to the new set of essential features, through the introduction of additional radios, controlled keys, command encoders and a comparison unit, the selection of the best reception channel (branch) with a minimum percentage of telegraphic distortions is ensured, and through the introduction of additional elements into control units and controlled splitters, one or more channels for transmitting a relay message.

 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 invention with the condition of patentability "novelty".

 Search results 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 showed 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 inventive device is illustrated by drawings, in which:
figure 1 shows a functional diagram of a multi-channel repeater;
in FIG. 2 - the structure of the commands transmitted during the organization of communication through the relay.

figure 3 - diagram of the radio 4;
figure 4 is a diagram of a managed key 5;
5 is a diagram of a controlled splitter 6;
6 is a diagram of a comparison unit 23;
7 is a diagram of a comparison element 23.2;
on Fig is a diagram of a managed key 23.22 (23.23);
figure 9 is a diagram of a control element 21;
figure 10 is a graph explaining the operation of the control element 21.

The inventive device shown in FIG. 1, consists of: L receiving units 1 ₁ ... 1 _L , L transmitting units 2 ₁ ... 2 _L , L control units 3 ₁ ... 3 _L , L controlled splitters 24 ₁ ... 24 _L , unit comparisons 23. Moreover, each receiving unit 1 contains a radio 4, a controlled key 5, a delay element 7, an instruction encoder 6. The first service, information and second service outputs of the radio 4 are connected respectively to the first, second and third inputs of the controlled key 5, the first control and the second control inputs of which are connected respectively to the first and second inputs of the command encoder 6 and are the second and first inputs of the receiving unit 1. The output of the command encoder 6 is connected to the service input of the radio 4. The first and second outputs of the managed key 5 are connected respectively to the output and input of the delay element 7, and the first and second outputs of the managed key 5 are the third and first, respectively the output of the receiving unit 1. The third output of the managed key 5 is the second output of the receiving unit 1.

 Each transmitting unit 2 contains a radio transmitter 10, a frequency code decoder 8 and a delay element 9. Moreover, the first input of a radio transmitter 10 is connected to the output of a delay element 9, the input of which is connected to the input of a frequency code decoder 8 and is an input of a transmitting unit 2. Output of a frequency code decoder 8 connected to the second input of the radio transmitter 10.

Each control unit 3 comprises a channel 11 occupation time decoder, a second delay element 12, an address decoder 13, a first delay element 14, an auxiliary signal decoder 15, L AND-NOT elements 16 ₁ ... 16 _L , L triggers 17 ₁ . . .17 _L , L memory elements 18 ₁ ... 18 _L , L adders 19 ₁ ... 19 _L , L output elements AND 20 ₁ ... 20 _L , control element 21, L enable elements And 22 ₁ ... 22 _L. The input of the second delay element 12 is connected to the input of the busy time decoder of channel 11 and is the input of the control unit 3. The output of the second delay element 12 is connected to the inputs of the first delay element 14 and the address decoder 13. L outputs of the address decoder 13 are connected to the second inputs of the corresponding triggers 17 ₁ ... 17 _L , the outputs of which are connected to the second inputs of the corresponding output elements AND 20 ₁ ... 20 _L. The output of the first delay element 14 is connected to the input of the service signal decoder 15. The output of the channel 11 time decoder is connected to the second inputs L of the enabling elements AND 22 ₁ ... 22 _L , the outputs of which are connected to the inputs of the corresponding memory elements 18 ₁ ... 18 _L . The outputs of the L memory elements 18 ₁ . . .18 _{L are} connected to the second inputs of the respective adders 19 ₁ ... 19 _L , the outputs of which are connected to the first inputs of the corresponding output elements AND 20 ₁ . . . 20 _L. The outputs L of the output elements AND 20 ₁ ... 20 _{L are} connected to the first inputs of the corresponding enable elements AND 22 ₁ ... 22 _L and are the corresponding L switched outputs of the control unit 3. The first inputs of the adders 19 ₁ . . . 19 _{L are} combined and connected to the output of the service signal decoder 15. The outputs of L memory elements 18 ₁ ... 18 _{L are} combined and connected to the input of the control element 21, the output of which is the control output of the control unit 3.

The third output of the i-th receiving unit 1 _i , where i = 1, 2, ... L, is connected to the information input of the i-th controlled splitter 24 _i . The first output of the i-th receiving unit 1 _{i is} connected to the input of the i-th control unit 3 _i . The first control input of the i-th receiving unit 1 _{i is} connected to the control output of the i-th control unit 3 _i , and the second control input of the i-th receiving unit 1 _{i is} connected to the i-th output of the comparison unit 23. Second output of the i-th receiving unit 1 _{i is} connected to the i-th input of the comparison unit 23. The input of the i-th transmitting unit 2 _{i is} connected to the i-th outputs L of the controlled splitters 24 ₁ ... 24 _L. L switching inputs of the i-th controlled splitter 24 _{i are} connected to the corresponding L switching outputs of the i-th control unit 3 _i .

Comparison unit 23 is designed to compare L voltage values at L inputs and generate a logic level control signal for that receiving unit 1, at the output of the radio receiver 4 of which this value is maximum. The comparison unit may be implemented in various ways, in particular, as shown in FIG. 6. To simplify the description in the above diagram, the value of L is taken equal to 8. Thus, for this case, the comparison unit 23 consists of eight (L = 8) analog-to-digital converters 23.1 ₁ ... 23.1 ₈ , the inputs of which are the corresponding inputs 1. ..8 blocks, two (k = log ₂ (L) -1 = 3-1 = 2) stages of the comparison elements 23.2, the digital comparator 23.3 and eight elements AND 23.4 ₁ ... 23.4 ₈ . The outputs of the elements And 23.4 ₁ ... 23.4 ₈ are the corresponding outputs 1 ... 8 of the block. The first (g = 1) stage of the comparison elements includes two (p _{g = 1} = 2) comparison elements 23.2 ₁ , 23.2 ₂ . The second (g = k = 2) stage of the comparison elements includes four (p _{g = 2} = 4) comparison elements 23.2 ₁ , 23.2 ₂ , 23.2 ₃ , 23.2 ₄ . The outputs of the first 23.1 ₁ and second 23.1 ₂ , third 23.1 ₃ and fourth 23.1 ₄ , fifth 23.1 ₅ and sixth 23.1 ₆ , seventh 23.1 ₇ and eighth 23.1 ₈ (j-th and (j + 1) -th, where j = 1, 3, 5, 7) analog-to-digital converters are connected respectively to the first and second inputs of the first 23.2 ₁ , the first and second inputs of the second 23.2 ₂ , the first and second inputs of the third 23.2 ₃ , the first and second inputs of the fourth 23.2 ₄ ([(j + 1 ) / 2] th) comparison elements of the second (k = 2) stage of the comparison elements. Each analog-to-digital converter 23.1 converts the voltage supplied to its input into a q-bit number, so the outputs of the analog-to-digital converters are a bus consisting of q physical wires. The third outputs of the first 23.2 ₁ and second 23.2 ₂ comparison elements (n = 1 and (n + 1) = 2) the second (g = 2) stage of the comparison elements are connected respectively to the first and second inputs of the first comparison element 23.2 ₁ ((n + 1 ) / 2, where n = 1), which belongs to the first ((g-1) -th) stage of the elements of comparison. The third outputs of the third 23.2 ₃ and fourth 23.2 ₄ (n = 3 and (n + 1) = 4) comparison elements of the second stage of the comparison elements are connected respectively to the first and second inputs of the second ((n + 1) / 2, where n = 3) the comparison element 23.2 ₂ belonging to the first stage of the comparison elements. The third outputs of the first 23.2 ₁ and second 23.2 ₂ comparison elements of the first stage of the comparison elements are connected respectively to the first and second inputs of the digital comparator 23.3. The first and second outputs of the t-th comparison element 23.2 _t , where t = 1, 2, 3, p _{g = k = 2} = 4, belonging to the second (k = 2) stage of the comparison elements, are connected to the first inputs, respectively (2t-1 ) of the 2nd and 2nd elements of AND 23.4. The first and second outputs of the first (m = 1) comparison element 23.2 ₁ belonging to the first (g = 1) stage of the comparison elements are connected to the second ((kg) + 1 = 2-1 + 1 = 2) inputs, respectively, of the first 23.4 ₁ , second 23.4 ₂ (from 4b (m-1) + 1 = 4 (1-1) + 1 = 1 to 2b (2m-1) = 2 (2-1) = 2, where b = 2 ^(kg-1) = 2 ^(2-1-1) = 1) and the third 23.4 ₁ , the fourth 23.4 ₁ (from 2b (2m-1) + 1 = 2 (2-1) + 1 = 3 to 4bm = 4) elements I. The first and the second outputs of the second (m = 2) comparison element 23.2 ₂ belonging to the first (g = 1) stage of the comparison elements are connected to the second ((kg) + 1 = 2-1 + 1 = 2) inputs, respectively, of the fifth 23.4 ₅ , sixth 23.4 ₆ (from 4b (m-1) + 1 = 4 (2-1) + 1 = 5 to 2b (2m-1) = 2 (4-l) = 6) and 23.4 seventh _7, an eight nd 23.4 ₈ (from 2b (2m-1) +1 = 2 (4-1) + 1 = 7 to 4bm = 8) items I. The first output of the digital comparator is connected to a third 23.3 ((k + 1) = 2 + 1 = 3) the inputs of the first, second, third and fourth elements AND 23.4 ₁ . ..23.4 ₄ (with numbers respectively from 1 to L / 2 = 4), and the second output - to the third inputs of the fifth, sixth, seventh and eighth elements And 23.4 ₅ ... 23.4 ₈ (with numbers respectively from (L / 2 ) + 1 = 4 + 1 = 5 to L = 8).

Comparison element 23.2 is intended to determine the larger of the two q-bit numbers supplied to its inputs. Depending on which number is large: received at the first or second input, the resulting high-level voltage appears on the corresponding output (first or second), and the code of this number appears on the third output. The comparison element 23.2 is shown in Fig.7 and consists of a digital comparator 23.21 and two managed keys 23.22, 23.23. The inputs to which the codes of the two numbers A and B are compared, the digital comparator 23.21 are respectively the first and second inputs of the comparison element and physically represent the bus consisting of q physical wires. In addition, the first and second inputs of the comparison element are connected to the information input of the first 23.22 and second 23.23 managed keys, respectively. The output from which the resulting signal comes in when the number at the first input is greater than the number at the second input (A> B) of the digital comparator 23.21 is connected to the control input of the first managed key 23.22 and is the first output of the comparison element. The outputs from which the resulting signal arrives in cases where the number at the first input is less than or equal to the number at the second input (A <B and A = B) are combined, connected to the control input of the second managed key 23.22 ₂ and are the second output of the element comparisons. The information outputs of the first and second managed keys 23.22 ₁ , 23.22 _{2 are} combined and are the third output of the comparison element, which is also a q-bit bus.

 Command encoder 6 is designed to generate a command to resume scanning (similar to a command when you press the Enter key on the front panel of the radio) if there is high potential at the first input and generate commands to stop scanning (similar to a command when you press the Return key on the front panel of the radio ) and reading the code with the frequency number (similar to the command requesting the status of the radio receiver) in the presence of high potential at the second input of the command encoder. The output block described above can be used as the command encoder - O. Golovin Decameter professional radio receivers. -M .: Radio and communications, 1985, p.134 ... 154.

 As the radio receiver 4 of the receiving unit 1 (Fig. 3), any of the known radio receivers having the ability to scan by frequencies, for example, the Artek-Helios KB receiver, which is described as “KB radio receivers of 4-5 generations”, can be used. Ed. V.D. Chelysheva. -SPb .: YOU, 1998, -88s. As an information output, the "Outputs" jack (X20) is used. The signal of evaluating the reception quality of 0.6 ... 10 V depending on the percentage of telegraph distortions (the less distortion the greater the voltage) can be output through the control point of the KT5 interface of unit B5-96 (Artek-Helios product. Technical description. ЦЛ2 .003.143TO. S.173 ... 178 .; Appendix 2. TSL2.003.143 TO2. 1991). This output is designated as "Control". To obtain information about the number of the receiving frequency (upon request about the state of the radio) at which the call is received, and to send commands to stop and resume scanning, it is necessary to connect to the inputs of the remote control, by which the radio is remotely controlled. Synchronization of the tuning of all radios in frequencies can be provided either manually by operators or automatically when creating a synchronization system. In the latter case, to the socket of one of the radios 4 with the output voltage of the reference frequency "Output, OG" (X30), the inputs of the oscillation of the reference frequency can be connected to operate from the external source "In. Ex OG" (X10) of the remaining radios 4 (in figure 1 not shown).

 Managed keys 23.22, 23.23 (Figs. 7, 8) are designed to connect your information input to the information output if a high level voltage is received at the control input. Managed key 5 (Fig. 4) is used to connect input 1 to output 1, input 2 to output 2, and disconnect input 3 from output 3 in the event that a high level voltage is supplied to control input 1, as well as disconnect inputs 1 and 2, respectively, from outputs 1 and 2 and connecting input 3 to output 3 when a high level voltage is supplied to the control input 2 of the key. The construction scheme of the managed key 5 (Fig. 4), as well as the managed keys 23.22, 23.23 (Fig. 8) of the comparison unit 23 are known and described; they can be built on series 435 microcircuits, for example, on the electronic key microcircuit 435KN1 (see Veniaminov V. N. and other Microcircuits and their application. Reference manual. -M.: Radio and communications, 1983, p. 66).

 The delay element 7 of the receiving unit 1 and the first delay element 14 of the control unit 3 are designed to delay the message for the duration of one service packet of the relayed message, the second delay element 12 of the control unit 3 is for the duration of two service packets, and the delay element 9 of the transmitting unit 2 is for the duration four service packs. These blocks are identical to the delay element described in the prototype, and can be implemented on the elements of the time delay K523BR1 or digital delay lines KR186IR5, described - Integrated circuits: Reference. Ed. B.V. Gibberish -M.: Radio and Communications, 1984, p. 288, p. 177.

 A frequency code decoder 8 and a channel 11 occupation time decoder are intended for extracting packets with a frequency code number and an RCR channel occupation time from a message. As decoders, input units or executive half-kits of tele-control and tele-signaling systems described above can be used - O. Golovin Decameter professional radio receivers. -M .: Radio and communications, 1985, p. 134 ... 154, and also - Fransev E.P., Mayorov A.A. Remote control equipment KB transmitters ADU-2. Telecommunications, 1982, 4, p. 34 ... 36.

 As the transmitter 10 of the repeater can be used one of the automated transmitters, implemented and described -Military radio communication systems. Part 1. Ed. V.V. Ignatova. -L .: YOU, 1989, p. 125 ... 258.

Two-input logic elements AND 22, identical to the elements AND 20 included in the control unit of the transmitter 3, as well as k + 1-input elements AND 23.4 ₁ . . .23.4 _L comparison block 23 known and described - Fundamentals of digital technology / L. A. Maltseva, E.M. Fromberg. -M .: Radio and communication, -s. 30 - 31. They can be implemented on the IC series 133 and 564.

 The control element 21 of the control unit 3 is designed to generate a short-term control pulse at the output (supplied to the control input 2 of the controlled key 5 and to the second input of the command encoder 6 of the corresponding receiving unit 1) when the high potential is changed to low (i.e., release transmission channel). One of the options for implementing the control element 21 may be the circuit shown in Fig.9. Moreover, it consists of: delay element 21.1, element NOT 21.2, element OR NOT 21.3. Moreover, the first input of the OR-NOT 21.3 element is connected to the input of the delay element 21.1 and is the input of the control element 21. The output of the delay element 21.1 is connected to the input of the element NOT 21.2, the output of which is connected to the second input of the OR-NOT 21.3 element. The output of the element OR NOT 21.3. is the output of the control element 21. Figure 10 presents graphs explaining the principle of operation of the control element.

 The element NOT 21.2 (inverter) and the element OR NOT 21.3 are known and described. Can be implemented on the IC K161LE1 described-Integrated circuits: Reference. Ed. B.V. Gibberish -M .: Radio and communications, 1984, p. 102, p. 109. The delay element 21.1 is known and described. It can be implemented on the IC K523BR1 described - Integrated circuits: Reference. Ed. B.V. Gibberish -M .: Radio and communications, 1984, p. 248.

Analog to Digital Converters 23.1 ₁ . . . 23.1 _L comparison unit 23 is designed to convert the voltage supplied to their inputs from the service outputs of the 4 L receiver units into parallel binary code (q-bit number), known and described - V. Veniaminov and other microcircuits and their application. Reference manual. -M .: Radio and communications, 1989, p. 184 ... 186. They can be implemented on IMSC572PV1.

 The digital comparators 23.21 of the comparison elements 23.2 and the digital comparator 23.3 of the comparison unit 23 perform the operation of comparing the codes of two numbers arriving at the first (A) and second (B) inputs. They form a sign of the result of the comparison in the form of a high level voltage at one of three outputs (A <B, A> B, A = B). If the number received at the first input is greater at the first output (A> B), if these numbers are equal (A = B) at the second output, and if the number received at the second input is greater at the third output (A < IN). The outputs A = B and A <B are combined. Digital comparators are known and described - V. Veniaminov and other microcircuits and their application. Reference manual. -M .: Radio and communications, 1989, p.113 ... 114. They can be implemented on IC K561IP2.

The controlled splitter 24 (Fig. 5) is designed to connect its information input (i.e., the information output of the receiver) to one or more (A ₁ ... A _L ) outputs (i.e. to the information input of one of L or several transmitters). As such a device, a controlled splitter of information signals can be used, described Transmitting antenna array, RF patent 2108646 bull. 11 from 04/18/98 (figure 2).

The inventive device operates as follows. The relay transmits and receives messages from a group of radio stations (serves the group), while the transmission of a message from one radio station of the group to another is possible only through the relay. For operation, the repeater is allocated K receiving and N transmitting frequencies that can be used by any radio station served by the repeater. The radios 4 of all unoccupied messages (out of L available) of the receiving units 1 of the repeater, each connected to its antenna, synchronously scan at K frequencies. The calling radio station determines the number of the free transmitter of the repeater, selects one free of K and one free of N frequencies, generates service packets, adds them to the message and starts its transmission. In this case, the relayed message should have the format as shown in Fig. 2 and consist of the following packets: the number of the called radio station (the duration of this packet is selected in accordance with the scanning speed and the number of frequencies), the number of the currently free transmitter on the relay, and the frequency number repeater transmission (the best for the group and currently free of N frequencies, which can be determined by the results of scanning and analysis of N frequencies of each radio station), the time of occupation of the relay channel (i.e. time The transfer of ownership of information t _inf and overhead transmission time t _servi) number of the calling station, and the message itself. During the transmission of the packet with the number of the called radio station, the radios 4 of all free receiving units 1 pass all K frequencies. At the frequency at which the information is transmitted, information about the signal quality, i.e., signal quality, is received from the service outputs 2 of the radio receivers 4 to the inputs 3 of the controlled keys 5 voltage appears, the level of which is inversely proportional to the magnitude of telegraph distortions in the received message. Through the closed contacts of the controlled keys 5, this voltage is supplied to the outputs 3 of these keys and then to the inputs of the comparison unit 23 corresponding to the receiving blocks.

On the example of the circuit shown in Fig.6, consider the operation of the eight-channel comparison unit 23. At the output of each analog-to-digital Converter 23.1 ₁ . . .23.1 ₈ a q-bit number code appears corresponding to the voltage value supplied to its input, i.e. to the corresponding input of the block. The numbers from the outputs of the first and second, third and fourth, fifth and sixth, seventh and eighth (j and j + 1, where j = 1, 3, 5) analog-to-digital converters 23.1 are received respectively at the first and second inputs of the first, second, third and fourth ((j + 1) / 2) elements of comparison 23.2 of the second stage. In each comparison element 23.2 (Fig. 7), two q-bit numbers A and B are compared, which are received respectively at the first and second inputs of the comparison element 23.2. As a result of their comparison in the digital comparator 23.21, at one of its outputs A> B or A <B (since A <B and A = B are combined), a high level voltage appears, which is fed to the control input of the first 23.22 (if the number A will be greater than the number B) or the second 23.23 (if A <B or A = B) of the managed key, as well as the first or second output of the comparison element 23.2, respectively. Depending on the control input of which key, a high level voltage has been received, at its output, and hence at the third output of the comparison element 23.2, the code of the largest of the two q-bit numbers A or B appears. Thus, on the third output of each element comparison 23.2 ₁ ... 23.2 _{4 of the} second stage will appear the code of the largest of the two numbers received respectively at the first and second, third, fourth, fifth and sixth, seventh and eighth inputs of block 23. Codes of these four remaining numbers are received at the first and second inputs 23.2 the first ₁ and ₂ 23.2 orogo comparison elements of the first stage, which is also mutually compared. In addition, at the first input of the first or second element And 23.4 appears a high level voltage, respectively, from the first or second output of the comparison element 23.2 _{1 of the} second stage. At the first input of the third or fourth element And 23.4 appears a high level voltage, respectively, from the first or second outputs of the comparison element 23.2 _{2 of the} second stage. At the first input of the fifth or sixth element And 23.4 appears a high level voltage, respectively, from the first or second outputs of the comparison element 23.2 _{3 of the} second stage. At the first input of the seventh or eighth element And 23.4 appears a high level voltage, respectively, from the first or second output of the comparison element 23.2 _{4 of the} second stage. At the third output of the first comparison element 23.2 _{1 of the} first stage, the code of the largest of the four numbers received at the first, second, third and fourth inputs of the block appears, and at the third output of the second comparison element 23.2 _{2 of the} first stage, the code of the largest of four numbers appears received on the fifth, sixth, seventh and eighth inputs of the block. The codes of these two largest remaining numbers arrive respectively at the first (A) or second (B) inputs of the digital comparator 23.3, where they are also compared. In addition, the second inputs of the first and second or third and fourth elements And 23.4 receives a high level voltage, respectively, from the first or second output of the comparison element 23.2 _{1 of the} first stage. The second inputs of the fifth and sixth or seventh and eighth elements And 23.4 receives a high level voltage, respectively, from the first or second output of the comparison element 23.2 _{2 of the} first stage. The result of comparing the remaining numbers in comparator 23.3 is a high-level voltage from its output A> B or the combined output A <B and A = B, which goes to the third (k + 1) inputs, respectively, or of the elements And 23.4 ₁ . . . 23.4 ₄ , or elements AND 23.4 ₅ ... 23.4 ₈ . High-level voltage appears at the output of that element And 23.4, at all inputs of which there is a high-resolution voltage from comparison elements 23.2 of all stages and a digital comparator 23.3. The number of this element will correspond to the input number of the comparison unit 23, which received the highest voltage, so a high level voltage will appear at the corresponding output of the unit.

 Thus, the comparison unit 23 generates a command to switch the managed key 5 of the receiving unit 1, at the output of the radio 4 which provides the best signal quality. This command arrives at the first control input of the managed key 5 of the selected receiving unit 1 and switches its contacts. In this case, input 1 is connected to output 1, input 2 is connected to output 2, and input 3 is disconnected from output 3. In addition, this command is sent to the first input of command encoder 6, which generates commands to stop scanning of radio receiver 4 and generating a receiving frequency code received at the service input of the radio 4. By these commands, the radio 4 stops scanning and generates a code number of the receiving frequency. This code comes from the service output 1 of the radio 4 to the first input of the managed key 5 and then through the closed contacts of the managed key 5 from its first output to the input of the managed splitter 24 corresponding to the receiving unit 1. Information from the information output of the receiver goes to the second input of the managed key 5 and through closed contacts - to its second output, and then to the input of the delay element 7 of the receiving unit 1. From the output of the delay element, the information goes to the input of the same controlled splitter 24 and thanks to Another service packet with the code number of the receiving frequency of the relay is added to the beginning of the relayed message (Fig. 2). Because Since all the radio stations of the group served by the repeater receive this message, they will be aware of the busy (forbidden for use by them) during the relay of the message of the frequency of reception and transmission of the message, as well as the transmitter of the repeater.

 Also, information from the second output of the managed key 5 of the receiving unit 1 is fed to the input of the control unit 3 corresponding to the receiving unit.

The control unit 3 operates as follows. The decoder time occupation channel 11 information is received without delay. Thanks to the first delay element 14 and the second delay element 12 to the service signal decoder 15, information arrives with a delay equal to the duration of three service packets, and thanks to the second delay element 12 to the address decoder information arrives with a delay equal to the duration of two service packets. Thus, service packets with the time taken by the repeater channel, the number of the called radio station (call), the number of the radio transmitter of the repeater are simultaneously sent to the channel time decryptor 11, service signal decoder 15 (call commands), address decoder 13 (repeater number decoder). From the output of the decoder of the occupation time of channel 11 to the inputs of the memory elements 18 ₁ ..18 _L receives information about the occupation time of the channel. At the same time, writing to one or more memory elements 18 is performed only if the first input of the corresponding resolving element And 22 has a resolving command from the output of the corresponding output element And 20. This command is formed as follows. Depending on the number (numbers) of the radio transmitter transmitted in the corresponding service packet, a signal appears at the corresponding output of the decoder 13 at the same time as the signal at the output of the service signal decoder 15. The signal from the output of the service signal decoder 15 is fed to the first input of the adder 19. The signal from the output of the decoder 13 transfers the corresponding trigger 17 to a single state. At the output of the trigger, a high potential appears, which is fed to the second input of the corresponding output element And 20. The first input of the adder 19 first receives a command from the output of the call command decoder 15, and after its end, a command from the corresponding memory element 18 for the entire time the channel is occupied. If there is a single output signal corresponding to the number of the radio transmitter at the two inputs of the output element And 20, a command is generated at its output to allow the recording of occupation time in memory element 18 and to turn on the transmitter. This command, in addition, is supplied to the input (S ₁ -S _L ) of the controlled splitter 24 corresponding to the number of the radio transmitter. The controlled splitter 24 connects the corresponding radio transmitter to its information input (and, therefore, to the information output of the receiver). The command to occupy the channel from the memory element 18 through the adder 19 also arrives at the input of the NAND 16 element and there is no command at its output to transfer the corresponding trigger 17, which is in a single state, to the zero state. At the end of the transmission time of the message and the transmission channel of the repeater is released, the high potential at the output of the memory element 18 is changed to low and a control signal appears at the output of the NAND 16 element, which puts the corresponding trigger 17 to zero. Also in this case, a short-term pulse appears at the output of the control element 21, which is supplied to the second input of the command encoder 6 of the corresponding receiving unit 1. The command encoder 6, in turn, generates a command to resume scanning by the radio receiver 4, arriving at its service input. This pulse also arrives at the control input 2 of the controlled key 5 of the corresponding receiving unit 1 and transfers it to its initial state (inputs 1 and 2 are respectively disconnected from outputs 1 and 2, and input 3 is connected to output 3).

 Thus, in accordance with the information on the number (s) of the repeater radio transmitter contained in one of the packages, the control unit 3 generates a command to connect this radio transmitter (s) to the information output of the radio receiver for a time, which is also indicated in one of the message packets (Fig. .2). Information from the output of the radio receiver 4 through the controlled key 5, the delay element 7 of the corresponding receiving unit 1 and through the corresponding managed splitter is fed to the input of one or more transmitting units 2. Before entering the information input of the radio transmitter 10 of the corresponding transmitting unit 2, the message is delayed in the delay element 9 for the time required for the decoder of the frequency code 8 to instruct the radio transmitter 10 to the frequency whose value is transmitted in one of the service packets (number pilots at the transmitter repeater in Figure 2). The radio transmitter 10 tunes to the desired frequency and transmits a message that is received by all the radio stations of the group.

 Thus, the proposed device allows you to select the channel (direction, branch) of the reception, providing the best signal quality. In addition, by connecting one or more radio transmitters (which can operate on different antennas and at different frequencies) to the information output of the radio receiver, both relaying the message simultaneously to several selected correspondents and spatial signal diversity during transmission can be provided.

Claims (2)

 1. A repeater comprising a first receiving unit including a radio receiver with an antenna, a first transmitting unit including a radio transmitter with an antenna, and a first control unit containing a first delay element, the output of which is connected to the input of the service signal decoder, an address decoder, L triggers, where L ≥2, L of the output elements AND, the first adder, the memory element and the element NAND, L of the outputs of the address decoder are connected to the second inputs of the corresponding triggers, the outputs of which are connected to the second inputs of the corresponding output elements ntov And, characterized in that L-1 transmitting units, L-1 receiving units, L-1 control units, a comparison unit and L controlled splitters are additionally introduced, moreover, a controlled key, a delay element, an instruction encoder are additionally introduced into each receiving unit, the first service, information and second service outputs of the radio are connected respectively to the first, second and third inputs of the managed key, the first control and second control inputs of which are connected respectively to the first and second inputs of the command encoder and are the second and first inputs of the receiving unit, the output of the command encoder is connected to the service input of the radio receiver, the first and second outputs of the managed key are connected respectively to the output and input of the delay element, the first and second outputs of the managed key are respectively the third and first outputs of the receiving unit, the third the output of the controlled key is the second output of the receiving unit, a frequency code decoder and a delay element are additionally introduced into each transmitting unit, the first input of the radio transmitter is connected is connected to the output of the delay element, the input of which is connected to the input of the frequency code decoder and is the input of the transmitting unit, and the output of the frequency code decoder is connected to the second input of the radio transmitter, a channel occupation time decoder, a second delay element, and a control element are additionally introduced into each control unit, L -1 AND-NOT elements, L-1 memory elements, L-1 adders, L enable elements AND, and the command to occupy the channel from the memory elements through the adders goes to the inputs of the AND-NOT elements and a control appears on their outputs The signal that translates the triggers to the corresponding state, the input of the second delay element is connected to the input of the channel occupation time decoder and is the input of the control unit, the output of the second delay element is connected to the inputs of the first delay element and the address decoder, the output of the channel occupation time decoder is connected to the second inputs L allowing elements And, the outputs of which are connected to the inputs of the corresponding memory elements, and the outputs of the L memory elements are connected to the second inputs of the corresponding adders, the outputs to which are connected to the first inputs of the corresponding output elements AND, the outputs L of the output elements AND are connected to the first inputs of the corresponding enabling elements AND and are the corresponding L switched outputs of the control unit, the first inputs of the adders are combined and connected to the output of the service signal decoder, the outputs of the L memory elements are combined and connected to the input of the control element, the output of which is the control output of the control unit, the third output of the i-th receiving unit, where i = 1, 2,. . . , L, is connected to the information input of the i-th controlled splitter, the first output of the i-th receiving unit is connected to the input of the i-th control unit, the first control input of the i-th receiving unit is connected to the control output of the i-th control unit, and the second control the input of the i-th receiving unit is connected to the i-th output of the comparison unit, the second output of the i-th receiving unit is connected to the i-th input of the comparison unit, the input of the i-th transmitting unit is connected to the i-th outputs of L controlled splitters, L switching inputs i-th managed splitter connected to corresponding L switching outputs of the i-th control unit. 2. The repeater according to claim 1, characterized in that the comparison unit consists of L analog-to-digital converters, the inputs of which are the corresponding L inputs of the block, k steps of the comparison elements, the digital comparator and L elements And, the outputs of which are the corresponding L outputs of the block, the gth step of the elements of comparison, where g = 1, 2,. . . , k, includes p _g comparison elements, where p _g = 2 ^g , outputs of j- and (j + 1) -go analog-to-digital converters, where j = 1, 3, 5,. . . , L-1, are connected respectively to the first and second inputs of the [(j + 1) / 2] th comparison element of the kth step of the comparison elements, the third outputs of the n- and (n + 1) th comparison elements of the gth stage comparison elements, except for the step with the number g = 1, where n = 1, 3, 5,. . . , (p _g -1), respectively, are connected to the first and second inputs of the (n + 1) / 2 comparison element belonging to the (g-1) -th stage of the comparison elements, and the third outputs of the first and second comparison elements of the first stage of the comparison elements connected respectively to the first and second inputs of the digital comparator, the first and second outputs of the t-th comparison element, where t = 1, 2,. . . , p _{g = k} , belonging to the k-th stage of the comparison elements, are connected to the first inputs of (2t-1) and 2t-th elements And, respectively, the first and second outputs of the m-th comparison element, where m = 1, 2,. . . , p _g belonging to the gth step of the elements of comparison, except for the step with the number g = k, are connected to the [(kg) +1] th inputs, respectively, from 4b (m-1) +1 to 2b (2m-1) and from 2b (2m-1) -H to 4bm AND elements, where b = 2 ^(kg-1) , and the first and second outputs of the digital comparator are connected to the (k + 1) -th inputs of AND elements with numbers, respectively, from 1 to L / 2 and from (L / 2) + 1 to L.

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