RU2168271C1 - Device for radio transmitter backup - Google Patents

Abstract

FIELD: radio communication equipment. SUBSTANCE: device is designed to be used in radio transmitting units of increased reliability. Device for radio transmitter backup has two exciters, two power amplifiers, antenna. antenna switch, ballast load, control unit, power supply units of exciters, power amplifiers with switches, analyzers of state of exciters and amplifiers. , pickups controlling current of exciters and amplifiers, splitter of information signal, delay line of information signal, switches of delay of information signal. In case of failure of key transmission path control unit disconnects it from antenna, turns off supply of exciter and power amplifier of major transmission path, connects antenna to backup path, switches on supply of exciter and power amplifier of backup path, feeds information signal through delay line placed across of backup radio path. Thanks to insertion of additional units and new couplings, switching over of radio paths backup is carried out without information loss with raised reliability of device and reduced energy losses. EFFECT: ensured transition from key path of transmitter to backup path without information loss with rise of reliability and reduced power loss. 1 cl, 3 dwg

Description

 The invention relates to radio communications technology and is intended for use in digital radio transmitting devices of high reliability.

 A device for switching on a backup radio transmission path is known, comprising a master oscillator and two amplification paths, one of which is the main, the other is backup, and the high-frequency outputs of which are connected to the antenna via an antenna switch. In the device, the signal is fed to both paths. If some time after the input signal arrives, the signal at the output of the main path does not appear, then the backup path is turned on and the main path is turned off (see A.S. N 35456, NRB, MKI 4 H 04 V 7/005, 1984). The main disadvantage of this device is the presence of a high-frequency contact switch designed for switching amplification paths, which at high power leads to a decrease in the reliability of the device. To increase the reliability of the switch, you can turn off the high voltage during the transition from the main path to the backup one, but this leads to an increase in the transition time. The known redundant radio transmitter (see A.c.N. 1070696, USSR, MKI H 04 B 1/04, 1981) and the radio transmitter backup device (Application N 23394, Japan, MKI H 04 B 1/74, 1985 have similar disadvantages) g.). The closest in number of similar features is a radio transmitter backup device containing an exciter, a primary and backup power amplifiers, an antenna, a non-contact antenna switch, two delay lines of a high-frequency signal, one at the output of each power amplifier, power supplies for each power amplifier with power switches, current control sensors in the power amplifier power circuits, power amplifier status analyzers and a control unit that generates control commands power amplifiers switchover from primary to standby and connect the antenna to a working amplifier.

 We will take this device as a prototype.

The disadvantages of the prototype include:
1. Large power losses in the high-frequency channel of the radio transmitter. This is due to the fact that, firstly, the power of the high-frequency signal of the backup amplifier (when both power amplifiers are in good condition) is wasted in a ballast load, and, secondly, incomparably large losses are introduced by delay lines in the form of pieces of coaxial cable introduced into high-frequency paths between the outputs of power amplifiers and the antenna (or ballast load). If the propagation speed of an electromagnetic wave in a high-frequency cable is 200,000 km / s, a cable length of 200,000 km will be required to ensure a delay of the high-frequency signal even by 1 second. The attenuation introduced by such a length of cable will be approximately 10 ⁵ - 10 ⁶ dB.

 2. The introduction of a delay line in both paths in principle cannot exclude information loss when switching power amplifiers, since in the presence of delay lines in both paths there is no relative delay in the signal in one path compared to the other. Therefore, when switching amplifiers, information is lost.

 3. The reliability of the device is low due to the presence of one pathogen in it, since the radio transmitter with both amplifiers operational, but with a faulty exciter turns out to be inoperative. In addition, since in the case of a good condition of both amplifiers they (both) turn on, the time between failures becomes half as much as when the amplifiers are switched on alternately.

 The aim of the invention is to develop a device that provides a transition from the main transmission path to the backup without loss of information while improving reliability and reducing power losses.

 To achieve a technical result, a known radio transmitter backup device containing an exciter with its own power supply unit, first and second power amplifiers, state analyzers of the first and second power amplifiers, antenna switch, antenna, ballast load, power amplifier power supplies, power amplifier power switches, sensors current control of power amplifiers and a control unit, moreover, one of the outputs of the antenna switch is connected to the antenna, and the other to the ballast load, input The odes of the power amplifier status analyzers are connected to the outputs of the respective power amplifiers, and the outputs are connected to the corresponding inputs of the control unit, the other information inputs of which are connected to the information outputs of the current control sensors of the respective power amplifiers, the input of the current monitoring sensor of each of the power amplifiers is connected to the output of the corresponding power switch , and the output is with the power input of its power amplifier, the input of each power switch is connected to the output accordingly power supply, the control input of the power switch of the first power amplifier is connected to the control input of the antenna switch and the first control output of the control unit, the second control output of which is connected to the control input of the power switch of the second power amplifier, a second driver with a power supply, power switches of the first and second pathogens, state analyzers of the first and second pathogens, current monitoring sensors of the first and second pathogens, splitter inf signal, information signal delay line, information signal delay switches. The outputs of the power amplifiers are connected to the corresponding inputs of the antenna switch. The information input of the backup device of the radio transmitter is connected to the input of the splitter of the information signal, and the input of the clock pulses is connected to the clock input of the delay line. The outputs of the splitter of the information signal are connected to the information inputs of the corresponding input delay switches of the information signal, the first output of each of which is connected to the first input of the corresponding output delay switch of the information signal, and the second output of each of the input switches of the delay of the information signal is connected to the information input of the delay line, the output of which connected to the second inputs of the output switches delay information signal. The control inputs of the input and output delay switches of the first path are combined and connected to the third control output of the control unit, the fourth control output of which is connected to the control inputs of the input and output delay switches of the information signal of the second path. The output of each of the output delay switches of the information signal is connected to the input of the pathogen of the corresponding path. The output of each pathogen is connected to the input of the power amplifier of its path, as well as to the input of its state analyzer, the output of each of which is connected to the corresponding information input of the control unit. The output of the power supply unit of each pathogen is connected through a series-connected power switch and a current monitoring sensor with a supply input of the pathogen. The outputs of the sensors for monitoring the current of pathogens are connected to the corresponding information inputs of the control unit. The control input of the first path exciter power switch is connected to the control input of the power switch of the power amplifier of the first path, as well as to the control input of the antenna switch and to the first control output of the control unit. The control input of the power path switch of the second path is connected to the control input of the power switch of the power amplifier of the same path and with the second control output of the control unit.

 The control unit contains four OR-NOT elements, five AND elements, two OR elements, two NOT elements, a manual switch, six controllable switches, two capacitors, four resistors and a constant voltage source. The inputs of the elements OR are NOT the corresponding information inputs of the control unit. The outputs of the first and third elements OR are NOT connected to the inputs of the first AND element, and the outputs of the second and fourth elements OR are NOT connected to the inputs of the second AND element. The outputs of the first and second elements AND are connected to the first inputs of the first and second OR elements, respectively. One of the terminals of the DC voltage source is connected to the input of the manual switch, and the other is grounded. The input of the manual switch is connected to the inputs of the first four controllable switches. The outputs of the first two controllable switches are combined and connected to the first input of the third element And, as well as to the first output of the first capacitor and to the first output of the second resistor, the second output of which is grounded. The second terminal of the first capacitor is connected to the second input of the first OR element and to the first terminal of the first resistor, the second terminal of which is grounded. The output of the first OR element is connected to the second input of the third AND element, the output of which is connected to the first control output of the control unit and to the input of the first element NOT. The outputs of the third and fourth controlled switches are combined and connected to the first input of the fourth element And, as well as to the first output of the second capacitor and to the first output of the fourth resistor, the second output of which is grounded. The second terminal of the second capacitor is connected to the second input of the second OR element and to the first terminal of the third resistor, the second terminal of which is grounded. The output of the second OR element is connected to the second input of the fourth AND element, the output of which is connected to the second control output of the control unit and to the input of the second element NOT. The first output of the manual switch is connected to the third control output of the control unit and to the control inputs of the first and fifth controlled switches. The second output of the manual switch is connected to the fourth control output of the control unit and to the control inputs of the third and sixth controlled switches of the control unit. The output of the first element is NOT connected to the first input of the fifth element And and to the input of the fifth controlled switch, the output of which is connected to the control input of the fourth controlled switch. The output of the second element is NOT connected to the second input of the fifth element And and to the input of the sixth controllable switch, the output of which is connected to the control input of the second controllable switch. The output of the fifth AND element is the output of the "ALARM" signal.

 Thanks to a new set of essential features, due to the introduction of a second driver with a power supply, power switches for the first and second drivers, condition analyzers for the first and second drivers, current monitoring sensors for the first and second drivers, an information signal splitter, a switched delay line, and an information signal delay switches, it is possible to switch the radio transmitter from the main radio path to the backup one in case of failure of the main path, without loss of information while reducing power losses and increasing device reliability.

 The analysis of the prior art made it possible to establish that analogues that are characterized by a combination of features identical to all the features of the claimed technical solution are absent, which indicates the compliance of the claimed device with the patentability condition of "novelty". Search results for known solutions in this and related fields in order to identify features that match the distinctive features of the claimed device from the prototype have shown that they do not follow explicitly from the prior art. The prior art also did not reveal the popularity of the influence provided by the essential features of the claimed invention transformations to achieve the specified technical result. Therefore, the claimed invention meets the condition of patentability "inventive step".

The claimed device is illustrated by diagrams:
FIG. 1 is a functional diagram of a radio transmitter reservation device;
figure 2 - diagram of the control unit;
FIG. 3 is a diagram of an information signal delay line.

 The backup device of the radio transmitter (see Fig. 1) consists of the first driver 1, the power supply 2 of the first driver, the first 3 and second 4 power amplifiers, antenna 5, antenna switch 6, ballast load 7, control unit 8, power supplies 9 and 10 respectively, of the first and second power amplifiers, power switches 11 and 12, respectively, of the first and second power amplifiers, current monitoring sensors 13 and 14, respectively, of the first and second power amplifiers, state analyzers 15 and 16, respectively, the first and second power amplifiers, the second driver 17, the power supply 18 of the second driver, the power switches 19 and 20, respectively, the first and second drivers, current monitoring sensors 21 and 22, respectively, the first and second drivers, state analyzers 23 and 24, respectively, of the first and second drivers, the information splitter signal 25, delay line information signal 26, input 27 and output 29 delay switches information signal of the first path, input 28 and output 30 delay switches inform signal of the second path. The outputs of power amplifiers 3 and 4 are connected to the corresponding inputs of the antenna switch 6, one of the outputs of which is connected to the antenna 5 and the other to a ballast load 7. The information input of the radio transmitter reservation device is connected to the input of the splitter of the information signal 25, and the input of clock pulses to the clock the input of the delay line of the information signal 26. The outputs of the splitter of the information signal 25 are connected to the information inputs of the corresponding input switches 27 and 28 of the delay information signal. The first output of the input switch 27 is connected to the first input of the output switch 29 of the first path, and the first output of the input switch 28 is connected to the first input of the output switch 30 of the second path. The second outputs of the input delay switches of the information signal 27 and 28 are connected to the information input of the delay line of the information signal 26, the output of which is connected to the second inputs of the output delay switches of the information signal 29 and 30. The control inputs of the input 27 and output 29 of the delay switches of the information signal are combined and connected to the third control output of the control unit 8, the fourth control output of which is connected to the control inputs of the input 28 and output 30 delay switches nformatsionnogo second signal path. The output of the output delay switch of the information signal 29 is connected to the input of the pathogen 1 of the first path, and the output of the switch 30 is connected to the input of the pathogen 17 of the second path. The output of the pathogen 1 is connected to the input of the power amplifier 3 of the first path and to the input of its state analyzer 23, the output of which is connected to the sixth information input of the control unit 8. The output of the pathogen 17 is connected to the input of the power amplifier 4 of the second path and the input of its state analyzer 24, output which is connected to the eighth information input of the control unit 8. The output of the power amplifier 3 of the first path is connected to the first input of the antenna switch 6 and to the input of its state analyzer 15, the output of which is connected the second information input of the control unit 8. The output of the power amplifier 4 of the second path is connected to the second input of the antenna switch 6 and to the input of its state analyzer 16, the output of which is connected to the fourth information input of the control unit 8. The first output of the antenna switch 6 is connected to the antenna 5, and the second - with a ballast load 7. The output of the power supply unit 2 of the pathogen of the first path through the power switch 19 and the current control sensor 21 is connected to the power input of the pathogen 1. The output of the current control sensor 21 will excite For the first path, it is connected to the fifth information input of the control unit 8. The output of the power supply unit 18 of the exciter of the second path through the power switch 20 and the current monitoring sensor 22 is connected to the power input of the exciter 17. The output of the current sensor 22 of the exciter of the second path is connected to the seventh information input of the control unit 8. The output of the power supply unit 9 of the power amplifier of the first path through the power switch 11 and the current monitoring sensor 13 is connected to the power input of the power amplifier 3. The output of the current monitoring sensor 13 of the amplifier The first path is connected to the first information input of the control unit 8. The output of the power supply unit 10 of the power amplifier of the second path through the power switch 12 and the current monitoring sensor 14 is connected to the power input of the power amplifier 4. The output of the current control sensor 14 is connected to the third information input of the control unit 8 The first control output of the control unit 8 is connected to the control inputs of the power switches 19 and 11 and the antenna switch 6. The second control output of the control unit 8 is connected to the control inputs of lyuchateley supply 20 and 12.

 The control unit 8 (see FIG. 2) contains four elements OR-NOT 31.1, 31.2, 31.3 and 31.4, five elements AND 32.1, 32.2, 32.3, 32.4 and 32.5, two elements OR 33.1 and 33.2, two elements NOT 34.1 and 34.2 , manual switch 35, six managed switches 36.1, 36.2, 36.3, 36.4, 36.5 and 36.6, two capacitors 37.1 and 37.2, four resistors 38.1, 38.2, 38.3 and 38.4 and a constant voltage source 39. The inputs of the OR-NOT 31.1 element are connected to the fifth and sixth information inputs of the control unit 8. The inputs of the OR-NOT 31.2 element are connected to the seventh and eighth information inputs of the control unit 8. The inputs of the OR-NOT 31.3 element connected to the first and second information inputs of the control unit 8. The inputs of the OR-NOT 31.4 element are connected to the third and fourth information inputs of the control unit 8. The outputs of the OR-NOT 31.1 and 31.3 elements are connected to the inputs of the And 32.1 element. The outputs of the elements OR NOT 31.2 and 31.4 are connected to the inputs of the element AND 32.2. The output of the first AND 32.1 element is connected to the first input of the first OR 33.1 element and the output of the second And 32.2 element to the first input of the second OR 33.2 element. One of the terminals of the DC voltage source 39 is connected to the input of the manual switch 35, and the other is grounded. The input of the manual switch 35 is connected to the inputs of the first four controllable switches 36.1, 36.2, 36.3 and 36.4. The outputs of the first two managed switches 36.1 and 36.2 are combined and connected to the first input of the third OR element 32.3, as well as to the first output of the first capacitor 37.1 and to the first output of the second resistor 38.2, the second output of which is grounded. The second terminal of the first capacitor 37.1 is connected to the second input of the first OR 33.1 element and to the first terminal of the first resistor 38.1, the second terminal of which is grounded. The output of the first element OR 33.1 is connected to the second input of the third element And 32.3, the output of which is connected to the first control output of the control unit 8 and to the input of the first element NOT 34.1. The outputs of the third and fourth controlled switches 36.3 and 36.4 are combined and connected to the first input of the fourth element And 32.4, as well as to the first output of the second capacitor 37.2 and to the first output of the fourth resistor 38.4, the second output of which is grounded. The second terminal of the second capacitor 37.2 is connected to the second input of the second OR element 33.2 and to the first terminal of the third resistor 38.3, the second terminal of which is grounded. The output of the second element OR 33.2 is connected to the second input of the fourth element And 32.4, the output of which is connected to the second control output of the control unit 8 and to the input of the second element NOT 34.2. The first output of the manual switch 35 is connected to the third control output of the control unit 8 and to the control inputs of the first and fifth controlled switches 36.1 and 36.5. The second output of the manual switch 35 is connected to the fourth control output of the control unit 8 and to the control inputs of the third and sixth controlled switches 36.3 and 36.6. The output of the first element NOT 34.1 is connected to the first input of the fifth element And 32.5 and to the input of the fifth controlled switch 36.5, the output of which is connected to the control input of the fourth managed switch 36.4. The output of the second element NOT 34.2 is connected to the second input of the fifth element And 32.5 and to the input of the sixth controlled switch 36.6, the output of which is connected to the control input of the second managed switch 36.2. The output of the fifth element And 32.5 is the output of the signal "ALARM".

может быть использована, например, микросхема К531ИР18 (см. В.Л.Шило. Популярные цифровые микросхемы. - Челябинск: "Металлургия", 1989, рис. 1.86.а, стр.120), либо регистр на универсальных J-K-триггерах (см. В.В.Гусев, К.В.Конев, Л.Г.Зеличенко и др. Основы импульсной и цифровой техники. - М.: Сов.радио, 1975, рис.14.33, стр. 389).The used elements AND, OR, NOT, OR-NOT are known and described, for example, in the book by G. I. Gorbachev and E. E. Chaplygin "Industrial Electronics" on pages 135-138. As a manual switch 35, for example, a PGK-ZPZN biscuit switch (see "Reference for Developers and Constructors of CEA. Element Base", authors: Maslennikov M.Yu., Sobolev EA, Sokolov G.V. and Moscow, ITAR-TASS, 1993, p. 31), in which contact 1 is used as the input of the manual switch, contact 2 as the first output (incl. 1tr), contact 2 as the second output (incl. 2tr) 4, as an unused output (off) - contact 3, which is advisable to isolate. As controlled switches 36.1 - 36.6, small-sized direct-current electromagnetic relays can be used (see R. M. Tereshchuk, K. M. Tereshchuk, S. A. Sedov. Semiconductor receiving and amplifying devices. Radio amateur manual, Kiev, "Naumova Dumka"", 1982, pp. 77-85). The delay line of the information signal 26 (see Fig. 3) contains N shift registers 26.1 - 26.N, the clock inputs of which are connected in parallel, the information input of the first shift register 26.1 is the information input of the delay line 26, the information output of each previous shift register 26.k . connected to the information input of the subsequent register 26. (k + 1), the information output of the last (Nth) shift register 26.N is the information output of the delay line 26, the power inputs of the shift registers are connected in parallel and connected to the power input of the delay line (+ U _n ). As a shift register 26.k

can be used, for example, the K531IR18 microcircuit (see V.L.Shilo. Popular digital microcircuits. - Chelyabinsk: Metallurgy, 1989, Fig. 1.86.a, p.120), or the register on universal JK triggers (see V.V.Gusev, K.V. Konev, L.G. Zelichenko and other Fundamentals of pulsed and digital technology.- M .: Sov.radio, 1975, fig. 14.33, p. 389).

 As a splitter of the information signal 25, a two-channel power divider based on a six-terminal device can be used (see Radio transmitting devices / M.V. Balakirev, Yu.S. Vokhmyakov, A.V. Zhurikov et al .; Edited by O.A. Chelnokov . - M.: Radio and Communications, 1982, p. 110, Fig. 5.2.zh), or a splitter of video and audio signals (see the article by I. Nechaev "Splitter of video and audio signals." Radio, 1999, No. 1 , p.13, fig. 1), in which it is necessary to use two outputs, for example, “Video output 1” and “Video output 2”, or an electronic multiplier of telegraph signals (see A.S. Adge mov, A.I. Koblents, V. N. Gordienko, Multichannel telecommunications and channel-forming telegraph equipment. - M.: Radio and Communications, 1989, p. 340, 341, Fig. 14.5), using two outputs in it.

 The functions of the state analyzers of pathogens and power amplifiers 23,24,15,16 can be implemented on a magnetoelectric sensor (see Rosenblatt MA Magnetic elements of automation and computer technology. - M.: Nauka, 1974, Magnetic semiconductor sensors for tolerance control of increased sensitivity in collection “Magnetic semiconductor elements for information processing.” - M .: Nauka, 1978, pp. 45-55) or on integrated circuits of the 521 series (see Semiconductor sensors IC 521 series comparators). As sensors for current control can be applied semiconductor sensors of tolerance control of increased sensitivity (see. Collection "Magnetic semiconductor elements for information processing." - M .: Nauka, 1978, pp. 45-55).

 Relays can be used as power supply switches for exciters and power amplifiers 11, 12, 19, 20 (see. "Directory of the developer and designer of REA. Elemental base" / Maslennikov M.Yu., Sobolev EA, Sokolov G.V. et al. - M.: ITAR-TASS, 1993, p. 36, 37).

 As the antenna switch 6, a non-contact antenna switch described in the prototype can be used (see Pat. RF N 2099872, Bull. N 35 from 12.20.1997).

Purpose of input elements:
- the second pathogen 17 - for the formation of a radio signal in the second radio path;
- power supply 18 of the second pathogen - to provide power to the second pathogen;
- a power switch 19 of the first pathogen and 20 of the second pathogen - to turn on the power of the used (working) pathogen and turn off the power of the unused (backup) pathogen;
- current monitoring sensors 21 and 22 - for checking the functioning of the first and second pathogens by short circuit;
- analyzers of the state of pathogens 23 and 24 - to check the functioning of pathogens on the cliffs;
- splitter information signal 25 - to separate the information signal between the first and second radio paths;
- delay line of the information signal 26 - to delay the information signal supplied to the input of the pathogen backup radio path;
- switches 27, 29 and 28, 30 - to enable (switch) the delay line of the information signal 26 in the path (first or second), which is a backup.

 The device operates as follows.

 Any path (first or second) can be both working and backup. The selection of the working path (the backup will be different) is carried out using the manual switch 35 of the control unit 8. In the position of the switch 35 "Exit 1" ("On 1tr"), the power supply to the exciter and power amplifier of the first path and the antenna are connected to it, in this case, the first path is working, the second is backup. In the "Out.2" position ("On 2tr") - provides power to the pathogen and power amplifier of the second path, while the second path is working, and the first is backup. When the switch 35 is set to the middle position (Off), power to the exciters and power amplifiers of both paths is not supplied, the transmitter is turned off.

 Suppose that initially the first was chosen as the working radio path, and the second as the backup. To do this, switch 35 is set to "Exit 1" ("On 1 Tr."). In this case, the constant voltage from the voltage source 39 through the closed contacts "In." and “Output 1” of switch 35 is supplied to the third control output (“Output 3”) of control unit 8 and further to the control inputs of switches 27 and 29, which connect the first output (“Output 1”) of the information signal splitter 25 to the input pathogen 1 of the first path along the chain: Out. 1 splitter of the information signal 25, the signal input of the switch 27, the first output (Output 1) of the switch 27, the first input (Input 1) of the switch 29, the output of the switch 29, the input of the exciter 1. Since the fourth control output (Output 4) of the block control 8 voltage from the voltage source 39 is not supplied, at the control inputs of the switches 28 and 30 it is absent. In this case, the information signal from the OUTPUT. 2 splitters 25 through closed contacts "In." and "Exit 2" of the switch 28, the delay line 26, the closed contacts "In 2" and "Exit." of the switch 30 is fed to the input of the pathogen 17 of the second path. Thus, due to the corresponding connection of the contacts of the switches 27, 29 and 28, 30, the information signal is fed to the input of the pathogen 1 of the first path (which is selected as the working one) without delay, and to the input of the pathogen 17 of the second path (which in this case is the backup one) with delayed.

 In addition, the constant voltage from "Out.1" of the manual switch 35 of the control unit 8 is supplied to the control inputs of the switches 36.1 and 36.5, as a result of which the contacts of these switches are closed. Through the closed contacts of the switch 36.1, the voltage corresponding to the logical unit is supplied to the first input of the logical element And 32.3. The voltage surge that occurred when the switch 36.1 was turned on will cause the charge current of the capacitor 37.1 through the resistor 38.1. The voltage created by this current from the resistor 38.1 is supplied to the second input of the OR 33.1 logical element, as a result of which a voltage corresponding to the logical unit appears on its output, which will be supplied to the second input of the And 32.3 logical element. Since there are voltages corresponding to a logical unit at both inputs of the And 32.3 element, its output will have a voltage of a logical unit, which through the first control output (Output 1) of the control unit 8 will be supplied to the control inputs of the power switch 19 of the exciter of the first path, power switch 11 power amplifier of the first path and antenna switch 6. These switches provide power to the pathogen 1 and power amplifier 3 of the first path and connect the antenna 5 to the output of the amplifier m 3 generality, that is, to the first output (working) of the radio link.

 The digital information signal applied to the input of the pathogen 1 modulates the high-frequency signal in it, which is amplified in the power amplifier 3 and from its output through the antenna switch 6 enters the antenna 5 and is emitted by the antenna into space.

 In the case of a healthy state of the pathogen 1 and power amplifier 3, the outputs of the current monitoring sensors 21 and 13, as well as the outputs of the state analyzers 23 and 15, go to the information inputs Bx.5, Bx.6, Bx.1, and Bx.2 of the control unit 8 logical zero signals that are fed to the inputs of the elements OR NOT 31.1 and 31.3. The outputs of these elements will generate signals of a logical unit, which are fed to the inputs of the AND 32.1 element, from the output of which the signal of the logical unit will be fed to the first input of the OR element 33.1. The signal of the logical unit from the output of the OR element 33.1 is fed to the second input of the And 32.3 element, the first input of which is from the voltage source 39 through closed contacts Bx. - Out. 1 (On 1tr) of the manual switch 35, the closed contacts of the controlled switch 36.1 a voltage corresponding to a logical unit is applied. The output of the And 32.3 element will be the voltage of the logical unit, which is fed through the first control output (Output 1) of the control unit 8 to the control inputs of the power switches 19 and 11 of the exciter and amplifier of the first path, as well as to the control input of the antenna switch 6, ensuring the operation of the first tract and connecting an antenna to it.

 After a certain period of time, the capacitor 37.1 will be charged, the current in the charge circuit (capacitor 37.1, resistor 38.1) will stop, as a result of which the voltage at the second input of the OR 33.1 element will correspond to a logical zero. Since in the case of a healthy state of the first path there will be a voltage corresponding to a logical unit at the first input of the OR 33.1 logic element, a voltage corresponding to a logical unit will remain at its output, which ensures the operation of the first path.

 In this case, the pathogen 17 and the power amplifier 4 of the second path do not work, being in a redundant state, since they are not supplied with power. This is provided as follows. Firstly, the signal of the logical unit from the output of the AND 32.3 element is fed to the input of the element NOT 34.1, from the output of which the logical zero signal through the closed contacts of the switch 36.5 is fed to the control input of the switch 36.4, at which its contacts are open. Secondly, the contacts of the switch 36.3 are also open, since voltage from the voltage source 39 is not supplied to its control input.

 In the event of a failure of the first (working) path due to a "short circuit" or "open" at the output of the current monitoring sensor 21 or 13, or of the analyzer 23 or 15, or the outputs of several of the indicated blocks of the first (working) path, a logical unit signal will appear. In this case, at the output of the OR-NOT 31.1 element, either at the output of the OR-NOT 31.3 element, or at the outputs of both elements 31.1 and 31.3, a logical zero signal will appear. In any of these cases, a logical zero signal will appear at the output of AND 32.1, which will go to the first input of OR 33.1. Since a logical zero signal is present at the second input of the OR 33.1 element (voltage is zero), a voltage (signal) corresponding to a logical zero will appear at the output of the OR 33.1 element, which will be fed to the second input of the And 32.3 element, resulting in its output a logic zero signal will be generated. This signal through the first control output (Output 1) of the control unit 8 will go to the control inputs of the power switches 19, 11 of the pathogen and the power amplifier of the first path, as well as to the control input of the antenna switch 6, as a result of which the power from the pathogen 1 and the amplifier will be disconnected power 3 of the first path, and the antenna switch 6 will connect the antenna 5 to the output of the power amplifier 4, that is, to the output of the second path, which was as a backup.

 At the same time, the logical zero signal from the output of the AND 32.3 element is fed to the input of the HE 34.1 element, the output of which is the logical unit signal, which, through the closed contacts of the managed switch 36.5, is fed to the control input of the switch 36.4, closing its contacts. The voltage from the source 39 of the control unit 8 through the closed contacts of the switch 36.4 is supplied to the first input of the element And 32.4 and ensures the flow of the charge current of the capacitor 37.2 through the resistor 38.3. The voltage created by this current on the resistor 38.3, corresponding to a logical unit, is supplied to the second input of the OR element 33.2, creating a signal of the logical unit at its output, which is fed to the second input of the AND element 32.4. Since there are voltages (signals) corresponding to a logical unit at both inputs of the And 32.4 element, a signal of a logical unit will be generated at its output, which through the second control output (Output 2) of control unit 8 will go to the control inputs of switches 20 and 12, providing connecting power to the pathogen 17 and power amplifier 4 of the second path.

 Digital information signal from the second output (Output 2) of the splitter 25 through closed contacts "In." and “Out.2” of switch 28, delay line 26, closed contacts “In.2” and “Out.” the switch 30 is fed to the input of the pathogen 17 of the second path. Since the input signal of the exciter 17 of the second path receives an information signal delayed relative to the information signal supplied to the input of the exciter 1 of the first path, there is no loss of information when the transmitter switches from the first (working) to the second (backup) path, provided that the delay time provided by the delay line of the information signal 26 is slightly longer than the time required to switch the transmitter from the first path to the second. To ensure the push-pull promotion of the digital information signal in the delay line 26, a sequence of clock pulses is received from the clock input of the backup device (connected to the clock output of the information source) to its clock input.

 The delayed information signal received at the input of the pathogen 17, modulates the high-frequency oscillations in it. These oscillations, amplified in the power amplifier 4, through the antenna switch 6 enters the antenna 5.

 In the event of a failure of the second path with a faulty first path, the power must be disconnected from the pathogen 17 and the power amplifier 4 of the second path and the power supply to the pathogen 1 and power amplifier 3 of the faulty first path must be prohibited.

 It is carried out as follows.

 Suppose that initially the first path was turned on as the worker, that is, the switch 35 of the control unit 8 is set to the Exit position. 1 (On 1tr.). As shown above, when the first path fails, a logical zero signal from the output of the And 32.3 element turns off the power from the pathogen 1 and the power amplifier 3 of the first path. If the second path fails, the logical zero signal will be generated at the output of the And 32.4 element, which will turn off the power from the pathogen 17 and the power amplifier 4 of the second path. In this case, the signal of the logical unit from the output of the element NOT 34.2 will go to the input of the controlled switch 36.6, at the control input of which, due to open contacts "Input." and “Out.2” (On 2tr.) of switch 35, there will be zero voltage. Therefore, the contacts of the switch 36.6 will be open, and the signal of the logical unit from the output of the element NOT 34.2 will not go to the control input of the managed switch 36.2 and its contacts will remain open. The contacts of the switch 36.1 are closed, and the voltage corresponding to the logical unit from the voltage source 39 is supplied to the first input of the And 32.3 element. At the second input of the AND 32.3 element there will be a voltage corresponding to a logical zero, since there are voltages corresponding to a logical zero at both inputs of the OR 33.1 element. To turn on the (faulty) first path when the second path fails, it would be necessary to open the contacts of the switch 36.1 for a while, allow the capacitor 37.1 to discharge through the resistor 38.2, and then close the contacts of the switch 36.2, ensuring the flow of the charge current of the capacitor 37.1 through the resistor 38.1, what is necessary for the voltage corresponding to a logical unit to appear on the second input of the OR 33.1 element. Since this does not happen, the power to the faulty first path of the transmitter will not turn on when the second path fails. Power will be disconnected from both paths.

 The signals of a logical unit from the outputs of the elements NOT 34.1 and 34.2, submitted to the element And 32.5, will cause the formation of the signal "EMERGENCY" at its output.

 To turn off (power) the radio transmitter, switch 35 must be set to the off position.

 Evaluation of the effect obtained from the claimed device in comparison with the prototype will spend on three indicators: reliability, energy loss and loss of information when switching paths.

1. We denote by P _in - the probability of a healthy state of the pathogen and by P _mind - the probability of a healthy state of the power amplifier. We consider the events of the failure of the pathogens and power amplifiers independent. Probability of good condition of the prototype transmitter
P _{fix prot.} = P _in [1- (1-P _d . ₁ ) (1-P _d . ₂ )].

The probability of good condition of the claimed device
P _{fix declared} = 1- (1-P _in1 • P _mind1 ) (1-P _in2 • P _mind2 ).

Suppose, for example, P _in = P _c2 = P _c1 = P = P _{UM1 um2} = 0.8.

Then
P _{fix prot.} = 0.8 [1- (1-0.8) (1-0.8)] = 0.766,
P _{fix declared} = 1- (1-0.8 • 0.8) (1-0.8 • 0.8) = 0.87.

 Thus, the reliability of the claimed device is higher than the reliability of the prototype device.

 In addition, due to the possibility of alternately including as the worker either the first or the second path, the MTBF of each of them doubles.

 2. Due to the fact that the outputs of the power amplifiers in the claimed device are connected directly to the inputs of the antenna switch, and not through the delay lines, as in the prototype, the energy costs of the claimed device are significantly lower compared to the prototype. In addition, in the prototype, the power of the high-frequency signal of the backup path is wasted on a ballast load, in the claimed device the backup path is turned off and therefore does not consume energy (power) at all.

 3. The inclusion of one delay line of the information signal in the composition of the claimed device with its switching each time to the backup path ensures that there is no loss of information when the transmitter is switched from a working radio path to a backup one. In the prototype, due to the presence of non-switchable delay lines in both paths, such losses are unavoidable due to the same signal delay in both paths, and therefore the absence of relative delay.

Claims (2)

 1. A radio transmitter backup device containing an exciter with its own power supply, first and second power amplifiers, state analyzers of the first and second power amplifiers, antenna switch, antenna, ballast load, control unit, power amplifier power supplies, power amplifier power switches, control sensors current of power amplifiers, one of the outputs of the antenna switch connected to the antenna, and the other with a ballast load, the inputs of the state analyzers of power amplifiers are connected with the outputs of the respective power amplifiers, and the outputs are with the corresponding information inputs of the control unit, the other information inputs of which are connected to the information outputs of the current control sensors of the respective power amplifiers, the input of the current control sensor of each of the power amplifiers is connected to the output of the corresponding power switch, and the output is with the power input of its power amplifier, the input of each power switch is connected to the output of the corresponding power supply, the control input p The power switch of the first power amplifier is connected to the control input of the antenna switch and the first control output of the control unit, the second control output of which is connected to the control input of the power switch of the second power amplifier, characterized in that a second exciter with a power supply, power switches of the first and second pathogens, state analyzers of the first and second pathogens, current monitoring sensors of the first and second pathogens, information splitter signal, the delay line of the information signal, the delay switches of the information signal, while the outputs of the power amplifiers are connected to the corresponding inputs of the antenna switch, the information input of the backup device of the radio transmitter is connected to the input of the splitter of the information signal, and the input of clock pulses to the clock input of the delay line, the outputs of the splitter information signal connected to the information inputs of the corresponding input delay switches information signal a, the first output of each of which is connected to the first input of the corresponding output delay switch of the information signal, and the second output of each of the input delay switches of the information signal is connected to the information input of the delay line, the output of which is connected to the second inputs of the output switches of the delay of the information signal, input control inputs and the output delay switches of the first path are combined and connected to the third control output of the control unit, the fourth control the first output of which is connected to the control inputs of the input and output delay switches of the information signal of the second path, the output of each of the output delay switches of the information signal is connected to the input of the exciter of the corresponding path, the output of each exciter is connected to the input of the power amplifier of its path, and also to the input of its state analyzer , the output of each of which is connected to the corresponding information input of the control unit, the output of the power supply unit of each pathogen is connected through therefore, the connected power switch and a current control sensor with a power input of its pathogen, the outputs of the current control sensors of the pathogens are connected to the corresponding information inputs of the control unit, the control input of the power path of the first path exciter is connected to the control input of the power switch of the power amplifier of the first path, as well as with the control input the antenna switch and the first control output of the control unit, the control input of the second exciter power switch rakta connected to the power switch control input of the power amplifier of the same path and the second control output of the control unit.  2. The device according to claim 1, characterized in that the control unit contains four OR-NOT elements, five AND elements, two OR elements, two NOT elements, a manual switch, six controllable switches, two capacitors, four resistors and a constant voltage source, the inputs of the OR elements are NOT the corresponding information inputs of the control unit, the outputs of the first and third elements OR are NOT connected to the inputs of the first element AND, and the outputs of the second and fourth elements OR are NOT connected to the inputs of the second element AND, the outputs of the first o and the second AND elements are connected to the first inputs of the first and second OR elements, respectively, one of the terminals of the DC voltage source is connected to the input of the manual switch, and the other is grounded, the input of the manual switch is connected to the inputs of the first four controlled switches, the outputs of the first two controlled switches are combined and connected to the first input of the third element And, as well as to the first output of the first capacitor and to the first output of the second resistor, the second output of which is grounded, the second output of the first the first capacitor is connected to the second input of the first OR element and to the first output of the first resistor, the second output of which is grounded, the output of the first OR element is connected to the second input of the third AND element, the output of which is connected to the first control output of the control unit and the input of the first element NOT, the outputs of the third and the fourth controllable switches are combined and connected to the first input of the fourth element And, as well as to the first output of the second capacitor and the first output of the fourth resistor, the second output of which is grounded, the second terminal of the second capacitor is connected to the second input of the second OR element and the first terminal of the third resistor, the second terminal of which is grounded, the output of the second OR element is connected to the second input of the fourth AND element, the output of which is connected to the second control output of the control unit and to the input of the second element NOT, the first output of the manual switch is connected to the third control output of the control unit and the control inputs of the first and fifth controlled switches, the second output of the manual switch is connected to the fourth the control output of the control unit and the control inputs of the third and sixth controlled switches, the output of the first element is NOT connected to the first input of the fifth element AND and the input of the fifth controlled switch, the output of which is connected to the control input of the fourth controlled switch, the output of the second element is NOT connected to the second input of the fifth element And and the input of the sixth controllable switch, the output of which is connected to the control input of the second controllable switch, the output of the fifth element And is the output Signal "EMERGENCY".

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