RU2253945C1 - Radio transmitter reservation device - Google Patents

Abstract

FIELD: radio communications.

SUBSTANCE: device has information signal router, second and first activators, first and second power amplifiers, first and second activators feeding blocks, first and second main power blocks of power amplifiers, additional power block, first and second activators current control sensors, first and second power amplifiers current control sensors, first and second activators state analyzers, first and second power amplifiers current control sensors, antenna switch, antenna, reservation control block, first and second circulators at activators outputs, first and second circulators at inputs of power amplifiers, first and second activators switches, first and second power amplifiers inputs switches.

EFFECT: higher reliability, higher speed of operation, higher efficiency.

3 cl, 3 dwg

Description

The invention relates to techniques for radio communications and is intended for use in radio transmitting devices of high reliability. The claimed device extends the arsenal of funds for this purpose.

A radio transmitter backup device is known, comprising two pathogens, two amplifiers, two antenna switches and an antenna switch control unit. In the device, the signal is fed to both transmitters, one of which is the main (working), and the second is the backup. From the output of the main transmitter, the signal through the circulators and the antenna switch is fed to the antenna, and from the backup output through the circulators to the ballast load. When the main transmitter fails, its output is disconnected from the antenna, and a backup transmitter is connected to it. Due to this, the reliability is high (Patent No. 1209821, Japan MKI N 04 V 1/74, dated 23.08.1989).

The disadvantage of this device is its low efficiency due to useless losses in the ballast load.

A radio transmitter backup device is known, comprising 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 monitoring sensors in the power circuits power amplifiers, state analyzers of power amplifiers and a control unit that generates control commands for switching power amplifiers from the main go to standby and connect the antenna to a working amplifier (RF Patent №2099872 IPC H 04 B 1/74, H 05 K 10/00, from 20.12.1997, the).

The disadvantages of this device are large power losses in the high-frequency path 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 uselessly lost in the ballast load and, secondly, additional losses are introduced by delay lines in the form of “segments” of the coaxial cable introduced into high-frequency paths between the outputs of power amplifiers and the antenna (or ballast) load.

The reliability of the device is not high enough due to the presence of one exciter in it, since the radio transmitter with both amplifiers operational, but with a faulty exciter is inoperative.

This device is applicable only for the transmission of digital signals and cannot be used for the transmission of analog signals.

The closest in number of similar features and the achieved technical result is the device (RF Patent No. 2168271, IPC Н 04 В 1/04, 17/00, dated 05.27.03).

The known device consists of a first driver, a power supply of the first driver, the first and second power amplifiers, an antenna, an antenna switch, a ballast load, a control unit, power supplies, respectively, the first and second power amplifiers, current monitoring sensors, respectively, the first and second power amplifiers, state analyzers first and second power amplifiers, second driver, power switches of the first and second drivers, current monitoring sensors of the first and second driver d, analyzers of the state of the first and second pathogens, the splitter of the information signal, the delay line of the information signal, the input and output delay switches of the information signal of the first path, the input and output delay switches of the information signal of the second path. The outputs of the first and second power amplifiers are connected to the corresponding inputs of the antenna switch, one of the outputs of which is connected to the antenna, and the other to the ballast load. 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 of the information signal. 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 the input switch of the first path is connected to the first output of the output switch of the first path, and the first output of the input switch of the second path with the first input of the output switch of the second path. The second outputs of the input delay switches of the information signal are connected to the information input of the delay line of the information signal, the output of which is connected to the second inputs of the output switches of the delay of the information signal. The control inputs of the input and output delay switches of the information signal of the first path are interconnected with 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 the output delay switch of the information signal of the first path is connected to the input of the first pathogen, and the output of the output delay switch of the information signal of the second path with the input of the second pathogen. The output of the first driver is connected to the input of the power amplifier of the first path and to the input of its state analyzer, the output of which is connected to the sixth information input of the control unit. The output of the second driver is connected to the input of the power amplifier of the second path and to the input of its state analyzer, the output of which is connected to the eighth information input of the control unit. The output of the power amplifier of the first path is connected to the first input of the antenna switch and the input of its state analyzer, the output of which is connected to the second information input of the control unit. The output of the power amplifier of the second path is connected to the second input of the antenna switch and to the input of its state analyzer, the output of which is connected to the fourth information input of the control unit. The first output of the antenna switch is connected to the antenna, and the second to the ballast load. The output of the power supply of the first pathogen through the power switch of the first pathogen and the current sensor of the first pathogen is connected to the power input of the first pathogen. The output of the current path sensor of the first path is connected to the fifth information input of the control unit. The output of the second path exciter power supply through the second path exciter power switch and the second path exciter current control sensor is connected to the supply of the second path exciter. The output of the current path sensor of the second path is connected to the seventh information input of the control unit. The output of the power supply unit of the power amplifier of the first path through the power switch of the power amplifier of the first path and the current monitoring sensor is connected to the power input of the power amplifier of the first path. The output of the current sensor of the power amplifier of the first path is connected to the first information input of the control unit. The output of the power supply unit of the power amplifier of the second path through the power switch of the power amplifier of the second path and the current monitoring sensor is connected to the power input of the power amplifier of the second path. The output of the current sensor of the power amplifier of the second path is connected to the third information input of the control unit. The first control output of the control unit is connected to the control inputs of the power supply switches of the pathogen and the power amplifier of the first path. The second control output of the control unit is connected to the control inputs of the power switch of the pathogen and the amplifier of the second path.

In the event of a failure of the main transmission path, the backup control unit disconnects it from the antenna, turns off the power of the pathogen and the power amplifier of the main path, connects the antenna to the backup path, turns on the power of the pathogen and power amplifier of the backup path, supplies an information signal through the delay line connected at the input of the backup radio path . Reservation is carried out while reducing energy losses.

However, the prototype device has disadvantages.

This device is applicable only for the transmission of digital signals and cannot be used for transmission of analog signals due to the use of a digital information signal delay line in the device.

Relatively low reliability, due to the inability to switch pathogens and power amplifiers, in the event of failure of the pathogen of the main path and the backup power amplifier (or vice versa).

In the event of an accident, information may be lost due to the excess of the readiness time for the backup path to work over the delay time of the information signal.

The aim of the invention is to develop a device suitable for transmitting both analog and digital information, providing redundancy while increasing reliability and lowering the readiness for work when any pathogen or amplifier fails, by maintaining new connections and additional blocks.

To achieve a technical result, in the known backup device containing the splitter of the information signal, the first and second exciters, the information inputs of which are connected respectively to the first and second outputs of the splitter of the information signal, the first and second power supplies of the pathogens, the first and second controlled switches of the power supply of the pathogens, the first and second sensors for monitoring the current of pathogens, the inputs of which are connected to the outputs of the first and second controlled switches, respectively pathogens power supplies, the first outputs of the first and second pathogen current sensors are connected to the supply inputs of the first and second pathogens, the first and second pathogen condition analyzers, the inputs of which are connected to the outputs of the first and second pathogens, the first and second power amplifiers, the first and the second main power supply units for power amplifiers, the first and second controlled switches of the main power supply units for power amplifiers, the first and second sensors for monitoring current amplifiers power amplifiers, the inputs of which are connected to the outputs of the first and second controlled switches of the main power supply units of the power amplifiers, and their outputs are connected to the power inputs of the first and second power amplifiers, respectively, the first and second state analyzers of power amplifiers, the inputs of which are connected to the outputs of the first and a second power amplifier, an antenna switch, the first and second inputs of which are connected to the outputs of the first and second power amplifiers, respectively connected to the first output of the antenna switch, the first ballast load connected to the second output of the antenna switch, the backup control unit, the first and fourth control outputs of which are connected respectively to the control inputs of the first and second controlled switches of the power supply of the exciters, the seventh control output of the backup control unit connected to the control inputs of the first and second controlled switches of the main power supply units of power amplifiers, the eighth control the output of the backup control unit is connected to the third input of the antenna switch control, the first and third information inputs of the backup control unit are connected to the second outputs of the first and second sensors for monitoring the current of pathogens, and the second and fourth information inputs of the backup control unit are connected to the outputs of the first and second pathogen condition analyzers, the fifth and seventh information inputs of the backup control unit are connected to the second the outputs of the first and second sensors for monitoring the current of the power amplifiers, respectively, and the sixth and eighth information inputs of the redundancy control unit are connected to the outputs of the first and second state analyzers of the power amplifiers, the first and second manual power switches of the exciters, the first and second manual power switches of the power amplifiers are additionally introduced , the first and second circulators at the outputs of the pathogens, the second, third, fourth and fifth ballast loads, the first and second circulatory ry at the inputs of power amplifiers, the first and second switches of exciters, the first and second switches of inputs of power amplifiers, a radio signal splitter, the first and second controlled switches of the main power supply units of power amplifiers, the first and second controlled switches of the additional power supply unit of power amplifiers, the first and second capacitors power amplifier power circuits, optional power supply.

The information input of the backup device of the radio transmitter is connected to the input of the splitter of the information signal. The outputs of the splitter of the information signal are connected to the inputs of the first and second pathogens, the outputs of which are connected to the inputs of the first and second analyzers of the state of the pathogens, as well as the inputs of the first and second circulators at the outputs of the pathogens. The first outputs of the first and second circulators at the outputs of the pathogens are connected to the inputs of the second and third ballast loads. The second outputs of the first and second circulators at the output of the pathogen are connected to the inputs of the first and second switches of the pathogens, respectively, the outputs of the first and second switches of the pathogens are connected to each other and to the input of the radio signal splitter. The outputs of the radio signal splitter are connected to the inputs of the first and second circulators at the inputs of the power amplifiers, the first outputs of the first and second circulators at the input of the power amplifier are connected to the input of the fourth and fifth ballast loads, respectively, the second outputs of the first and second circulators at the inputs of the power amplifiers and second power amplifier input selectors. The outputs of the first and second switch inputs of the amplifiers are connected respectively to the inputs of the first and second power amplifiers. The output of the first power amplifier is connected to the first input of the antenna switch, as well as to the input of the first analyzer of the state of the power amplifier. The output of the second power amplifier is connected to the second input of the antenna switch and to the input of the second analyzer of the state of the power amplifier. The first output of the antenna switch is connected to the input of the antenna, and the second to the input of the first ballast load. The outputs of the first and second pathogen power supplies are connected in series through the respective first and second manual power switches, the corresponding first and second controllable switches of the pathogen power supplies, the respective first and second pathogen current sensors with the power inputs of the first and second pathogens. The second output of the first sensor for monitoring the current of the pathogen is connected to the first information input of the backup control unit. The second output of the second sensor for monitoring the current of the pathogen is connected to the third information input of the backup control unit. The output of the first main power supply of the power amplifier, providing operation in half power mode, is connected in series through the first manual power switch of the power amplifier, the first controllable switch of the main power supply with the input of the first sensor for monitoring the current of the power amplifier. Also, an additional power supply unit is connected to the input of the first current control sensor through the first controlled switch of the additional power supply unit, which ensures that the power amplifier operates at full power. The first output of the first sensor of the current control of the power amplifier is connected to the power input of the first power amplifier and to the first contact of the first capacitor, the second contact of the first capacitor is grounded. The output of the second main power amplifier power supply unit, which provides half power operation, is connected through a second manual power amplifier power switch, the second controlled switch of the main power amplifier power supply is connected to the input of the second current sensor of the power amplifier, to the input of the second amplifier current control sensor power is also connected through a second controlled switch of an additional power supply unit of amplifiers the output of an additional power supply unit I, providing the second amplifier at full power. The first output of the second sensor of the current control of the power amplifier is connected to the supply input of the second power amplifier, as well as to the first contact of the second capacitor, the second contact of the second capacitor is grounded. The second outputs of the first and second sensors for monitoring the current of the power amplifiers are connected respectively to the fifth and seventh information inputs of the redundancy control unit. The outputs of the first and second state analyzers of the power amplifiers are connected respectively to the sixth and eighth information inputs of the redundancy control unit. The control input of the first exciter switch is connected to the second control output of the redundancy control unit. The control input of the second exciter switch is connected to the third control output of the redundancy control unit. The control input of the first input switch of the power amplifier is connected to the sixth control output of the redundancy control unit. The control input of the second input switch of the power amplifier is connected to the ninth control output of the redundancy control unit. The control input of the first controllable switch of the additional power amplifier power supply unit is connected to the fifth input of the antenna switch and to the eleventh control output of the redundancy control unit. The control input of the second managed switch of the additional power amplifier power supply in full power mode is connected to the fourth input of the antenna switch and to the tenth control output of the redundancy control unit. The fifth control output of the backup control unit is the output of the "Failure of pathogens" signal. The twelfth control output of the redundancy control unit is the output of the “Power Amplifier Failure” signal.

The backup control unit includes the first, second, third, fourth elements OR, the first, second, third, fourth, fifth, sixth, seventh, eighth elements And, the first, second, third, fourth, fifth, sixth, seventh, eighth , ninth, tenth, eleventh elements AND NOT. The output of the third AND-NOT element is connected to the first inputs of the first and seventh AND elements, as well as to the first and second inputs of the ninth AND-NOT element. The output of the fourth AND-NOT element is connected to the second input of the seventh AND element, the first and second inputs of the eighth AND-NOT element, and also to the first input of the second element I. The output of the eighth AND-NOT element is connected to the second inputs of the first and third elements I. Output the ninth element AND is NOT connected to the second input of the second AND element and the first input of the third element I. The output of the seventh AND element is connected to the first inputs of the first and second OR elements, the output of the first AND element is connected to the second input of the first OR element. The output of the second AND element is connected to the second input of the second OR element. The output of the first OR element is connected to the first and second inputs of the first AND-NOT element, the output of the second OR element is connected to the first and second inputs of the second AND-NOT element. The output of the sixth AND-NOT element is connected to the first and second inputs of the tenth AND-NOT element, the first input of the fourth AND element and the second input of the eighth element I. The output of the seventh AND-NOT element is connected to the first and second inputs of the eleventh AND-NOT element, the second the input of the fifth element And and the first input of the eighth element I. The output of the eighth element And is connected to the second inputs of the third and fourth elements OR, the output of the tenth element AND is NOT connected to the first input of the fifth element And the second input of the sixth element I. The output of the fifth element And with is connected to the first input of the fourth OR element, the output of the eleventh AND element is NOT connected to the second input of the fourth AND element and to the first input of the sixth element I. The output of the fourth AND element is connected to the first input of the third OR element, the output of the third OR element is connected to the inputs of the fifth element AND NOT. The first and second information inputs of the reservation control unit are respectively the first and second inputs of the third AND-NOT element. The third and fourth information inputs of the redundancy control unit are respectively the first and second inputs of the fourth NAND element, the fifth and sixth information inputs of the redundancy control unit are respectively the first and second inputs of the sixth AND element, and the seventh and eighth information inputs of the redundancy control unit respectively, the first and second inputs of the seventh element AND NOT. The outputs of the first AND element, the first OR element, the second AND element, the second AND element, the third AND element, the third OR element, the fifth AND element, the eighth AND element, the fourth OR element, the fifth AND element, the fourth AND element and the sixth element And are respectively the first, second, third, fourth, fifth ("Failure of pathogens"), sixth, seventh, eighth, ninth, tenth, eleventh, twelfth ("Failure of power amplifiers") control outputs of the redundancy control unit.

The antenna switch consists of the first and second quadrature bridges, the first, second, third, fourth, fifth, sixth high-frequency switches, phase shifters 90 and 180 degrees. The first output of the first quadrature bridge is connected to the inputs of the first, third and fifth high-frequency switches. The outputs of the first, third and fifth high-frequency switches are connected to the inputs of the phase shifters 180, 90 degrees, and the sixth high-frequency switch, respectively. The outputs of the second, fourth and sixth high-frequency switches are connected to the first input of the second quadrature bridge, and the outputs of the phase shifters 180 and 90 degrees are connected to the inputs of the second and fourth high-frequency switches, respectively. The second output of the first quadrature bridge is connected to the second entrance of the second quadrature bridge. The control inputs of the first and second, third and fourth, fifth and sixth high-frequency switches are paired and are respectively the third, fourth and fifth inputs of the antenna switch. The first and second inputs of the first quadrature bridge and the first and second outputs of the second quadrature bridge are respectively the first and second inputs and the first and second outputs of the antenna switch.

Thanks to the new set of essential features due to the possibility of the first or second pathogens working with any operational power amplifier or simultaneously with two power amplifiers, the absence of an information signal delay line, the first and second power amplifiers operating in the initial state in half power mode, and in case of failure one of them switching the second to full power provides redundancy while increasing reliability and reducing the availability for work at Failure of any pathogen or amplifier to transmit digital and analog signals.

The analysis of the prior art made it possible to establish that analogues that are characterized by a set 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".

The results of the search 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 showed that they do not follow explicitly from the prior art. The prior art also did not reveal the popularity of the impact provided for by the existing 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:

Figure 1. - functional diagram of the backup device of the radio transmitter;

Figure 2. - functional diagram of the backup control unit;

Figure 3. - functional diagram of the antenna switch.

The backup device of the radio transmitter (see Fig. 1) consists of an information signal splitter 1, first 2 and second 3 pathogens, the first 8 and second 9 power supplies, respectively, the first 2 and second 3 pathogens, the first 6 and second 7 controllable switches of the power supply paths, the first 4 and second 5 sensors for monitoring the current of pathogens, the first 10 and second 11 analyzers of the state of pathogens, the first 12 and second 13 power amplifiers, the first 18 and second 19 main power supplies of power amplifiers, the first 16 and second 17 controlled switches of the main power supply units of the power amplifiers, the first 14 and second 15 sensors for monitoring the current of the power amplifiers, the first 20 and the second 21 state analyzers of the power amplifiers, the antenna switch 22, the antenna 23, the first ballast load 24, the backup control unit 25, the first 26 and the second 27 manual power supply switches of the pathogens, the first 28 and second 29 circulators at the output of the pathogens, the second 30 and third 31 ballast loads, the first 32 and second 33 switches of pathogens, branch For the radio signal 34, the first 35 and the second 36 circulators at the input of power amplifiers, the fourth 37 and fifth 38 ballast loads, the first 39 and second 40 switches of the inputs of the power amplifier, the first 41 and second 42 manual power switches of the power amplifiers, the first 43 and second 44 capacitors , the first 45 and second 46 managed switches of the additional power supply unit of the power amplifier, additional power supply 47. The information input of the backup device of the radio transmitter is connected to the input of the splitter information of the first signal 1. The first output of the splitter of the information signal 1 is connected to the input of the first pathogen 2, and the second output is connected to the input of the second pathogen 3. The output of the first pathogen 2 is connected to the input of the first analyzer of the state of the pathogen 10 and the input of the first circulator at the output of the pathogen 28. The output of the first the pathogen analyzer 10 is connected to the second information input of the backup control unit 25. The output of the second pathogen 3 is connected to the input of the second pathogen analyzer 11 and to the input of the second compass ora output exciter 29. The output of second analyzer status of agent 11 is connected to a fourth data input redundancy control unit 25. The first outputs of the first 28 and second 29 outlet pathogens circulators respectively connected to the second 30 and third 31 ballast loads. The second output of the first circulator at the output of the pathogen 28 is connected to the input of the first switch of the pathogen 32. The second output of the second circulator at the output of the pathogen 29 is connected to the input of the second switch of the pathogen 33. The outputs of the first 32 and second 33 switches of the pathogen are connected to each other and to the input of the radio signal splitter 34. The first output of the radio signal splitter 34 is connected to the input of the first circulator at the input of the power amplifier 35, the second output of the radio signal splitter 34 is connected to the input of the second circulator e of the power amplifier 36. The first output of the first circulator at the input of the power amplifier 35 is connected to the fourth ballast load 37, the second output of the first circulator at the input of the power amplifier 35 is connected to the input of the first input switch of the power amplifier 39. The first output of the second circulator at the input of the power amplifier 36 is connected with the fifth ballast load 38, and the second output of the second circulator at the input of the power amplifier 36 is connected to the input of the second input switch of the power amplifier 40. The outputs of the first 39 and second 40 switch s radio signal inputs respectively coupled to the first 12 and second 13 amplifiers. The output of the first power amplifier 12 is connected to the first input of the antenna switch 22, and also to the input of the first analyzer of the state of the power amplifier 20. The output of the first analyzer of the state of the power amplifier 20 is connected to the sixth information input of the backup control unit 25. The output of the second power amplifier 13 is connected to the second input antenna switch 22 and with the input of the second analyzer of the state of the power amplifier 21. The output of the second analyzer of the state of the power amplifier 21 is connected to the eighth information input b backup control windows 25. The first output of the antenna switch 22 is connected to the antenna 23, the first ballast load 24 is connected to the second output. The output of the first pathogen power supply unit 8 is connected in series through the first manual exciter power switch 26, the first controllable exciter power supply switch 6, the first sensor control of the current of the pathogen 4 with the power input of the first pathogen 2. The second output of the first sensor for monitoring the current of the pathogen 4 is connected to the first information input of the control unit by reservation 25. In turn, the output of the second exciter power supply 9 is connected in series through the second manual exciter power switch 27, the second controllable exciter 7 power supply switch, the second exciter current control sensor 5 with the power input of the second exciter 3. The second output of the second current control sensor the pathogen 5 is connected to the third information input of the backup control unit 25. The output of the first main power supply unit of the power amplifier 18 is connected in series through the first manual the power amplifier’s power switch 41, the first controllable switch of the main power amplifier’s power supply 16 with the input of the first current sensor of the power amplifier 14. Also, an additional power supply 47 is connected to the input of the first current sensor of the power amplifier 14 through the first controlled switch of the additional power supply of the amplifier 45. The first output of the first current sensor of the power amplifier 14 is connected to the power input of the first power amplifier 22 and the first contact of the first capacitor 43, the second contacting the first capacitor 43 is grounded. The second output of the first current sensor of the power amplifier 14 is connected to the fifth information input of the redundancy control unit 25. The output of the second main power supply unit of the power amplifier 19 is connected in series through the second manual power switch of the power amplifier 42, the second controllable switch of the main power supply unit of the power amplifier 17 with the input of the second the current monitoring sensor of the power amplifier 15, to the input of which is also connected via a second controlled switch of an additional power supply unit To yield 46 additional power supply unit 47. The first output of the second power amplifier current monitor sensor 15 is connected to the second input of the power amplifier 13 and also to a first terminal of the second capacitor 44, a second contact which is earthed. The second output of the second current sensor of the power amplifier 15 is connected to the seventh information input of the backup control unit 25. The control input of the first controllable switch of the power supply unit of the exciter 6 is connected to the first control output of the backup control unit 25. The control input of the first switch of the exciter 32 is connected to the second control output of the unit backup control 25. The control input of the second switch of the pathogen 33 is connected to the third control output of the reserve control unit 25. The control input of the second managed switch of the exciter power supply unit 7 is connected to the fourth control output of the redundancy control unit 25. The control input of the first input switch of the power amplifier 39 is connected to the sixth control output of the redundancy control unit 25. The control input of the second switch of the power amplifier 40 is connected to the ninth the control output of the redundancy control unit 25. The control input of the first controllable switch of the main power amplifier power supply unit and 16 is connected to the control input of the second switch of the main power supply unit of the power amplifier 17, as well as to the seventh control output of the redundancy control unit 25. The eighth control output of the redundancy control unit 25 is connected to the third input of the antenna switch 22. The control input of the first managed switch of the additional amplifier power supply 45 is connected to the fifth input of the antenna switch 22 and to the eleventh control output of the redundancy control unit 25. The control input of the second control The desired switch of the additional power supply unit of the amplifier 46 is connected to the fourth input of the antenna switch 22 and to the tenth control output of the redundancy control unit 25. The fifth control output of the redundancy control unit 25 is the output of the “Emergency Exciter” signal, and the twelfth control output is the “Emergency Power Amplifier” alarm.

The splitter of the information signal 1 is intended for dividing the input information signal between the first and second drivers 2, 3. It can be implemented as a two-channel power divider based on a six-terminal network (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 g.).

The first 2 and second 3 pathogens are designed to generate a radio signal, respectively, in the first and second radio path. As the first 2 and second 3 pathogens, any pathogens commercially available can be used.

The first 4 and second 5 sensors control the current of pathogens designed to generate a signal of a logical unit in case of exceeding the permissible current consumption, respectively, the first 2 and second 3 pathogens. As the first 4 and second 5 sensors for monitoring the current of pathogens, semiconductor sensors for tolerance control of increased sensitivity can be used (see the collection "Magnetic semiconductor elements for information processing" - M .: Nauka, 1978, pp. 45-55).

The first 6 and second 7 controllable power switches of the pathogens are designed to turn off the power at the command of the backup control unit 25, respectively, of the first 2 and second 3 pathogens when they fail. Relays can be used as the first 6 and second 7 controlled switches of exciter power supplies (see "Reference for the developer and designer of REA. Elemental base" / Maslennikov M.Yu., Sobolev EA, Sokolov GV, etc. - M .: ITAR-TASS, 1993, pp. 36-37.).

The first 8 and second 9 power supplies of pathogens are designed to provide power to the first 2 and second 3 pathogens. As the first 8 and second 9 power supply units of the pathogens, known power supplies are used that provide the required output parameters (current strength, voltage, power).

The first 10 and second 11 pathogen condition analyzers are designed to generate a logical unit signal in case of failure of the first 2 and second 3 pathogens, respectively. The functions of the first 10 and second 11 analyzers of the state of pathogens can be implemented on a magnetic-electric sensor (see M. Rosenblatt, Magnetic semiconductor sensors for permissible control of increased sensitivity - in the collection "Magnetic semiconductor elements for information processing" - M .: Nauka, 1978, p. .45-55) or on integrated circuits of the 521 series (see Semiconductor sensors IC 521 series comparators).

The first 12 and second 13 power amplifiers are designed to amplify the generated radio signal to the required power. As the first 12 and second 13 power amplifiers, any satisfactory power amplifiers can be used.

The first 14 and second 15 sensors of monitoring the current of power amplifiers are designed to generate a signal of a logical unit in case of exceeding the permissible current consumption by power amplifiers 12 and 13, respectively. As sensors for monitoring the current of power amplifiers 14, 15, semiconductor sensors of tolerance control of increased sensitivity can be used (see Collection "Magnetic semiconductor elements for information processing" - M .: Nauka, 1978, pp. 45-55).

The first 16 and second 17 controllable switches of the main power amplifier power supplies are designed to turn off the power of the first 12 and second 13 power amplifiers, respectively, in the event of failure of any one at the command of the backup control unit 25. As the first and second controllable switches of the main power supply units of the power amplifiers 16 , 17 relays can be used (see. "Directory of the developer and designer of REA. Elemental base" / Maslennikov M.Yu., Sobolev EA, Sokolov GV and others - M .: ITAR-TASS, 1993, pg. 36-37.).

The first 18 and second 19 main power supply units of power amplifiers are designed to provide power respectively to power amplifiers 12 and 13 in half power mode. As the first 18 and second 19 main power supply units of power amplifiers, it is necessary to use known power supplies that ensure the operation of the selected power amplifiers in half power mode.

The first 20 and second 21 state analyzers of power amplifiers are designed to generate a signal of a logical unit in case of failure of the first 12 and second 13 power amplifiers, respectively. As the first 20 and second 21 analyzers of the state of power amplifiers, semiconductor sensors of tolerance control of increased sensitivity can be used (see the collection "Magnetic semiconductor elements for information processing" - M .: Nauka, 1978, pp. 45-55).

Antenna switch 22 is designed to add the power of the first 12 and second 13 power amplifiers while simultaneously operating in half power mode and summing the total power to the antenna 23, as well as summing the power of the first 12 or second 13 power amplifiers to the antenna 23 when it is operating at full power in case of failure of the second 13 or first 12 power amplifier, respectively. An implementation option (see figure 3). Antenna switch 22 (see figure 3), consists of the first 22.1 and second 22.2 quadrature bridges, the first 22.3, second 22.4, third 22.5, fourth 22.6, fifth 22.7, sixth 22.8 high-frequency switches, phase shifters 22.10 and 22.9, respectively, 90 and 180 degrees, the first output of the first quadrature bridge device 22.1, depending on the control signal from the backup control unit 25, is connected to the first input of the second quadrature bridge 22.2 either through a fifth high-frequency switch 22.7 and sixth 22.8 connected in series, or through the third 22.5 high-frequency switch serially connected, a 90-degree phase shifter 22.10, the fourth high-frequency switch 22.6, or the first high-frequency switch 22.3 in series, the 180-degree phase shifter 22.9, the second high-frequency switch 22.4. The second exit of the first quadrature bridge 22.1 is connected to the second entrance of the second quadrature bridge 22.2. The first input of the first quadrature bridge 22.1 is connected to the output of the first power amplifier 12, the second input of the first quadrature bridge device 22.1 is connected to the output of the second power amplifier 13. The first output of the second quadrature bridge 22.2 is connected to the input of the antenna 23, and the second to the first ballast load 24. Inputs control of the first 22.3 and second 22.4 high-frequency switches are interconnected and with the fifth input of the antenna switch 22. The control inputs of the third 22.5 and fourth 22.6 high-frequency switches are connected m I am waiting for myself and with the third input of the antenna switch 22. The control inputs of the fifth 22.7 and sixth 22.8 high-frequency switches are connected to each other and to the fourth input of the antenna switch 22, and the third, fourth and fifth inputs of the antenna switch are connected respectively to the eighth, tenth and eleventh control outputs of the unit backup management 25.

The first quadrature bridge 22.1 is intended for dividing the radio signal from the outputs of power amplifiers 12, 13.

The second quadrature bridge 22.2 provides the addition of the radio signal at the first output of the antenna switch 22 and compensation at the second.

As the first 22.1 and second 22.2 quadrature bridges, three dB bridge devices described in the book by Zaitsev V.V., Katushkina V.M., London S.E., Model Z.I. Devices for the addition and distribution of power of high-frequency oscillations - M .: Sov. Radio, 1980 .-- 296 p.

The phase shifter 90 degrees 22.10 is designed to rotate the phase of the radio signal 90 degrees. As a phase shifter 90 degrees 22.10 can be used a piece of coaxial cable length λ / 4.

The phase shifter 180 degrees 22.9 is designed to rotate the phase of the radio signal 180 degrees. As a phase shifter 180 degrees 22.9 can be used a piece of coaxial cable with a length of λ / 2.

The first 22.3 and 22.4 second RF switches are designed to be included in the radio path phase shifter 180 degrees 22.9.

The third 22.5 and fourth 22.6 RF switches are designed to turn on the phase shifter 90 degrees 22.10.

The fifth 22.7 and the sixth 22.8 RF switches are designed to connect the first output of the first quadrature bridge 22.1 to the first input of the second quadrature bridge 22.2.

As high-frequency switches 22.3-22.8 can be used known vacuum switches manufactured by the industry, for example type B2B-1B.

Antenna 23, is designed to convert the radio signal at the first output of the antenna switch 22 into electromagnetic waves and emit them into the propagation medium. As the antenna 23, any antenna with satisfactory characteristics can be used.

The backup control unit 25 is designed to control the operation of the blocks of the backup device of the radio transmitter. An implementation option (see figure 2). The backup control unit 25 includes the first 25.12, the second 25.13, the third 25.14, the fourth 25.15 OR elements, the first 25.16, the second 25.17, the third 25.18, the fourth 25.19, the fifth 25.20, the sixth 25.21, the seventh 25.22, the eighth 25.23 elements I, the first 25.1 , second 25.2, third 25.3, fourth 25.4, fifth 25.5, sixth 25.6, seventh 25.7, eighth 25.8, ninth 25.9, tenth 25.10, eleventh 25.11 NAND elements. The output of the third AND-NOT 25.3 element is connected to the first inputs of the first 25.16 and the seventh 25.22 AND elements, as well as to the inputs of the ninth AND-NOT 25.9 element. The output of the fourth AND-NOT 25.4 element is connected to the second input of the seventh AND 25.22 element, as well as the inputs of the eighth AND-NOT 25.8 element and the first input of the second AND 25.17 element. The output of the eighth AND-NOT element 25.8 is connected to the second inputs of the first 25.16 and the third 25.18 elements I. The output of the ninth AND-NOT element 25.9 is connected to the second input of the second AND element 25.17 and the first input of the third AND element 25.18. The output of the seventh element And 25.22 is connected to the first inputs of the first 25.12 and second 25.13 OR elements. The output of the first element AND 25.16 is connected to the second input of the first element OR 25.12. The output of the second element And 25.17 is connected to the second input of the second element OR 25.13. The output of the first element OR 25.12 is connected to the inputs of the first element AND 25.1. The output of the second element OR 25.13 is connected to the inputs of the second element AND-NOT 25.2. The output of the sixth AND-NOT 25.6 element is connected to the inputs of the tenth AND-NOT 25.10 element, the first input of the fourth AND 25.19 element and the second input of the eighth AND 25.23 element. The output of the seventh AND-NOT element 25.7 is connected to the inputs of the eleventh AND-NOT element 25.11, the second input of the fifth AND element 25.20 and the first input of the eighth AND element 25.23. The output of the eighth element AND 25.23 is connected to the second inputs of the third 25.14 and fourth 25.15 OR elements. The output of the tenth element AND-NOT 25.10 is connected to the first input of the fifth element And 25.20 and the second input of the sixth element And 25.21. The output of the fifth element AND 25.20 is connected to the first input of the fourth element OR 25.15. The output of the eleventh element AND 25.11 is connected to the second input of the fourth element And 25.19 and to the first input of the sixth element And 25.21. The output of the fourth element AND 25.19 is connected to the first input of the third element OR 25.14. The output of the third element OR 25.14 is connected to the inputs of the fifth element AND-NOT 25.5. The first and second information inputs of the redundancy control unit are respectively the first and second inputs of the third AND-NOT element 25.3. The third and fourth information inputs of the redundancy control unit are respectively the first and second inputs of the fourth AND-25.4 element, the fifth and sixth information inputs of the redundancy control unit are the first and second inputs of the sixth AND-25.6 element, respectively. The seventh and eighth information inputs of the redundancy control unit are respectively the first and second inputs of the seventh AND-NOT element 25.7. The outputs of the first element AND 25.1, the first element OR 25.12, the second element AND 25.17, the second element NAND 25.2, the third element AND 25.18, the third element OR 25.14, the fifth element AND 25.5, the eighth element AND 25.23, the fourth element OR 25.15, the fifth element And 25.20, the fourth element And 25.19 and the sixth element And 25.21 are respectively the first, second, third, fourth, fifth ("Accident pathogens"), sixth, seventh, eighth, ninth, tenth, eleventh, twelfth ("Accident power amplifiers ") control outputs of the control unit is reserved have 25.

The used elements AND 25.16-25.23, AND-NOT 25.1-25.11, OR 25.12-25.15 are known and described, for example, in the book by G. I. Gorbachev and E. E. Chaplygin "Industrial Electronics" on page 135-138.

The first 26 and second 27 manual power supply switches of pathogens are designed to turn on (turn off) the power of the first 2 and second 3 pathogens, respectively. As the first 26 and second 27 manual power supply switches of the pathogens, standard toggle switches can be used.

The first circulator at the output of the pathogen 28 with the second ballast load 30 connected to it is designed to ensure the passage of the radio signal in the forward direction from the output of the first pathogen 2 to the input of the radio signal splitter 34 when the contacts of the first switch of the pathogen 32 are closed and the same radio signal is scattered when the contacts are open on the second ballast load 30.

The second circulator at the output of the pathogen 29 with the third ballast load 31 connected to it is designed to ensure the passage of the radio signal in the forward direction from the output of the second pathogen 3 to the input of the radio signal splitter 34 when the contacts of the second switch of the pathogen 33 are closed and the same signal is scattered when the contacts are open on the third ballast load 31.

The first circulator at the input of the power amplifier 35 with the fourth ballast load 37 connected to it is designed to ensure the passage of the radio signal in the forward direction from the output of the radio signal splitter 34 to the input of the first power amplifier 12 with the contacts of the first input switch of the power amplifier 39 closed and the scattering of the same radio signal when open contacts at the fourth ballast load 37.

The second circulator at the input of the amplifier 36 with the fifth ballast load 38 connected to it is designed to ensure the forward direction of the radio signal from the output of the radio signal splitter 34 to the input of the second power amplifier 13 with closed contacts of the second input switch of the amplifier 40 and the scattering of the same radio signal when the contacts are open fifth ballast load 38.

As the first 28 and second 29 circulators at the outputs of the pathogens as well as the first 35 and second 36 circulators at the inputs of the power amplifiers, waveguide circulators described in the book of DM Sazonov can be used and other microwave devices. Textbook / ed. D.M.Sazonova - M .: Higher School, 1981, - 296 p., See Fig. 9.14 on p. 281.

The first ballast load 24 is intended for power dissipation at the second output of the antenna switch 22.

As the first 24, second 30, third 31, fourth 37, fifth 38 ballast loads, you can use active resistances of a value equal to half the wave impedance of the radio path, the required power.

The first pathogen switch 32 is designed to turn on (off) the radio signal from the output of the first pathogen 2 to the input of the radio signal splitter 34, by command from the backup control unit 25.

The second switch of the pathogen 33 is designed to turn on (off) the radio signal from the output of the second pathogen 3 to the input of the splitter of the radio signal 34, by command from the backup control unit 25.

The first switch of the input of the power amplifier 39 is designed to turn on (off) the radio signal from the first output of the splitter of the radio signal 34 to the input of the first power amplifier 12, by command from the backup control unit 25.

The second input switch of the power amplifier 40 is designed to turn on (off) the radio signal from the second output of the radio signal splitter 34 to the input of the second power amplifier 13, by command from the backup control unit 25.

As the first 32 and second 33 switches of the pathogens, as well as the first 39 and second 40 switches of the inputs of the power amplifiers 39, 40, vacuum switches manufactured by the industry, for example, type B2B-1B, can be used.

The radio signal splitter 34 is intended for dividing the radio signal from the outputs of pathogens 2, 3 between the inputs of the first 35 and second 36 circulators at the inputs of the power amplifiers. As a splitter of the radio signal 34 can be used six-terminal T-or Y-shaped connection (see J. Buduris, P. Schenevier. Microwave chains. Translated from French. Edited by A. L. Zinoviev. - M .: Sov Radio, 1979, p. 165 - Fig. 6.2.1 and 6.2.2, p. 169 Fig. 6.2.7).

The first 41 and second 42 manual power amplifier power switches are designed to turn on (turn off) the power of the first 12 and second 13 power amplifiers. Standard toggle switches can be used as the first 41 and second 42 manual power amplifier power switches.

The first capacitor 43 is designed to provide uninterrupted power to the first power amplifier 12 at the time of switching it from the first main power supply unit of the power amplifier 18 to an additional power supply 47.

The second capacitor 44 is designed to provide uninterrupted power to the second power amplifier 13 at the time of switching it from the second main power supply 19 to an additional power supply 47.

As the first 43 and second 44 capacitors can be used capacitors of known brands of the required capacity.

The first 45 controlled switch of the additional amplifier power supply is designed to switch the power of the first power amplifier 12 to the additional power supply 47, by command from the backup control unit 25.

The second 46 controlled switch of the additional amplifier power supply is designed to switch the power of the second power amplifier 13 to the additional power supply 47, by command from the backup control unit 25.

Relays can be used as the first 45 and second 46 controllable switches of the additional power supply unit (see "Reference for the developer and designer of REA. Elemental base" / Maslennikov M.Yu., Sobolev EA, Sokolov GV, etc. - M .: ITAR-TASS, 1993, pp. 36-37).

Additional power supply 47 is designed to provide power to one of the operational power amplifiers 2, 3 in the mode of full power output, in case of failure of the other. As an additional power supply 47, it is necessary to use a power supply that ensures the normal operation of the selected power amplifier at full power.

The device operates as follows.

The power supply of the first driver 2, the second driver 3, the first power amplifier 12 and the second power amplifier 13 is carried out by the corresponding first 26, 41 and second 27, 42 manual power switches of the pathogens and power amplifiers. In this case, the voltage from the first power supply of the pathogen 8 is supplied to the power input of the first pathogen 2 through the closed contacts of the first manual power switch of the pathogen 26, the first managed switch of the power supply of the pathogen 6 and the first sensor monitoring the current of the pathogen 4. The voltage from the second power supply of the pathogen 9 fed to the power input of the second pathogen 3 through the closed contacts of the second manual power switch 27, the closed contacts of the second managed switch of the power supply exciter 7 and a second exciter current control sensor 5. The voltage from the first main power supply unit of the power amplifier 18 through the closed contacts of the first manual power switch of the power amplifier 41, the closed contacts of the first controllable switch of the main power supply 16 and the first current sensor of the power amplifier 14 are supplied to the power input of the first power amplifier 12. The voltage from the second main power supply unit of the power amplifier 19 through the closed contacts of the second manual power switch power amplifier 42, the closed contacts of the second managed switch of the main power supply 17 and the second current control sensor of the power amplifier 15 is fed to the power input of the second power amplifier 13. The first and second power amplifiers work from the first and second main power supplies 18 and 19 respectively in half power mode.

Suppose that the first 2 and second 3 exciters, as well as the first 12 and second 13 power amplifiers are operational. Then, at the output of the first sensor for monitoring the current of the pathogen 4 and the output of the first analyzer of the state of the pathogen 10, logical zero signals are generated and are supplied respectively to the first and second information inputs of the reservation control unit 25. Logical zero signals from the first and second information inputs of the reservation control unit 25 are fed to the inputs third element AND NOT 25.3. At the output of the third AND-NOT 25.3 element, a signal of a logical unit is generated, which is fed to the first inputs of the seventh 25.22 and the first 25.16 And elements, as well as to the first and second inputs of the ninth AND-NOT 25.9 element. At the output of the second sensor for monitoring the current of the pathogen 5 and the output of the second analyzer of the state of the pathogen 11, logic zero signals are also generated, and respectively fed to the third and fourth information inputs of the reservation control unit 25. Logical zero signals from the third and fourth information inputs of the reservation control unit 25 are fed to the inputs of the fourth element AND NOT 25.4, which generates a logical unit signal at its output. This logical unit signal is supplied to the second input of the seventh AND 25.22 element, the first and second inputs of the eighth AND-NOT element 25.8 and the first input of the second AND element 25.17. Thus, at the output of the seventh AND 25.22 element, a logical unit signal is generated, which is fed to the first inputs of the first 25.12 and second 25.13 of the OR elements. At the output of the eighth element AND-NOT 25.8, a logical zero signal is generated, which arrives at the second input of the first element And 25.16 and the second input of the third element And 25.18. At the output of the ninth AND-NOT 25.9 element, a logic zero signal is also generated and fed to the second input of the second AND element 25.17 and the first input of the third AND element 25.18. From the logical zero signals coming to the first and second inputs of the third AND element 25.18, the third AND 25.18 element generates a logic zero signal, which does not cause the “Exciters alarm” signal at the fifth control output of the backup control unit 25. Since the first and second inputs of the first element AND 25.16 receives logical unit and zero signals, then the output of the element generates a logic zero signal, which is fed to the second input of the first element OR 25.12. At the output of the second element AND 25.17, a logical zero signal is also generated that is fed to the second input of the second element OR 25.13 and to the third control output of the redundancy control unit 25. At the output of the first element OR 25.12, a signal of a logical unit is generated that is fed to the second control output of the reservation control unit 25 and the inputs of the first AND-NOT element 25.1, at the output of which a logic zero signal is generated, which arrives at the first control output of the backup control unit 25. At the output of the second OR element 25.1 3, a logical unit signal is generated, which is input to the inputs of the second AND-NOT 25.2 element, the output of which is a logical zero signal and is fed to the fourth control output of the redundancy control unit 25. Thus, a logical zero signal from the first control output of the redundancy control unit 25 acts on the control input of the first managed switch of the exciter 6 power supply, leaving its contacts closed. At the control input of the switch of the first pathogen 32 acts a signal of a logical unit from the second control output of the backup control unit 25, closing its contacts. The logic zero signal from the third control output of the backup control unit 25 acts on the control input of the second switch of the pathogen 33, and its contacts remain open. The logic zero signal from the fourth control output of the backup control unit 25 acts on the input of the second managed switch of the power supply unit of the pathogen 7, and its contacts remain closed.

Based on this, it follows that the information signal supplied to the input of the splitter of the information signal 1 is divided in two and fed to the inputs of the first 2 and second 3 pathogens, where it modulates the carrier high-frequency signal. The modulated signal from the output of the first pathogen 2 through the first circulator at the output of the pathogen 28 and the closed contacts of the first switch of the pathogen 32 is fed to the input of the radio signal splitter 34. The modulated signal from the output of the second pathogen 3 is dissipated at the third ballast load 31, since the contacts of the second switch of the pathogen 33 are open . The first 12 and second 13 power amplifiers are operational, therefore, the fifth and seventh, as well as the sixth and eighth information inputs of the redundancy control unit 25 from the outputs of the first 14 and second 15 sensors for monitoring the current of the power amplifiers and from the outputs of the first 20 and second 21 power analyzer analyzers logical zero signals are being received. Logical zero signals from the fifth and sixth information inputs are fed to the first and second inputs of the sixth element AND-NOT 25.6. At the output of the sixth element AND-NOT 25.6, a signal of a logical unit is formed. From the output of the sixth AND-NOT 25.6 element, the logical unit signal is fed to the inputs of the tenth AND-NOT 25.10 element and the second input of the eighth AND 25.23 element. Signals of logical zero from the seventh and eighth information inputs are fed to the first and second inputs of the seventh element AND-NOT 25.7. At the output of the seventh element AND-NOT 25.7, a signal of a logical unit is formed. From the output of the seventh AND-NOT 25.7 element, the logical unit signal is supplied to the first and second inputs of the eleventh AND-NOT 25.11 element, the second input of the fifth AND 25.20 element and the first input of the eighth AND 25.23 element. Thus, a logical zero signal is generated at the output of the tenth AND-NOT 25.10 element and fed to the first input of the fifth AND 25.20 element and the second input of the sixth AND 25.21 element, and at the output of the eleventh AND-25.11 element, a logic zero signal is also generated and fed to the second input the fifth element And 25.20 and the first input of the sixth element And 25.21. A logical unit signal is generated at the output of the eighth element AND 25.23 and is fed to the second inputs of the third and fourth elements OR 25.14 and 25.15, as well as to the eighth control output of the backup control unit 25. A logic zero signal is generated at the output of the sixth element 25.21, which does not indicate a malfunction power amplifiers at the control output 12 "Failure of power amplifiers" of the backup control unit 25. From the output of the fourth element AND 25.19, a logic zero signal is fed to the first input of the third element OR 25.14 and about the eleventh control output of the backup control unit 25. A logical zero signal from the output of the fifth AND 25.20 element is supplied to the first input of the fourth OR element 25.15 and the tenth control output of the redundancy control unit 25. From the logical zero and logical unit signals at the inputs of the third OR element 25.14, it is formed at its output, a signal of a logical unit, which is fed to the sixth control output of the redundancy control unit 25 and the first and second inputs of the AND-NOT 25.5 element, is formed at the output of the AND-NOT 25.5 element the logical zero and is fed to the seventh control output of the redundancy control unit 25. The generated signal of the logical unit from the output of element 25.15 is fed to the ninth control output of the redundancy control unit 25. Thus, the signal of the logical unit from the sixth control output of the redundancy control unit 25 acts on the control input the first input switch of the power amplifier 39 and closes its contacts. The logic zero signal from the seventh control output of the redundancy control unit 25 arrives at the control inputs of the first 16 and second 17 controlled switches of the main power supply units of the power amplifiers, therefore their contacts remain closed. The signal of the logical unit from the eighth control output of the redundancy control unit 25 acts on the control inputs of the third 22.5 and fourth 22.6 high-frequency switches of the antenna switch 22, the contacts which are closed, thereby connecting the phase shifter 90 degrees 22.10. The signal of the logical unit from the ninth control output of the backup control unit 25, acting on the control input of the second input switch of the amplifier 40 and ensures the closure of its contacts. The logic zero signal from the tenth control output of the redundancy control unit 25 acts on the control input of the second controlled switch of the additional power supply unit 46 and on the fourth inputs of the antenna switch 22, respectively, on the control inputs of the fifth 22.7 and sixth 22.8 high-frequency switches, without causing them to close. The logic zero signal from the eleventh control output of the redundancy control unit 25 acts on the control input of the first 45 controlled switch of the additional power amplifier power supply unit, the fifth input of the antenna switch 22 and, accordingly, the control inputs of the first 22.3 and second 22.4 high-frequency switches, their contacts remain open.

Then, the modulated signal of the first exciter 2 from the first and second outputs of the radio signal splitter 34, respectively, passes through the first 35 and second 36 circulators at the inputs of the power amplifiers, the closed contacts of the first 39 and second 40 switches of the inputs of the power amplifiers to the inputs of the first 12 and second 13 power amplifiers operating in half power mode. The radio signal amplified in the first 12 and second 13 power amplifiers is respectively supplied to the first and second inputs of the quadrature bridge 22.1 of the antenna switch 22. Next, the radio signal from the first output of the quadrature bridge 22.1 is through the closed contacts of the third high-frequency switch 22.5, the phase shifter is 90 degrees 22.10, the closed contacts of the high-frequency fourth the radio signal switch 22.6 is fed to the first input of the quadrature bridge 22.2 of the antenna switch 22. The signal from the second output of the quadrature bridge 22.1 is fed to The entrance of the quadrature bridge 22.2. In the second quadrature bridge 22.1, the radio signals from the first 12 and second 13 power amplifiers are added in phase and fed to the first output connected to the antenna 23, while the signals from the first 12 and second 13 power amplifiers supplied to the second output of the antenna switch 22 connected with the first ballast load 24, add up in antiphase.

Suppose the first pathogen 2 has failed. Then, at the output of the first sensor for monitoring the current of the pathogen 4 or the first analyzer of the state of the pathogen 10, a logic zero signal is generated, which arrives at the first or second information input of the reservation control unit 25. At the first control output of the reservation control unit 25, a logical unit signal is generated that acts on the control input of the first controllable switch of the exciter 6 power supply, its contacts open. Under the action of a logic zero signal from the second control output of the backup control unit 25 to the input of the first switch of the pathogen 32, its contacts open. The first driver 2 is disconnected from the first power supply unit of the driver 8 and the input of the radio signal splitter 34. At the same time, a logical unit signal is generated at the third control output of the reservation control unit 25, which acts on the control input of the second switch of the driver 33. The contacts of the second switch of the driver 33 are closed, and the modulated the input information signal the radio signal from the output of the second pathogen 3 is fed through the second circulator at the output of the pathogen 29, the contacts of the second switch I exciter 33 to the input of the radio signal splitter 34. Further from its outputs, respectively, through the first 35 and second 36 circulators at the inputs of the amplifiers, the contacts of the first 39 and second 40 switches of the power amplifiers, the first 12 and second 13 power amplifiers, the antenna switch 22 to the antenna input 23 .

In the event of a failure of the second exciter 3, the logical zero signal from the second sensor for monitoring the current of the exciter 5 or the second analyzer of the state of the exciter 11 is supplied respectively to the third or fourth information inputs of the reservation control unit 25. A logical unit signal is generated at the output of the fourth AND-NOT 25.4 element. . At the outputs of the eighth 25.8 and ninth 25.9 elements AND signals are not formed logical unit signals. The signal of a logical unit from the output of the eighth element AND-25.8 is fed to the second inputs of the first 25.16 and second 25.18 elements I. The signal of a logical unit from the output of the ninth element AND-NOT 25.9 is fed to the second input of the second element And 25.17 and the first input of the third element And 25.18. At the output of the third element And 25.18, a signal of a logical unit is generated, which is fed to the fifth control output of the backup control unit 25 "Pathogen alarm". Logical zero signals generated by the first 25.16, second 25.17 and seventh 25.22 AND elements are supplied to the inputs of the first 25.12 and second 25.13 OR elements, while the output of the second AND element 25.17 also receives a logical zero signal to the third control output of the reservation control unit 25. Under the action the logic zero signal from the third control output of the redundancy control unit 25, the contacts of the second switch of the pathogen 33 open, and the second driver 3 is disconnected from the input of the radio signal splitter 34. At the same time of this, under the action of a logic one signal from the fourth control output of the control unit 25 redundant, break contact of the second controllable unit power switch exciter 7 and the second driver 3 is de-energized. There is no radio signal at the outputs of the first 2 and second 3 pathogens and the first 12 and second 13 power amplifiers.

Suppose that at least one of the pathogens 2,3 is faulty, and the first power amplifier 12 fails. Then the logic zero signal from the output of the first current sensor of the power amplifier 14 or the output of the first analyzer of the state of the power amplifier 20 goes to the fifth or sixth information the inputs of the backup control unit 25. Based on the logic zero signals at the fifth or sixth information inputs and the logical unit at the seventh and eighth information inputs, the backup control unit 25 generates logic zero signals at the sixth, eighth, eleventh control outputs and logical unit signals at the seventh and tenth control outputs. The logic zero signal from the sixth control output of the reservation control unit 25 is supplied to the control input of the first input switch of the power amplifier 39, the contacts of the first input switch of the power amplifier 39 are opened, and the signal from the first 2 or second 3 exciters does not pass to the input of the first amplifier 12. The logical signal units from the seventh control output of the redundancy control unit 25 acts on the control inputs of the first 16 and second 17 controlled switches of the main power supplies of the amplifiers In fact, the logic zero signal from the eighth control output of the redundancy control unit 25 acts on the control input of the third 22.5 and fourth 22.6 high-frequency switches of the antenna switch 22. The contacts of the first controlled switch of the main power supply unit of the power amplifier 16 are opened, and the first power amplifier 12 is de-energized. The contacts of the third 22.5 and fourth 22.6 high-frequency switches of the antenna switch 22 are also opened, and the phase shifter 90 degrees 22.10 is excluded from the radio path of the radio signal. The contacts of the managed switch of the main power supply unit of the power amplifier 17 are opened, and the contacts of the second managed switch of the additional power supply unit of the amplifier 46 are closed by a logic unit signal from the tenth control output of the redundancy control unit 25, the second power amplifier 13 is connected to the additional power supply unit 47 and starts operating at full power. Also, by a signal of a logical unit from the tenth control output of the redundancy control unit 25, the contacts of the fifth 22.7 and sixth 22.8 high-frequency switches are closed, which connect the first output of the first quadrature bridge 22.1 with the first input of the second quadrature bridge 22.2. The contacts of the first switch of the additional power supply unit of the amplifier 45 remain open, since a logic zero signal acts on the eleventh control output of the reservation control unit 25. There is no signaling at the twelfth output of the redundancy control unit 25 “Power Amp Alarm”, since a logic zero signal is active at this output.

Thus, the radio signal from the first output of the splitter of the radio signal 34 is fed to the input of the first circulator at the input of the power amplifier 35 and is dissipated at the fourth ballast load 37, since the contacts of the first input switch of the power amplifier 39 are open. From the second output of the splitter of the radio signal 34, the radio signal enters through the second circulator at the input of the power amplifier 36, the contacts of the second switch input of the power amplifier 40 to the input of the second amplifier 13, where it is amplified to the desired value. From the output of the second power amplifier 13, the radio signal is supplied to the second input of the first quadrature bridge 22.1 of the antenna switch 22. In the first quadrature bridge 22.1, the radio signal is divided between the outputs. Moreover, at the first output, the radio signal acquires a phase shift of 90 degrees. Further, the radio signal from the first output of the first quadrature bridge 22.1 through the closed contacts of the fifth 22.7 and sixth 22.8 high-frequency switches is fed to the first input of the second quadrature bridge 22.2. The radio signal from the second output of the first quadrature bridge 22.1 is fed to the second input of the second quadrature bridge 22.2. In the second quadrature bridge 22.2, in-phase power addition occurs at the first output, to which the antenna 23 is connected. At the second output of the second quadrature bridge 22.2, the radio signals are compensated, since they are added in antiphase.

Suppose that a second power amplifier 13 fails (the first power amplifier 12 is operational). Then, at the output of the second current monitoring sensor of the power amplifier 15 or the output of the second analyzer of operability of the power amplifier 21, a logical zero signal is generated, which arrives at the seventh or eighth information input of the redundancy control unit 25. The signals of the logical unit operate at the sixth and fifth information inputs of the redundancy control unit 25 . Using this combination of input signals, logical unit signals are generated at the sixth, seventh and eleventh control outputs of the redundancy control unit 25, and logic zero signals are generated at the eighth, ninth, tenth control outputs. The signal of the logical unit from the seventh control output of the redundancy control unit 25 opens the contacts of the first 16 and second 17 controlled switches of the main power supply units of the power amplifiers, and the signal of the logical zero from the eighth control output opens the contacts of the third 22.5 and fourth 22.6 high-frequency switches of the antenna switch 22. The contacts of the second controlled switch of the main power supply unit of the power amplifier 17 open the power circuit of the second power amplifier 13. The contacts of the third 22.5 and h 22.6 tvertogo high frequency switches disconnect phase shifter 90 22.10 degrees. The contacts of the first controlled switch of the main power supply 16 open and break the power circuit of the first power amplifier 12 from the main power supply of the power amplifier 18, at the same time, by the signal of a logical unit from the eleventh control output of the backup control unit 25, the contacts of the first switch of the additional power supply of the power amplifier are closed 45, the first 22.3 and the second 22.4 high-frequency radio signal switches of the antenna switch 22. The first power amplifier 12 connect rushes to the optional power supply 47 and runs at full power. In the radio signal circuit in the antenna switch 22, a 180-degree phase shifter 35 is connected, which is necessary for the in-phase addition of the radio signals at the first output of the antenna switch 22 connected to the antenna 23.

Thus, the radio signal of the first 2 or second 3 exciters from the second output of the radio signal splitter 34 is fed to the input of the second circulator at the input of the power amplifier 36, where it is dissipated at the fifth ballast load 38, since the contacts of the second input switch of the power amplifier 40 are open. The radio signal from the first output of the splitter of the radio signal 34 enters through the first circulator at the input of the power amplifier 35 and the closed contacts of the first switch of the power amplifier 39 to the input of the first power amplifier 12, where it is amplified to the desired value. From the output of the first power amplifier 12, the radio signal enters the input of the antenna switch 22, where, thanks to the 180-degree phase shifter 22.9 included in the circuit, two components of the radio signal are added in phase at the first output of the antenna switch 22 connected to the antenna 23.

In case of failure of the first 12 and second 13 power amplifiers, they are opened on command from the backup control unit 25 of their power supply circuit, both from the first 18 and second 19 main power supply units of the power amplifiers, and from an additional power supply unit 47. By a logic zero signal from the sixth and the ninth control outputs of the backup control unit 25, the inputs of the first 12 and second 13 power amplifiers are disconnected, respectively, the first 39 and second 40 switches of the inputs of the amplifiers from the outputs of the first 35 and second 36 are circulated s on inputs of power amplifiers and a radio signal from any of the actuators 2, 3 does not pass to the inputs of the first 12 and second 13 amplifiers. According to the logic zero signals from the eighth, tenth, eleventh control outputs of the redundancy control unit 25, the contacts of the first to sixth high-frequency switches 22.3-22.8 open. At the same time, at the twelfth control output “Amplifier Failure” of the backup control unit 25, a logic unit signal is generated by the AND 25.21 element, which signals a failure of the power amplifiers.

Evaluation of the effect obtained from the claimed device in comparison with the prototype will perform on indicators: reliability, versatility, time to work when any of the pathogens or amplifiers fail.

1. We denote by P _in - the probability of a healthy state of the pathogen and through P _mind - the probability of a healthy state of the power amplifier. We consider the failure of pathogens and power amplifiers independent. Then the probability of a working state of the prototype radio transmitter

R _isprot. = 1- (1-P _b1 · P _mind1 ) · (1-P _b2 · P _mind2 ).

The probability of good condition of the claimed device

R _Spanish. = {1- (1-F _c1) + (1-F _c2)} · {1- (1-P _UM1) + (1-P _um2)}.

For example, let P = P _c1 = _c2 = P _{UM1 um2} P = 0.8.

Then

P _{use protop.} = 1- (1-0.8 · 0.8) · (1-0.8 · 0.8) = 0.87

R _Spanish. = {1- (1-0.8) · (1-0.8)} · {1- (1-0.8) · (1-0.8)} = 0.92.

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

2. Due to the lack of an information signal delay line in the claimed device, it can be used both for digital and analog signal transmission, which is not possible in the prototype device.

3. Since the first and second pathogens and the first and second power amplifiers of the claimed device are constantly in working condition, therefore, time for their heating is not required, which reduces the switching time in case of an accident of the pathogen or power amplifier. In the prototype device, one of the paths is always turned off, therefore, additional time will be required for the characteristics of the path included in the event of an accident to normal, which may exceed the delay time of the information signal of the backup path, and therefore lead to loss of information.

Claims (3)

1. The backup device of the radio transmitter containing the splitter of the information signal, the input of which is the information input of the device, the first and second exciters, the information inputs of which are connected respectively with the first and second outputs of the splitter of the information signal, the first and second power supplies of the exciters, the first and second controlled switches of the blocks exciters, the first and second sensors control the current of pathogens, the inputs of which are connected to the outputs of the first and second, respectively controlled switches of the power supply of the pathogens, the first outputs of the first and second sensors for monitoring the current of pathogens are connected to the supply inputs of the first and second pathogens, the first and second analyzers of the state of pathogens, the inputs of which are connected to the outputs of the first and second pathogens, the first and second power amplifiers, and the second main power supply units of power amplifiers, the first and second controlled switches of the main power supply units of power amplifiers, the first and second d current control sensors of power amplifiers, the inputs of which are connected to the outputs of the first and second controlled switches of the main power supply units of the power amplifiers, and their outputs are connected to the power inputs of the first and second power amplifiers, respectively, the first and second state analyzers of power amplifiers, the inputs of which are connected to the outputs respectively, of the first and second power amplifiers, an antenna switch, the first and second inputs of which are connected to the outputs of the first and second power amplifiers, an antenna connected to the first output of the antenna switch, the first ballast load connected to the second output of the antenna switch, a backup control unit, the first and fourth control outputs of which are connected respectively to the control inputs of the first and second controllable switches of the exciter power supply, the seventh control output the backup control unit is connected to the control inputs of the first and second managed switches of the main power supply units of the amplifiers power, the eighth control output of the reservation control unit is connected to the third input of the antenna switch control, the first and third information inputs of the reservation control unit are connected to the second outputs of the first and second sensors for monitoring the current of pathogens, and the second and fourth information inputs of the reservation control unit are connected to the outputs, respectively the first and second analyzers of the state of pathogens, the fifth and seventh information inputs of the control unit are reserved connected to the second outputs of the first and second sensors of current control of the power amplifiers, respectively, and the sixth and eighth information inputs of the redundancy control unit are connected to the outputs of the first and second state analyzers of power amplifiers, characterized in that the first and second manual power switches are additionally inserted into it pathogens, the inputs of which are connected to the outputs of the first and second power supplies of pathogens, respectively, and the outputs with the inputs of the first and second, respectively of the controlled switches of the power supply of the pathogens, the first and second circulators at the outputs of the pathogens, the inputs of which are connected to the outputs of the first and second pathogens, the second and third ballast loads connected to the first outputs of the first and second circulators at the output of the pathogens, the first and second switches of pathogens the information inputs of which are connected to the second outputs of the first and second circulators respectively at the output of the pathogens, and the control inputs of the first and W of the exciter switches are connected respectively to the second and third control outputs of the backup control unit, a radio signal splitter, the input of which is connected to the outputs of the first and second exciter switches, the first and second circulators at the inputs of the power amplifiers, the inputs of which are connected to the output of the radio signal splitter, the fourth and fifth ballast loads connected to the first outputs, respectively, of the first and second circulators at the input of the power amplifiers, the first and second switch and inputs of power amplifiers, the information inputs of which are connected to the second outputs of the first and second circulators respectively at the input of power amplifiers, the control inputs of the first and second switches of the inputs of the power amplifiers are connected respectively to the sixth and ninth control outputs of the redundancy control unit, the outputs of the first and second switches of the inputs of the amplifiers power are connected to the inputs of the first and second power amplifiers, respectively, the first and second manual power switches will amplify power lei, the inputs of which are connected to the outputs of the first and second main power supplies of the power amplifiers, respectively, and the outputs of the first and second manual power switches of the power amplifiers are connected to the inputs of the first and second controlled switches of the main power supplies of the power amplifiers, the first and second capacitors, first contacts which are connected to the power inputs of the first and second power amplifiers, respectively, and the second are grounded, the first and second controlled switches are additional body power supply, the outputs of which are connected respectively to the inputs of the first and second sensors for monitoring the current of power amplifiers, and the control inputs of the first and second controlled switches of the additional power supply are connected respectively to the eleventh and tenth outputs of the control of the backup control unit and with the fourth and fifth inputs of the antenna switch, additional power supply, the output of which is connected to the inputs of the first and second controlled power switches of the additional power supply I power amplifier, wherein the fifth and twelfth control outputs redundancy control block are respectively outputs "Accident activators" and "Emergency power amplifiers" device. 2. The backup device of the radio transmitter according to claim 1, characterized in that the backup control unit consists of the first, second, third, fourth elements OR, first, second, third, fourth, fifth, sixth, seventh, eighth elements AND, first, second , third, fourth, fifth, sixth, seventh, eighth, ninth, tenth, eleventh AND-NOT elements, the output of the third AND-NOT element is connected to the first inputs of the first and seventh AND elements, as well as to the first and second inputs of the ninth AND element NOT, quarter exit of the first AND-NOT element is connected to the second input of the seventh AND element, with the first and second inputs of the eighth AND-element, and also to the first input of the second AND element, the output of the eighth AND-NOT element is connected to the second inputs of the first and third AND elements, output of the ninth element AND NOT connected to the second input of the second AND element and the first input of the third AND element, the output of the seventh element AND connected to the first inputs of the first and second OR elements, the output of the first AND element connected to the second input of the first OR element, the output of the second element AND connected n with the second input of the second OR element, the output of the first OR element is connected to the first and second inputs of the first AND-NOT element, the output of the second OR element is connected to the first and second inputs of the second AND-NOT element, the output of the sixth AND-NOT element is connected to the first and the second inputs of the tenth AND-NOT element, the first input of the fourth AND element and the second input of the eighth AND element, the output of the seventh AND-NOT element is connected to the first and second inputs of the eleventh AND-NOT element, the second input of the fifth AND element and the first input of the eighth AND element eighth exit AND element is connected to the second inputs of the third and fourth OR elements, the output of the tenth element AND is NOT connected to the first input of the fifth element AND and the second input of the sixth element AND, the output of the fifth element AND is connected to the first input of the fourth element OR, the output of the eleventh element AND connected to the second input of the fourth AND element and to the first input of the sixth AND element, the output of the fourth AND element is connected to the first input of the third OR element, the output of the third OR element is connected to the inputs of the fifth AND element, the outputs of the first an AND-NOT element, the first OR element, the second AND element, the second AND element, the third OR element, the fifth AND element, the eighth AND element, the fourth OR element, the fifth AND element and the fourth AND element, respectively, are the first, second, the third, fourth, sixth, seventh, eighth, ninth, tenth and eleventh control outputs of the redundancy control unit, and the outputs of the third and sixth AND elements are respectively the fifth control output “Pathogen Failure” and the twelfth control output “Force Failure firs power "unit, first and second inputs of the third, fourth, sixth and seventh AND-NO elements are respectively first, second, third, fourth, fifth, sixth, seventh and eighth data inputs of the redundant control unit. 3. The backup device of the radio transmitter according to claims 1 and 2, characterized in that the antenna switch consists of the first and second quadrature bridges, the first, second, third, fourth, fifth, sixth high-frequency switches, phase shifters 90 ° and 180 °, the first output the first quadrature bridge is connected to the inputs of the first, third and fifth high-frequency switches, the outputs of which are connected to the inputs of the phase shifters 180 °, 90 ° and the sixth high-frequency switch, respectively, the outputs of the second, fourth and sixth of the high-frequency switches are connected to the first input of the second quadrature bridge, and the outputs of the phase shifters 180 ° and 90 ° are connected to the inputs of the second and fourth high-frequency switches, the second output of the first quadrature bridge is connected to the second input of the second quadrature bridge, the control inputs of the first and second, the third and fourth, fifth and sixth high-frequency switches are paired and are respectively the third, fourth and fifth inputs of the antenna switch, the first and second the swarm of the inputs of the first quadrature bridge, and the first and second outputs of the second quadrature bridge are respectively the first and second inputs and the first and second outputs of the antenna switch.

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