RU2784623C1 - Solid state radio transmission system - Google Patents

Abstract

FIELD: radio engineering.

SUBSTANCE: invention relates to radio engineering and can be used in radar systems. The solid-state radio transmitting system contains a power supply unit, a divider, a frequency synthesizer, the first, second and third coaxial-waveguide transitions, an input power detector head, N amplifying modules, a control unit, the first ... (N-1)-th load, an adder, the second, third and fourth attenuators, an incident wave detector head, a reflected wave detector head, first, second, and third temperature sensors, and a fan assembly. The power supply unit consists of a network filter, a voltage control module, a power and voltage control unit, a current sensor, the first and second phase control modules, a power supply control unit, the first, second and third contactors and a power supply module. The power divider consists of the first attenuator, the first, second ... N-th phase shifters. The control node consists of the first and second nodes for generating synchronization pulses, the node for controlling external synchronization pulses, the first, second and third video amplifiers, the first, second, third and fourth interface nodes, the control controller, the ADC node, the memory node, the real-time node, the node for generating video control signal and power unit. The adder consists of the first ... N-1 difference channels.

EFFECT: increased reliability with improved performance.

1 cl, 2 dwg

Description

The invention relates to radio engineering and can be used in radar systems.

Known radio transmission system containing a frequency synthesizer 1, a high-voltage power source 2, a modulator 3, a power amplifier 4, a synchronization control unit 5, a valve 6, a directional coupler 7, a high power level valve 8, an antenna/equivalent switch 9, an antenna equivalent 10, an attenuator 11, the detector section 12, the unit 13 for searching for the optimal power and controlling the antenna/equivalent switch as part of the synchronization control nodes 5, 14 optimal power settings, 15 antenna/equivalent switching control and 16 built-in control, waveguides 17, cathode current sensors 18 and 19 and collector, respectively, while the high-voltage power source 2 and the modulator 3 are equipped with control and monitoring units 20 and 21 (Patent for the invention of the Russian Federation No. 2 616 872 C1, IPC G01S 7/00).

Despite the fact that the above well-known radio transmitting system is the closest analogue for its intended purpose, it cannot be chosen as a prototype, representing an elemental implementation of a radio transmitting system of the previous generation using a vacuum device (klystron) as a powerful output microwave amplifier. It is known that vacuum devices, as a rule, have a limited resource, and the need to use high-voltage voltage sources to power them significantly reduces reliability.

A closer technical solution adopted for the prototype is a radar high-frequency solid-state monotransmitter of an average power level, containing a pathogen 1 for generating radio pulses, consisting of a high-frequency generator 2 connected in series with each other, formed by several switchable high-frequency quartz oscillators, and a frequency converter 3. Exciter 1 connected through a discrete attenuator 4 at the input of the broadband preamplifier (PU) 5 to the input signal power amplifier 6 contained in it, connected by its output to the input of a two-channel power divider 7, connected by outputs to two basic power amplifiers (BPA) 8 as part of the PU 5, connected to the inputs of a two-channel power adder 9, connected by the output, in turn, through a series-connected ferrite decoupler 10 and a discrete attenuator 11 at the output of the PU 5 with the input in this example of a six-channel of the power divider 12 at the input of the final power amplifier (OPA) 13. Each output channel of the power divider 12 is connected to the input of its four-channel power divider 14, connected by outputs to four BOOM 8, forming one of its amplification units 15 as part of the OPA 13 and connected to the inputs of the four-channel power adder 16, connected at the output of the block 15 by its output through a ferrite decoupling device 17 at the output of the OAM 13 with one of the inputs in this example of the execution of the six-channel adder 18, which has an output to the antenna-feeder system. At the same time, PU 5 and amplification units 15 as part of OAM 13 are equipped with secondary power sources 19, and dividers 7, 12 and 14 and adders 9 and 16 have a high-frequency isolation and BOOM 8 as part of PU5 and OAM 13 contains the first amplification stage on one transistor 20 , connected through a two-channel divider with two transistor amplification cells 21 of the second amplification stage, connected at the output of the latter to the inputs of a two-channel power adder as part of BUM 8 (Utility model patent of the Russian Federation No. 40 492, IPC G01S 7/282).

The disadvantage of the device, taken as a prototype, is the lack of reliability due to the lack of automatic control of operating modes during operation and the adoption of measures to protect individual components and the product as a whole according to data received from the controls. In particular, individual units and the product as a whole are not protected from non-compliance with the specified requirements of external power sources and external synchronization signals, there is no protection against a high load factor (VSWR) at the transmitter output, against unacceptable overheating, from an increased power level at the input of amplifying stages, caused by violations of permissible modes during operation, which can lead to their irreversible failure. The prototype has insufficiently good operational characteristics due to the lack of the possibility of automatic control of operating modes by the consumer in order to timely eliminate possible violations of operating modes that could lead to failure. Automatic control of operating modes will help to conduct a qualitative analysis of the causes that led to a possible failure of the amplifier, in order to prevent them during further operation at the consumer.

The problem to which this invention is directed is the creation of a solid-state radio transmission system in the microwave range of wavelengths of increased reliability with improved performance.

The technical result is achieved by introducing protection against non-compliance with the specified requirements of external power sources, from increased input (output) power of amplifying modules, while improving the accuracy of its control, increased output VSWR, increased temperature, from unacceptable duty cycle and duration of input synchronization pulses, and in ensuring saving in electronic memory data about the operating modes of the amplifier with real-time reference.

The task is achieved by the fact that a frequency synthesizer, the first, second and third coaxial-waveguide transitions, an input power detector head, a control unit, a fan unit, the first , ... N-1 load, second, third and fourth attenuators, incident wave detector head, reflected wave detector head, first, second and third temperature sensors, while the power supply is made as part of a network filter, a voltage control module, a power supply and control unit voltage, current sensor, first and second phase control modules, power supply control unit, first, second and third contactors, power module; the divider is made as part of the first attenuator, the first, ... N-th phase shifters; the control node is made as part of the first and second nodes for generating synchronization pulses, the node for controlling external synchronization pulses, the first, second and third video amplifiers, the first, second, third and fourth interface nodes, the control controller, the ADC node, the memory node, the real-time node, the node formation of a video control signal, a power supply unit; the fan unit is made as part of the first and second groups of fans; the adder is made as part of the first, ... N-1 difference channels, and the inputs of the network filter and the voltage control module are connected to the first external power supply (220 V / 400 Hz 3-phase), the output of the network filter is connected to the input of the current sensor, and the output of the control module voltage is connected to the first input of the control unit of the power supply, the first output of the current sensor is connected to the second input of the control unit of the power supply, and the second output of the current sensor is connected to the first input of the first contactor, the output of the first contactor is connected to the first inputs of the second contactor, the third contactor and the first input of the power supply module, the second inputs of the second and third contactors are connected to the third and fourth outputs of the power supply control unit, respectively, the second input of the power supply module is connected to the first output of the power supply control unit, the second output of the power supply control unit is connected to the second input of the first contactor, the output power supply module is connected to the first inputs of N amplifying modules, the output of the second its contactor is connected to the inputs of the first phase control module and the first group of fans, the output of the third contactor is connected to the inputs of the second phase control module and the second group of fans, the output of the first phase control module is connected to the third input of the power supply control unit, the output of the second phase control module is connected to the fourth input of the power supply control unit, the input of the power supply and voltage control unit is connected to the second external power supply (+27 V), and the output of the power supply and voltage control unit is connected to the fifth input of the power unit control unit, the second, third, fourth and fifth outputs of the power unit and voltage control modules are connected to the nodes of the voltage control module, the first phase control module, power supply control module, the second phase control module, the first input of the frequency synthesizer is connected to the second external power supply (+27 V), the second input of the frequency synthesizer is connected to an external chirp input signal or FM, the third input of the frequency synthesizer is connected to an external device that forms an external External commands for controlling the frequency synthesizer, the fourth input of the frequency synthesizer is connected to the output of the second node for generating synchronization pulses, the first output of the frequency synthesizer is connected to the input of the first coaxial-waveguide transition, the output 4/5 Fop of the frequency synthesizer is connected to one of the inputs of an external digital information processing system, the output Fop of the frequency synthesizer is connected to one of the inputs of the external digital information processing system, the M outputs of the signal of the first local oscillator of the frequency synthesizer are connected to the corresponding inputs of the external receiving system with double frequency conversion, the M outputs of the signal of the second local oscillator of the frequency synthesizer are connected to the corresponding inputs of the external receiving system with double frequency conversion, To the outputs of the pilot signals of the frequency synthesizer are connected to the corresponding inputs of the external systems of the radar station, which includes a solid-state radio transmitting system, the output of the first coaxial-waveguide transition is connected line with the input of the second coaxial-waveguide transition, the output of the second coaxial-waveguide transition is connected to the input of the first attenuator, the output of the divider is connected to the input of the head of the detector input power, the outputs of the first, ... N-th phase shifters are connected to the second inputs of the first, ... N-th amplifying modules, the third inputs of the first, ... N-th amplifying modules are connected to the output of the first node for generating synchronization pulses, the first input of the first node for generating synchronization pulses is connected to external synchronization pulses, and the second input of the first node for generating synchronization pulses is connected to the first output of the control controller, the first the input of the second node for generating synchronization pulses is connected to external synchronization pulses, the second input of the second node for generating synchronization pulses is connected to the second output of the control controller, the input of the node for monitoring external synchronization pulses is connected to external synchronization pulses, and the output of the node control of external synchronization pulses is connected to the first input of the control controller, the output of the first, ... N-th amplifying modules is connected to the first, ... N-th inputs of the adder, the fourth inputs of the first, ... N-th amplifying modules are connected to the output of the first interface node, the input of the first the interface node is connected to the third output of the control controller, the outputs of the first ... (N-1)-th differential channels are connected to the first ... (N-1)-th load, the first output of the adder is connected to an external consumer, to which the output microwave signal is supplied, formed by a solid-state radio transmission system, the second output of the adder is connected to the input of the second attenuator, the output of which is connected to the input of the third coaxial-waveguide junction, the output of which is the input to standard instrumentation to control the parameters of the output microwave signal of the solid-state radio transmission system at the tuning stage, the third the output of the adder is connected to the input of the third attenuator, the output of which connected to the input of the head of the detector incident wave, the output of which is connected to the input of the third video amplifier, the fourth output of the adder is connected to the input of the fourth attenuator, the output of which is connected to the input of the head of the detector reflected wave, the output of which is connected to the input of the second video amplifier, the output of which is connected to the first input of the node ADC, the first output of the third video amplifier is connected to the second input of the ADC node, the output of the detector input power head is connected to the input of the first video amplifier, the output of which is connected to the third input of the ADC node, the output of the ADC node is connected to the second input of the control controller, the input of the second interface node is connected to external frequency synthesizer control commands, and the output of the second interface node is connected to the third input of the control controller, the input of the third interface node is connected to external commands for controlling the solid-state radio transmission system, and the output of the third interface node is connected to the fourth input of the control controller, the output of the memory node is connected to the fifth input of the control controller, the output of the real-time node is connected to the sixth input of the control controller, the input of the fourth interface node is connected to the third output of the control node of the power supply, and the output of the fourth interface node is connected to the seventh input of the control controller, the output of the first the temperature sensor is connected to the eighth input of the control controller, the output of the second temperature sensor is connected to the ninth input of the control controller, the output of the third temperature sensor is connected to the tenth input of the control controller, the input of the power unit is connected to the second external power supply (+27 V), and the outputs of the power unit are connected with inputs of the first and second synchronization pulse generating units, first, second and third video amplifiers, control controller, external synchronization pulse control units, ADC, memory, real time, video control signal generation, first, second, third and fourth units interface, first, second and third temperature sensors.

The inventive solid-state radio transmitting system has a set of essential features that are not known from the prior art for products of this purpose, which allows us to conclude that the invention meets the criterion of "novelty".

The inventive solid-state radio transmitting system, according to the applicant and the authors, meets the criterion of "inventive step", because for specialists, it does not explicitly follow from the prior art, i.e. not known from available sources of information at the date of application.

The essence of the invention is illustrated using the block diagram shown in figures 1 and 2.

The solid-state radio transmitter contains a power supply unit 1 consisting of a network filter 2, a voltage control module 3, a power supply and control unit 4, a current sensor 5, a first phase control module 6, a power supply control unit 7, a first contactor 8, a second phase control module 9, power module 10, second contactor 11, third contactor 12; frequency synthesizer 13, the first coaxial-waveguide transition 14, the divider 15 as part of the first attenuator 16, the first phase shifter 18, the second phase shifter 19 and ... ... N-th phase shifter 20; the second coaxial-waveguide transition 17, the input power detector head 21, the first amplifying module 22, the second amplifying module 23, ... ... the N-th amplifying module 24, the control unit 25 as part of the first node for generating synchronization pulses 26, the second node for generating synchronization pulses 27 , control node of external synchronization pulses 28, first video amplifier 29, first interface node 30, control controller 31, second interface node 32, ADC node 33, third interface node 34, second video amplifier 35, memory node 36, third video amplifier 37, real time node 38, the node for generating a video control signal 39, the fourth node of the interface 40, the power node 41; block of fans 42 in the first group of fans 43, the second group of fans 44; the first load 45, N-1 load 46, the adder 47 in the first differential channel 48, N-1 differential channel 49; second attenuator 50, third attenuator 51, fourth attenuator 52, third waveguide-coaxial junction 53, incident wave detector head 54, reflected wave detector head 55, first temperature sensor 56, second temperature sensor 57, third temperature sensor 58 2 and voltage control module 3 are connected to the first external power supply (220 V/400 Hz 3-phase), the output of network filter 2 is connected to the input of current sensor 5, and the output of voltage control module 3 is connected to the first input of the control unit of power supply 7, the first output of the current sensor 5 is connected to the second input of the control unit of the power supply 7, and the second output of the current sensor 5 is connected to the first input of the first contactor 8, the output of the first contactor 8 is connected to the first inputs of the second contactor 11, the third contactor 12 and the first input of the power module 10 , the second inputs of the second 11 and third 12 contactors are connected, respectively, with the third and fourth outputs of the control unit of the power supply 7 , the second input of the power supply module 10 is connected to the first output of the control unit of the power supply 7, the second output of the control unit of the power supply module 7 is connected to the second input of the first contactor 8, the output of the power module 10 is connected to the first inputs of the first amplifying module 22, the second amplifying module 23, ... … … N-th amplifying module 24, the output of the second contactor 11 is connected to the inputs of the first phase control module 6 and the first group of fans 43 of the fan unit 42, the output of the third contactor 12 is connected to the inputs of the second phase control module 9 and the second group of fans 44 of the fan unit 42 , the output of the first phase control module 6 is connected to the third input of the control unit of the power supply 7, the output of the second phase control module 9 is connected to the fourth input of the control unit of the power supply 7, the input of the power and voltage control unit 4 is connected to the second external power supply (+27 V) , and the output of the power supply and voltage control unit 4 is connected to the fifth input of the control unit of the power supply 7, the second, third, the fourth and fifth outputs of the power and voltage control unit 4 are connected to the nodes of the voltage control module 3, the first phase control module 6, the power supply control module 7, the second phase control module 9, the first input of the frequency synthesizer 13 is connected to the second external power supply (+27 V) , the second input of the frequency synthesizer 13 is connected to an external input signal (chirp or FM), the third input of the frequency synthesizer 13 is connected to an external device that generates external commands to control the frequency synthesizer, the fourth input of the frequency synthesizer 13 is connected to the output of the second node for generating synchronization pulses 27, the first the output of the frequency synthesizer 13 is connected to the input of the first coaxial-waveguide transition 14, the output 4/5 Fop of the frequency synthesizer 13 is connected to one of the inputs of the external digital information processing system, the output Fop of the frequency synthesizer 13 is connected to one of the inputs of the external digital information processing system, M - signal outputs of the first local oscillator of the frequency synthesizer 13 are connected to the corresponding M - outputs of the signal of the second local oscillator of the frequency synthesizer 13 are connected to the corresponding inputs of the external receiving system with double frequency conversion, K - outputs of the pilot signals of the frequency synthesizer 13 are connected to the corresponding inputs of external systems from the composition of the radar station , in which a solid-state radio transmitting system operates, the output of the first coaxial-waveguide junction 14 is connected to the input of the second coaxial-waveguide junction 17, the output of the second coaxial-waveguide junction 17 is connected to the input of the first attenuator 16, the output of the divider 15 is connected to the input of the head of the detector input power 21, the output of the first phase shifter 18 is connected to the second input of the first amplifying module 22, the output of the second phase shifter 19 is connected to the second input of the second amplifying module 23, the output of the N-th phase shifter 20 is connected to the second input of the N-th amplifying module 24, the third inputs of the first th amplifying module 22, second amplifying module 23, ... .... The N-th amplifying module 24 is connected to the output of the first node for generating synchronization pulses 26, the first input of the first node for generating synchronization pulses 26 is connected to external synchronization pulses, and the second input of the first node for generating synchronization pulses 26 is connected to the first output of the control controller 31, the first the input of the second synchronization pulse generation unit 27 is connected to external synchronization pulses, the second input of the second synchronization pulse generation unit 27 is connected to the second output of the control controller 31, the input of the external synchronization pulse control unit 28 is connected to external synchronization pulses, and the output of the external synchronization pulse control unit 28 connected to the first input of the control controller 31, the output of the first amplifying module 22 is connected to the first input of the adder 47, the output of the second amplifying module 23 is connected to the second input of the adder 47, the output of the Nth amplifying module is connected to the Nth input of the adder 47, the fourth inputs of the first amplifying module 22, the second amplifying module 23, the N-th amplifying module 24 are connected to the output of the first interface node 30, the input of the first interface node 30 is connected to the third output of the control controller 31, the output of the first difference channel 48 from the adder 47 connected to the first load 45, the N-1 output of the difference channel 49 from the adder 47 is connected to the N-1 load 46, the first output of the adder 47 is connected to an external consumer, which is supplied with an output microwave signal generated by a solid-state radio transmission system, the second output of the adder 47 is connected to the input of the second attenuator 50, the output of which is connected to the input of the third coaxial-waveguide adapter 53, the output of which can be connected to standard instrumentation to control the parameters of the output microwave signal of the solid-state radio transmission system at the tuning stage, the third output of the adder 47 is connected to input of the third attenuator 51, the output of which which is connected to the input of the head of the detector incident wave 54, the output of which is connected to the input of the third video amplifier 37, the fourth output of the adder 47 is connected to the input of the fourth attenuator 52, the output of which is connected to the input of the head of the detector reflected wave 55 52, the output of which is connected to the input of the second video amplifier 35 , the output of the second video amplifier 35 is connected to the first input of the ADC node 33, the first output of the third video amplifier 37 is connected to the second input of the ADC node 33, the second output of the third video amplifier 37 is connected to the input of the video control signal generation node 39, the output of which can be connected to an external instrumentation device at the setup stage, the output of the detector input power head 21 is connected to the input of the first video amplifier 29, the output of the first video amplifier 29 is connected to the third input of the ADC node 33, the output of the ADC node 33 is connected to the second input of the control controller 31, the input of the second interface node 32 is connected to external synth control commands frequency congestion, and the output of the second interface node 32 is connected to the third input of the control controller 31, the input of the third interface node 34 is connected to external commands to control the solid-state radio transmission system, and the output of the third interface node 34 is connected to the fourth input of the control controller 31, the output of the memory node 36 is connected with the fifth input of the control controller 34, the output of the real-time node 38 is connected to the sixth input of the control controller 31, the input of the fourth interface node 40 is connected to the fifth output of the control node of the power supply 7, and the output of the fourth interface node 40 is connected to the seventh input of the control controller 31, the output of the first temperature sensor 56 is connected to the eighth input of the control controller 31, the output of the second temperature sensor 57 is connected to the ninth input of the control controller 31, the output of the third temperature sensor 58 is connected to the tenth input of the control controller 31, the input of the power unit 41 is connected to the second external power supply (+27 AT) , and the outputs of the power supply unit 41 are connected to the inputs of the first 26 and second 27 nodes for generating synchronization pulses, the control unit for external synchronization pulses 28, the first 29, the second 35 and the third 37 video amplifiers, the control controller 31, the ADC 33, the memory 36, the real time 38, generating a video control signal 39, the first 30, the second 32, the third 34 and the fourth 40 interface nodes, the first 56, the second 57 and the third 58 temperature sensors.

Solid state radio transmitting system operates as follows. When turned on, the solid-state radio transmitting system is supplied with: an external signal with linear frequency or phase modulation (external input signal (chirp or FM)) to the second input of the frequency synthesizer 13, external synchronization pulses supplied to the inputs of the control unit for external synchronization pulses 28, the first generation unit synchronization pulses 26, the second node for the formation of synchronization pulses 27, the first external power supply (220 V / 400 Hz 3-phase) supplied to the input of the network filter 2 and to the input of the voltage control module 3 and the second external power supply (+27 V) supplied to the input of the power supply unit and voltage control 4, the first input of the frequency synthesizer 13 and to the input of the power unit 41.

If the supplied external supply voltages meet the specified requirements, then the solid-state radio transmitting system operates in accordance with the specified algorithm. However, if the voltage control module 3 or the power supply and voltage control unit 4 determine that the characteristics of external power sources do not meet the specified requirements in a solid-state radio transmission system, protection is provided. In such a situation, the control unit 7 will issue a command to prohibit the activation of the first contactor 8, which will prevent the supply of the first external power supply (220 V/400 Hz 3-phase) to the units of the radio transmission system, their failure and costly repairs. The control unit of the power supply 7 will issue a command to disable the switching on of the first contactor 8 also in the event that the first phase control module 6 or the second phase control module 9 establishes the absence or decrease of the voltage of one or more phases at the output of the second contactor 11 or the third contactor 12. Prohibition to turn on the first contactor 8 when the voltage of one or more phases at the output of the second contactor 11 or the third contactor 12 drops below the permissible value will prevent unacceptable overheating of the solid-state radio transmission system due to a decrease in the efficiency of the fan unit 42, which can lead to its failure or the failure of the fans from the fan assembly 42, caused by a lack of voltage in one or two phases. In addition, the control unit of the power supply 7 will issue a command to prohibit the activation of the first contactor 8 when the second input receives information from the first output of the current sensor 5 about the excess current consumption on the first external power supply (220 V/400 Hz 3-phase) above the allowable value . If the external power supply is within the allowable values, according to the external control commands received at the third input, the frequency synthesizer 13 sets the values of the generated frequencies of the continuous signals of the first and second local oscillators intended for supply to external radio receiver systems with double frequency conversion. Moreover, the number of local oscillator signal outputs can vary in accordance with the number of channels of external radio receiving systems. Signals Fop and 4/5 Fop are formed, designed to be fed to an external digital processing system of a radar station in order to ensure coherent processing of input radar signals. If necessary, according to external commands, pilot signals of a given frequency are generated, designed to test the systems of a radar station, which includes a solid-state radio transmitting system. The number of pilot outputs may vary depending on the number of radar systems under test. The frequency synthesizer 13 carries out the transfer of the spectrum of the external input pulse signal with linear frequency or phase modulation, coming to the second input, in the operating frequency range of the solid-state radio transmission system. The frequency of the probing pulsed RF signal generated in this way at the first output of the frequency synthesizer 13 is determined by an external command to control the frequency synthesizer supplied to the third input. The fourth input of the frequency synthesizer 13 receives a synchronization pulse from the output of the second node for generating synchronization pulses 27, in which, according to the command arriving at its second input from the second output of the control controller 31, the delay of the external synchronization pulse entering the input is controlled in order to ensure synchronization of the device operation transfer of the spectrum and amplitude modulator from the frequency synthesizer 13. The amplitude modulator from the frequency synthesizer 13, controlled by the synchronization pulse generated by the second synchronization pulse generation unit 27, allows for additional suppression of unwanted parasitic oscillations in the pause between the probing pulsed RF signals at the first output of the frequency synthesizer 13. From the first output of the frequency synthesizer 13, the generated probing pulsed RF signal is fed to the waveguide input of the first coaxial-waveguide transition 14, from the coaxial output the ode of which, via a coaxial line, it enters the coaxial input of the second coaxial-waveguide transition 17, and from the waveguide output of the second coaxial-waveguide transition it enters the waveguide input of the first attenuator 16. The first attenuator 16 is necessary to provide the required input signal power at the first inputs of the first amplifying module 22, the second amplifying module 23, … … …N-th amplifying module 24. In the divider 15, the input probing pulsed RF signal is divided into N channels of equal power. In addition, the divider provides a branch of a part of the input probing pulsed RF signal to the input power detector head 21. The input power detector head 21 is designed to control the power level at the input of the divider 15. phase shifter. From the outputs of the N phase shifters of the divider 15, the signals are fed to the inputs of N amplifying modules, from the outputs of which the amplified signals are fed to the N inputs of the adder 47. The adder 47 is made on waveguide slotted bridges (see, for example, Devices for combining and distributing the power of high-frequency oscillations / V.V. Zaentsev, V. M. Katushkina, S. E. London, Z. I. Model of Soviet Radio, 1980. - P. 97-99). The elements of power summation are waveguide slotted bridges having 2 ... N inputs, an output for the sum of in-phase equal-amplitude signals, 1 ... N-1 outputs for a difference signal, the level of which is determined by the degree of non-identity in phase and amplitude of the input signals and 1 ... N-1 spur outputs from the difference channels used to provide fine tuning. A matched absorbing load is connected to the output of each difference channel. The specified load, when one of the amplifying modules is turned off, absorbs half of the output power of the amplifying module connected to the second input arm of the slot bridge. For the bridges of the subsequent stages of the adder, the absorbing load must dissipate at least half of the total average output power of the amplifying modules connected to the arms of the summing bridge. Obviously, the most powerful absorbing load is installed in the output bridge. The use of this summation scheme with difference channels loaded with high power loads and having a branch channel from the difference signal allows sequential tuning of the gain channels using phase shifters installed in the power divider 15. As a result, tuning time is reduced, the highest output power and resulting in an increase in efficiency. The output probing pulsed microwave signal, the power level of which is determined by the sum of the signal powers of each of the N amplifying modules, from the output 1 of the adder 47 is supplied to the consumer. The outputs of all N-1 difference channels of the adder 47 are connected to N-1 matched loads 46 of a high power level. From the second output of the adder 47 part of the output microwave signal through the power coupler from the adder 47 and the second attenuator 50 is fed to the third coaxial-waveguide transition 53, designed to switch from coaxial to waveguide channel. The output of the third coax-to-waveguide junction 53 can be connected to measuring devices in the setup step. At one of the outputs of the coupler from the adder 47, a signal is generated that is proportional to the power of the output microwave signal, and at the second output of the coupler from the adder 47, a signal is generated that is proportional to the power of the reflected microwave signal from the load. A signal proportional to the power of the output microwave signal through the third attenuator 51 and a signal proportional to the power of the reflected signal through the fourth attenuator 52 from the outputs of the adder 47 are fed to the incident wave detector head 54 and the reflected wave detector head 55, respectively. The first synchronization pulse generating unit 26 generates synchronization pulses for all N amplifying modules. The formation of synchronization pulses is carried out by the commands of the control controller 31, taking into account the parameters of the input synchronization pulses arriving at the first input of the synchronization pulse generation unit 26, the delay in the passage of the probing pulsed RF signal generated by the frequency synthesizer 13 in the nodes and connecting lines, and the logic of operation of the solid-state radio transmission system. The first interface node 30 provides data exchange between all N amplifying modules and the control controller 31, as well as the control of all N amplifying modules through commands from the control controller 31. The second interface node 32 provides the ability to exchange data between the frequency synthesizer 13 and the control controller 31. The third node The interface 34 allows the control controller 31 to receive external commands for controlling the solid state radio transmission system, as well as the exchange of data on the operating modes and the status of individual nodes of the solid state radio transmission system between the control controller 31 and the external control device. The fourth interface node provides the ability to exchange data between the control node of the power supply 7 and the control controller 31. The power node 41 provides supply voltages to the first 26 and second 27 nodes for generating synchronization pulses, the first 29, second 35 and third 37 video amplifiers, control controller 31, control node external synchronization pulses 28, ADC node 33, memory node 36, real-time node 38, video control signal generation node 39, first 30, second 35, third 34 and fourth 40 interface nodes, first 56, second 57 and third 58 temperature sensors.

In the solid state radio transmission system, additional protection circuits are provided to improve reliability, which operate as follows. To improve the accuracy of control of the power of the input microwave signal, the power proportional to the power of the output microwave signal, the power proportional to the power of the reflected microwave signal used in the implementation of protection circuits, the first temperature sensor 56, which has direct thermal contact with input power detector head 21, a second temperature sensor 57 in direct thermal contact with the incident wave detector head 54 and the reflected reflected wave detector head 55, which in turn are also in direct thermal contact with each other. The values of the signal levels proportional to the controlled ones are fed through the first video amplifier 29, the second video amplifier 35, the third video amplifier 37 to the ADC node 33, from the output of which the digitized signals are sent to the control controller 31. temperature sensors are also sent to the control controller 31. In addition, the third input of the control controller 31 through the second interface node 32 from the frequency synthesizer receives information about the frequency value of the generated probing pulsed RF signal. As a result, the control controller 31, using tabular data on the power conversion coefficients of the detector heads in the temperature and frequency ranges stored in the memory unit 36, can correct the value of the controlled power at each temperature and frequency point and significantly increase the reliability of power control. A high VSWR at the output of a solid state radio transmitting system can lead to its failure. The newly introduced incident wave detector head 54 and reflected wave detector head 55, the signals from which are finally sent to the control controller 31, allow the latter to calculate the VSWR value from the output of the amplifier. The accuracy of the calculated VSWR value is increased due to the control of the signal level using data obtained from the second temperature sensor 57, and data on the frequency of the generated probing pulsed RF signal received from the frequency synthesizer 13. When the VSWR reaches a critical value at the output of the amplifier, the level of which is stored in the node memory 36, the control controller 31 generates a command to turn off all N amplifying modules supplied to the first synchronization pulse generation node 26, which blocks the synchronization pulses supplied to all N amplifying modules. The amplifying modules are disabled, preventing failure of the solid state radio transmission system. Disabling all N amplifying modules on command from the control controller 31 will also occur if the specified requirements stored in the memory node 36, the input power level of the amplifying modules, controlled by the detector input power head 21, the control accuracy of which is corrected according to the data obtained from the first temperature sensor 56 , and data on the frequency of the generated probing pulsed radio frequency signal received from the frequency synthesizer 13, as well as in case of non-compliance with the specified requirements stored in the memory node 36, the power level at the output of the adder 47, controlled by the head of the detector incident wave 54, the control accuracy of which is corrected according to the data obtained from the second temperature sensor 57, and data on the frequency of the generated probing pulsed RF signal received from the frequency synthesizer 13.

The control controller 34 issues a command to turn off all N amplifying modules if the duration and duty cycle of the input (output) microwave radio pulses of the amplifying modules, information about which comes from the detector input head 21 and the detector incident wave head 54, do not match the specified requirements stored in the memory node 36, exceeding the temperature inside the housing of the radio transmission system, according to the data received from the third temperature sensor 58, above the permissible level determined by the threshold, the level of which is stored in the memory node 36. In addition, if using the node for monitoring external synchronization pulses 28 a discrepancy is established of the controlled pulses to the given permissible values of duration and duty cycle stored in the memory node 36, about which the corresponding information will be sent from the output of the control node of external synchronization pulses 28 to the first input of the control controller 31, the control controller 31 also issues a command to turn off in of all N amplifying modules. The introduction of this protection will prevent the operation of the solid state radio transmission system outside the allowable operating conditions and may prevent its possible failure. The introduction of the memory node 36 and the real-time node 38 in the control node 25 allows you to capture and store data on the modes of operation of the solid-state radio transmission system with reference to real time. Thanks to this, by an external command to control a solid-state radio transmitting system, it is possible to request information about the operation of the amplifier with binding of the received data to the real time of the events that have occurred. Information about the output (input) power, duty cycle, output pulse duration, temperature inside the case, output VSWR, etc. help to take measures to prevent possible failures of a solid state radio transmission system, for example, due to violations of operating conditions, or help to understand the reason for its failure if it could not be avoided, which ultimately will lead to increased reliability in operation at the consumer.

From the foregoing, it follows that in the event of adverse conditions, high reliability of the solid-state radio transmission system will be ensured due to the expansion of the number of parameters, when they deviate from the required values, a decision is made to trigger the protection, as well as due to an increase in the accuracy of monitoring parameters, the reliability of the values of which affects the efficiency of work. protection schemes, and, consequently, the reliability of the product as a whole. Improved performance by storing in electronic memory data on the modes of operation of the solid-state radio transmission system with real-time reference. As a result of the analysis of these data during the operational phase, it is possible either to prevent a possible failure of a solid state radio transmitting system, or to help understand the cause of its failure if it could not be avoided, which, in turn, can help prevent similar failures in the future.

The applicant company has developed design documentation for the proposed technical solution, according to which product samples have been successfully tested, which confirms compliance with the "industrial applicability" criterion for the invention.

Claims (1)

Solid-state radio transmission system containing a power supply, a divider, N amplifying modules, an adder, characterized in that it additionally includes a frequency synthesizer, the first, second and third coaxial-waveguide transitions, an input power detector head, a control unit, a fan unit, the first, ... N-1 load, second, third and fourth attenuators, incident wave detector head, reflected wave detector head, first, second and third temperature sensors, while the power supply is made as part of a network filter, a voltage control module, a power unit and voltage control , current sensor, first and second phase control modules, power supply control unit, first, second and third contactors, power supply module; the divider is made as part of the first attenuator, the first, ... N-th phase shifters; the control node is made as part of the first and second nodes for generating synchronization pulses, the node for controlling external synchronization pulses, the first, second and third video amplifiers, the first, second, third and fourth interface nodes, the control controller, the ADC node, the memory node, the real-time node, the node formation of a video control signal, a power supply unit; the fan unit is made as part of the first and second groups of fans; the adder is made as part of the first, ... N-1 difference channels, and the inputs of the network filter and the voltage control module are connected to the first external power supply, the output of the network filter is connected to the input of the current sensor, and the output of the voltage control module is connected to the first input of the power supply control unit, the first output of the current sensor is connected to the second input of the control unit of the power supply, and the second output of the current sensor is connected to the first input of the first contactor, the output of the first contactor is connected to the first inputs of the second contactor, the third contactor and the first input of the power module, the second inputs of the second and third contactors are connected , respectively, with the third and fourth outputs of the power supply control unit, the second input of the power supply module is connected to the first output of the power supply control unit, the second output of the power supply control unit is connected to the second input of the first contactor, the output of the power supply module is connected to the first inputs of N amplifying modules, the output of the second contactor is connected to inputs of the first phase control module and the first group of fans, the output of the third contactor is connected to the inputs of the second phase control module and the second group of fans, the output of the first phase control module is connected to the third input of the power supply control unit, the output of the second phase control module is connected to the fourth input of the control unit power supply unit, the input of the power and voltage control unit is connected to the second external power supply, and the output of the power supply and voltage control unit is connected to the fifth input of the power unit control unit, the second, third, fourth and fifth outputs of the power and voltage control unit are connected to the units of the voltage control module , the first phase control module, power supply control module, the second phase control module, the first input of the frequency synthesizer is connected to the second external power supply, the second input of the frequency synthesizer is connected to an external chirp or FM input signal, the third input of the frequency synthesizer is connected to an external device that generates external commands synthesizer control hour the fourth input of the frequency synthesizer is connected to the output of the second unit for generating synchronization pulses, the first output of the frequency synthesizer is connected to the input of the first coaxial-waveguide transition, the output 4/5 Fop of the frequency synthesizer is connected to one of the inputs of an external digital information processing system, the output Fop of the frequency synthesizer connected to one of the inputs of the external digital information processing system, M signal outputs of the first local oscillator of the frequency synthesizer are connected to the corresponding inputs of the external receiving system with double frequency conversion, M signal outputs of the second local oscillator of the frequency synthesizer are connected to the corresponding inputs of the external receiving system with double frequency conversion, K the outputs of the pilot signals of the frequency synthesizer are connected to the corresponding inputs of the external systems of the radar station, which includes a solid-state radio transmitting system, the output of the first coaxial-waveguide transition is connected to the input of the second coaxial waves one transition, the output of the second coaxial-waveguide transition is connected to the input of the first attenuator, the output of the divider is connected to the input of the head of the detector input power, the outputs of the first, ... N-th phase shifters are connected to the second inputs of the first, ... N-th amplifying modules, the third inputs of the first, ... The N-th amplifying modules are connected to the output of the first node for generating synchronization pulses, the first input of the first node for generating synchronization pulses is connected to external synchronization pulses, and the second input of the first node for generating synchronization pulses is connected to the first output of the control controller, the first input of the second node for generating synchronization pulses connected to external synchronization pulses, the second input of the second synchronization pulse generation unit is connected to the second output of the control controller, the input of the external synchronization pulse control unit is connected to external synchronization pulses, and the output of the external synchronization pulse control unit connected to the first input of the control controller, the output of the first, ... N-th amplifying modules is connected to the first, ... N-th inputs of the adder, the fourth inputs of the first, ... N-th amplifying modules are connected to the output of the first interface node, the input of the first interface node is connected to the third output of the control controller, the outputs of the first ... (N-1)-th difference channels are connected to the first ... (N-1)-th load, the first output of the adder is connected to an external consumer, to which the output microwave signal generated by a solid-state radio transmission system is supplied , the second output of the adder is connected to the input of the second attenuator, the output of which is connected to the input of the third coaxial-waveguide transition, the output of which is the input to standard instrumentation to control the parameters of the output microwave signal of the solid-state radio transmission system at the tuning stage, the third output of the adder is connected to the input of the third attenuator, the output of which is connected to the input of the detector head driving wave, the output of which is connected to the input of the third video amplifier, the fourth output of the adder is connected to the input of the fourth attenuator, the output of which is connected to the input of the head of the detector reflected wave, the output of which is connected to the input of the second video amplifier, the output of which is connected to the first input of the ADC unit, the first output of the third of the video amplifier is connected to the second input of the ADC unit, the output of the detector input power head is connected to the input of the first video amplifier, the output of which is connected to the third input of the ADC unit, the output of the ADC unit is connected to the second input of the control controller, the input of the second interface unit is connected to external frequency synthesizer control commands, and the output of the second interface node is connected to the third input of the control controller, the input of the third interface node is connected to external commands for controlling the solid-state radio transmission system, and the output of the third interface node is connected to the fourth input of the control controller, the output of the memory node is connected to the fifth input of the control controller, the output of the real-time node is connected to the sixth input of the control controller, the input of the fourth interface node is connected to the third output of the control node of the power supply, and the output of the fourth interface node is connected to the seventh input of the control controller, the output of the first temperature sensor is connected to the eighth input of the control controller, the output of the second temperature sensor is connected to the ninth input of the control controller, the output of the third temperature sensor is connected to the tenth input of the control controller, the input of the power node is connected to the second external power supply, and the outputs of the power node are connected to the inputs of the first and second nodes for generating synchronization pulses, the first, second and third video amplifiers, control controller, control units for external synchronization pulses, ADC, memory, real time, video control signal generation, first, second, third and fourth interface units, first, second and third sensors temperature.

Images