RU2497278C1 - Multimode microwave transmitter - Google Patents

Abstract

FIELD: radio engineering, communication.

SUBSTANCE: device has a power supply, a modulator, an input channel, a first travelling-wave tube (TWT), an intermediate channel, a second TWT, an output channel, a control and monitoring device, a dc amplifier, a first protective device, a second protective device, a first filter, a high-voltage three-phase transformer, a first divider, a high-voltage rectifier, a VL lamp, a second filter, a second divider, a second current sensor, a first current sensor, a waveguide for feeding an input microwave signal W1, an output microwave signal waveguide W2, an output microwave signal waveguide for tuning the heterodyne of the guidance system of a radio head W3, a plurality of contacts for functional connections between said components.

EFFECT: high reliability, low noise level, providing optimum output power at carrier frequencies and enabling operation of the microwave transmitter in multiple modes.

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Description

The invention relates to the field of radar and is intended to work on flying objects as part of airborne radar stations using Doppler signal processing.

The microwave transmitter is known from the prior art (Patent RU No. 2208909, published 2003.07.20, IPC: H04B 1/00, H05K 7/20). The microwave transmitter contains a master oscillator, a decoupling device, a p-i-n attenuator, a microwave amplifier, a load, a current source, a discriminator, a power source and a modulator, and a closed-loop cooling system. This microwave transmitter allows you to increase operating efficiency by improving the heat dissipation from the transmitter units and improving the overall dimensions, but it does not solve the problem of overcurrent protection on the input three-phase power circuit.

The known amplifier pulsed microwave power (Certificate for a utility model of the Russian Federation No. 16238, published 2000.12.10, IPC: H03F 3/58). The amplifier contains a traveling wave lamp (TWT), the collector output of which is connected to the positive bus of the collector power supply, and the negative bus of the collector power supply is connected to the cathode of the TWT, as well as the anode power supply. The negative bus of the anode power source is connected to the positive bus of the collector power source. The positive bus of the anode power source is connected to the positive terminal of the control stage of the high voltage stabilizer, the negative terminal of which is connected to the housing, and the control input is connected to the regulatory output of the voltage divider, one terminal of which is connected to the TWT cathode, and the second to the housing. The common output of the modulator power supply is connected to the TWT cathode, the negative bus of the modulator power supply is connected to the output of the first key, and the positive bus to the inputs of the second and third keys. The input of the first key is connected to the output of the third key, the second TWT control grid, and through the dividing diode, to the first TWT control grid, which is connected to the anode of the separation diode, with the second key output and, through the discharge resistor, to the output of the first key. The control input of the first key is connected to the output of the first starting device, the input of which is connected to the output of the switch. The control input of the second key is connected to the output of the second starting device, the input of which is connected to the first input of the switch and the connector of "short" pulses. The control input of the third key is connected to the output of the third starting device, the input of which is connected to the output of the inverter. The inverter input is connected to the trigger connector for long pulses and the second input of the switch. This pulsed microwave power amplifier expands the functionality of the amplifier, but does not provide increased reliability of the TWT as part of the microwave amplifier.

Closest to the claimed technical essence is the microwave transmitter (Patent RU No. 2187880, published 2002.08.20, IPC: H03B 9/06). The microwave transmitter includes a frequency discriminator and a current source controlled from the discriminator between the second output of the master oscillator and the control input p-i-n of the attenuator. The current source provides direct current stabilization through the p-i-n attenuator and, as a result, stabilizes the input power and reduces the noise level of the microwave amplifier. The current source is controlled by a discriminator, which generates a frequency-dependent voltage control current p-i-n attenuator. The disadvantages of this microwave transmitter can be attributed to the fact that when obtaining the optimal output power in the frequency range and reducing the level of amplitude and phase noise, it does not solve the problem of overcurrent protection on the input three-phase power circuit, protection against exceeding the anode current of the first TWT does not provide optimal output power at carrier frequencies, it is not possible to obtain a significant amount of output power.

In order to obtain long-range detection of an airborne radar station (RLS), a transmitter with a large output pulse power is required. To obtain a significant value of the output pulse power in the transmitter, two successive traveling-wave tubes (TWTs) are used.

One of the ways to provide radar immunity is the possibility of its operation at several frequencies. Carrier frequencies are switched automatically using an on-board digital computer (BCM) and a master oscillator. Therefore, the transmitter must operate on several tens of carrier frequencies in a wide frequency range. In the prototype, a wide frequency range is divided into several narrow frequency subbands and the average input optimal power for this frequency subband is set. But in the frequency sub-band there may appear two or several carrier frequencies, therefore, at one carrier frequency the input power is insufficient, and on the other it is redundant.

The technical result of the proposed technical solution is aimed at improving reliability, reducing noise, ensuring optimal output power at carrier frequencies and making it possible for the microwave transmitter to operate in several modes (high output pulse power mode, low output pulse power mode, radio backlight mode).

The specified technical result is achieved in that the transmitter contains a power source and a modulator. Moreover, it differs from the prototype in that it contains an input path, a first TWT, an intermediate path, a second TWT, an output path, a control and monitoring device (CC), a direct current amplifier (DCT), a first protection device, a second protection device, a first filter , three-phase high-voltage transformer, first divider, high-voltage rectifier, VL lamp, second filter, second divider, second current sensor, first current sensor, input microwave signal supply waveguide W1, output microwave signal waveguide W2, output microwave waveguide for tuning of the local oscillator of the guidance system of the radio head guidance system (RGSN) W3, terminal connector for supplying an input AC power supply voltage of phase A, connector terminal for supplying an input AC power voltage of phase B, terminal connector for supplying an input AC voltage supply phase C, contact terminal of an input pulse start-up of the transmitter, contact of the input signal connector mode P1, contact of the input signal connector mode RP, contact of the input signal connector ANTENNA ON (ON ANT), START input signal connector pin, TRANSMISSION LOCK STROBE (SBP) input connector pin, frequency code input signal connector pin, phase A input common voltage supply connector pin, phase B input common voltage input connector pin, phase B input common voltage connector pin, input connector pin AC phase C common supply voltage, input connector pin HIGH VOLTAGE ON (ON HV), input signal connector pin + 27V DELAYED (+ 27V REF.), IC output signal connector pin EQUILIBILITY, output signal connector PREPAREDNESS, output signal connector contact HIGH VOLTAGE POWER SOURCE (FIXED VIP), output signal connector Fault 1 path, output signal connector 2 Fault path 2, output signal connector Fault 2 .), the contact of the output signal connector is AVAILABLE Rye, the contact of the output signal connector is AVAILABLE P1, the contact of the output signal connector is AVAILABLE P5, the contact of the output signal connector TURN ON THE ANTENNA (ON. ANT.), The terminal connector of the output signal EQUIVALENT is ON (EQ. ON).

In this case, the waveguide for supplying the input microwave signal W1 is connected to the first input of the input path. The second input of the input path is connected to the twentieth input of the CID, the output of the input path is connected to the first input of the first TWT, the output of the first TWT is connected to the input of the intermediate path. The first output of the intermediate path is connected to the waveguide of the output microwave signal to fine-tune the local oscillator of the WGSN W3, the second output of the intermediate path is connected to the eleventh input of the CID, the third output of the intermediate path is connected to the first input of the second TWT. The output of the second TWT is connected to the input of the output path, the first output of the output path is connected to the tenth input of the CAM, the second output of the output path is connected to the ninth input of the CAM, the third output of the output path is connected to the waveguide of the output microwave signal W2. The second input of the first TWT is connected to the first output of the modulator, the third input of the first TWT is connected to the second output of the modulator, the fourth input of the first TWT is connected to the third output of the modulator, the fifth input of the first TWT is connected to the fourth output of the modulator, the sixth input of the first TWT is connected to the second output of the first sensor current. The second input of the second TWT is connected to the fifth output of the modulator, the third input of the second TWT is connected to the sixth output of the modulator, the fourth input of the second TWT is connected to the seventh output of the modulator, the fifth input of the second TWT is connected to the sixth output of the second filter. The first input of the modulator is connected to the second output of the second current sensor, the second input of the modulator is connected to the third output of the first protection device, the third input of the modulator is connected to the seventeenth output of the CAM, the fourth input of the modulator is connected to the eighteenth output of the CAM, the fifth input of the modulator is connected to the nineteenth output of the CAM, the sixth the modulator input is connected to the input signal connector + 27V REF., the seventh modulator input is connected to the third output of the second protection device and the first input of the power source, the eighth mode input Yator connected to the second output of the second protection device and the second input of the power source, the ninth input modulator coupled to the first output of the second protection device and the third power supply input. The first input of the second protection device is connected to the terminal terminal of the input alternating common voltage supply of phase A, the second input of the second protection device is connected to the terminal terminal of the input alternating general voltage of phase B, the third input of the second protection device is connected to the terminal terminal of the input alternating common phase C voltage , the fourth input of the second protection device is connected to the terminal of the input signal + 27V ON. BH, the fourth output of the second protection device is connected to the fourth input of the first protection device. The fifth output of the second protection device is connected to the eighth input of the CC. The first input of the CID is connected to the terminal of the input pulse of the transmitter start-up, the second input of the CID is connected to the terminal of the input signal of mode P1, the third input of the CID is connected to the terminal of the input signal of the RP mode, the fourth input of the CID is connected to the terminal of the input signal of the ANT. ON, the fifth CID input is connected to the STC input signal connector pin, the sixth CID input is connected to the SBP input signal terminal pin, the seventh CAM input is connected to the frequency code input signal connector pin, the twelfth CID input is connected to the fifth output of the first protection device. The first CID output is connected to the output signal connector pin CORRECTNESS, the second CID output is connected to the output signal connector pin READY, the third CID output is connected to the output signal connector PIN VIRTUAL, the fourth CID output is connected to the output signal connector pin CORRECTIVE TREATMENT 1, the fifth CID output connected to the pin of the output signal connector TROUBLESHOOT 2, the sixth CID output is connected to the pin of the output signal connector is the TRACK Σ, the seventh output of the CAM is connected to the terminal pin AVAILABILITY of the output signal Rvykh, the eighth ACC output is connected to the output signal connector pin AVAILABILITY P1, the 9th ACM output is connected to the output signal connector pin AVAILABILITY P5, the tenth ACM output is connected to the output signal ON connector pin. ANT., The eleventh ACC output is connected to the terminal of the output signal of the ECV. ON, the sixteenth ACC output is connected to the third input of the first protection device, the fifteenth ACC output is connected to the second input of the first protection device, the fourteenth ACC output is connected to the first input of the first protection device, the thirteenth ACC output is connected to the fourth input of the protection device, the twelfth output of the ACC is connected to the third input of the UPT, the twentieth output of the CAM is connected to the second input of the input path, the twenty-first output of the CAM is connected to the fourth input of the output path. The first input of the CTF is connected to the output of the second divider, the second input of the CTF is connected to the third output of the second filter, the fifth input of the CTF is connected to the first output of the first protection device, the sixth input of the CTF is connected to the second output of the first protection device, the seventh input of the CTF is connected to the fourth output of the first device protection, the eighth input of the OTT is connected to the second output of the power source, the ninth input of the OTT is connected to the third output of the power source, the tenth input of the OTT is connected to the fourth output of the power source, the eleventh input of the OTT is connected en to the body. The first output of the UPT is connected to the fourth input of the lamp VL, the second output of the UPT is connected to the sixth input of the first protection device. The fifth input of the first protection device is connected to the first output of the power source, the seventh input of the first protection device is connected to the first output of the first current sensor, the eighth input of the first protection device is connected to the first output of the second current sensor, the ninth input of the first protection device is connected to the second output of the second filter. The fifth output of the power source is connected to the third input of the VL lamp, the sixth output of the power source is connected to the second input of the VL lamp, the seventh output of the power source is connected to the fifth input of the VL lamp. The contact of the connector for supplying the input AC phase A power voltage is connected to the third input of the three-phase high-voltage transformer and to the first input of the first filter. The contact of the connector for supplying the input power AC voltage of phase B is connected to the second input of the three-phase high-voltage transformer and to the second input of the first filter. The contact of the connector for supplying the input power AC voltage of the phase C supply is connected to the first input of the three-phase high-voltage transformer and to the third input of the first filter. The fourth input of the first filter is connected to the housing. The output of a three-phase high-voltage transformer is connected to the input of a high-voltage rectifier. The output of the high voltage rectifier is connected to the input of the second filter. The first output of the second filter is connected to the input of the first divider. The output of the first divider is connected to the first input of the VL lamp. The fourth output of the second filter is connected to the input of the first current sensor, the fifth output of the second filter is connected to the sixth input of the second TWT, the seventh output of the second filter is connected to the input of the second divider and the input of the second current sensor. The seventh input of the first TWT and the seventh input of the second TWT are connected to the housing.

The drawing shows a structural diagram of the proposed multimode microwave transmitter. The transmitter includes an input path 1, a first TWT 2, an intermediate path 3, a second TWT 4, an output path 5, a modulator 6, a power supply 7, a control and monitoring device 8, a DC amplifier 9, a first protection device 10, a second protection device 11, first filter 12, three-phase high-voltage transformer 13, first divider 14, high-voltage rectifier 15, lamp VL 16, second filter 17, second divider 18, second current sensor 19, first current sensor 20, input microwave signal waveguide W1 21, output microwave waveguide signal W2 22, output waveguide Microwave signal for adjusting the local oscillator heterodyne of the guidance system in the radar W3 23, terminal connector for supplying the input AC power supply voltage of phase A 24, terminal contact for supplying the input AC power voltage of phase B 25, terminal contact for supplying the input AC voltage supply of phase C 26, contact of the input terminal of the start pulse of the transmitter 27, contact of the input signal connector mode P1 28, contact of the input signal connector mode RP 29, contact of the input signal connector Ant. On 30, start signal input connector pin 31, SBP input signal connector pin 32, frequency code 33 input signal connector pin, phase A 34 input AC common voltage connector pin, phase B 35 common AC input voltage connector pin contact, input connector pin AC total voltage of phase C 36, contact of the input signal connector + 27V ON. VN 37, input signal connector pin + 27V REF. 38, output signal connector pin CORRECTIVE 39, output signal connector terminal READY 40, output signal connector PIN VIBRATION (high-voltage power supply) 41, output signal connector pin PROTECT 1 42, output signal connector PROTECT 2 2 43, output connector pin Signal PROBLEM Σ 44, pin of the output signal connector AVAILABILITY Out. 45, the output connector pin is AVAILABLE P1 46, the output connector pin is AVAILABLE P5 47, the output connector pin is ON. ANT 48, pin output connector EQ. ON 49. The waveguide for supplying the input microwave signal W1 21 is connected to the first input of the input path 1. The second input of the input path 1 is connected to the twentieth output of the CC 8. The output of the input path 1 is connected to the first input of the first TWT 2. The output of the first TWT 2 is connected to the input of the intermediate path 3. The first output of the intermediate path 3 is connected to the waveguide of the output microwave signal to adjust the local oscillator RGSN W3 23. The second output of the intermediate path 3 is connected to the eleventh input of the CC 8. The third output of the intermediate path 3 is connected to the first input of the second TWT 4. Exit One second TWT 4 is connected to the input of the output path 5. The first output of the output path 5 is connected to the tenth input of the ACC 8. The second output of the output path 5 is connected to the ninth input of the ACC 8. The third output of the output path 5 is connected to the waveguide of the output microwave signal W2 22. Second the input of the first TWT 2 is connected to the first output of the modulator 6. The third input of the first TWT 2 is connected to the second output of the modulator 6. The fourth input of the first TWT 2 is connected to the third output of the modulator 6. The fifth input of the first TWT 2 is connected to the fourth output of the modulator 6. Sixth input of the first TWT 2 with is single with the second output of the first current sensor 20. The second input of the second TWT 4 is connected to the fifth output of the modulator 6. The third input of the second TWT 4 is connected to the sixth output of the modulator 6. The fourth input of the second TWT 4 is connected to the seventh output of the modulator 6. Fifth input of the second TWT 4 connected to the sixth output of the second filter 17. The first input of the modulator 6 is connected to the second output of the second current sensor 19. The second input of the modulator 6 is connected to the third output of the first protection device 10. The third input of the modulator 6 is connected to the seventeenth output of the CC 8. The fourth input of the mod of the regulator 6 is connected to the eighteenth output of the AMC 8. The fifth input of the modulator 6 is connected to the nineteenth output of the AMC 8. The sixth input of the modulator 6 is connected to the terminal of the input signal + 27V rear 38. The seventh input of the modulator 6 is connected to the third output of the second protection device 11 and the first input power supply 7. The eighth input of modulator 6 is connected to the second output of the second protection device 11 and the second input of the power source 7. The ninth input of modulator 6 is connected to the first output of the second protection device 11 and the third input of the power source 7. R the first input of the second protection device 11 is connected to the terminal connector of the input variable common voltage supply of phase A 34. The second input of the second protection device 11 is connected to the terminal terminal of the input alternating general voltage of phase B 35. The third input of the second protection device 11 is connected to the terminal terminal of the input variable the total supply voltage of phase C 36. The fourth input of the second protection device 11 is connected to the terminal of the input signal + 27V ON. VN 37. The fourth output of the second protection device 11 is connected to the fourth input of the first protection device 10. The fifth output of the second protection device 11 is connected to the eighth input of the AMC 8. The first input of the AMC 8 is connected to the contact terminal of the input pulse of the start of the transmitter 27. The second input of the AMC 8 is connected with the contact of the input signal connector mode Р1 28. The third input of the УУК 8 is connected to the contact of the input connector of the signal mode РП 29. The fourth input of the УУК 8 is connected to the contact of the input signal connector ANT ON 30. The fifth input of the УУК 8 is connected to the contact of the input connector about the START signal 31. The sixth input of the AMC 8 is connected to the contact of the input signal connector of the UPS 32. The seventh input of the AMC 8 is connected to the terminal of the input signal of the frequency code 33. The twelfth input of the AMC 8 is connected to the fifth output of the first protection device 10. The first output of the AMC 8 is connected with the pin of the output signal connector CORRECTIVE 39. The second output of the MCU 8 is connected to the terminal of the connector of the output signal READY 40. The third output of the MCU 8 is connected to the terminal of the connector of the output signal CORRECT VIP 41. The fourth output of the MCU 8 is connected to the terminal of the connector of output of the second signal CORRECT PERFORMANCE 1 42. The fifth output of the CAM 8 is connected to the terminal pin of the output signal CORRECT 2. The sixth output of the CAM 8 is connected to the terminal pin of the output signal TROUBLESHOOT Σ 44. The seventh output of the CC 8 is connected to the terminal pin of the output signal PRESENCE The eighth output of CCM 8 is connected to the terminal pin of the output signal AVAILABILITY P1 46. The ninth output of CCM 8 is connected to the terminal of the connector of the output signal AVAILABILITY P5 47. The tenth output of CCM 8 is connected to the terminal of the output signal ANT. ON 48. The eleventh output of the CC 8 is connected to the terminal of the output signal of the ECV. ON 49. The sixteenth output of the UUK 8 is connected to the third input of the first protection device 10. The fifteenth output of the UUK 8 is connected to the second input of the first protection device 10. The fourteenth output of the UUK 8 is connected to the first input of the first protection device 10. The thirteenth output of the UUK 8 is connected to the fourth input of UPT 9. The twelfth output of the CCM 8 is connected to the third input of the PMT 9. The twenty-first output of the CMC 8 is connected to the fourth input of the output path 5. The first input of the PMC 9 is connected to the output of the second divider 18. The second input of the PMC 9 is connected to the third output of the second filter 17. The fifth input of UPT 9 is connected to the first output of the first protection device 10. The sixth input of UPT 9 is connected to the second output of the first protection device 10. The seventh input of UPT 9 is connected to the fourth output of the first protection device 10. The eighth input of UPT 9 is connected to the second output of the power supply 7 The ninth input of UPT 9 is connected to the third output of the power source 7. The tenth input of UPT 9 is connected to the fourth output of the power supply 7. The eleventh input of the UPT is connected to the housing. The first output of the UPT 9 is connected to the fourth input of the lamp VL 16. The second output of the UPT 9 is connected to the sixth input of the first protection device 10. The fifth input of the first protection device 10 is connected to the first output of the power source 7. The seventh input of the first protection device 10 is connected to the first output of the first current sensor 20. The eighth input of the first protection device 10 is connected to the first output of the second current sensor 19. The ninth input of the first protection device 10 is connected to the second output of the second filter 17. The fifth output of the power supply 7 is connected to the third lamp input VL 16. The sixth output of the power supply 7 is connected to the second input of the lamp VL 16. The seventh output of the power supply 7 is connected to the fifth input of the lamp VL 16. The terminal connector for supplying the input power AC voltage of phase A 24 is connected to the third input of the three-phase high-voltage transformer 13 and with the first input of the first filter 12. The contact of the connector for supplying the input AC power supply voltage of phase B 25 is connected to the second input of the three-phase high-voltage transformer 13 and to the second input of the first filter 12. Contact of the connector ma for supplying the input AC power supply voltage phase C 26 is connected to the first input of the three-phase high-voltage transformer 13 and to a third input of the first filter 12. The fourth input of the first filter 12 is connected to the housing. The output of the three-phase high-voltage transformer 13 is connected to the input of the high-voltage rectifier 15. The output of the high-voltage rectifier 15 is connected to the input of the second filter 17. The first output of the second filter 17 is connected to the input of the first divider 14. The output of the first divider 14 is connected to the first input of the lamp VL 16. The fourth output of the second filter 17 is connected to the input of the first current sensor 20. The fifth output of the second filter 17 is connected to the sixth input of the second TWT 4. The seventh output of the second filter 17 is connected to the input of the second divider 18 and the input of the second sensor then 19. The seventh and the first input of TWT 2 is connected with the housing. The seventh input of the second TWT 4 is connected to the housing.

The operation of the microwave transmitter is as follows.

In order to obtain a long radar detection range (400 km), a transmitter with a large output pulse power of 16 kW is required.

To obtain a significant value of the output pulse power in the transmitter, a multi-mode microwave amplifier of three-centimeter wavelength range U52252, consisting of two series-connected TWTs (the first TWT 2 and the second TWT 4) with low-voltage control connected via an intermediate 3 path, is used as the output amplifier stage.

TWT in terms of the combination of the most important parameters, including the operating frequency bandwidth, gain, average power, efficiency, high frequency and phase stability, low noise level, significant attenuation of the output signal in the pause between pulses, strength and compact design, surpass other types of amplification devices Microwave (Kukarin S.V. Electronic microwave devices - M., Radio and communications, 1981, p. 64-100; Katsman Yu.A. Microwave devices - M., Higher school, 1983, p. 196-264 ; edited by Skolnik M. Handbook of Radar Vol. 3, M., Soviet Radio, 1979, pp. 7-127).

The transmitter operates in search, tracking, target illumination, and radio correction modes when using missiles with an RGSN. On command from the on-board digital computer (BCM), a microwave carrier frequency signal is generated in the master radar generator. From the master oscillator through the waveguide of the input microwave signal W1 21, the microwave signal (signal) is fed to the input path 1. In the input path 1, the signal passes through the decoupling device, which protects the master oscillator from the backward wave and pin attenuator, controlled by the current from the CC 8, which provides setting the passport value of the input power of the first TWT at carrier frequencies (Vaysblat A.V. Microwave Switching Devices with Semiconductor Diodes. - M., Radio and Communications, 1987, p. 5-116).

From the output of the input path 1, the signal is supplied to the first input of the first TWT 2. The amplified signal from the output of the first TWT 2 is fed to the input of the intermediate path 3. From the output of the intermediate path 3, the signal goes to the second TWT 4, from the output of the second TWT 4 to the output path 5 and further to the waveguide of the output microwave signal W2 22.

In the intermediate path 3 and the output path 5 there are detector sections, which together with the CC, 8 modulator 6 and the first protection device 10 protect the TWT from an elevated level of SWR. When the SWR level is exceeded in the intermediate path 3 or (and) the output path 5, breakdown signal envelopes are formed at the output of the detector sections.

The envelopes of the breakdown signal from the second output of the intermediate path 3 or (and) from the second output of the output path 5 go to the eleventh and ninth inputs to the AMC 8, which generates a breakdown signal of the path and feeds it to the sixteenth output of the AMC 8, which then goes to the third input of the first protection devices 10. The first protection device 10 generates a PROHIBITION OF RADIATION signal, which from the third output of the first protection device 10 is fed to the second input of modulator 6. Modulator 6 disconnects the pulses of the modulator from TWT on this signal, TWT closes . In the absence of breakdowns, the AMC 8 generates ISPR signals. TAPE 1 on the pin of the output signal connector TROUBLESHOOTING 1 42, FIX TRACK 2 on the pin of the output signal connector PATH 2 43, the health of both paths TRACK Σ on the pin of the output signal connector PROBLEM OF THE TRACK Σ 44. (Vambersky M.V. Microwave Transmitters. - M., Higher School, 1984, p. 404-430; edited by AM Chernushenko Design of Microwave Devices and Screens, - M., Radio and Communications, 1983, p. 78-207).

The following modes are provided in the radar: long-range combat (high output pulse power of the P5 transmitter is 16 kW), melee (low output pulse power of the P1 transmitter is 3 kW), radio illumination for RP guidance systems is 1.6 kW. Before launching missiles with semi-active guidance, a pre-launch control is carried out using the reference signal at the backlight carrier frequency, therefore, part of the signal amplified by the transmitter (pulse power - 2-5 W) is fed through the directional coupler of the intermediate path 3 to the waveguide of the microwave output signal to fine-tune the local oscillator receiver in the radar W3 23.

In the mode of low output power of the radar, the first TWT 2 operates in the transmitter, in the mode of high output power of the radar in the transmitter, the first TWT 2 and the second TWT 4. The second TWT 4 operates as a radio-transparent device in P1 mode and with amplification in P5 mode. The RP mode is combined, for example, the RP radio backlight mode - the P5 review mode - RP radio backlight mode, etc. The operating modes of both TWTs are determined by the control voltages supplied from the modulator 6 from outputs 3, 4, 7 to inputs 4, 5 of the first TWT 2 and input 4 of the second TWT 4, respectively. Anode and filament voltages from outputs 1, 2, 5, 6 of modulator 6 are supplied to the cathode and heater of both TWTs - inputs 2, 3 of the first TWT 2 and inputs 2, 3 of the second TWT 4, respectively. The collector voltage at the sixth input for the first TWT 2 is supplied from the second output of the first current sensor 20. The sixth input of the second TWT 4 from the fifth output of the second filter 17 receives voltage for the first collector. The fifth input of the second TWT 4 from the sixth output of the second filter 17 receives voltage for the second collector. The anodes of both TWTs (seventh inputs) are connected to the housing. All voltages for TWT are formed relative to the voltage at the cathode.

Commands for switching the transmitter modes are received from the digital computer on the contact of the input signal connector mode Р1 28, the contact of the input signal connector mode РП 29. In the absence of a command, the P1 mode of the CID 8 generates the P5 mode enable command, which from the eighteenth output of the CID 8 goes to the fourth input of the modulator 6, modulator 6 with the help of control voltages opens the second TWT 4.

The envelope of the signal from the first output of the output tract 5 is fed to the tenth input of the AMC 8, where it is compared with the reference voltage on the comparators (the value of the reference voltage depends on the mode), as a result of which the following signals are formed, depending on the mode: AVAILABILITY P1, AVAILABILITY P5, AVAILABILITY Diggings, which from the seventh, eighth, ninth outputs of UUK 8 are supplied to the contacts of the connector 45, 46, 47, respectively. The signal AVAILABILITY Rvykh (presence of output power) is formed in the presence of signals AVAILABILITY P1 and AVAILABILITY P5.

The input trigger pulses of the transmitter (PPS) in the form of pulse sequences are received from the BCMU synchronizer to the terminal 27 connector, then to the first input of the PLC 8 and from the seventeenth output of the PLC 8 to the third input of the modulator 6. The modulator 6 generates control signals for the duration of the PPS pulse voltage for the electrodes of both TWTs with the aim of opening them.

Doppler radars have stringent noise requirements at the transmitter output. To reduce the noise level, the input power of the TWT should be optimal.

The decrease in the output power, starting from a certain value, is due to the fact that the input signal does not provide optimal focusing of the electron beam into bunches. Their formation is too rapid, and with their further movement along the TWT slowing system, the clots are inhibited and fall out of synchronism. In this case, the clumps are defocused, the shape of the envelope of the microwave pulse is distorted, parasitic modulation occurs, and the current of the TWT slowing down system increases. In order to obtain an optimum mode in terms of output power, the input power must be such that the formation of clots ends at the end of the decelerating system, at its exit. With optimal input power, the noise is minimal. (Vambersky M.V. Microwave Transmitting Devices. M., Higher School, 1984, p. 238-249). Setting the optimal input power at the TWT input at all carrier frequencies and, as a result, obtaining the optimal output power of the transmitter is ensured by the frequency code decoder (decoder) - Fig 5, located in CC 8, together with the p-i-n attenuator located in the input path 1.

The frequency code decoder is made on a separate circuit board. The frequency code decoder operates in two modes: adjustment and standard (as part of the radar). A sign of enabling the adjustment mode is the presence of a technological interface connected to the decoder via a contact for connecting the technological interface.

At the stage of adjusting the decoder, it is necessary to select a control code for each carrier frequency, at which the optimal value of the output power is fixed for the permissible current value of the TWT slow-down system. These codes are stored in the internal FLASH memory of the control device. In this case, each carrier frequency corresponds to its own memory cell address.

When the decoder is in normal operation, the codes of the number of the specific carrier frequency from the master radar generator are sent to the contact of the input signal of the frequency code 33 of the transmitter. The code number of this carrier frequency through the matching device is supplied to the control device and determines the address of the FLASH memory cell, which stores the control code previously set when adjusting for this carrier frequency.

The input signal (TTL levels) in the form of a digital code of the carrier frequency number from the master radar in the normal mode is supplied to the terminal of the input signal of the frequency code 33 of the transmitter and then through the seventh input of the AMC 8 to the input of the matching device of the frequency code decoder.

The matching device is designed to convert the TTL levels of the input signals of the frequency code decoder to the LVTTL levels (standard LVTTL, low voltage transistor - transistor logic 3.3 V) necessary for the operation of the control device. The matching device is made on chips SN74AHC14PWRG4. The converted signal from the matching device enters the control device.

The control device is based on a programmable logic integrated circuit (FPGA) of the company Altera EPM1270T144I5, which includes FLASH memory and a built-in generator of reference signals (Antonov A.P. Description language for digital devices. Altera HDL, M., Radio Soft, 2001, p. 69-171).

The control device controls the digital-to-analog converter (DAC). From the output of the control device, codes on a serial data line are transmitted to the DAC. To synchronize the serial data line, an integrated reference signal generator of the control device (FPGA) is used. The DAC is based on the AD5320BRTZ chip. The converted signal from the DAC output is fed to a controlled current source that converts voltage to current to control the pin diode in the pin attenuator of the input path 1. The controlled current source is made on 140UD20B microcircuits (J. Kar Design and manufacture of electronic equipment, M., Mir, 1980 ., p. 126-135, 235-257).

Before installing the frequency code decoder in the transmitter, the FPGA of the control device is programmed. A specially designed program is installed in the computer. Using a USB Blaster Altera programmer, the computer is connected to the decoder at the second input of the control device through the connection terminal for the technological interface of the UUK 8. This program establishes the necessary FPGA configuration for operation and then codes corresponding to the maximum attenuation p-i-n attenuation are recorded in its FLASH memory cells. The maximum attenuator p-i-n attenuation is set to exclude the supply of a high power microwave signal to the TWT input at the stage of adjustment, which will lead to its failure. After programming, the frequency code decoder is installed in CC 8.

At the stage of adjusting the decoder, the connection contact of the technological interface of the UUK 8 is connected to the technological interface connected via an adapter to the computer that is part of the transmitter adjustment workstation.

The adapter is designed to convert a universal serial bus (USB) to an SMI bus and is based on a microprocessor (ATM89 chip AT89C5131A - S3 SIM).

The SMI technology interface is a synchronous, three-wire bus (MDC, MDIO signals and GND bus).

In the process of adjusting the transmitter from the computer through the adapter and a technological interface of the SMI type (Serial Management Interface, IEE 802.3u Specification of Ethernet Network Technology from 1995), the control codes (digital code) of current control are sent to the second input of the control device of the UUK 8 technological interface pin diode pin attenuator.

A microwave signal with a frequency corresponding to one of the carrier frequencies is supplied to the waveguide for supplying the input microwave signal W1 21 from the microwave generator (included in the workplace of the transmitter settings).

On the computer display, the carrier frequency number is selected and a control code is selected in which the controlled current source of the frequency code decoder gives a control current p-i-n to the diode p-i-n attenuator at which the optimal output power of the transmitter is fixed for an allowable current value of the TWT slow-wave system. Similarly, control codes are set for all carrier frequencies. Next, the adapter and the technological interface of the SMI type are disconnected from the connection terminal of the technological interface of the UUK 8 (John F. Wakerley Designing Digital Devices Volume 1, Moscow Publishing House, 2002). Then the decoder is ready to work in normal mode.

When the decoder is operating in the normal mode, the microwave signal of a certain carrier frequency is also supplied to the input waveguide of the input microwave signal W1 21, and the codes of the carrier frequency number (digital code of TTL levels) from the radar set generator are sent to the contact of the input connector of the transmitter frequency code 33. The code number of this carrier frequency through the matching device is fed to the first input of the control device and determines the address of the FLASH memory cell, which stores the control code previously set for this carrier frequency. This code is transmitted via a serial data line to the DAC for conversion and further to a controlled current source that controls the attenuation of the pin attenuator 4, which leads to setting the input power at the TWT input that is optimal for a given frequency and, as a result, to setting the transmitter output power optimally . The response time of the circuit from the moment of feeding a new digital code to the input until the voltage value corresponding to the code is received from the DAC output is not more than 20 μs.

An alternating three-phase voltage of 200 V, 400 Hz from the radar is supplied to the terminals of the connector for supplying an input AC voltage of 34, 35, 36 for the power supply 7 and modulator 8. In the event of a failure in the power supply 7 or modulator 8, an increase in current with respect to the three-phase AC may occur voltage of 200V, 400 Hz, which will lead to significant failures in the transmitter. To protect against over-current on a three-phase alternating voltage of 200V, 400 Hz, a second protection device 11 was introduced (Fig. 2), therefore, an alternating three-phase voltage of 200V, 400 Hz from the contacts of the connector for supplying an input alternating voltage of 34, 35, 36 is supplied to the first, second , the third inputs of the second protection device 11, respectively.

To generate a current proportional to the circuit current of 200 V, 400 Hz, specially designed current transformers (TA1, TA2, TA3) are used for each phase of the alternating voltage. The measured current is the current of the primary winding of the transformer I ₁ , the amplitude of which is proportional to the load current. The design of the current transformer is a ring of ferromagnetic material with a winding through the opening of which a wire with a measured current passes. This wire plays the role of the primary winding with the number of turns W ₁ = 1 (conclusions 1-2). The secondary winding with the number of turns W ₂ (terminals 3-4), wound on the ring, together with the load, performs the function of a linear converter of the secondary current I ₂ to voltage U ₂ (I ₂ = I ₁ / W ₂ ). (A.V. Khnykov. Theory and design of transformers of secondary power sources - M., SOLON - Press, 2004, pp. 93-97). The voltage U ₂ from each current transformer is alternating and applied to the inputs of the first, second, third rectifiers, where it is converted to a constant voltage, which then goes to the comparator.

The maximum current of the primary winding of each current transformer is 5A, the secondary winding is 125 mA. From the contacts of the input AC input voltage supply phase A 34, B 35, C 36, a three-phase alternating voltage of 200 V, 400 Hz is supplied to the first terminals of the primary winding of three current transformers TA1, TA2, TA3, respectively (all current transformers are identical). From the second terminals of the primary winding of the three current transformers TA1, TA2, TA3, three-phase alternating voltage 200V, 400 Hz is supplied to the first, second, third inputs of the switch, respectively, and from the first, second, third outputs of the switch to the first, second, third outputs of the second protection devices and then to the ninth, eighth, seventh inputs of the modulator 6 and the first, second, third inputs of the power source 7.

Each phase of a three-phase alternating voltage of 200 V, 400 Hz from the secondary windings of three current transformers TA1, TA2, TA3 is supplied for rectification to the first and second inputs of the first, second, third rectifiers (rectifiers are identical), respectively. At the output of each rectifier is a resistor for the load and a decoupling diode. The signals from the output of the first, second, third rectifiers are fed to the comparator input, where its value is compared with the threshold voltage pre-set during adjustment and the corresponding operating current in the primary winding of the current transformer - 2A, and in the secondary winding - 50 mA.

The output signal of the comparator is fed to the standby multivibrator, the second key stage, inverter. The output signal of the standby multivibrator is fed to the first key stage that controls the switch. If the current value for three-phase alternating voltage of 200V, 400 Hz is exceeded, the signal from the key stage closes the switch and the three-phase alternating voltage of 200V, 400 Hz does not go to the first, second, third outputs of the second protection device and then to the ninth, eighth, seventh inputs of the modulator 6 and the first, second, third inputs of the power source 7.

The high voltage enable command is received from the radar to the contact of the high voltage enable command input connector 37, then to the fourth input of the second protection device 11, from the fourth input to the key stage that controls the supply of this command to the fourth output of the second protection device 11, depending on current values for three-phase alternating voltage 200V, 400 Hz. From the fourth output, this command is sent to the fourth input of the first protection device 10, which, in the presence of the signal FUNCTION (unit health) at the first input, gives the VIP FIRM signal to the fifth output of the first protection device 10 and then to the twelfth input of the CC 8. From the third output of the CC 8 The VIP FUNCTION signal arrives at the output contact of the connector 41. From the transmitter output, this signal enters the radar power supply, in the presence of this signal the power supply supplies a three-phase AC voltage of 200 V, 400 Hz to the contacts times transmitter 24, 25, 26 for the formation of high-voltage voltages for supplying TWT.

If the current value for three-phase alternating voltage of 200V, 400 Hz is exceeded, the FORBID signal is generated on the inverter of the second protection circuit 11, which from the fifth output of the second protection circuit 11 goes to the eighth input of the CC 8, after the formation in the CC 8 goes to the sixteenth output of the CC 8, the third the output of the CAM 8, then to the third input of the first protection device 10, from the third output of the first protection device 10 is fed to the second input of the modulator 6, which, according to the signal PROHIBIT, supplies a blocking voltage to the control electrodes of both TWTs.

If the magnitude of the current in the primary winding of the current transformer exceeds 2.5 A, the input signal on the first comparator will exceed the set threshold, and, as a result, the inverter will issue the “FORBID” command. The second key stage disables the high voltage enable command. The first key stage will give a signal to the switch, and it disconnects the three-phase alternating voltage from the power supply 7 and the modulator 6, preventing failures. The time delays for the signals in cascades are selected so that the teams are formed in the above sequence.

Exceeding the maximum values of the currents of the TWT electrodes leads to their rapid failure. Excessive anode current is especially dangerous (OST 110348-86, p.16). In technical conditions, the permissible value of the anode current is necessarily indicated on the TWT, therefore protection is applied to the transmitters on the TWT, which measures the value of the anode current and, when the anode current increases more than the permissible norm, gives the radar power source a command by which the power source disconnects the power supply voltage from the transmitter .

When two serially connected TWTs are used in the transmitter, protection against excess anode current is also applied, it is located in the first protection device 10 and UPT 9. Since the first TWT 2 and the second TWT 4 are connected in series, it is possible to measure the anode current only for both TWTs, therefore overcurrent protection is applied for both TWTs.

When analyzing TWT failures, the transmitter shows an increased failure of the first TWT. To reduce the failure of the first TWT, it is proposed to introduce protection against exceeding the anode current of the first TWT, the second protection device 11 (Fig 3), defining the value of the anode current of the first TWT, as the difference between the cathode and collector current values of the first TWT.

To measure the cathodic and collector current of the first TWT 2 along the cathodic and collector current circuits of the first TWT 2, the first Hall sensor 20 and the second Hall sensor 19 are installed in the transmitter. The first Hall sensor 20 and the second Hall sensor 19 are used as current sensors. The most important advantage of such sensors is the complete absence of electrical connection with the measured circuit, the convenience of contactless operation (complete absence of mechanical wear) and ease of use make them indispensable in this case.

The output voltage of the sensor is proportional to the induction of the magnetic field surrounding the conductor. The magnitude of the induction, in turn, is proportional to the current. (A. Abrikosov, Fundamentals of the Theory of Metals - M., Science, Main Edition of Physics and Mathematics, 1987, p.520, Ashcroft N., Mermin N. Solid State Physics, - M., Mir, 1979 , "Hall Effect Sensing and Application Book" (Honeywell MICRO SWITCH Sensing and Control. 1999r.).

The output signals from the first outputs of the first 20 and second 19 current sensors are supplied to the seventh and eighth inputs of the first protection device 10 and further to the cascades of the protection circuit: a subtractor, a comparator, waiting for the multivibrator. From the subtractor, a voltage proportional to the difference between the cathode and collector currents of the TWT 2 is supplied to the comparator, where it is compared with a predetermined threshold voltage. If the output signal of the subtractor exceeds the voltage of the threshold of the comparator previously set, a signal appears at the output of the comparator, which then goes to the standby multivibrator. The waiting multivibrator generates a FORBID pulse, which from the third output of the first protection device 10 is supplied to the second input of the modulator 6, which, according to the FORBID signal, supplies a blocking voltage to the control electrode of the first TWT 2, thereby preventing the failure of the first TWT 2.

For the first protection device 10, the first 20 and second 19 Hall sensors CLSM-50LA are used, the subtractor is assembled on the 140UD26A chip, the comparator on the AD8561ARZ chip, waiting for the multivibrator on the 533AGZ chip.

A three-phase AC voltage of 200 V, 400 Hz from the contacts of the transmitter connector 24, 25, 26 is fed to the 3, 2, 1 inputs of a three-phase high-voltage transformer 13 respectively and then to a high-voltage rectifier 15. Control voltage for the anode voltage stabilizer, collector voltage for traveling lamps the wave forms a high-voltage rectifier 15. The collector voltage for the first TWT 2 after filtering on the second filter 17 and through the first current sensor 20 enters the sixth input of the first TWT 2, and the collector voltage eniya the second TWT 4 after filtering at the second filter 17 arrive at the 5, 6 inputs a second TWT 4.

High-voltage rectifier 15 consists of several rectifiers on semiconductor diodes, which rectify AC voltage and smoothing filters that reduce ripple rectified voltage. The first 14 and second 18 dividers consist of a set of resistors. (Nayvelt G.S., Power sources of REA - M., Radio and communication, 1986, p. 121-208; edited by M. Skolnik; Guide to radar vol. p.118-127; V.N. Gaevich Radio Engineering, M., Military Publishing House of the Ministry of Defense of the USSR Union, p.204-218).

The values of the anode voltage, the voltage of the control electrode, the locking voltage across the control electrode of the traveling wave lamp are specified in the technical specifications for the traveling wave lamp in the form of a voltage range. For a specific traveling wave lamp, individual values are indicated in the passport, which must be set in the transmitter with high accuracy. Therefore, the stabilizers of the anode voltage, the voltage of the control electrode, the locking voltage across the control electrode of the traveling wave lamp are built on the principle of a compensation voltage stabilizer and allow you to get an adjustable, stabilized voltage relative to its body. (J. Car Design and manufacture of electronic equipment, M., Mir, 1980, p. 199-319; edited by M. Skolnik; Guide to radar, vol. 3, M., Soviet radio, 1979, p. 118 -127).

The anode voltage stabilizer consists of a high-voltage rectifier 15, a second filter 17, a first divider 14, a DC amplifier 9, traveling wave tubes 2, 4, and a lamp VL 16. The lamp VL 16 is a regulating element in the anode voltage stabilizer.

The voltage stabilizers of the control electrode, the locking voltage across the control electrode of the traveling wave lamp are in the modulator 6.

The power source 7 performs the formation of all the supply voltages for the DC amplifier 9, lamp VL 16, the first protection device 10 (Naivelt G.S., Power sources REA - M., Radio and communications, 1986, p. 121-208, Kostikov V.G. Power sources of high voltage REA, - M., Radio and communications, 1986, p. 5-125, Minaev M.I. 40-93, edited by Skolnik M. Handbook of Radar, vol. 3, M., Soviet Radio, 1979, pp. 7-127).

In the output path 5 there is a switch, which, by the ANT ON command (turning on the antenna), supplies the transmitter output signal to the antenna. At the stage of setting up, checking, operating in the terrestrial conditions of the transmitter, the ANT ON command is absent, the switch supplies the output signal to the antenna equivalent located in the output path 5. The ANT ON command is sent from the radar to the contact of the ANT ON 30 input signal connector, then to the fourth input of the UC . Depending on this command, the UCM generates the ANT ON or EKV ON commands (including the antenna equivalent), which from the tenth and eleventh outputs of the UUK come to the contact of the output signal terminal of the ANT ON 48 and the contact of the output signal terminal of EKV ON 49, respectively, in the radar, for control. From the twenty-first output of the CAM, the ANT ON signal is supplied to the fourth input of the output path 5 for controlling the switch.

The command to contact the input signal connector Start 31 (missile launch) is received from the radar to the fifth input of the CC. By this command, the READY signal is blocked in the AMC, which from the second output of the AMC is supplied to the terminal of the output signal READY 40. The READY signal is issued when the liquid cooling system and the supercharger of the transmitter are in good condition. On the contact of the input signal connector SBP 32 with radar comes the signal blocking the transmitter, which blocks the start pulse of the transmitter during operation of the receiver. The transmitter issues a FAILURE signal from the first output of the CAM to the contact of the output signal connector FUNCTION 39 in the radar if it is in good condition: liquid cooling systems, pressurization and high voltage switching commands on the input signal connector pin + 27V ON VN 37.

The command from the radar arriving at the contact of the input signal + 27V REF. 38, it is fed to the sixth input of modulator 6. In modulator 6, by this command and in the presence of a transmitter start pulse, the formation of a modulator pulse for the control electrodes of both TWTs is allowed, depending on the mode, the TWT is opened for the duration of the frequency converter, the input microwave signal is amplified and fed to transmitter output.

Some of the elements of the transmitter are located in a pressurized chamber. Elements in the pressurized area are cooled by fans. The transmitter provides a liquid cooling system for cooling a high voltage transformer, a set of TWT, intermediate and output paths.

Obtaining the required technical parameters of the transmitter is due to:

- the use of a multi-mode microwave power amplifier in the three-centimeter wavelength range U52252, consisting of two TWTs, providing a large output pulse power, low noise level, a significant attenuation of the output signal level in the pause between pulses;

- protection of the first TWT by exceeding the anode current;

- setting the optimal input power on both TWTs at carrier frequencies;

- ensuring coordination of both TWTs on entry and exit;

- overcurrent protection for three-phase alternating voltage 200V, 400 Hz;

Based on the proposed technical solution, prototypes of the transmitter were manufactured. The transmitter provides an output pulse power in the ranged mode (P5) of up to 16,000 watts, in the melee mode (P1) of not less than 2500 watts, in the RP mode of 1600 watts, the spectral density of amplitude noise (in the 1 Hz band) at a detuning of 0, 3-35 kHz is 110 dB. Technical parameters are confirmed by the positive results of preliminary and interagency tests.

Claims (1)

A multi-mode microwave transmitter containing a power source and a modulator, characterized in that it includes an input path, a first traveling wave lamp (TWT), an intermediate path, a second TWT, an output path, a control and monitoring device (UCF), a direct current amplifier (CTF), first protection device, second protection device, first filter, three-phase high-voltage transformer, first divider, high-voltage rectifier, VL lamp, second filter, second divider, second current sensor, first current sensor, microwave input signal waveguide W1, the waveguide of the output microwave signal W2, the waveguide of the output microwave signal for adjusting the local oscillator of the guidance system of the radio head (CWG) W3, the contact of the connector for supplying the input AC power supply voltage of phase A, the contact of the connector for supplying the input AC power voltage of phase B, the contact of the connector for supplying the input AC phase C supply voltage, terminal of the input pulse of the transmitter start trigger, terminal of the input signal terminal mode P1, terminal terminal of the input signal RP mode, terminal terminal Signal Antenna is ON (ON ANT), START input signal connector pin, TRANSMISSION LOCK STROBE (SBP) input connector pin, frequency code input connector pin, phase A input common voltage input connector pin, phase B input common voltage input connector pin, phase B input common voltage connector pin, input connector pin AC C phase common voltage, input connector pin HIGH VOLTAGE ON (ON HV), input signal connector pin + 27B DELAYED (+ 27B REF.), IC output signal connector pin AUTO, output connector pin READY, output connector pin HIGH VOLTAGE POWER SUPPLY (FIX VIP), output signal pin Fault 1, output connector pin 2 Fault 2, output signal connector FIRST SPACE 2. .), the output connector pin is AVAILABLE Rye, the output connector pin is AVAILABLE P1, the output connector pin is AVAILABLE P5, the output connector pin is ON ANTENNA (ON. ANT.), The terminal connector of the output signal EQUIVALENT is ON (EQ. ON), while the waveguide for supplying the input microwave signal W1 is connected to the first input of the input path, the second input of the input path is connected to the twentieth input of the CID, the output of the input path is connected to the first input of the first TWT, the output of the first TWT is connected to the input of the intermediate path, the first output of the intermediate path is connected to the waveguide of the output microwave signal to fine-tune the local oscillator WGSN W3, the second output of the intermediate path is connected to the eleventh input of the CID, the third output is the exact path is connected to the first input of the second TWT, the output of the second TWT is connected to the input of the output path, the first output of the output path is connected to the tenth input of the CAM, the second output of the output path is connected to the ninth input of the CAM, the third output of the output path is connected to the waveguide of the output microwave signal W2, the second input of the first TWT is connected to the first output of the modulator, the third input of the first TWT is connected to the second output of the modulator, the fourth input of the first TWT is connected to the third output of the modulator, the fifth input of the first TWT is connected to the fourth output modulator, the sixth input of the first TWT is connected to the second output of the first current sensor, the second input of the second TWT is connected to the fifth output of the modulator, the third input of the second TWT is connected to the sixth output of the modulator, the fourth input of the second TWT is connected to the seventh output of the modulator, the fifth input of the second TWT is connected to the sixth output of the second filter, the first input of the modulator is connected to the second output of the second current sensor, the second input of the modulator is connected to the third output of the first protection device, the third input of the modulator is connected to the seventeenth output of the CAM, the fourth input of the modulator is connected to the eighteenth output of the CAM, the fifth input of the modulator is connected to the nineteenth output of the CAM, the sixth input of the modulator is connected to the terminal of the input signal + 27V REF., the seventh input of the modulator is connected to the third output of the second protection device and the first input of the power source, the eighth input the modulator is connected to the second output of the second protection device and the second input of the power source, the ninth input of the modulator is connected to the first output of the second protection device and the third input of the power source, p the first input of the second protective device is connected to the terminal connector of the input variable common voltage supply of phase A, the second input of the second protective device is connected to the terminal connector of the input variable common voltage of phase B, the third input of the second protection device is connected to the terminal connector of the input common phase C voltage , the fourth input of the second protection device is connected to the terminal of the input signal + 27V ON. VN, the fourth output of the second protection device is connected to the fourth input of the first protection device, the fifth output of the second protection device is connected to the eighth input of the CAM, the first input of the CAM is connected to the terminal of the input pulse of the transmitter start-up, the second input of the CID is connected to the terminal of the input signal of the P1 mode, the third input of the CID is connected to the terminal of the input signal connector RP mode, the fourth input of the CID is connected to the terminal of the input signal ANT. ON, the fifth input of the CID is connected to the terminal of the input signal connector START, the sixth input of the CID is connected to the terminal of the input signal of the UPS, the seventh input of the CID is connected to the terminal of the input signal of the frequency code, the twelfth input of the CID is connected to the fifth output of the first protection device, the first output The CID is connected to the pin of the output signal connector CORRECTNESS, the second output of the CID is connected to the pin of the connector of the output signal READY, the third output of the CID is connected to the pin of the output signal connector VIRTUALITY, fourth output of the UD K is connected to the output signal connector pin FUNCTION 1, the fifth CID output is connected to the output signal connector pin 2, the sixth CID output is connected to the output signal connector TRACK Fault Σ, the seventh CMC output is connected to the output signal connector pin EXISTENCE P ACC output is connected to the output signal connector pin AVAILABILITY P1, the 9th ACC output is connected to the output signal connector pin AVAILABILITY P5, tenth ACC output is connected to the output signal connector pin ON. ANT., The eleventh ACC output is connected to the terminal of the output signal of the ECV. ON, the sixteenth ACC output is connected to the third input of the first protection device, the fifteenth ACC output is connected to the second input of the first protection device, the fourteenth ACC output is connected to the first input of the first protection device, the thirteenth ACC output is connected to the fourth input of the protection device, the twelfth output of the ACC is connected to the third input of the UPT, the twentieth output of the ACC is connected to the second input of the input path, the twenty-first output of the ACC is connected to the fourth input of the output path, the first input of the ACC is connected to the output of the second divider, the second input of the AC T is connected to the third output of the second filter, the fifth input of the CTF is connected to the first output of the first protection device, the sixth input of the CTF is connected to the second output of the first protection device, the seventh input of the CTF is connected to the fourth output of the first protection device, the eighth input of the CTF is connected to the second output of the power source , the ninth input of the OTT is connected to the third output of the power source, the tenth input of the OTT is connected to the fourth output of the power source, the eleventh input of the OTT is connected to the housing, the first output of the OTT is connected to the fourth input of the lamp VL , the second output of the CTD is connected to the sixth input of the first protection device, the fifth input of the first protection device is connected to the first output of the power source, the seventh input of the first protection device is connected to the first output of the first current sensor, the eighth input of the first protection device is connected to the first output of the second current sensor, the ninth input of the first protection device is connected to the second output of the second filter, the fifth output of the power source is connected to the third input of the lamp VL, the sixth output of the power source is connected to the second input of the lamp VL, the seventh output of the power source is connected to the fifth input of the VL lamp, the contact of the connector for supplying the input power AC voltage of phase A is connected to the third input of the three-phase high voltage transformer and the first input of the first filter, the contact of the connector for supplying the input power of AC voltage of the phase B is connected to the second the input of the three-phase high-voltage transformer and with the second input of the first filter, the contact of the connector for supplying the input power AC voltage supply phase C is connected from the first the input of the three-phase high-voltage transformer and with the third input of the first filter, the fourth input of the first filter is connected to the housing, the output of the three-phase high-voltage transformer is connected to the input of the high-voltage rectifier, the output of the high-voltage rectifier is connected to the input of the second filter, the first output of the second filter is connected to the input of the first divider, the output of the first the divider is connected to the first input of the lamp VL, the fourth output of the second filter is connected to the input of the first current sensor, the fifth output of the second filter is connected to estym TWT input of second, seventh output of the second filter is connected to the input of the second divider and the input of the second current sensor, the seventh input of the first and seventh TWT TWT second input connected to the housing.