RU176921U1 - Transmitter with frequency synthesizer - Google Patents

Abstract

The utility model relates to the field of radio engineering, in particular to microwave technology and is intended to operate as part of a complex of an active radar system as a transmitting link. The technical result of the proposed utility model is to increase the stability of the carrier frequencies of a three-channel transmitting device. The result is achieved in that the device transmitting with the frequency synthesizer contains a device for controlling the antenna matching device and a power control circuit (ACS and SCM), a power and control board, as well as three channels spaced apart in frequency. In this case, the first channel includes a self-oscillator, a first valve, a first amplifier, a second amplifier, a first filter, a first circulator connected to the first load, the first board of the antenna matching device (ACS). The second and third channels contain a second valve, a third amplifier, a second circulator connected to the second load, a fourth amplifier, a fifth amplifier, a third circulator connected to a third load, and a detector assembly, a second filter, a second antenna matching device (ACS) , a frequency synthesizer, a first two-way amplifier and a second two-way amplifier.

Description

The utility model relates to the field of radio engineering, in particular to microwave technology and is intended to operate as part of a complex of an active radar system as a transmitting link.

The pulse transmitter is known from the prior art (patent for the invention of the Russian Federation No. 2356164, published May 20, 2009, IPC: Н04В 1/02 (2006.01). The pulse transmitter consists of three channels spaced apart in frequency. The first channel includes a first pulse modulator, a first oscillator the first valve, the second power amplifier, the third pulse modulator, the first directional power coupler, the sixth power amplifier, the first power control device, the seventh power amplifier, the second power control device, the first power addition circuit , a second circulator, a first filter, a first antenna switch, a sixth power control device.

The second and third channels contain a second oscillator, a second pulse modulator, a first power amplifier, a first circulator, a fourth power amplifier, a fourth pulse modulator, a fifth pulse modulator, a frequency separation device, a second valve, a third power amplifier, a third valve, a fifth power amplifier, and a second directional power coupler, eighth power amplifier, third power control device, ninth power amplifier, fourth power control device, tenth power amplifier spacers, fifth power control device, first additional filter chain, second additional filter chain, third additional filter chain, fourth additional filter chain, fifth additional filter chain, sixth additional filter chain, seventh additional filter chain, eighth additional filter chain, ninth additional filter a circuit, a tenth additional filter circuit, a second power addition circuit, a second filter, a third circulator, a second antenna re switch, seventh power control device, eighth power control device. And also, the IP includes the first energy storage device, the second energy storage device, a temperature controller, a health signal generation circuit, a control circuit.

The disadvantages of this pulse transmitter include low reliability and significant weight and size characteristics of the device due to the presence of a large number of incoming units, low stability of carrier frequencies.

The closest in technical essence and the achieved result to the claimed device is a transmitting device (patent for the invention of the Russian Federation No. 2586570, published 06/10/2016, IPC: Н03В 5/18 (2006.01), which is selected as a prototype. The transmitting device consists of three Frequency spaced channels: The first channel includes a first oscillator, a first valve, a first amplifier, a second amplifier, a first filter, a first circulator, a first load, and a first ACS board.

The second and third channels contain a reference signal amplifier with a modulator, a fourth circulator, a sixth amplifier, a frequency separation device, a second oscillator, a second valve, a third amplifier, a second circulator, a second load, a fourth amplifier, a fifth amplifier, a third circulator, a third load, and a second filter, second ACS board, detector assembly. And also the transmitting device contains an ACS and SCM control device, a power and control board.

The disadvantages of this transmitting device include the low stability of the carrier frequencies, which is ensured by the selection of the temperature coefficient (TKE) of the material capacity and mechanical adjustment, as a result, low reliability.

The technical problem solved by the creation of this technical solution is the lack of stability of the carrier frequencies in a three-channel transmitting device.

The technical result of the proposed utility model is to increase the stability of the carrier frequencies of a three-channel transmitting device by introducing a frequency synthesizer.

The technical result is achieved by the fact that the transmitting device with the frequency synthesizer contains a control device for an antenna matching device and a power control circuit (ACS and SCM) and a power and control board, as well as three channels spaced apart in frequency. Moreover, the first channel includes a serially connected oscillator, a first valve, a first amplifier, the input of which is connected to the output of the power and control board, a second amplifier, a first filter, a first circulator connected to the first load, the first board of the antenna matching device (ACS). The second and third channels contain a second gate, a third amplifier, a second circulator connected to a second load, a fourth amplifier, a fifth amplifier, a third circulator connected to a third load, and a detector assembly, the input of which is connected to the output of the fifth amplifier, and the output it is connected to the input of the ACS and SCM control device, a second filter, the input of which is connected to the output of the third circulator, and its output is connected to the input of the second ACS board, the inputs of which are connected to the outputs of the control detecting ACS and SCM, the other output of which is connected to the input of the first card ACS, and third outputs are connected to inputs of the oscillator. Moreover, the transmitting device differs from the prototype in that the second and third channels additionally include a series-connected frequency synthesizer, a first two-way amplifier and a second two-way amplifier.

The first input of the frequency synthesizer, the inputs of the first two-way amplifier, the second two-way amplifier, interconnected inputs of the third and fourth amplifiers are connected to the outputs of the power and control board.

The second input of the frequency synthesizer receives a signal of the reference carrier frequency f2.

The essence of the utility model is illustrated by the drawings of FIG. 1 - FIG. 2.

In FIG. 1 is a structural diagram of a transmitting device with a frequency synthesizer. In FIG. 2 presents a table of comparative characteristics of the prototype and the proposed device transmitting with a frequency synthesizer.

A transmitting device with a frequency synthesizer contains the following blocks and elements:

1 - control device antenna matching device and power control circuit (ACS and SCM),

2 - power and control board,

3 - auto generator,

4 - the first valve

5 - the first amplifier

6 - second amplifier

7 - the first filter,

8 - the first circulator,

9 - the first load

10 - the first board of the antenna matching device (ACS),

11 - the second valve,

12 is the third amplifier,

13 - second circulator

14 - the second load,

15 is the fourth amplifier

16 - fifth amplifier

17 - the third circulator

18 - the third load,

19 is a detector assembly,

20 is a second filter,

21 - the second board of the antenna matching device (ACS),

22 - frequency synthesizer,

23 - the first two-way amplifier,

24 - the second two-way amplifier.

The frequency synthesizer allows the device transmitting with the frequency synthesizer with high stability and carrier frequency switching speed, increased reliability, with the ability to operate at three spaced frequencies with high speed.

When one of the three start signals is fed to input 1 of the frequency synthesizer, Y- _f1 or Y- _f2 or Y- _f3 from the power and control board, the frequency synthesizer produces one of three frequencies: f2, f3 or f4.

Two-band power amplifiers are made on broadband semiconductor devices, they allow working in two frequency channels.

A transmitting device with a frequency synthesizer includes an ACS and SCM 1 control device, a power and control board 2, and three channels spaced apart in frequency.

The first channel contains a serially connected oscillator 3, a first valve 4, a first amplifier 5, the input of which is connected to the output of the power and control board 2, a second amplifier 6, a first filter 7, a first circulator 8 connected to the first load 9, and a first ACS 10.

The second and third channels comprise a second valve 11 connected in series, a third amplifier 12, a second circulator 13 connected to a second load 14, a fourth amplifier 15, a fifth amplifier 16, a third circulator 17 connected to a third load 18, and a detector assembly 19, input which is connected to the output of the fifth amplifier 16, and its output is connected to the input of the control system of ACS and SCM 1, the second filter 20, the input of which is connected to the output of the third circulator 17, and its output is connected to the input of the second board of the ACS 21, the inputs of which are connected to strokes of the control system of the ACS and SCM 1, the other output of which is connected to the input of the first board of the ACS 10, and the third outputs are connected to the inputs of the oscillator 3. In this case, the second and third channels include a series-connected frequency synthesizer 22, the first two-way amplifier 23 and the second two-way amplifier 24 Moreover, the first input of the frequency synthesizer 22, the inputs of the first two-way amplifier 23, the second two-way amplifier 24, interconnected inputs of the third amplifier 12 and the fourth amplifier 15 are connected to the outputs of the power board and control 2. 2. At the second input of the frequency synthesizer, a signal of the reference carrier frequency f2 is received.

The transmitting device with a frequency synthesizer includes three frequency channels and provides operation in three frequency ranges, each of which performs a specific function.

The power and control board includes: storage capacitors and pulse modulators for power amplifiers and thermal heating circuits.

The control system of the ACS and SCM is designed to generate health signals by the presence of power when operating in the "Transmission" mode, as well as to control the first ACS board 10, the second ACS board 21, to switch between the first, second and third antennas in the "Transmission" modes or "Reception".

Circulators and valves are used to provide isolation between cascades.

Filters suppress spurious components in the spectrum of the transmitted signal, made by microstrip technology.

In this scheme, a decimeter wave frequency synthesizer is used, which allows for operation at three spaced frequencies. The frequency synthesizer has high speed, high stability and speed switching carrier frequencies.

A transmitting device with a frequency synthesizer operates as follows. The device is controlled from a central computing device (CVC). The transmitting device with the frequency synthesizer operates in three frequency channels, each of them at a specific carrier frequency: the first channel at a carrier frequency of ƒ1, the second channel at a carrier frequency of ƒ2, the third channel at carrier frequencies на3 and ƒ4. The frequency spacing between the channels is 30-50%. The spacing of the carrier frequencies in the third channel is 0.7%.

A transmitting device with a frequency synthesizer operates on radiation at a particular moment in time in only one of the three channels. The third channel operates on radiation at a particular moment in time only on one of the carrier frequencies ƒ3 or ƒ4.

In the first channel, the signal of the carrier frequency рует1 forms the oscillator 3. The signal of the reference carrier frequency во2 in the second channel is fed to the second input of the frequency synthesizer 22 from an external device. In the third channel, a carrier frequency signal ƒ3 or ƒ4 forms a frequency synthesizer 22.

The pulse mode of operation of the device transmitting with the frequency synthesizer in the first channel is carried out by applying a supply voltage pulse at a certain point in time: from the control system of the ACS and SCM 1 to the oscillator 3 and the first board of the ACS 10, from the power and control board 2 to the first amplifier 5 In the second and third channels: from the control system of the ACS and SCM 1 - to the first board of the control system 10 and the second board of the control system 21, from the power and control board 2 - to the first input of the frequency synthesizer 22, to the first and second two-way amplifiers 23, 24, to the third amplifier b 12 and the fourth amplifier 15.

In the "Transmission" mode, the first channel has one radiation output through the first ACS board 10 and operates on the first antenna.

In the "Transmission" mode, the second and third channels have two radiation outputs through the second ACS board 21 and operate on the second and third antennas.

The “Receive” and “Transfer” modes in the device are controlled by the CVC. In the "Receive" mode, the first channel receives a signal from the first antenna and feeds it to the first receiver through the first ACS board 10. In the "Reception" mode, the second and third channels simultaneously receive a signal from the second antenna and the third antenna, and then, through the second board, the ACS 21 are fed, respectively, to the second receiver and the third receiver. The first ACS board 10 and the second ACS board 21 are controlled by the control system of the ACS and SCM 1, which, in turn, controls the CVD by control pulses.

The device is made on semiconductor devices using microstrip technology. The matching circuits are built on elements with distributed parameters, since at ultrahigh frequencies the inductances and capacitances of the resonant circuits become comparable to stray inductances and capacitors.

When a start pulse Yzap ƒ1 arrives at the control system of the ACS and SCM 1, the first channel starts working and the signal passes to the oscillator 3. From the output of the oscillator 3, the pulse through the first valve 4 is fed to the first amplifier 5 for power amplification. The power of the microwave semiconductor devices is limited. The required power of the device on the first channel exceeds the power of the semiconductor device. Therefore, the signal is then fed to the second amplifier 6 for amplification in power, then to the first filter 7, where the stray components in the spectrum of the transmitted signal are suppressed. Next, the signal through the first circulator 8 is fed to the first circuit board of the ACS 10, in the "Transfer" mode - to the first antenna.

When applying power and a reference signal to the frequency synthesizer 22 and the presence of a certain signal on the power and control board 2, the second or third frequency channels begin to work. In the frequency synthesizer 22, at this moment, the carrier frequencies ƒ3 or ƒ4 of the third channel are already formed, and the carrier frequency ƒ2 is supplied to the second input of the frequency synthesizer 22 from an external device. Thus, after applying voltage to the frequency synthesizer 22, three carrier frequencies ƒ2, ƒ3, ƒ4 are formed.

When the frequency synthesizer receives 22 start pulses Yzap ƒ2, he gives a radio pulse with a frequency of радио2. From the output of the frequency synthesizer 22, the radio pulse is transmitted to the first two-way amplifier 23, then to the second two-way amplifier 24, the signal is amplified by power and, through the second valve 11, is fed to the input of the third amplifier 12 for power gain. For further power gain from the output of the third amplifier 12 through the second circulator 13 is fed to the input of the fourth amplifier 15. The required power of the device on the second channel exceeds the power of one semiconductor device. Therefore, then the signal passes to the fifth amplifier 16. Next, the signal through the third circulator 17 enters the second filter 20, after suppressing spurious components in the spectrum of the transmitted signal passes to the second ICS board 21. After that, depending on the control signals received from the ACS control device and SCM 1, the signal enters the second or third antenna.

When the frequency synthesizer receives 22 start pulses Yzap ƒ3, it generates a radio pulse with a frequency of ƒ3. From the output of the frequency synthesizer 22, the radio pulse through the first and second two-way amplifiers 23, 24 is fed to the second gate 11 and then in stages, including blocks 12, 13, 15, 16, 17, 20, 21, processing that is similar to the processing of the radio pulse of the second channel passes.

When the frequency synthesizer receives 22 start pulses Yzap ƒ4, it gives out a radio pulse with a frequency of ƒ4. From the output of the frequency synthesizer 22, the radio pulse through the first and second two-way amplifiers 23, 24 is fed to the second gate 11 and then in stages, including blocks 12, 13, 15, 16, 17, 20, 21, processing is carried out similar to the processing of the radio pulse of the second channel.

In the proposed circuit of the device transmitting with a frequency synthesizer, high stability of the carrier frequencies is achieved by introducing a frequency synthesizer, which, after applying a supply voltage to it, generates two frequencies, the third frequency comes to it from an external device, and when a certain start pulse is applied to the frequency synthesizer on a two-way amplifier, the desired frequency.

Comparative characteristics of the claimed transmitting device with a frequency synthesizer and prototype are presented in the table of FIG. 2.

Thus, the proposed technical solution allows for high stability of the carrier frequencies of the transmitting device operating in three frequency channels, which is achieved using a frequency synthesizer in the second and third channels.

Claims (1)

A device transmitting with a frequency synthesizer, comprising a control device for an antenna matching device and a power control circuit (ACS and SCM) (1) and a power and control board (2), as well as three channels spaced in frequency, the first channel including a series-connected oscillator ( 3), the first valve (4), the first amplifier (5), the input of which is connected to the output of the power and control board, the second amplifier (6), the first filter (7), the first circulator (8) connected to the first load (9) , the first board of the antenna matching device (AC ) (10), the second and third channels contain a second valve (11) connected in series, a third amplifier (12), a second circulator (13) connected to a second load (14), a fourth amplifier (15), a fifth amplifier (16), the third circulator (17) connected to the third load (18), as well as the detector assembly (19), the input of which is connected to the output of the fifth amplifier, and its output is connected to the input of the control system of the ACS and SCM, the second filter (20), the input of which connected to the output of the third circulator, and the output of the second filter is connected to the input of the second antenna-co speaker device (ACS) (21), the inputs of which are connected to the outputs of the ACS and SCM control device, the other output of which is connected to the input of the first ACS board, and the third outputs are connected to the inputs of the oscillator, characterized in that the second and third channels additionally include series-connected frequency synthesizer (22), the first two-way amplifier (23) and the second two-way amplifier (24), while the first input of the frequency synthesizer, the inputs of the first two-way amplifier, the second two-way amplifier, interconnected inputs of This and the fourth amplifiers are connected to the outputs of the power and control board.

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