RU84654U1 - DIGITAL MICROWAVE RECEIVER WITH HIGH SECURITY - Google Patents

Abstract

Digital stealth digital microwave transceiver comprising a serially connected valve and power amplifier, serially connected a third band-pass filter, a circulator and a fourth band-pass filter, an antenna whose input-output is connected to a second input-output of a circulator, a fifth-band filter and a first step-down mixer are connected in series connected in series with a boost mixer and a second band-pass filter, a first frequency synthesizer, the first output of which is connected to the second, get home, up-mixer input, and the second output connected to the second heterodyne, input of the first down-mixer, reference oscillator, transmitter intermediate frequency amplifier, first band-pass filter, low-noise amplifier, sixth band-pass filter, receiver first intermediate-frequency amplifier, second step-down mixer, seventh a band-pass filter, an amplifier of the second intermediate frequency of the receiver, characterized in that the first input converter is introduced in series, the input of which is the first the input of the device, the multiplexer and the first differential amplifier; serially connected demodulator, demultiplexer and a first output converter, the output of which is the second output of the device; serially connected frequency multiplier and quadrature modulator; clock generator; connected in series to a second input converter, the input of which is the third input of the device, and a second differential amplifier; second output converter, the output of which is the third

Description

The proposed utility model relates to the field of radio communications and can be used to organize digital radio-relay communication lines.

Known transceivers used for radio relay communications, for example, the Radan-2 system (Mordukhovich LG, Stepanov AP Radio communication systems. M., Radio and communications, 1987). However, these transceivers have high power consumption and large dimensions.

Of the known transceivers closest in technical essence to the proposed device is the "Millimeter-wave transceiver" according to the patent for utility model No. 74535 of 02.20.2008, adopted as a prototype.

Figure 1 shows the functional diagram of the device of the prototype, where the following notation is introduced:

35 - corrector amplitude-frequency characteristics;

36 - second controlled attenuator;

37 - the first step-up mixer;

10 - the first band-pass filter;

9 - amplifier of the second intermediate frequency of the transmitter;

16 - circulator;

17 - antenna;

12 - the first band-pass waveguide filter;

21 is a first step-down mixer;

40 - preliminary power amplifier;

13 - the second valve;

19 - low noise receiver amplifier;

46 - the first controlled attenuator;

11 - second boost mixer;

23 - the first amplifier of the first intermediate frequency of the receiver;

6 - reference generator;

48 - video amplifier;

49 - peak detector;

50 - algebraic adder;

51 - DC voltage generator;

32 - frequency synthesizer;

53 - block Association-separation;

52 - output amplifier;

41 - the third valve;

43 - the fifth valve;

20 - fourth band-pass waveguide filter;

14 - power amplifier;

15 - the third band-pass waveguide filter;

44 - the third controlled attenuator;

45 - the second amplifier of the first intermediate frequency of the receiver;

25 - second band-pass filter;

54 - block reference frequencies;

24 - second step-down mixer;

26 - amplifier of the second intermediate frequency of the receiver;

22 - the third band-pass filter;

42 - the fourth valve;

47 - amplitude detector;

18 - second band-pass waveguide filter;

38 - low-noise amplifier of the transmitter;

39 - the first valve.

The prototype device contains a series-connected corrector of the amplitude-frequency characteristic 35, a second controlled attenuator 36, a first step-up mixer 37, a first band-pass filter 10, an amplifier of the second intermediate frequency of the transmitter 9, a second step-up mixer 11, a first band-waveguide filter 12, a low-noise transmitter amplifier 38 , the first valve 39, the preliminary power amplifier 40, the second valve 13, the power amplifier 14, the third valve 41, the third band-pass waveguide filter 15 and the circulator 16, the second input-output one of which is connected to the antenna 17; connected in series with a second band-pass waveguide filter 18, a fourth gate 42, a low-noise amplifier of the receiver 19, a fifth gate 43, a fourth band-waveguide filter 20, a first step-down mixer 21, a first amplifier of a first intermediate frequency of a receiver 23, a third controlled attenuator 44, a second amplifier of a first intermediate frequency receiver 45, a second band-pass filter 25, a first controllable attenuator 46, a second step-down mixer 24, a second intermediate frequency amplifier of the receiver 26, a third band-pass filter 22 and an output Noise Amplifier 52; connected in series with an amplitude detector 47, a video amplifier 48, a peak detector 49, and an algebraic adder 50. In addition, it contains a constant voltage generator 51, a combining-separation unit 53, a reference frequency unit 54, a reference generator 6 and a frequency synthesizer 32, the second output of which is connected to the second heterodyne input of the second boost mixer 11, the first output of the frequency synthesizer 32 is connected to the second, heterodyne input of the first step-down mixer 21, the second, reference input to the first output of the reference generator 6, and the first th, control input - with the third output of the combining-separation unit 53, the second output of which is connected to the second, controlling input of the second controlled attenuator 36; the second input of the combining-separation unit 53 is connected to the output of the output amplifier 52, the first output is connected to the input of the corrector of the amplitude-frequency characteristic 35, and the input-output of the combining-separation unit 53 is the input-output of the device. The second output of the reference generator 6 is connected to the input of the block of reference frequencies 54, the first output of which is connected to the second heterodyne input of the second step-down mixer 24, and the second output is connected to the second, heterodyne input of the first step-up mixer 37; the second output of the third bandpass filter 22 is connected to the input of the amplitude detector 47, the output of the constant voltage generator 51 is connected to the second input of the algebraic adder 50, the output of which is connected to the second, control inputs of the first 46 and third 44 controlled attenuators, the output of the circulator 16 is connected to the input of the second bandpass waveguide filter 18.

The prototype device operates as follows.

From the input of the device, the signal of the first intermediate transmission frequency is fed through the combining-separation unit 53 to the input of the corrector of the amplitude-frequency characteristic 35, intended to equalize the amplitude-frequency characteristic of the transmission path. Next, the signal through the second attenuator 36 is fed to the first, signal input of the first boost mixer 37, to the second, heterodyne input of which a fixed frequency signal from the block of reference frequencies 54 is supplied.

The signal of the second intermediate frequency from the output of the first boost mixer 37 is filtered by the first band-pass filter 10, amplified by the amplifier of the second intermediate frequency of the transmitter 9 and fed to the first, signal input of the second boost mixer 11, to the second, heterodyne input of which a signal from the frequency synthesizer 32 is supplied. The output frequency the signal of the frequency synthesizer 32 is tuned by the control signal from the combining-separation unit 53 and sets the frequency of the output signal of the transmitter radiated into the air.

The signal from the output of the second boost mixer 11 is filtered by a second band-pass waveguide filter 12 and sequentially amplified by a low-noise amplifier of the transmitter 38, a preliminary power amplifier 40, and a power amplifier 14. The distribution of the gain between these three amplifiers provides the maximum linearity of the amplitude-frequency characteristic of the transmission path. From the output of the power amplifier 14, the signal through the third gate 41, the third band-pass waveguide filter 15 and the circulator 16 is fed to the input of the antenna 17 and is broadcast.

The first 39, second 13 and third 41 gates are designed to match the input and output impedances of blocks 38, 40 and 14. The third band-pass waveguide filter 15 is designed to finally filter the output signal of the transmitter and reduce the noise level of the transmitter passing through the circulator 16 to the input of the receiver. The circulator 16 is used to separate the signals of the transmitter and receiver connected to a common antenna 17.

The signal received from the ether by the antenna 17 through the circulator 16, the second band-pass waveguide filter 18 and the fourth gate 42 is fed to the input of a low-noise amplifier of the receiver 19, which determines the sensitivity of the receiver. In this case, the second band-pass waveguide filter 18 provides the selectivity of the receiver along the mirror channel.

From the output of the low-noise amplifier of the receiver 19, the signal through the fifth gate 43 and the fourth band-pass waveguide filter 20 is fed to the first, signal input of the first step-down mixer 21, to the second, heterodyne input of which the local oscillator signal from the frequency synthesizer 32 is supplied. The frequency of the local oscillator signal from the frequency synthesizer 32 is set on the control signal from the block Association-separation 53.

The fourth 42 and fifth 43 gates are designed to match the input and output impedances of the low-noise amplifier of the receiver 19 with the impedances of the second 18 and fourth 20 band-pass waveguide filters. The fourth band-pass waveguide filter 20 reduces the noise level at the frequency of the mirror channel.

From the output of the first step-down mixer 21, the signal through the first amplifier of the first intermediate frequency of the receiver 23, the third attenuator 44, the second amplifier of the first intermediate frequency of the receiver 45, the second bandpass filter 25 and the first controlled attenuator 46 is fed to the first, signal input of the second step-down mixer 24, to the second the heterodyne input of which a fixed frequency signal is supplied from the block of reference frequencies 54.

The first 23 and second 45 amplifiers of the first intermediate frequency of the receiver provide the main gain of the receiving path. The first 46 and third 44 controlled attenuators change their attenuation according to the control signal from the output of the algebraic adder 50, ensuring a constant signal level at the output of the device when the level of the received signal changes, as well as the maximum linearity of the amplitude-frequency characteristic of the receive path.

The second band-pass filter 25 suppresses the signal from the frequency synthesizer 32, which passes to the output of the first step-down mixer 21. The second step-down mixer 24 transfers the signal to the second intermediate frequency. From the output of the second buck mixer 24, the signal is fed to the input of the amplifier of the second intermediate frequency of the receiver 26, where it is amplified to the level necessary for the amplitude detector 47 to work. From the output of the amplifier of the second intermediate frequency of the receiver 26, the signal through the third band-pass filter 22 and the output amplifier 52 the second input of the combining-separation unit 53 and further to the output of the device. The third bandpass filter 22 provides selectivity for the adjacent channel. The output amplifier 52 amplifies the signal to the level necessary for transmission to the output of the device.

From the second output of the third band-pass filter 22, the signal enters the amplitude detector 47. The amplitude detector 47 extracts the envelope of the input signal, which, after amplification in the video amplifier 48, is fed to the input of the peak detector 49, which maintains peak envelope values at its output. In the algebraic adder 50, the signal voltage from the output of the peak detector 49 is compared with the reference voltage from the constant voltage generator 51. When a difference in these voltages appears at the output of the algebraic adder 50, a control signal is generated that provides a change in the attenuation of the first 46 and third 44 controlled attenuators.

The reference generator 6 generates a stable frequency signal necessary for the operation of the block of reference frequencies 54 and the frequency synthesizer 32.

The combining-separation unit 53 is used to transmit the input and output signals of the device through one cable to the input-output device, as well as to generate control signals for blocks 36 and 32.

But the prototype device does not have a high enough bandwidth due to the fact that it uses on-off modulation.

The problem to be solved when creating the proposed utility model is to achieve a technical result in the form of increasing the throughput of a microwave transceiver with increased stealth.

To solve the problem, a millimeter wave transceiver containing a serially connected valve and power amplifier, serially connected a third band-pass filter, a circulator and a fourth band-pass filter, an antenna, the input-output of which is connected to the second input-output of the circulator, the fifth band-pass filter and the first a step-down mixer, a step-up mixer and a second band-pass filter connected in series, a first frequency synthesizer, the first output of which is connected to the second, the heterodyne input of the up-mixer, and the second output is connected to the second, heterodyne input of the first down-mixer, a reference generator, an intermediate frequency amplifier of the transmitter, a first band-pass filter, a low-noise amplifier, a sixth band-pass filter, an amplifier of the first intermediate frequency of the receiver, a second down-mix, a seventh-band filter , the amplifier of the second intermediate frequency of the receiver, according to the utility model, the first input converter, the input of which is Xia first input device, the first multiplexer and a differential amplifier; serially connected demodulator, demultiplexer and a first output converter, the output of which is the second output of the device; serially connected frequency multiplier and quadrature modulator; clock generator; connected in series to a second input converter, the input of which is the third input of the device, and a second differential amplifier; a second output converter, the output of which is the third output of the device, and the input is connected to the second output of the demodulator; a second frequency synthesizer, the output of which is connected to the second heterodyne input of the second step-down mixer, the output of which is connected to the input of the seventh bandpass filter, and the first signal input is connected to the output of the amplifier of the first intermediate frequency of the receiver; an automatic gain control unit, the input of which is connected to the input of the demodulator, and the output is connected to the second, control input of the amplifier of the second intermediate frequency of the receiver; a codec, the first, the signal input of which is the second input of the device, the first output of which is the first output of the device, the second output of the codec is connected to the second, signal input of the multiplexer, the second, signal input of the codec is connected to the second output of the demultiplexer, and the third, clock input is connected to the first the output of the clock generator, the second output of which is connected to the third, clock input of the multiplexer; the output of the first differential amplifier is connected to the first modulating input of the quadrature modulator, the second, modulating input of which is connected to the output of the second differential amplifier, and the output is connected to the input of the intermediate frequency amplifier of the transmitter, the output of which is connected through the first bandpass filter to the first signal input of the boost mixer; the output of the reference generator is connected to the input of the frequency multiplier, the output of the second bandpass filter is connected to the input of the valve, the output of the power amplifier is connected to the input of the third bandpass filter, the output of the fourth bandpass filter is connected through the low-noise amplifier to the input of the fifth bandpass filter, the output of the first step-down mixer through the sixth bandpass filter connected to the input of the amplifier of the first intermediate frequency of the receiver, the output of the seventh band-pass filter is connected to the input of the amplifier of the second intermediate frequency of the reception nickname, the output of which is connected to the input of the demodulator; the control input of the first frequency synthesizer is the fourth input of the device.

Figure 2 shows the functional diagram of the proposed digital microwave transceiver with increased stealth, where the following notation is introduced:

1 - first input converter;

2 - multiplexer;

3 - the first differential amplifier;

4 - codec;

5 - clock generator;

6 - reference generator;

7 - frequency multiplier;

8 - quadrature modulator;

9 - amplifier of the intermediate frequency of the transmitter;

10 - the first band-pass filter;

11 - step-up mixer;

12 - second band-pass filter;

13 - valve;

14 - power amplifier;

15 - the third band-pass filter;

16 - circulator;

17 - antenna;

18 - the fourth band-pass filter;

19 - low noise amplifier;

20 - fifth band-pass filter;

21 is a first step-down mixer;

22 - sixth band-pass filter;

23 - amplifier of the first intermediate frequency of the receiver;

24 - second step-down mixer;

25 - seventh band-pass filter;

26 - amplifier of the second intermediate frequency of the receiver;

27 - demodulator;

28 - demultiplexer;

29 - the first output converter;

30 - second output converter;

31 - block automatic gain control;

32 - the first frequency synthesizer;

33 is a second frequency synthesizer;

34 - second input converter;

35 is a second differential amplifier.

The proposed device comprises a series-connected reference oscillator 6, a frequency multiplier 7, a quadrature modulator 8, an intermediate frequency amplifier of the transmitter 9, a first bandpass filter 10, a boost mixer 11, a second bandpass filter 12, a valve 13, a power amplifier 14, a third bandpass filter 15 and a circulator 16, the second input-output of which is connected to the antenna 17; connected in series with a fourth bandpass filter 18, a low noise amplifier 19, a fifth bandpass filter 20, a first step-down mixer 21, a sixth band-pass filter 22, a amplifier of the first intermediate frequency of the receiver 23, a second step-down mixer 24, a seventh band-pass filter 25, a amplifier of the second intermediate frequency of the receiver 26, a demodulator 27, a demultiplexer 28, and a first output converter 29; connected in series to the first input converter 1, the input of which is the first input of the device, the multiplexer 2 and the first differential amplifier 3; connected in series to a second input converter 34, the input of which is the third input of the device, and a second differential amplifier 35. In addition, it contains a clock 5, a second output converter 30, an automatic gain control unit 31, a first frequency synthesizer 32, a second frequency synthesizer 33, and codec 4, the first, the signal input of which is the second input of the device, the first output is the first output of the device, the second output is connected to the second, signal input of the multiplexer 2, sec oh, the signal input of the codec 4 is connected to the second output of the demultiplexer 28, and the third, clock input of the codec 4 is connected to the first output of the clock 5, the second output of which is connected to the third, clock input of the multiplexer 2; the output of the first differential amplifier 3 is connected to the first modulating input of the quadrature modulator 8, the second, modulating input of which is connected to the output of the second differential amplifier 35; the second output of the demodulator 27 is connected to the input of the second output Converter 30, the output of which is the third output of the device; the output of the second frequency synthesizer 33 is connected to the second heterodyne input of the second step-down mixer 24; the first output of the first frequency synthesizer 32 is connected to the second heterodyne input of the first boost mixer 11, the second output is connected to the second, heterodyne input of the first step mixer 21, and the control input is the fourth input of the device; the third output of the circulator 16 is connected to the input of the fourth band-pass filter 18; in addition, the output of the amplifier of the second intermediate frequency of the receiver 26 is connected to the input of the automatic gain control unit 31, the output of which is connected to the second control input of the amplifier of the second intermediate frequency of the receiver 26; the output of the first output converter 29 is the second output of the device.

Digital microwave transceiver with increased stealth works as follows.

The input bipolar signal is fed to the first input of the device and, using the first input converter 1, is converted into a unipolar TTL-level signal, which then goes to the first signal input of multiplexer 2.

An audio signal is received at the second input of the device, which is digitized in codec 4 and then fed to the second, signal input of multiplexer 2. Multiplexer 2 combines these signals into a single digital stream with an increased transmission rate. The clock frequency of this digital stream is set by the clock generator 5. The output signal of the multiplexer 2 is fed to the input of the first differential amplifier 3, the output of which is a differential signal, which is then fed to the first modulating input of the quadrature modulator 8.

The input bipolar signal is fed to the third input of the device and, using the second input converter 34, is converted into a unipolar TTL level signal, which is then fed to the input of the second differential amplifier 35, at the output of which a differential signal is generated, which then goes to the second modulating input of the quadrature modulator 8.

The signal of the highly stable reference generator 6 is multiplied in frequency to an intermediate frequency value using a frequency multiplier 7 and is fed to the signal input of the quadrature modulator 8. Quadrature modulator 8 performs quadrature phase shift keying of this intermediate frequency signal. Thus, since the intermediate frequency signal is manipulated by three (two of which are pre-compressed in the multiplexer) independent information signals, the throughput is increased.

The modulated signal from the output of the quadrature modulator 8 is fed through an intermediate frequency amplifier of the transmitter 9 and the first band-pass filter 10 to the signal input of the boost mixer 11, to the second, heterodyne input of which a signal is supplied from the first output of the first frequency synthesizer 32. Using the signal supplied to the control input the first frequency synthesizer 32, the tuning of its output frequency is carried out.

The intermediate frequency amplifier of the transmitter 9 amplifies the signal to the level necessary for subsequent supply to the input of the power amplifier 14. The first band-pass filter 10 filters out unwanted spectral components that appear after quadrature phase shift keying. Boost mixer 11 transfers the input signal of the intermediate frequency to the carrier frequency. From the output of the boost mixer 11, the signal through the second band-pass filter 12 and the valve 13 is fed to the input of the power amplifier 14, which amplifies the carrier frequency signal to the level radiated into the air.

The second band-pass filter 12 filters out unwanted spectral components that appear after the frequency conversion in the mixer 11. The valve 13 serves to match the input impedance of the power amplifier 14 with the output impedance of the second band-pass filter 12.

From the output of the power amplifier 14, the signal through the third band-pass filter 15 and the circulator 16 is fed to the input of the antenna 17 and is broadcast. The third bandpass filter 15 filters the output noise of the power amplifier 14 falling into the passband of the fourth bandpass filter 18. The circulator 16 serves to separate the transmission and reception signals.

The signal received from the ether output from the antenna 17 enters through the circulator 16 and the fourth bandpass filter 18 to the input of a low-noise amplifier 19, which provides amplification of the signal before feeding it through the fifth bandpass filter 20 to the information input of the first step-down mixer 21. The fourth bandpass filter 18 attenuates the mirror signals frequency. The fifth bandpass filter 20 attenuates the noise of a low noise amplifier 19 at a frequency of the mirror channel.

The first step-down mixer 21 transfers the input signal of the carrier frequency to the first intermediate frequency using a signal that is fed to its second heterodyne input from the output of the first frequency synthesizer 32.

From the output of the first step-down mixer 21, the signal passes through the sixth band-pass filter 22 and the amplifier of the first intermediate frequency of the receiver 23, which amplifies the signal before applying it to the signal input of the second step-down mixer 24. The sixth band-pass filter 22 filters out unwanted spectral components that appear after frequency conversion in the first step-down mixer 21.

The second buck mixer 24 transfers the input signal of the first intermediate frequency to the second intermediate frequency using a signal that is fed to its local oscillator input from the output of the second frequency synthesizer 33. From the output of the second buck mixer 24, the signal through the seventh bandpass filter 25 and the amplifier of the second intermediate frequency of the receiver 26 arrives at the inputs of the demodulator 27 and the automatic gain control unit 31. The seventh band-pass filter 25 filters out unwanted spectral components, I appear after conversion of the frequency in the mixer 24. The automatic gain control unit 31 measures the output signal of the amplifier of the second intermediate frequency 26 and generates a signal at its output that is supplied to the second control input of the amplifier of the second intermediate frequency of the receiver 26. Due to this, the output signal of the amplifier is of the second intermediate frequency receiver 26 is kept constant.

The demodulator 27 performs quadrature phase demodulation of the second intermediate frequency signal. The signal from the first output of the demodulator 27 is fed to the input of the demultiplexer 28, which performs the separation of the two compressed digital signals.

The first of these signals passes through the first output converter 29 to the second output of the device, and the second to the second, signal input of the codec 4. The first output converter 29 converts the TTL level signal into a two-level signal. The signal supplied to the second signal input of the codec 4 is subjected to digital-to-analog conversion and is transmitted to the first output of the device as an audio signal.

Thus, the introduction of the proposed microwave transceiver with increased stealth of new blocks and communications provides higher throughput.

The implementation of the blocks of the proposed utility model is not difficult, because they are widely described in the technical literature.

Claims (1)

Digital stealth digital microwave transceiver comprising a serially connected valve and power amplifier, serially connected a third band-pass filter, a circulator and a fourth band-pass filter, an antenna whose input-output is connected to a second input-output of a circulator, a fifth-band filter and a first step-down mixer are connected in series connected in series with a step-up mixer and a second band-pass filter, a first frequency synthesizer, the first output of which is connected to the second, get home, up-mixer input, and the second output connected to the second heterodyne, input of the first down-mixer, reference oscillator, transmitter intermediate frequency amplifier, first band-pass filter, low-noise amplifier, sixth band-pass filter, receiver first intermediate-frequency amplifier, second step-down mixer, seventh band-pass filter, amplifier of the second intermediate frequency of the receiver, characterized in that the first input converter, the input of which is the first the input of the device, the multiplexer and the first differential amplifier; serially connected demodulator, demultiplexer and a first output converter, the output of which is the second output of the device; serially connected frequency multiplier and quadrature modulator; clock generator; connected in series to a second input converter, the input of which is the third input of the device, and a second differential amplifier; a second output converter, the output of which is the third output of the device, and the input is connected to the second output of the demodulator; the second frequency synthesizer, the output of which is connected to the second heterodyne input of the second step-down mixer, the output of which is connected to the input of the seventh bandpass filter, and the first signal input is connected to the output of the amplifier of the first intermediate frequency of the receiver; an automatic gain control unit, the input of which is connected to the input of the demodulator, and the output is connected to the second, control, input of the amplifier of the second intermediate frequency of the receiver; codec, the first, signal, the input of which is the second input of the device, the first output of which is the first output of the device, the second output of the codec is connected to the second signal input of the multiplexer, the second, signal, the input of the codec is connected to the second output of the demultiplexer, and the third, clock, input is connected with the first output of the clock generator, the second output of which is connected to the third, clock, input of the multiplexer; the output of the first differential amplifier is connected to the first, modulating, input of the quadrature modulator, the second, modulating, the input of which is connected to the output of the second differential amplifier, and the output is connected to the input of the intermediate frequency amplifier of the transmitter, the output of which is connected through the first bandpass filter to the first signal input boost mixer; the output of the reference generator is connected to the input of the frequency multiplier, the output of the second bandpass filter is connected to the input of the valve, the output of the power amplifier is connected to the input of the third bandpass filter, the output of the fourth bandpass filter is connected through the low-noise amplifier to the input of the fifth bandpass filter, the output of the first step-down mixer through the sixth bandpass filter connected to the input of the amplifier of the first intermediate frequency of the receiver, the output of the seventh band-pass filter is connected to the input of the amplifier of the second intermediate frequency of the reception nickname, the output of which is connected to the input of the demodulator; the control input of the first frequency synthesizer is the fourth input of the device.