RU48134U1 - MILLIMETER WAVE DUPLEX TRANSMITTER - Google Patents

Abstract

The proposed utility model is tapped to radio communications and can be used to organize digital radio-relay communication lines. The technical result achieved is an increase in the dynamic range. For this, a bandpass filter, a low-noise amplifier, a controlled attenuator, a second threshold block, a peak detector, a constant voltage generator and an algebraic adder are introduced into the well-known duplex millimeter wave transceiver.

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 communication, for example, the Radan-2 system (Mordukhovich LG, Stepanov AI Radio communication systems. ML, Radio and communications, 19S7). However, these transceivers have high power consumption and large dimensions.

Of the known transceivers, the closest but technical essence to the proposed device is "Duplex millimeter wave transceiver" but with a certificate for utility model No. 24062 from 20. 07. 2002, adopted as a prototype.

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

1 - input matching unit;

2 - input signal receiver;

3 - the first regenerator;

4 - transmitter synchronization unit;

5 - decoder three-level code;

6 - scrambler;

7 - encoder relative code;

8 - amplifier-driver;

9 - modulator;

10 - generator;

11 - circulator;

12 - antenna;

13 - mixer;

14 - local oscillator;

15 - high-pass filter;

16-intermediate frequency amplifier;

17 - mountains demodule;

18 - video amplifier;

19 - threshold block;

20 - second regenerator;

21 is a receiver synchronization unit;

22 - relative code decoder:

23 - descrambler;

24 - encoder three-level code;

25 - output amplifier;

26 - output matching unit.

The prototype device contains a serially connected input matching unit 1, an input signal receiver 2, a first regenerator 3, a three-level code decoder 5, a scrambler 6, a relative code encoder 7, an amplifier-shaper 8, a modulator 9, the output of which is connected to the first input of the circulator 11, the second input to the mount, which is also its second output, is connected to the antenna 12. In this case, the output of the receiver of the input signal 2 is connected to the input of the synchronization unit of the transmitter 4, the output to the mount is connected to the synchronization inputs of the first regenerated RA 3, a three-level decoder code 5, a scrambler 6 and an encoder relative code 7. The output of the generator 10 is connected to the second signal input of the modulator 9. In addition, it contains a series-connected mixer 13, a high-pass filter 15, an intermediate frequency amplifier 16, a demodulator 17, video amplifier 18, threshold block 19, second regenerator 20, relative code decoder 22, descrambler 23, three-level code encoder 24, output amplifier 25 and output matching unit 26, the output of which is the output of the device. In addition, the output of the threshold block 19 is connected to the input of the synchronization unit of the receiver 21, the output of which is connected to the synchronization inputs of the second regenerator 20, the relative code decoder 22, the descrambler 23, and the three-level code encoder 24. The output of the local oscillator 14 is connected to the second heterodyne input of the gel mixture 13 , the input of which is connected to the first output of the circulator 11. The input of the input matching unit 1 is the input of the device.

The prototype device operates as follows. From the input of the device, the digital signal through the input matching unit 1 is fed to the input of the input signal receiver 2, from the output the signal is fed to the inputs of the first regenerator 3 and the synchronization unit of the transmitter 4. The synchronization unit of the transmitter 4 extracts the clock frequency signal and generates clock synchronization signals from it, necessary for the first operation of the regenerator 3, the three-level code decoder 5, the scrambler 6 and the relative code encoder 7. The regenerator 3 restores the shape and temporary positions of the code symbols. A three-level code decoder 5 converts a digital signal transmitted in HDB-3 code with a fill of 0.5 into a two-level binary signal with a fill of 1.

Next, the signal is scrambled in the scrambler 6 and relative encoded in the encoder relative code 7 in order to give it the appropriate statistical characteristics necessary to isolate the clock synchronization signal in the synchronization unit of the receiver 21. The amplifier-shaper 8 provides the level and shape of the signal fed to the first control input modulator 9. Modulator 9 modulates the signal supplied to its second, signal input from the output of the generator 10. The modulated signal through the compass 11 Torr is supplied to the antenna 12 and radiated into air.

The signal received from the ether from the output of the antenna 12 through the circulator 11 goes to the input of the mixer 13. The circulator 11 provides a separation of the transmitted and received signals. The mixer 13 using the local oscillator 14 converts the received signal into an intermediate frequency signal. The high-pass filter 15 attenuates the signal generated by the interaction in the mixer 13 of the received signal and the signal from the generator 10, which enters the input of the mixer 13 through the circulator 11.

The intermediate frequency amplifier 16 provides signal amplification and frequency selectivity of the receiver. After the demodulator 17, the signal is input to the video amplifier 18, which provides the necessary signal amplification for the operation of the threshold unit 19. The threshold unit 19 provides a decision

about the received character - “0” or “1”. From the output of the threshold unit 19, the signal arrives at the inputs of the second regenerator 20 and the synchronization unit of the receiver 21. The synchronization unit of the receiver 21 extracts the clock signal and generates the clock synchronization signals necessary for the operation of the regenerator 20, the relative code decoder 22, the descrambler 23 and three-level code encoder 24.

The second regenerator 20 restores the shape and temporary positions of the code symbols. The relative code decoder 22 and the descrambler 23 perform operations inverse to the operations of the relative code encoder 7 and the scrambler 6, respectively. A three-level code encoder 24 converts a binary two-level signal into a three-level code signal HDB-3. Further, the signal amplified by the output amplifier 25 enters through the output matching unit 26 to the output of the device.

The prototype device does not have a high enough dynamic range.

To eliminate this drawback in a duplex millimeter-wave transceiver, containing a series-connected input matching unit, the input of which is the input of the device, and the receiver of the input signal; serially connected amplifier-driver, modulator and circulator; a serially connected mixer and a high-pass filter; a series-connected intermediate frequency amplifier, demodulator and video amplifier; a series-connected output amplifier and output matching unit, the output of which is the output of the device; a generator whose output is connected to the second signal input of the modulator, a local oscillator, the output of which is connected to the second heterodyne input of the mixer, the first threshold block and the antenna connected to the second input-output of the circulator, according to the utility model, a band-pass filter and a second threshold block are introduced, DC voltage generator, series-connected low-noise amplifier and controlled attenuator; a series-connected peak detector and an algebraic adder, while the output of the input receiver

the signal is connected to the input of the amplifier-former; the first output of the circulator is connected to the input of the bandpass filter, the output of which is connected to the first signal input of the mixer; the output of the high-pass filter is connected to the input of a low-noise amplifier; the output of the video amplifier is connected to the first signal input of the second threshold block, the output of which is connected to the input of the output amplifier; the output of the DC voltage generator is connected to the second input of the algebraic adder, the output of which is connected to the second control input of the controlled attenuator, the output of which is connected to the input of the intermediate frequency amplifier; in addition, the output of the video amplifier is connected to the input of the peak detector, the output of which is connected to the input of the first threshold block, the output of which is connected to the second, gate input of the second threshold block.

Figure 2 shows the functional diagram of the proposed duplex transceiver millimeter waves, where the following notation is introduced:

1 - input matching unit;

2 - input signal receiver;

3 - band-pass filter;

4 - low noise amplifier;

5 - controlled attenuator;

6 - peak detector;

7 - algebraic adder;

8 - amplifier-driver;

9 - modulator;

10 - generator;

11 - circulator;

12 - antenna;

13 - mixer;

14 - local oscillator;

15 - high-pass filter;

16 - intermediate frequency amplifier;

17 - demodulator;

18 - video amplifier;

19 is a first threshold block;

20 - DC voltage generator;

21 - second threshold block;

22 - output amplifier;

23 - output matching unit.

The proposed device contains a serially connected input matching unit 1, the input of which is the input of the device, an input signal receiver 2, an amplifier-shaper 8 and a modulator 9, the output of which is connected to the first input of the circulator 11, the second input-output to the antenna is connected to the antenna 12; series-connected band-pass filter 3. mixer 13, high-pass filter 15, low-noise amplifier 4, controlled attenuator 5, intermediate-frequency amplifier 16, demodulator 17, video amplifier 18, second threshold block 21, output amplifier 22 and output matching block 23, the output of which is device output. In addition, it contains a generator 10, the output of which is connected to the second, signal input of the modulator 9; a local oscillator 14, the output of which is connected to the second, local oscillator input of the mixer 13; a DC voltage generator 20, the output of which is connected to the second input of the algebraic adder 7, the output of which is connected to the second, control input of the controlled attenuator 5. In addition, the output of the video amplifier 18 through the peak detector 6 is connected to the first input of the algebraic adder 7 and the input of the first threshold block 19 the output of which is connected to the second, gate input of the second threshold unit 21. The first output of the circulator 11 is connected to the input of the bandpass filter 3.

Duplex transceiver millimeter waves works as follows. From the input of the device, a digital signal through the input matching unit 1 is fed to the input of the input signal receiver 2, from the output of which the signal is fed to the input of the amplifier-former 8, which provides the level and shape of the signal supplied to the first modulating input of the modulator 9. Modulator 9 modulates the signal arriving at his second,

the signal input from the output of the generator 10. The generator 10 operates in the range 36 39.5 GHz. The modulated signal through the circulator 11 enters the antenna 12 and is transmitted to the air. The circulator 11 provides separation of the transmitted and received signals.

The signal received from the ether from the output of the antenna 12 through the circulator I! enters the input of the bandpass filter 3, from the output of which the filtered signal enters the first signal input of the mixer 13. the second, heterodyne input of which receives the signal from the output of the local oscillator 14, operating in the frequency range 36 - 39.5 GHz. The mixer 13 converts the received signal into an intermediate frequency signal. The high-pass filter 15 attenuates the signal generated by the interaction of the received signal in the mixer 13 and the signal from the generator 10, which enters the input of the mixer 13 through the circulator 11 and the band-pass filter 3. From the output of the high-pass filter 15, the signal is transmitted through a low-noise amplifier 4, controlled attenuator 5, and the intermediate frequency amplifier 16 is fed to the input of the demodulator 17, where an information modulating signal is extracted, which is then amplified in the video amplifier 18. From the output of the video amplifier IS, the signal is fed to the input of the peak detector 6 and to the first, signal input of the second threshold block 21. The peak detector 6 monitors slow changes in the signal level, and the algebraic adder 7 determines the difference between this level and the level of the reference voltage generated by the constant voltage generator 20. The signal from the output of the algebraic adder 7 controls the attenuation of the controlled attenuator 5, maintaining the output signal of the video amplifier 18 at a constant level with changes in the signal level at the input of the controlled attenuator 5.

Such a system of automatic gain control can significantly increase the dynamic range of the receiving part of the transceiver, since the signal level at the input of the intermediate frequency amplifier 16 is kept almost constant, avoiding the overload of the intermediate frequency amplifier 16 and the signal distortion caused by this overload.

When the received useful signal appears at the output of the antenna 12, a peak is formed at the output of the peak decree 6, which exceeds the response level of the first threshold block 19. The first threshold block 19 is triggered and gives a permission-strobe to trigger the second threshold block 21. If there is no Angle 12 at the input, the received useful sieve-pa first threshold block 19 prohibits the activation of the vurey threshold block 21 (which is possible from the noise voltage).

The second threshold block 21 provides a decision on the received symbol - "0" or "1". From the output of the second threshold block 21, the signal generated by the output amplifier 22 is fed through the output matching block 23 to the output of the device.

Thus, the proposed duplex millimeter wave transceiver has a higher dynamic range. Due to this, when organizing a radio line consisting of two such transceivers, it becomes possible to place them at any distance in the range from 50 m to 5 km, without causing overload of the amplifier at an intermediate frequency of 16 and signal distortion.

Claims (1)

A millimeter-wave duplex transceiver, comprising an input matching unit in series, the input of which is the input of the device, and an input signal receiver; serially connected amplifier-driver, modulator and circulator; a serially connected mixer and a high-pass filter; a series-connected intermediate frequency amplifier, demodulator and video amplifier; a series-connected output amplifier and an output matching unit, the output of which is the output of the device; a generator whose output is connected to the second signal input of the modulator, a local oscillator, the output of which is connected to the second heterodyne input of the mixer, a first threshold unit and an antenna connected to the second input-output of the circulator, characterized in that a band-pass filter and a second threshold a unit, a DC voltage generator, a low-noise amplifier and a controlled attenuator connected in series; in series connected peak detector and algebraic adder, while the output of the input signal receiver is connected to the input of the amplifier-former; the first output of the circulator is connected to the input of the bandpass filter, the output of which is connected to the first signal input of the mixer; the output of the high-pass filter is connected to the input of a low-noise amplifier; the output of the video amplifier is connected to the first signal input of the second threshold block, the output of which is connected to the input of the output amplifier; the output of the DC voltage generator is connected to the second input of the algebraic adder, the output of which is connected to the second, control input of the controlled attenuator, the output of which is connected to the input of the intermediate frequency amplifier; in addition, the output of the video amplifier is connected to the input of the peak detector, the output of which is connected to the input of the first threshold block, the output of which is connected to the second, gate input of the second threshold block.