SU1277409A1 - Device for double reception of signals with frequency spacing - Google Patents

Abstract

The invention relates to radio engineering. The purpose of the invention is to increase the noise immunity with respect to narrowband interference (USh1). The device contains two mixers 1 and 2, two local oscillators 3 and 4, unit 5 of signal phasing, two keys 6 and 7, six adders (C) 8.9,10 , 11,12 and 24, two inverters. 13 and 14, four bandpass filters 15-18, switch 19, automatic gain control regulator 20, reference element 21, variable gain amplifier 22, frequency-tuned notch filter 23, tuning frequency control unit 25, amplitude detector circuit 26 - 29, two subtractors 30 and 31, and two averaging elements 32 and 33, a level equalization unit 34, and an interference fixation unit 35. When the soft starter acts on any of the frequency diversity channels, the output of the C 9 always contains a signal affected by the soft starter and the output of the C 8 is a signal free from the soft starter. At the same time, only the signal free from USh1 is sent to the input (L4 C 24), and the signal affected by it is turned off. After equalizing the useful component of both frequency channels, its part is rejected. Then, the signal cleared of the soft starter enters C 24, where it is combined with the separated signal that is released from the soft starter. 1 Il.

Description

1 The invention relates to radio engineering and can be used in tropospheric communication systems with frequency diversity under conditions of external interference. The purpose of the invention is to improve the noise immunity with respect to narrowband interference. The drawing shows the structures on the electrical circuit of the device for dual reception of signals with frequency separation. The device for dual reception of signals with frequency separation contains the first mixer 1, the second mixer 2, the first local oscillator 3, the second local oscillator 4j the signal phasing unit 5, the first key 6, the second key 7 the third adder 8, the fourth adder 9, the fifth adder 10, An adder 11, a second adder 12, a first inverter 13, a second inverter 14, a third band-pass filter 15, a fourth, band-pass filter 16, the first polo 25 key

owl filter 17, second bandpass filter 18, switch 19, automatic gain control regulator 20, reference element 21, variable gain amplifier 22, frequency-tuned notch filter 23, first adder 24, tuning frequency control unit 25, first amplitude detector 26, third amplitude detector 27, second amplitude detector 28, quarter amplitude detector 29, first subtractor 30, second subtractor 31, first averaging element 32, second averaging element 33, level equalizing block 34 and block to 35 fixing noise.

The device works as follows. Frequency-spaced useful signals are fed to the device inputs by the center frequencies f, and f. In the first and second mixers 1 and 2, using the first and second local oscillators 3 and 4, the signals are transferred to the common intermediate frequency f. In block 5, both signals are adjusted so that they coincide in phase. In this case, the presence of narrowband interference in one of the frequency channels does not affect the measurement result, since it is uncorrelated with the signal of the other frequent channel. At the output of block 5, under the influence of narrowband interference on any of the frequency channels of diversity, at the output of the fourth adder 9 there is always a signal struck by interference, and at the output of the third adder 8 a signal free from interference. The inputs of the first adder 24 are only supplied free from interference.

this signal, and the signal affected by it is turned off.

In block 34, an equalization of the value of the useful component of both frequency channels occurs before further

Claims (1)

40 by rejecting its part. The equalization is necessary to neutralize the effect of different transmission coefficients in the processing paths of both signals and the difference in the 9-level levels of the useful components of the input signals phasing and differ only in amplitude. In the absence of narrowband interference in both channels, the first and second keys 6 and 7 are open, the input signals are summed in the third 8 and fourth 9 adders. However, in the fourth adder 9, the output signal of the third adder 8, the first inverter 13, is also summed, so there is no signal at its output. If there is interference in the first frequency channel, the first key 6 is closed, the second key 7 remains open. In this case. At the output of the fourth adder 9 there is the first spaced signal (with noise), and at the output of the third adder 8 - the second spaced signal. If the second frequency channel is struck by interference, then the first 6 is open, the second key 7 is closed, 45 receive signals due to the influence of the propagation channel. The adjustment is done in the following way. . The bandwidths of the third and fourth bandpass filters 15 and 16 are located in the upper and lower halves of the spectrum of the frequencies of the desired signal so that the narrowband interference can only fall into one of them at a time. In this case, the switch 19 is switched in such a way that the signal from the one of the band-pass filters without interference is input to the controller 20. In the regulator. 20, a comparison is made of the averaged values of the signal level of this bandpass filter and the level of the entire signal from the output of amplifier 22, through which the diversity signal passes, which was not affected by interference. Since the type of modulation and the shape of the spectrum, the useful signal is known, it is also known how much the average power of the signal passing through the bandpass filter is from the power of the entire signal. At this, the regulator 20 controls the gain of the amplifier 22 in this way. so that the level of the useful signal at its output (without interference) coincides with the level of the useful part of the signal of another frequency channel affected by interference. Next, the signal of the unaffected channel is inverted in the second inverter 14, ck adyvaets in the fifth adder 10 with the signal infected obstacle passes through the imaginary Tunable frequency bandstop filter 23 and re-folded to a signal amplifier 22 in the adder 11. When the pestle ztom following occurs. 1 Let y be an external disturbance; P |, n, “parts of the process n, falling into and not falling into the notch band; p., parts of the process p, falling into and not falling into the notch band of the notch filter, tunable in frequency 23. Sj-X + П2 „n- Pgn. After passing S through the second: inverter 14 and adding with S in the fifth adder 10, the signal at its output is "1-Sito i in 2n iH. After passing the notch filter 2, which is tunable in frequency, the signal at its output is P, m - P. After the sixth adder 1 1 the signal has the form and „sU and. (x + n + n ,,) + (n, „n, S. - y. Since the notch band is narrow, the power of the component compared to n | is small and the signal UK is almost equal to the signal S ,, but also with the exception of external interference, as required. Next, the cleared interference signal goes to the first adder 24, where it is combined with the separated signal that is free from interference. The presence of interference in one of the separated channels, as well as switching of the switch 19 (determining which half is the useful signal spectrum is narrowband interference) is performed in block 35. Consider Driving the signal of the first frequency channel. It is detected in the first amplitude detector 26, passes the first band-pass filter 17, and is detected in the third amplitude detector 27. The bandwidth of the first band-pass filter I7 is half the entire frequency band of the useful signal. Next, the output signals of both amplitude detectors are subtracted into the first subtraction is 30 and its signal is averaged in the first element 32. The subtraction is performed with certain weights. The proportion of the useful signal transmitted through the band-pass filter 17, in relation to the entire useful signal, is known. It determines the weighting coefficients when subtracting in such a way that, in the absence of interference in this spaced signal, the voltage at the output of element 32 is absent. The weighting factors in the subtraction are inversely proportional to the ratios of the average powers of the useful signal before and after the first band-pass filter 17. The circuit of the second frequency channel, formed by the second band-pass filter 18, the fourth amplitude detector 29, the second subtractor, the second element 33 and the second amplitude detector 28, functions similarly . Thus, if a significant voltage of an arbitrary sign appears at the output of the first or second element 32 or 33, this means that the ratio between the signal power before and after the passage of the band-pass filter is violated in this branch of the spacing, and narrowband interference. In comparison element 21, the absolute value of the signal level from the outputs of the first and second elements 32 and 33 is monitored. If it is greater than a certain value (significantly deviates from zero), element 2 generates a voltage by controlling the operation of the first and second keys 6 and 7 If both keys need to be opened, this control voltage is zero if you need to open only one key, the control voltage is one of the polarities; if the other is the key, then the sex of the control voltage is opposite. The sign of the signals from the output of the first and second elements 32 and 33 also contains information on the location of the interference in the spectrum of the useful signal (if the fraction of the power at the output of the bandpass filter compared to the total power is more known, then the interference is in its band; less known, the interference is out of its band, in the other half of the signal spectrum). The signals from the averagers are added to the second adder 12, and the voltage sign controls the switching of switch 19. At the moments when the third and fourth band-pass filters 15 and 16 do not interfere, there is no voltage, the amplifier 22 is locked, and only two input spacers are fed to the first adder 24 signal. Tunable frequency filter torch filter 23 is controlled by a signal from block 25, the claims of the device for dual reception of signals with frequency separation, containing the first adder, the output of which is The device's unit, the signal phasing unit, the first and second local oscillators, the first and second mixers, the signal input of each of which is the input of the corresponding frequency channel of the device, the heterodyne input is connected to the appropriate horizontal oscillator, the output of each mixer is connected to the corresponding input of the signal phasing unit , characterized in that, in order to increase the noise immunity with respect to narrowband interference, a parallel element of comparison and a second adder, the first and Amplitude amplitude detectors, connected subsequently to the first band-pass filter, whose input is connected to the output of the first frequency channel of the signal phasing unit and the input of the first amplitude detector, the third amplitude detector, the first subtractor, the other input connected to the output of the first amplitude detector, and the first element of the average, connected successively a second bandpass filter, the input of which is connected to the output of the second frequency channel of the signal phasing unit and the input of the second amplitude circuit torus, a fourth amplitude detector, a second subtractor, another input connected to the output of the second amplitude detector, and a second averaging element, a tuning frequency control unit, the first and second keys, whose inputs are connected to the outputs of the first and second frequency channels of the phasing unit, respectively, the outputs are connected the first and second inputs of the first adder, and the control inputs are connected to the output of the reference element, the third bandpass filter, connected in series by the third adder ,. the first and second inputs of which are connected to the outputs of the first and second keys, the first inverter, the fourth adder, the other inputs of which are connected to the outputs of the first and second frequency channels of the signal phasing unit, and the output connected to the input of the third band-pass filter, the fourth band-pass filter, switch, another input which is connected to the output of the third bandpass filter, and the control input is connected to the output of the second adder, and an automatic gain control regulator, connected in series with an amplifier a variable gain, the input of which is connected to the output of the third adder, and the output and regulating input are connected to the inputs and output of the automatic gain control controller, respectively, the second inverter, five adder, the other input of which is connected to the output of the fourth adder, Frequency reject filter control input 12774098 which is connected to the output of the block building are connected respectively to control of the tuning frequency, and the neck-output of the fourth adder and the output of the adder, another input of the amplifier with an adjustable coefficient connected to the output of the amplifier with the transmission response, the outputs of the first and by the amplified gain, the second averaging element, the output connection is connected to the third input and the corresponding inputs of the first adder, the first and second inserted in parallel to the first element the inputs of the frequency control unit and the second adder.