SU943620A1 - Calibration signal shaper - Google Patents

Description

one

 The invention relates to radio engineering and can be used as control equipment in aircraft landing systems.

A calibrator driver is known, comprising a first phase detector, whose input is an input of a calibration signal generator, connected to a series controlled oscillator, a first frequency divider, a first adder and a minimum limiter, the output of which is a calibration signal generator output, connected in series to a second frequency divider and the third frequency divider, with the first input of the first frequency divider connected to the first input of the second frequency divider, the second input cat cerned coupled to a second input of the first divider The frequencies and the output of the third frequency divider whose input is coupled to a second input of the first adder C 1,

However, the known calibrator shaper does not allow to measure the phase shift between the input voltage modulating voltages and requires the use of a separate meter in the control equipment.

The purpose of the invention is to enhance the functionality of the form Q of the calibration signal rotor by measuring the phase shift between the input voltage modulating voltages.

Claims (1)

The goal is achieved, 5 in that a calibration signal generator containing a first phase detector, whose input is an input of a calibration signal generator, connected to a sequentially controlled oscillator, a first frequency divider, a first adder and a minimum limiter, the output of which is a generator output calibration signal. the second frequency divider and the third frequency divider connected in series, the first input of the first frequency divider is connected to the first input of the second frequency divider, the second input of which is connected to the second input of the first frequency divider and the output of the third frequency divider, the input of which is connected to the second input of the first adder, A second phase detector connected in series is inputted, the input of which is connected to the input of the first phase detector, and a second adder, the output of which is connected to the input of the controlled generator. a, and the second input is connected to the output of the first phase detector, connected in series the first low-pass filter, the first limiter, the phase shifter, the third phase detector and the indicator, connected in series the second low-pass filter and the second limiter, the output of which is connected to the second input of the third phase detector, the second input and the output of the first phase detector are connected respectively to the output of the first frequency divider and the input of the first low-frequency filter, and the second input and output of the second phase detector connected respectively with the output of the second frequency divider and the input of the second filter low frequencies. The drawing shows the structural electrical circuit of the calibration signal generator, the calibration signal generator contains the first phase detector 1, the second phase detector 2, the first adder 3, the controlled oscillator k, the first frequency divider 5, the second frequency divider 6, the third frequency divider 7, the second adder 8, the limiter 9 to a minimum, the first low-frequency filter 10, the second low-frequency filter 11, the first limiter 12, the second limiter 13, the phase shifter 1, the third phase detector 15 and the indicator 16. Shaper l calibration signal works as follows. A signal envelope of the landing beacons, which is the sum of the harmonious coherent modulation signals of the carrier beacons, enters the input of the calibration signal generator. The modulation frequencies are equal to 90 and 150 Hz, respectively. The constants of the outputs of the outputs of the first and second phase detectors 1 and 2, which are the result of comparing the phases of the signals arriving at their inputs, after summing in the adder 3, control the frequency of the controlled oscillator k. the nominal frequency of the controlled oscillator is chosen equal to 900 Hz (twice the value of the lower total multiple for frequencies 0 and 150 Hz). The division factors of frequency dividers 5 and 6 are chosen respectively 10 and 6, and the output of the corresponding frequency dividers form coherent symmetric signals of the square wave type, which arrive at the inputs of the second adder 8, and then after summing up to the minimum limiter 9. The division factor of the third divider 7 frequency is chosen equal to 3 and its output voltage periodically phases the output signals of the first and second frequency dividers. Thus, after summing the output signals of the first and second frequency dividers and limiting the minimum at the output of the calibration signal generator, a normalized signal is formed, the frequency components of which and the phase shift between them exactly match the parameters of the envelope of the landing beacons at the input of the calibration signal shaper Simultaneously at the outputs the first and second phase detectors 1 and 2 are formed variable components of the difference frequency of 60 Hz, the phase shift between which is equal to AZOV shift between the frequency of the signal envelope constituting landing beacons on input of the calibration signal. These components, with the output of the phase detectors, are filtered out by the corresponding low-frequency filters 10 and 11, limited by the corresponding limiters 12 and 13, and fed to the third phase detector 15 to measure the phase shift between them. For ease of reading off the indicator 16, the phase of the signal from the output of the limiter 12 is changed by 90 using the phase shifter I. The technical and economic effect of using the invention is to reduce the manufacture cost of the calibration equipment by eliminating from its composition a special phase shift meter components the signal envelope of the landing beacons at the input of the former of the calibration signal Formula of the invention The former of the calibration signal containing the first phase detector, the input of which wired by the calibration signal generator, connected in series by a controlled generator, first frequency divider, first adder and minimum limiter, the output of which is the output of the calibration signal shaper, connected in series second frequency divider and third frequency divider, the first input of the first divider frequency is connected to the first input of the second frequency divider, the second input of which is connected to the second input of the first frequency divider and the output of the third frequency divider, input which is connected to the second input of the first adder, characterized in that, in order to expand 06 functionality by measuring the phase shift between the modulating voltages of the input signal, a second phase detector connected in series is inputted into it, the input of which is connected to the input of the first phase signal detector, and the second adder, the output of which is connected to the input of the controlled oscillator, and the second input is connected to the output of the first phase detector, connected in series the first low-frequency filter, p The first limiter, the phaser, the third phase detector and the indicator, are connected in series the second low-pass filter and the second limiter, the output of which is connected to the second input of the third phase detector, the second input and the output of the first phase detector connected to the output of the first frequency splitter respectively low frequency, and the second input and output of the second phase detector are connected respectively to the output of the second frequency divider and the input of the second low frequency filter. Sources of information taken into account in the examination 1. USSR author's certificate ff682851, cl. G 01 S y / jO, 1978 (prototype).