SU1550435A1 - Oscillographic phase meter - Google Patents

Abstract

The invention relates to a radio measuring technique and can be used in radar and communication, where signals with combined linear frequency modulation and phase shift manipulation are widely used. The aim of the invention is to extend the functionality of a photometer by visual assessment of the main parameters of signals with combined linear frequency modulation and phase shift manipulation. The goal is achieved by introducing into the phase meter two multipliers 16, 21 frequencies by eight and two dividers 17, 22 frequencies by eight, an adjustable delay unit 18, a narrow-band filter 23, a phase detector 24, a low frequency filter 25, a control unit 26, a frequency converter 27 voltage generator 28 sawtooth voltage, CRT 29, key 15. 1 Il.

Description

by a gray filter 20 and fed to the input JQ modulates the frequency electron multiplier 21 by eight, the output of which produces a voltage

Ufi (t) -U5cos (8u) 6t + 8tpK / t + 8tfo) “Uecos (8u et + 84V). .. 15

The voltage U61 (t) is fed to the input of the frequency divider 22 by eight, the output of which is the voltage

Uff3 (t) lVcos (e "fct + 45),. 20 which is a harmonic oscillation at a beat frequency.

Voltage U53 (t) is allocated by a narrow-band filter 23 and is fed to the first input of the phase detector .25 24, to the second input of which voltage is supplied from the output of the generator 10 of the reference voltage

Ue (t) U0-cos (w0t-nf0),

where, is the amplitude, frequency, and the initial phase of the generator voltage.

If said voltages differ in frequency and phase from each other, then a control voltage is generated at the output of the phase detector 24 35. Moreover, the amplitude and polarity of this voltage depend on the degree and direction of the beating frequency deviation.

beam in brightness. On the screen of a CRT 13, an image is formed in the form of several bright dots located on the circumference. The number of points determines the multiplicity of phase manipulation, m, and the angular distance between them is equal to the magnitude of phase jumps of the received chirp-FMN signal. In case of inequality, the frequency we and () brightness labels move in a circle with a difference frequency.

For a visual estimation of the linear frequency modulation parameters, the TF signal Un. (T) from the output of the frequency divider 17 is used by eight. It is possible to visually assess the main parameters of the chirp signal (frequency deviation dfo, rate of change of frequency y inside the pulse and its duration

t ").

Delay time C, delay line 7 is chosen so that the main parameters of the received chirp-FMN signal can be visually assessed by observing oscillograms on CRT screens 9, 13 and 29. After this time has passed, the voltage from the output of delay line 7 is fed to the reset input of accumulator 8 In this case, the sweep generator 1 is transferred to the tuning mode and the key 6 is closed, i.e. is transferred to its original state. From this point on, the review of the specified frequency range and the search for the chirp-FMN signals continues.

с с from frequency

and; 0 of the generator 10 reference voltage. The control voltage is extracted by the lowpass filter 25 and with the help of the control unit 26 it acts on the variable delay unit 18 by varying the delay so that the equality

 .

For a visual assessment of the magnitude of the phase jumps D1 / and the multiplicity of phase manipulation m of the received chirp-FMN, a CRT 13 with a circular scan is used. Moreover, the circular sweep is formed using the reference voltage generator 10, the frequency we of which is maintained equal to the beat frequency (105 o / using the phase locked loop. The voltage U $ ((t) at the beat frequency c

modulates the electronic

five

beam in brightness. On the screen of a CRT 13, an image is formed in the form of several bright points located on a circle. The number of points determines the multiplicity of phase manipulation m, and the angular distance between them is equal to the magnitude of phase jumps of the received chirp-FMN signal. When the we and () frequencies are unequal, the intensity labels move in a circle with a difference frequency.

For a visual estimation of the linear frequency modulation parameters, the TF signal Un. (T) from the output of the frequency divider 17 is used by eight. It is possible to visually assess the main parameters of the chirp signal (frequency deviation dfo, rate of change of frequency y inside the pulse and its duration

t ").

Delay time C, delay line 7 is chosen so that the main parameters of the received chirp-FMN signal can be visually assessed, the oscillograms are observed on CRT screens 9, 13 and 29. After this time has elapsed, the voltage from the output of delay line 7 goes to the accumulator reset input 8. In this case, the sweep generator 1 is transferred to the tuning mode and the key 6 is closed, i.e. is transferred to its original state. From this point on, the review of the specified frequency range and the search for the chirp-FMN signals continues.

Claims (1)

Invention Formula An oscillographic phase meter containing a series-connected local oscillator, a mixer, the second input of which is a phase meter input, an intermediate frequency amplifier and a drive, the second input of which is connected to the output of the delay line, and the output - to the input of the delay line, the input of which is connected to the output of the intermediate frequency amplifier, and with the ver the ticking electrode of the first cathode ray tube, the horizontal electrode of which is connected to the output of the sweep generator, as well as successively included reference voltage generator, phase shifter by 90 °, the first amplifier and the horizontal electrode of the second cathode ray tube, the vertical electrode of which is connected through the second amplifier with the output of the reference voltage generator, characterized in that, in order to expand its functionality, a second key is introduced into it, two frequency multipliers by eight, two frequency divider by eight, adjustable delay block, multiplier, band-pass filter, phase detector, low-pass filter, control block, frequency to voltage converter, sawtooth generator, pulse shaper, narrow-band filter, and a third electron-beam tube between the output of the intermediate frequency amplifier and the first input of the second key, the multiplier and the band-pass filter are connected in series, between the output of the second key and the second electrode by equalizing electrode g 5 0 0 five a pulse tube is connected to a pulse shaper, the second input of the second key is connected to the output of the accumulator, to the output of the first key are connected in series the first frequency multiplier by eight, the first frequency divider by eight and the adjustable delay unit, the output of which is connected to the second input of the multiplier, A second frequency multiplier by eight, a second frequency divider by eight, a narrow-band filter, a phase detector, the second input of which is connected to the output of the gene, are serially connected to the output of the bandpass filter. Ator reference voltage, a lowpass filter and a control unit, the output of which is connected to the second input of the adjustable delay unit, to the output of the first frequency divider into eight series connected frequency converter. the voltage and the vertical electrode of the third cathode ray tube, the horizontal electrode of which is connected to the output of a saw generator of a different voltage, the input of which is connected to the output of the first frequency divider by eight.