SU1136086A1 - Panoramic meter of critical sine waves and attenuations - Google Patents

Abstract

PANORAMIC CWS AND DECAYS MEASURER containing serially connected oscillator of oscillating frequency, directional splitter of the incident wave, to the output of the secondary channel of which is connected the first detector, directional reflector of the reflected wave, to the output of the secondary channel which is connected to the second detector connect the studied four. the third detector, the input of which is the input for connecting the output of the studied quadrupole, the ratio meter, the output of which is connected to the input of the panoramic indicator, the first input with the output of the first detector, the second input with the output of the switch, the inputs of which are connected respectively to the outputs of the second and The third detector, and an amplifier, the output of which is connected to the control of the oscillating frequency generator input, characterized in that, in order to expand the dynamic range of the measured SWR and the donkey bloyi, the input of the amplifier is connected to the second input of the ratio meter.

Description

CO 9d O 00 O) The invention relates to a radio measuring technique and can be used to automatically measure the frequency characteristics of four poles with a large dynamic attenuation range. The panoramic CWS and attenuations meter is known, which contains the oscillating frequency generator, the incident and reflected wave couplers with detectors in the secondary channels, the ratio meter and the DJ panorama. However, such a device has a small range of measurable CWS and attenuations. The closest technical solution to the invention is a panorama Hj ni meter of CWS and attenuation, containing series-connected oscillating frequency generator, a directional incident wave coupler, to the output of the secondary channel of which a first detector is connected, a directional reflector of the reflected wave, to the output of the secondary channel which is connected the detector, and the output of the main channel is the input for connecting the tested quadrupole, the third detector, whose input is the input for connecting there is no output of the studied quadrupole, a ratio meter, the output of which is connected to the input of the panoramic indicator, the first input is with the output of the first detector, the second input is with the output of the switch, the inputs of which are connected respectively to the outputs of the second and third detectors, and the amplifier whose output is connected with the control input of the oscillator of the frequency, frequency, and the input with the output of the first detector 2J. The disadvantage is known (The device is a small dynamic range of measured and attenuation. The purpose of the invention is to expand the dynamic range of the measured CWS and attenuation. To do this, in a panoramic CWS and attenuation meter, containing a series of oscillating frequency generator, a directional response of the incident wave, to the output of the secondary channel of which is connected the first ' detector of the reflected wave, to the output of the secondary channel which connects the second detector and the output The channel is the input for connecting the tested quadrupole, the third detector, whose input. is the input for connecting the output of the studied quadrupole, a ratio meter, the output of which is connected to the input of the panoramic indicator, the first input is with the output of the first detector, the second input is with the output of the switch, the inputs of which are connected respectively to the outputs of the second and third detectors, and the amplifier, output which is connected to the control input of the oscillating frequency generator, the input of the amplifier is connected to the second input of the ratio meter. The drawing shows a functional diagram of the panoramic meter CWS and attenuation. The panoramic meter contains a oscillating frequency generator 1, directional couplers 2 and 3, respectively, of the incident and reflected waves, the first, second and third detectors 4-6, the ratio meter 7, the panoramic indicator 8, the amplifier 9, the switch 10, the quadrupole 11. The panoramic meter The CWS and attenuation works as follows. When weakening the investigated four-pole 11, equal to the maximum weakening measured by the panoramic meter, there is no signal at the output of amplifier 9. The signal level of the oscillating frequency generator 1 is set in such a way that the first detector 4 operates at the upper boundary of the quadratic portion. The third detector 6 operates at the lower boundary of the quadratic part of the characteristic, since a large attenuation is introduced by the quadrupole. As the attenuation decreases, the third detector 6 reaches the upper limit of the quadratic segment, a voltage appears at the output of amplifier 9 proportional to the output signal of the third detector 6, which goes to the control input of the oscillating frequency generator 1, reduces the signal level until , until the working point of the third detector returns to the lower edge of the quadratic segment.

311360864

A further decrease in the attenuation of impolar 1: 11 is measured in a voltage leading to a proportional decrease in the range equal to twice the signal at the output of the first component of the characteristic of the third diode. Therefore, by

Thus, the characteristics of the dynamic range of variable SWR

(CWS and attenuation) of the test and attenuation is doubled.

compared to known device

Claims (1)

SWR • AND RELAXED MEASUREMENT CONVERTER, containing a serially connected oscillating frequency generator, a directional incident wave coupler, to the output of the secondary channel of which a first detector is connected, a directional reflected wave coupler, to the output of the secondary channel of which a second detector is connected, and the output of the main channel is an input for connection the investigated quadripole, the third detector, the input of which is the input for connecting the output of the studied quadrupole, the meter is relative the one whose output is connected to the input of the panoramic indicator, the first input. with the output of the first detector, the second input with the output of the switch, the inputs of which are connected respectively to the outputs of the second and third detectors, and an amplifier whose output is connected to the control input of the oscillating frequency generator, characterized in that, in order to expand the dynamic range of the measured SWR and attenuation, the input of the amplifier is connected to the second input of the ratio meter. ^FROM