SU1524016A1 - Radio-pulse method of determining the group delay time of high-frequency line - Google Patents

Abstract

The invention relates to radio engineering. The purpose of the invention is to improve the measurement accuracy. The essence of this measurement method is explained by a device containing a shaper 1 modulating video pulses, a 2 RF generator, a modulator 3 pulses, a circulator 4, an oscilloscope 5 and the RF path 6. Under the action of the generated modulating video pulses, the modulator 3 performs pulse modulation signal of generator 2. The radio pulses generated in this way go through the circulator 4 to the RF path 6, pass through it to the load, are reflected and, again passing through the RF path 6 and the circulator 4, go to the oscilloscope 5. It A part of the probe radio pulse transmitted through the circulator 4 in the opposite direction is also applied. The group delay time of the RF path 6 is defined as half the time interval between the marks of the probe and reflected pulses. The goal is achieved by increasing the power of the spectral components of the radio pulse lying outside the load matching band, the reflection coefficient module of which is close to unity outside the matching frequencies. 1 il.

Description

The invention relates to radio engineering, in particular to measuring the characteristics of communication lines and channels, and can be used to measure group delay time in passive microwave quadrupoles loaded on a load matched in the frequency band.

The purpose of the invention is to increase the accuracy of measurement jq.

The drawing shows a structural electrical diagram of a device that implements a radio-pulse method for measuring the group delay time of the 15 high-frequency path.

The device comprises a driver 1 of modulating video pulses, a high-frequency generator 2, a pulse modulator 3 20, a circulator 4, an oscilloscope 5, and a high-frequency path 6.

The radio-pulse method for measuring the group delay time of the high-frequency channel is implemented in a very efficient way.

Shaper 1 produces modulating video pulses, the duration of which is selected from the condition t _p i 2 / ^ f _c> where Δf _c is the frequency matching band 3 of the load of the high-frequency path 6, These modulating video pulses are fed to modulator 3, which performs pulse modulation of the output continuous signal of generator 2 , the frequency of which is chosen equal to the center frequency of the load matching band of the high-frequency path 6.

The radio pulses formed in this way through the circulator 4 enter the input of the high-frequency path 6, pass through it to the load, are reflected and, again passing through the high-frequency path 6 and circulator d 4, go to the oscilloscope 5, which also receives a part of the probe radio pulse, passed through the circulator 4 in the opposite direction.

Since the width of the spectrum of the probe radio pulse exceeds the frequency matching bandwidth of the load of the high-frequency path 6, the central part of the spectrum, the width of which is equal to the frequency matching band, is absorbed in the high-frequency channel load, and two symmetrically located side parts of the spectrum lying outside the frequency matching band are reflected from the load, whose reflection coefficient modulus is close to unity outside the matching band, and through the circulator 4 they are fed to the input of the oscilloscope 5. These spectral components -governing can be regarded as spectra radiopulse signals with different frequencies filling. They will interfere with the input converter of the oscilloscope 5, forming a mark from the radio pulse with a low-frequency filling on the screen. The group delay time of the high-frequency path 6 is defined as half the time interval between the marks of the probe and reflected pulses. In the presence of dispersion of the high-frequency path 6, the propagation velocities of the lateral parts of the spectrum will be different, and two marks of the reflected signal may appear on the screen of the oscilloscope 5. In this case, the group delay time of the high-frequency path at the load matching frequency is determined by averaging the time intervals between the probe pulse mark and the reflected pulse marks.

Improving the accuracy is achieved by increasing the power of the spectral components of the radio pulse lying outside the load matching band, the reflection coefficient module of which outside often ¹ / · matching is close to unity.

Claims (1)

Invent N'i Formula A radio-pulse method for measuring the group delay time of a high-frequency channel, based on sensing the studied high-frequency channel with a radio pulse, receiving a radio pulse reflected from its load, and measuring the interval between the probe and reflected radio pulses, characterized in that, in order to increase the measurement accuracy, the spectrum of the probe radio pulse is formed symmetrical with respect to the central part of the matching band of the load of the high-frequency path and increasing this matching band.