SU1109667A1 - Meter of standing wave total resistance and coefficient - Google Patents

Abstract

MEASURING COMPLETE RESISTANCE AND COEFFICIENT OF A STANDING WAVE, containing a series-connected generator, a measuring line in which P sensors are installed at the same distance from each other, the outputs of which through corresponding voltage converters are connected to the calculator, the output of which is connected to each other to the input of the display unit of the sesaBOiwiA information display, the output of the measuring line being the input for connecting the test load, characterized in that, in order to expand the In addition to that, the dynamic and dynamic ranges and the increase in measurement accuracy introduced two additional sensors, one of which is installed in the plane connecting the measuring line to the generator, and the other in the plane connecting the measuring line to the load under study, while the outputs of the additional sensors through the respective transducers voltage - the code is connected respectively to two additional inputs of the calculator, to the third additional input of which through the input converter frequency - code is connected to the generator output.

Description

The invention relates to a radio metering technique and can be used to measure a parameter of two-port networks, two-port networks, namely: measuring their impedance and reflection coefficient. Measure automatic impedances, containing a sequentially connected source of a frequency-frequency-modulated signal, mixer, another input which serves to connect the object under study, as well as the indicator fij. However, such a meter does not provide high accuracy of measurement. The closest to the invention is an impedance meter and a standing wave coefficient (SWR) containing a series-connected generator, a measuring line in which d sensors are installed at an equal distance from each other, the outputs of which are through the corresponding voltage converters are connected respectively to the inputs of the calculator whose output is connected to the input of the information display unit, while the output of the measuring line is the input for connecting the test load f2j. However, the known meter has narrow frequency and dynamic ranges and low measurement accuracy. The purpose of the invention is to expand the frequency and dynamic ranges and improve measurement accuracy. The goal is achieved by measuring an impedance and a standing-wave coefficient containing a measuring line connected in series, in which P sensors are installed at the same distance from each other, the outputs of which are connected to the inputs of the calculator via the corresponding voltage converters , the output of which is connected to the input of the information display unit, while the output of the measuring line is the input for connecting the test load, two additional sensors are introduced one, which is installed in the plane of connection of the measuring line to the generator, and the other in the plane of connection of the measuring line to the load under study, while the outputs are additional. sensors through the input of the corresponding voltage transducers - the code is connected respectively to two Additional inputs of the transmitter, to the third additional input of which through the entered frequency converter - the code the output of the generator is connected. The drawing shows a structural electrical circuit of the impedance meter and the CWS. The impedance meter and the CWS contains a series-connected generator 1, a measuring line 2, in which P sensors 3 are installed at the same distance from each other, the outputs of which are connected to the inputs of the calculator 5 through corresponding converters 4, the output of which, for example through the converter 6, the code-code is connected to the input of the information display unit 7, the output of the measuring line 2 being the input for connecting the test load 8, two additional sensors 9 and 10, one of which is installed in the plane of connection of the measuring line 2 to the generator 1, and the other is in the plane of connection to the load 8 under study, while the outputs of the additional sensors 9 and 10 are inserted through the corresponding voltage converters 4 — the code is connected to two additional inputs of the calculator 5, to the third auxiliary input of which, via the frequency converter inputted 11, the code is connected to the output of the generator 1. Measuring impedance and CWS works as follows. The incident wave voltage of the measurement frequency propagates from generator 1 along measuring line 2 to test load 8. If test load 8 is a complex, reactive or active resistance that is not equal to the characteristic impedance of measuring line 2, then a reflected wave appears. As a result of the interaction of the incident and reflected vopn, a certain amount is formed at the input, output and at the sections of the measuring line 2 according to a well-known law.

stress distribution depending on the frequency and nature of the load. Voltage converter 4 - code converts analog information about voltage distribution into machine code of calculator 5, which is based on the algorithm of the program using the known laws, known coordinates of the location of sensors 3, 9 and 10 and information about the frequency received through frequency converter 11 the code calculates the positions of nodes and antinodes along the length of the measuring line 2, their relative value and then the calculation of the CWS, impedances.

The results of the calculations, expressed in the output machine code, are sent to the converter 6 code

a code that converts the computer code of the calculator 5 to the code of the information display unit 7 (e.g., digital display boards) or to the actuator control code (for example, data printing systems or impedance matching systems).

The operation of the impedance meter and the CWS with a matched load occurs at equal voltages at all points of the measuring line 2.

The impedance meter and the CWS meter provides a measurement in a wider dynamic and frequency ranges due to a consistent measuring line, the possibility of taking into account parasitic parameters of the input and output circuits, as well as higher measurement accuracy.

Claims (1)

FULL RESISTANCE METER AND STANDING WAVE COEFFICIENT, comprising a generator connected in series, a measuring line in which And sensors are installed at the same distance from each other, the outputs of which are connected through the corresponding voltage-code converters to the inputs of the calculator, the output of which is connected to the input of the information display unit while the output of the measuring line is an input for connecting the test load, characterized in that, in order to expand the frequency and dynamics range and increase the accuracy of measurements, two additional sensors are introduced into it, one of which is installed in the plane of the measuring line connecting to the generator, and the other in the plane of connecting the measuring line to the load under study, while the outputs of the additional sensors through the corresponding voltage-code converters are connected accordingly, with two additional inputs of the calculator, to the third additional input of which, through the entered frequency converter, the code is connected od generator. '. <R * * * 4  * <1. - .... 1 1 ι eleven , X J, 1 1 1 1 4 4 G - ^J 1 5 I