RU72332U1 - DEVICE FOR MEASURING FULL RESISTANCE - Google Patents

Abstract

A device for measuring impedances, comprising a generator connected to the input of the measuring line, with sensors located along it, the outputs of which are connected to the information inputs of a program-controlled switch, the control input of which is connected to the first output of the processing and program control unit, the inputs of which are connected to the outputs a software-controlled switch and a computer, the inputs of which are connected to the second output of the software-controlled switch and the output of the block for generating numerical values of five measured parameters, the input of which is connected to the second output of the processing and program control unit, and the information output unit, characterized in that the measuring line is made in the form of segments of a transmission line parallel to each other, with the end of each fuzzy segment and the beginning of each even segment transmission lines are connected respectively through additional inductors, the middle terminals of which are connected to the inputs of the sensors, with the end of the next even and the beginning of the next odd segments of the transmission line, and the free ends of the first and last segments of the transmission line are the input and output of the transmission line, while a scaling unit is introduced into the device, the input of which is connected to the corresponding output of the processing and program control unit, and the output to the input of the information output unit.

Description

The utility model relates to the field of measurement technology, and can be used to measure the impedance of bipolar components, including active ones, in a wide frequency range in the nominal power mode.

Known devices for measuring the impedance based on measuring lines with a movable probe, described, for example, in the monograph: A.Z. Fradkin, E.V. Ryzhkov. “Measurement of the parameters of antenna-feeder devices” - M .: Communication, 1972, p. 87. The disadvantage of such devices is the length of the measurement process, low accuracy, the need for mechanical movement of the probe.

More promising, especially for automated measuring systems, are devices with multi-probe measuring lines in which several sensors (probes) are placed along the measuring line. The number of sensors and the distance between them is determined by the frequency range at which measurements are made.

The prototype of the alleged invention is the USSR AS No. 1337822 cl. G01R 27/04, 08.16.84 “Device for measuring the impedances”, containing a generator, to the output of which a measured load is connected through a measuring line, along the measuring line there are sensors, to the outputs of which a program-controlled switch is connected, one of the outputs of which is connected to the first input of the processing and program control unit, the first output of which is connected to the control input of the program-controlled switch, the second output is connected through the generator of numerical values of five variable parameters ene to one of the inputs of the calculator, the other input of which is connected to the second output of program-controlled switch, and a third output coupled to an input of the output unit, the output of the calculator is connected to a second input of the processing unit and software control.

The principle of operation of the known device for measuring the impedance is as follows. A sinusoidal signal is supplied from the generator to the measuring line, to the output of which the studied load is connected. From sensors located along the length of the measuring line, the voltages are removed, which through a program-controlled switch are supplied to one of the inputs of the processing unit and program control. At another input of this block, a signal is generated by the calculator in accordance with the formula:

information about the coordinates of the connected sensors x comes from the second output of the program-controlled switch, and from the generator of numerical values of five variable parameters, numerical values are received where α ₁ is the voltage at the measured load; α ₂ - losses in the measuring line; α ₃ - electric length of the measuring line; α ₄ is the active (resistive) part of the measured load resistance, α ₅ is the reactive part of the measured load resistance, L is the length of the measuring line, ρ is the wave impedance of the line. In the processing and program control unit, for each selected value of x, the measured and calculated signals are compared, squared and the error calculated by summing the result with the previous one. After interrogating all the sensors, the obtained error value is checked for the termination condition of the measurement process, if not fulfilled, the error value is reset to zero, a signal for changing the parameters is generated resulting in a reduction in error and the process is repeated. The termination of the process is the reduction of the total error below a predetermined level. In this case, the signal from the processing and program control unit enters the information output unit, which outputs the found parameters α ₄ and α ₅ .

The disadvantages of the known device for measuring the impedance are its large dimensions at the lower frequencies of the operating range and the decrease at these frequencies of measurement accuracy. This is due to the fact that the sensors are located along the measuring line, the length of which increases as the lower frequency of the operating range decreases, which, in turn, leads to an increase in the dimensions of the device. This is especially significant in the meter and decameter wavelength ranges, where the line length can reach units or even tens of meters. At the same time, when measuring at a high power level, the measuring line is very difficult to bend in any way due to its large cross-section, therefore, the length of the connecting wires from the sensors to the program-controlled switch increases, which leads to an increase in high-frequency pickups and, as a result, to a decrease in the measurement accuracy.

The presence of higher harmonic components in the signal of the measuring line, caused by the nonlinearity of the measured two-terminal network, which, as a rule, manifests itself when measuring active elements at a high power level, also leads to a significant decrease in the measurement accuracy. The difference between the signal and the sinusoidal leads to a mismatch of the measured voltage distribution along the line

theoretical, and, as a consequence, inaccurate determination of the actively reactive components of the input resistance.

The problem solved by the utility model is the development of a device having a short length at low frequencies of the operating range and high measurement accuracy.

The problem is solved due to the fact that the proposed utility model, like the known device, contains a generator connected to the input of the measuring line with sensors located along it, the outputs of which are connected to the information inputs of a program-controlled switch, the control input of which is connected to the first output of the unit processing and program control, the inputs of which are connected to the outputs of a program-controlled switch and a computer, the inputs of which are connected to the second output of a program-controlled nth switch and the output of the unit for generating numerical values of five measured parameters, the input of which is connected to the second output of the processing and program control unit and the information output unit. But, unlike the known one, in the proposed device the measuring line is made in the form of segments of the transmission line located parallel to each other, with the end of each fuzzy segment and the beginning of each even segment of the transmission line connected respectively through additional inductors, the middle terminals of which are connected to the inputs of the sensors , with the end of the subsequent even and the beginning of the subsequent odd segments of the transmission line, and the free ends of the first and last segments of the transmission line are the input and output ohm transmission line, wherein the apparatus introduced scaling unit, whose input is connected to the corresponding output of the processing unit and program control, and an output - to the input information unit output.

The technical result achieved at the same time - reducing the dimensions at the lower frequencies of the operating wavelength range and improving the measurement accuracy is achieved by performing a measuring line in the form of segments of a transmission line parallel to each other, with the end of each odd segment and the beginning of each even segment of the transmission line connected respectively additional inductors, where the inductance value is selected from the ratio:

(W, ΔL is the wave resistance and length of the segments of the measuring transmission line, Co = 3 × 10 ⁸ m / s is the speed of light in vacuum, k _y is the shortening factor of the wavelength in the segments of the transmission line

(Co / k _y is the propagation velocity of electromagnetic waves in segments of the transmission line), f _up is the value of the upper cutoff frequency at which measurements are taken), the average terminals of which are connected to the inputs of the sensors, with the end of the next even and the beginning of the next odd segments of the transmission line, and the free ends of the first and last segments of the transmission line are the input and output of the transmission line and the introduction of a scaling unit into the device, the input of which is connected to the corresponding input of the block and processing and software control I, and the output - to the input information block output provides improved measurement accuracy and reduction in the device size.

The drawing shows a structural diagram of a device for measuring impedances.

The utility model is an input generator 1, the output of which is connected to the measuring line 2, the output of which 3 is for connecting the measurement object, sensors 4, the outputs of which are connected to the information inputs of the program-controlled switch 5, the control input of which is connected to the first output of the processing unit and software control 6, the inputs of which are connected to the outputs of the program-controlled switch 5 and the calculator 7, the inputs of which are connected to the second output of the program-controlled switch 5 and you one of the unit for generating numerical values of the five measured parameters 8, the input of which is connected to the second output of the processing and program control unit 6, a scaling unit 9, the output of which is connected to the input of the information output unit 10, inductance coil 11, the middle conclusions of which are connected to the inputs of the sensors 4, the inputs are connected to the end of each previous odd and the beginning of each subsequent even segment of the transmission line 12, and the outputs are connected to the end of each subsequent even and the beginning of each subsequent odd neg viscous transmission line 12.

A device for measuring the impedance works as follows.

From the generator 1, a sinusoidal signal enters the measuring line 2, to the output 3 of which the measured load (measurement object) is connected. The voltage from the sensors 4 through a program-controlled switch 5 is supplied to one of the inputs of the processing unit 6 and program control. To another input of this block, a signal is generated by the calculator 7 in accordance with formula (1), and from block 8 of generating numerical values of five variable parameters, numerical values of five variable parameters are received where α ₁ is the voltage at the measured load; α ₂ - losses in line 2; α ₃ - electric length of the measuring line; α ₄ - active part of the measured load resistance} α ₅ - reactive

solid line; α ₄ - active part of the measured load resistance} α ₅ - reactive part of the measured load resistance; L is the length of the measuring line.

In block 6 processing and program control for each selected value of x, the measured and calculated signals are compared, squared and the error calculated by summing the result with the previous one. After interrogating all the sensors 4, the obtained error value is checked for the termination condition of the measurement process, if not fulfilled, the error value is reset, the signal for changing the parameters is generated resulting in a reduction in error, and the process is repeated.

The termination of the measurement process is the reduction of the total error below a predetermined level. In this case, the numerical values of the parameters α ₄ and α ₅ are fed to the input of the scaling unit 9, in which these parameter values are multiplied by the value of the wave impedance calculated according to the relation:

where f is the frequency at which measurements are made, and from the output of scaling unit 9, the numerical values of the parameters α ₄ ρ and α ₅ ρ are supplied to the information output unit 10.

Due to the connection of the segments of the transmission line through the introduced additional inductances 11, the values of which are calculated by the formula (2), frequency-selective properties appear on the measuring line 2. A signal with a frequency above the boundary - f _up quickly attenuates when propagating along the measuring line. Therefore, if the frequency of the test signal lies in the range (0.5 ... 1.0) f _up , then the higher harmonics arising in the reflected wave with the non-linear nature of the load connected to the output of the measuring line decay quickly, and the voltage distribution curve lines will be formed only by the first harmonic of the reflected signal. If the load has a symmetric current-voltage characteristic, then in addition to the first harmonic, only odd higher harmonics (3rd, 5th, etc.) will appear in the reflected wave. In this case, the frequency range in which the non-linearity of the load will not affect the measurement accuracy extends to (0.33 ... 1.0) f _up . This property also significantly reduces the higher harmonics in the generator signal if their frequency is higher than f _up , which also decay quickly.

However, in addition to the appearance of filtering properties of the measuring line, the introduction of inductances 11 leads to a frequency dependence of the equivalent wave impedance of the measuring line (in accordance with expression (3).

Therefore, a scaling unit 9 is introduced into the circuit of the impedance measuring device, in which the value of the wave resistance of the measuring line is calculated

at the measurement frequency, by which the found values of the parameters α ₄ and α _{5 are} then multiplied.

Functionally, the scaling unit consists of a calculator of the value of the scale factor ρ and multipliers of this value by the previously found values of the parameters α ₄ and α ₅ , W, ΔL are the wave resistance and length of the transmission line segments, C = 300 m / s is the speed of light in vacuum, Rx - coefficient of shortening the wavelength in segments of the transmission line.

The technical result achieved at the same time - reducing the dimensions at the lower frequencies of the operating wavelength range and improving the measurement accuracy is ensured by the implementation of the measuring line in the form of segments of the transmission line located parallel to each other and connected through additional inductances 11.

Claims (1)

A device for measuring impedances, comprising a generator connected to the input of the measuring line, with sensors located along it, the outputs of which are connected to the information inputs of a program-controlled switch, the control input of which is connected to the first output of the processing and program control unit, the inputs of which are connected to the outputs software-controlled switch and calculator, the inputs of which are connected to the second output of the software-controlled switch and the output of the block for generating numerical values of five measured parameters, the input of which is connected to the second output of the processing and program control unit, and an information output unit, characterized in that the measuring line is made in the form of segments of a transmission line located parallel to each other, with the end of each fuzzy segment and the beginning of each even segment transmission lines are connected respectively through additional inductors, the middle terminals of which are connected to the inputs of the sensors, with the end of the next even and the beginning of the next odd segments of the transmission line, and the free ends of the first and last segments of the transmission line are the input and output of the transmission line, while a scaling unit is introduced into the device, the input of which is connected to the corresponding output of the processing and program control unit, and the output to the input of the information output unit.