SU817596A1 - Device for reproducing high-frequency ac voltage - Google Patents

Description

, one . The invention relates to electrical measurements, in particular, to exemplary apparatus for the calibration and testing of measuring instruments for alternating high-frequency voltage. A device for reproducing high-frequency alternating voltage is known, which contains a generator / filter, switch, load, bridge circuit, tax-to-digital converter, a reading device and a connector, at the output of which a high-frequency alternating voltage is reproduced | l. The disadvantages of the known devices are low accuracy of determining the value of reproducible voltage at low values, as well as the dependence of the indications on temperature, as a result of which the reproducible voltage range cannot be wider than 0.1-1V and the absence of a direct reference. . It is also known / device containing series-connected generator, switch and load, series-connected first connector, the first bridge element and. the reading device, the second output of the switch is connected to the first connector 2. A disadvantage of the prior art device is the low accuracy in reproducing high-frequency alternating voltages less than 0, 1V, as a result of which the lower limit of reproducible voltages has to be limited to 0.1V. In addition, taking into account that the maximum level of reproducible voltages for creatures at present, thermoresistors are 1B, the range of reproducible voltages at a known device is narrow and is 0.1-1V. The purpose of the invention is to improve the accuracy and expand the range of reproducible voltages. This goal is achieved by the fact that a device containing a generator, a switch and a load connected in series, a first connector, a first bridge element and a reading device, and a second switching output connected to the first connector, are equipped with a second connector, a second bridge element, a symmetrical adjustable divider voltage and indicator, while

the third output of the switch is connected to the second connector, the indicator and the input of a symmetric adjustable voltage divider, the output of which is connected to the first connector; the second bridge element is connected to the second input of the reading device.

The drawing shows a block diagram of the device.

The device contains a generator 1, a switch 2, a load 3, a second connector 4, an indicator 5, a symmetrical adjustable voltage divider 6, the first connector 7, the first bridge element 8, the second bridge element 9 and the reading device 10. The generator is connected in series 1, switch 2 and load 3, the first connector 7 is connected in series, the first bridge element 8 and one of the inputs of the reading device 10, the second output of the high-frequency switch 2 is connected to the first connector 7, the free output of the high-frequency switch 2 connected to the second connector 4 by the indicator 5 and the input of the symmetric adjustable voltage divider 6, the output of which is connected to the first connector 7, the second bridge element 9 is connected to the other input of the reading device 10.

The proposed device works as follows.

At the first stage, the switch 2 is set to a position in which the high-frequency voltage from the input of the generator 1 is supplied to the load 3. At the output of the first bridge element 8 (the thermistor arm of the bridge), a constant voltage U (U) is established.

In the second bridge element 9, a thermistor resistor is used, which is identical in parameters to the thermistor used in the first bridge element B. Structurally, both thermistors are placed in close proximity to each other {however, the alternating high-frequency voltage will be applied only to the thermoresistor included in the first bridge element 8) and therefore equally perceive changes in ambient temperature; The mode of operation of the second bridge element 9 is selected so that the voltage on its thermistor is equal to the voltage on the thermistor in the first bridge element 8 (for zero digital display in the sample device 10. When the ambient temperature of the voltage U changes , ct Aca will change in the same way and their difference will remain equal to O, i.e. the reproduction error of the alternating voltage of high frequency and due to a change in the ambient temperature will be significantly reduced.

In the second stage, the switch 2 is set at a position in which a high-frequency voltage is applied to the first connector 7, the input of the first bridge element 8 (to the thermistor of the first bridge element 8). In this case, depending on the value of the high-frequency voltage at the input of the first bridge element 8 and the output of the first connector 7, a certain value of the constant voltage at its output will be set (for example, U -g and the voltage at the output of the second bridge element 9 will remain equal to / The ls2 of the display panel of the reading device 10 will indicate the value of the high-frequency voltage being reproduced at the output of the first connector 7.

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To reproduce the proposed device Urt / less than 0.03V, the self-calibration operation is first performed, during which the division factor of the symmetric adjustable voltage divider 6 is determined.

Claims (2)

This is done as follows. Switch 2 is set to a position in which a high-frequency voltage from the output of generator 1 is applied to the output of a symmetric adjustable voltage divider b, the input of the first bridge element 8 and the output of the first connector 7. The level of this voltage U is set equal to 0.03 V, as shown the display of the reading device 10 by adjusting the voltage at the output of the generator 1. Set the value of the division factor of the symmetric adjustable voltage divider 6 to 1 and at the same time record the indicator 5, switching on the input of a symmetric adjustable voltage divider 6. Then the voltage level and output of the symmetric adjustable voltage divider 6 is set to 1V (according to the digital scoreboard display from the counting device 10 by adjusting the voltage at the output of the generator 1). Increase the division factor | of the symmetric adjustable voltage divider 6 until the readings of the indicator 5, previously recorded, are restored. The division factor of the symmetric regulated voltage divider 6 is equal to the quotient of the case, or 1V by 0.03V, i.e. 30 dB. In this operation, the self-calibration is completed, then, at the output of the symmetric adjustable voltage divider 6 (as indicated by the digital reading device 10) of the high-frequency voltage in the range of 0.03-1B (as described above), At the input of a symmetric adjustable voltage divider 6 (the division factor of which was 30 dB during the self-calibration operation), and hence at the output of the second connector 4, to obtain high-frequency voltages in the range of 0.001-0.03 V. To determine the value of The produced high-frequency voltage. The readings of the display of the reading device 10 must be reduced by 30 dB 33 33 times. For reproduction, the proposed device values ц more than 1V, switch 2 is set to a position in which high-frequency voltage from the output of generator 1 is applied to the input of a symmetrically adjustable voltage divider 6, the input of indicator 5 and the output of the second connector 4. Since the loads connected at the input and the output of the symmetric adjustable voltage divider have a different impedance. The division ratio from input to output may differ from the division ratio from output to input. Now it is necessary to repeat the self-calibration operation, at which we determine the division factor of the symmetric adjustable divider 6 voltage from the input to the output. To do this, set the division factor of the symmetric adjustable voltage divider equal to 1. The level of the high-frequency voltage at the output of the generator 1 is set at which the high-frequency voltage at the output of the symmetric adjustable voltage divider is 1c (according to the reading device 10), fix the readings of the indicator 5, and keeping them constant (by adjusting the voltage at the output of the generator 1), changing the division ratio of the symmetric adjustable divider voltage establishing a voltage to its output vysokochas-frequency voltage equal to 0,03V (on board digital reading device 10). Thus, the division ratio of the symmetric regulated voltage divider 6 is equal to the partial from the division of 0.03V by 18, i.e. 30 dB. Subsequently, a high-frequency voltage in the range of 0.03-1V can be installed at the output of a symmetric regulated voltage divider 6 (based on the readings of the reading device 10) in the range of 0.03-1V at the input of the specified divider 6, and hence. At the output of the second connector 4, receive high-frequency voltages in the 1-ZOV range. The device provides the accuracy of reproduction of alternating high-frequency voltage at levels of less than 0.1 V is 5-10 times higher than that of the known device, which, in turn, allowed us to obtain a range of reproducible voltages but less than 30 times wider than at the known device. Claim device A device for reproducing alternating voltage is high; frequencies containing a generator, a switch and a load connected in series, the first connector, the first bridge element and the reading device, the second output of the switch are connected to the first connector, characterized in that, in order to increase the accuracy and expand the range of reproducible voltages, it is provided with a second a connector, a second bridge element, a symmetrical adjustable voltage divider, and an indicator; the third output of the switch is connected to the second connector, the indicator, and the input A symmetric adjustable voltage divider, the output of which is connected to the first connector, the second bridge element is connected to the second input of the reading device. Sources of information taken into account in the examination 1.Fyodorov A.N., Krestovsky V.V. State special standard unit of AC voltage at high frequencies. Measuring equipment, 1974,; .№ 11, p. 6-8. 2. USSR Author's Certificate No. 635432, G 01 R 19/02, 1978. V