SU815717A1 - High-frequency voltage source - Google Patents

Description

(54) HIGH FREQUENCY VOLTAGE SOURCE

The invention relates to electronics and can be used as an exemplary voltage measure when calibrating high-frequency voltmeters. A high-frequency voltage source is known, which comprises a generator, a divider, a wideband amplifier, a direct current amplifier, an alternating voltage converter into a constant circuit, a difference circuit, and a reference voltage source I. The closest to the technical essence is a high frequency voltage source which contains a series-connected master oscillator, a regulating node, a low-pass filter, and an attenuator, the output of which is connected to the output terminal, an alternating voltage converter into PICs are read only, whose input is connected to the output of the lowpass filter, and a difference amplifier having a first input connected to a reference voltage source 2. The disadvantage of known devices is the accuracy of the output voltage of high frequency. The aim of the invention is to improve the accuracy of the output voltage. The goal is achieved by adding an additional AC voltage converter to the source, an additional attenuator, an intermediate frequency amplifier with a detector, a mixer, four switches for several positions, two additional difference amplifiers, two memory blocks, and a heterodyne voltage source, moreover, the output of the variable voltage to constant voltage converter is connected to a common contact of the first switch, the first contact of which is connected to the first memory block and the first input of The first additional difference amplifier, the second input of which is connected to the second contact of the first switch and the output to the first contact of the second switch, an additional AC / DC converter is connected between the output terminal and the second input of the difference amplifier, the output of which is connected to the second contact of the second switch , the third contact of which is in common with the output of the second additional difference amplifier, and the common contact is connected to the control input of the regulating evil, the source the voltage of the local oscillator is connected to the first and second contacts of the third switch, the common contact of which is connected to one of the mix inputs, the other input of which is connected to the output terminal, and the output through an additional attenuator is connected to the input of the intermediate frequency amplifier with the detector, the output connected to the fourth common terminal the switch, the first contact of which is connected to the second memory unit and the first input of the second additional difference amplifier, the second input of which is connected to the second contact fourth switch.

The drawing shows a block diagram of a high frequency voltage source.

The voltage source contains a master oscillator 1, a broadband amplifier 2 with an adjustable transmission coefficient, a low-pass filter 3, an attenuator 4, a variable voltage constant-to-voltage converter 5, a reference voltage source 6, a difference amplifier 7, an additional variable voltage converter 8 constant, mixer 9, additional attenuator 10, intermediate frequency amplifier 11 with detector, four switches 12-15 three positions, first additional difference amplifier 16, second additional amplifier There are 17 differences, the first memory block 18, the second memory block 19, and a local oscillator voltage source 20.

The source works in three cycles.

The exact value of the voltage at the output of the source is obtained after the third cycle. In the first cycle, the common and second contacts of the switch 13 are connected, the common and first contacts of the switches 14 and 15. In the second cycle, the common and first contacts of the switch 12, the common and third contacts of the switch -13, the common and second contacts of the switches 14 and 15 are connected. In the third tact combined common and second contacts of the switch 12, the common and the first contacts of the switch 13.

In the first cycle, the voltage of the initial level at a given frequency is normalized and its value is stored in the second memory block 19. The voltage from the master oscillator 1 through the regulating unit 2, the filter 3, in which the highest harmonics are attenuated and the attenuator 4, in which the minimum attenuation is set, is fed to the variable voltage converter 8 to constant. From the output of the variable voltage converter, the direct voltage is supplied to the second input of the difference amplifier 7, the first input of which is supplied from the voltage source 6 of the reference voltage. The amplified difference of these voltages through the switch 13 "goes to the control input of the regulating

node 2 and changes its transmission coefficient in such a way that the source output is set to the voltage corresponding to the voltage of the source 6 of the reference voltage. The voltage error of the initial level at high frequencies is mainly determined by the error of the variable-voltage-to-constant voltage converter 8. At the same time, the voltage from the source output goes to the first (signal) input of the mixer 9, and to the second input of the mixer 9, the voltage from the source 20 of the local oscillator is supplied to the second input of the mixer 9. The voltage from the output of the mixer 9 with a frequency equal to the frequency difference between the master oscillator 1 and the source of the voltage 20 of the local oscillator enters the attenuator 10, in which the maximum attenuation is set. From the output of the attenuator 10, the voltage enters an intermediate frequency amplifier 11 with a detector. The detected intermediate frequency voltage through the switch 14 enters the memory unit 19 (for example, a capacitor), where it is recorded.

In the second cycle, the required value of the first harmonic of the output voltage is normalized and the voltage at the input of the attenuator 4 is memorized. The desired attenuation reduction is set in the attenuator 10, and the same attenuation increase is set in the attenuator 4. The voltage from the output of the intermediate frequency amplifier 11 with the detector through the switch 14 is supplied to the second input of the difference amplifier 17, and the voltage stored in the first clock in the second memory block 19 is applied to the first input of this difference amplifier. The difference of these voltages is amplified by the amplifier.

5 through the switch 13 enters the second input of the regulating node 2 and changes its transmission coefficient so that the output 21 of the source sets a voltage less than the initial value set in the first cycle by the value of the output attenuation in the attenuator 10. At the same time on the second cycle The input to the input of the attenuator 4 enters the converter 5, and from the output of the converter 5

5 via switch 12 to the first memory block 18 and recorded.

The failure rate of the output voltage after the second cycle is mainly determined by the failure rate of the initial level set in the first cycle, the failure of the attenuator 10 and the presence at the output 21 of a voltage source with a local oscillator frequency caused by the conductivity between the first and second input of the mixer 9 At low output values stress

Claims (2)

The j voltage with the frequency of the local oscillator can be many times greater than the required value. In the third cycle, the output voltage failure caused by the presence of a voltage output with a local oscillator frequency is excluded. The voltage source 20 of the local oscillator is disconnected from the mixer 9, the second input of the regulating unit 2 is connected to the output of the difference amplifier 16 and the voltage from the output of the converter 5 is fed to the second input of the difference amplifier 16, the first input of which receives the voltage of the memory block 18 recorded in him in the second measure. In this way, the voltage at the input of the attenuator 4 in the second and third cycle is equal. The error of the relative change in the level of the source considered does not depend on the parameters of the high-frequency attenuator 4, but is mainly determined by the error of the attenuator 10. Since the attenuator 10 operates at a low intermediate frequency, the ol can be made much more accurate than the attenuator 4 (for example, an inductive divider). Attenuator 4 is presented only with the requirement of constant attenuation after the second cycle, which does not cause technical difficulties. The error of the attenuator 4 should not exceed the range of adjustment of the transmission coefficient in the regulating node 2. The lowest voltage reproduced by the source is limited by the noise of the intermediate frequency amplifier 11 with the detector. If the bandwidth of amplifier 11 is sufficiently narrow, the output voltage may be 10-20 mV. A distinctive feature of the source under consideration is the simplicity of its metrological assurance. By virtue of the linearity of the mixer 9, to determine the error in the entire frequency range, it is sufficient to sum up the error of the initial source level at a given frequency with the error of the required level at a low frequency. The accuracy of measuring low-frequency voltage in a wide range of levels is much higher than the accuracy of measuring voltage of the same levels at high frequencies. Thus, the use of the source allows reducing the error of the output voltages of low levels, extending the range of output voltages to the direction of decreasing, eliminating the error of connecting the external load, simplifying the metrological support, and also significantly reducing the requirement for a high-frequency attenuator. The invention includes a high-frequency voltage source containing a series-connected master oscillator, a regulating unit, a low-pass filter and an attenuator whose output is connected to the output terminal, an alternating voltage-to-voltage converter whose input is connected to the low-frequency filter output, and an amplifier the difference, the first input of which is connected to the source of the reference voltage, characterized in that, in order to increase the accuracy of the output voltage, an additional converter is introduced into it DC voltage, auxiliary attenuator, an intermediate frequency amplifier with a detector, a mixer, four switches for several positions, two memory blocks and a local oscillator voltage source and two additional difference amplifiers, the output of the AC to DC converter to the common contact of the first switch, the first contact of which is connected to the first memory blocks and the first input of the first additional difference amplifier, the second input of which is connected to the second terminal The first switch of the first switch and the output to the first contact of the first switch, an additional AC / DC converter is connected between the output terminal and the second input of the difference amplifier, the output of which is connected to the second contact of the second switch, the third contact of which is connected to the output of the second additional difference amplifier and the common contact is connected to the control input of the regulating node, the source of the local oscillator is connected to the first and second contacts of the third switch, the common contact of which is connected to one of the mixer inputs, the other output of which is connected to the output terminal, and the output through an additional attenuator is connected to the input of the intermediate frequency amplifier with the detector, the output connected to the common contact of the fourth switch, the first contact of which is connected to the second memory block and with the first input of the second additional difference amplifier, the second input of which is connected to the second contact of the fourth switch. Sources of information taken into account during the examination 1. E. BELODARSKY et al. The source of the calibration voltage in the frequency range 0.01-25 MHz. - “Questions of radio engineering, M., 1974, vol. 3, s. 89 2. “Rohde und Schuarz. Elektronische Mepgerate, Leistung - Mepsender -SMLU. 1974/75, p. 40