SU819728A1 - Digital self-balancing potentiometer with variable level and time balancing steps - Google Patents

Description

one

The invention relates to the field of measurement technology.

Known digital devices based on the code-pulse quantization method with a variable step over the level. These devices, with sufficient quantization performance, have a significant equilibration time ij

The closest in technical essence to the present invention is a device containing a zero-body, a coarse and accurate relay, a pulse generator, a trigger-frequency divider, a counter of exact and coarse steps, a decoder. digital indicators, digital potentiometer (conversion x code-analog). A measured voltage is supplied to one input of the nullorgan, and the other input is supplied by a compensating voltage from a digital potentiometer. At the output of the null organ, a coarse and precise relay is connected in series. The pulse generator is connected to the coarse and accurate steps through the contact of a coarse relay, and through the contact of the exact relay and the trigger frequency divider to the counter of the exact stage, the inputs of the counters are connected to the decoder with digital indicators and digital potentiometer 2j.

The known device has a complex circuit, has a low speed and dynamic measurement error. So, in the initial period of work of the autocompensator, the counters of both stages work, which increases the capacity of the counter of the exact stage, and consequently, the complexity of the diffuser with the digital indicator and the code-analog converter. In addition, the response time of the relay is comparable to the speed of the entire autocompensator.

The purpose of the invention is to increase the speed and increase measurement accuracy.

The goal is achieved by the fact that a digital autocompensator with variable balancing steps in level and time, containing a null organ, the first input of which is connected to the object of measurement, a pulse generator, counters of exact and coarse steps, connected to a digital indicator and a code analog counterpart, output which is connected to the second input of the zero-body, provided with a threshold circuit, a driver amplifier, two prohibition elements and an inverter, the output of the zero-body connected to

the amplifier input and the threshold circuit input whose output is connected to the input of the inverter and the first input of the first prohibition element, the second input of which is connected to the output of the pulse generator and the second input of the second prohibition element, the first input of which is connected to the output of the inverter. the output is with the input of the counter of the exact stage, the output of the first prohibition element is connected to the input of the counting of the coarse stage, the input of the driver of the driver is connected to the input of the pulse generator.

The introduction of these elements makes it possible to exclude the operation of an exact stage counter in the initial period of operation of a digital autocompensator. Decreasing the performance of the digital compensator in such a scheme is eliminated by increasing the coarse quantization steps of the compensating voltage by the magnitude of the exact quantizing steps.

The exclusion of dynamic error is achieved by connecting the zero-organ to the input of the pulse generator, and the pulse generator is controlled by the voltage. At the same time, the frequency of the pulse generator Ea depends on the output voltage of the nullorgan and decreases as it decreases. When the output voltage of the zero-organ is zero, the frequency of the pulse generator is also zero.

An increase in the speed of the digital autocompensator is achieved by the inclusion between the zero-organ and the pulse generator of the amplifier-former, which controls the frequency of the pulse generator (F) according to the functions (f).

F, f (KU °),

where and is the voltage at the output of the nullorgan f

K is the transmission coefficient of the amplifier-former; j t is a constant value greater than unity.

With such a control law, the average frequency of the generator increases during the compensation period, which increases the speed of the digital compensator.

The drawing shows a block diagram of the proposed digital autocomponent.

A digital autocompensator with variable "1 balancing steps in level and time contains a null organ 1, one input of which is supplied by a ground voltage. and to the other input there is a compensating voltage from the output of the converter 2 code-analogue. The output of the zero-organ 1 is connected to the inputs of the amplifier -former 3 and the threshold circuit 4, the output of which

with the element 5 prohibition and inverter 6 The output of the amplifier maker 3 is connected to the input of the generator 7 pulses, the output of which is connected to the second inputs of the element 5 of the ban and the element 8 of the ban, the first input of which is connected to the output of the inverter b. The element of the prohibition element 5 is connected to the counter 9 of the coarse stage, and the element 8 of the ban - with the counter 10 of the exact stage. The outputs of the counters of both stages, for example, binary-decimal are connected to the digital indicator 11 and the code-analog converter 2.

Digital auto compensator works in the following way.

In the initial state, the compensating voltage at the input of the null organ

Equal to zero, the voltage at its output is of the greatest value; this is the greatest value of the voltage across the amplifier-driver.

3 is fed to a generator of 7 pulses which B is absorbing the voltage of the highest frequency | l. The frequency of the pulse generator through the open threshold circuit 4, the element 5 of the ban, enters the counter 9 coarse stages. The counter controls the status of the converter.

2 analogue code. With variable information of the counter 9 coarse stage, the transformer 2 code-analog generates a compensating voltage only with large steps, the amplitude of the quantum field, causing a decrease in the voltage at the output of the zero-organ 1. This decreasing voltage through the amplifier-shaper 3 reduces the frequency generator 7 pulses, and the amplifier forcing 3 produces a voltage at which the frequency of the generator varies according to a law close to Fr.f (ki).

The control according to such a law almost does not change the frequency of the generator 7 with a large difference between the input voltages of the zero-organ 1 and sharply reduces it when it approaches the moment of compensation. With a large difference between the input voltages of the zero-organ 1, the voltage at its output is almost constant. At the time of compensation, the frequency of the generator 7 pulses is zero.

The selected control law with an appropriate choice of Kla values allows to obtain a high average frequency for the compensation period, which increases the speed of the entire digital autocompensator. When approaching the moment of compensation, threshold scheme 4 will work, it is built on a voltage corresponding to the value of one rough stage. In this case, the prohibition element 5 will be banned, and the prohibition element 8 through the inverter b, on the contrary - permission, which will cause the arrival of the generator frequency

Claims (1)

Claim A digital auto-compensator with variable steps of balancing in level and time, containing zero-g-gan, the first input of which is connected to the measurement object, a pulse generator, accurate and coarse step counters connected to a digital indicator and a code-to-analog converter, the output of which is connected to the second input null-organ, which is characterized by the fact that, in order to increase speed and improve the accuracy of measurement, it is equipped with a threshold circuit, an amplifier-driver, two elements of a ban and an inverter, and the output is null-o Ghana is connected to the input of the driver-amplifier and the input of the threshold circuit, the output of which is connected to the inverter input and the first input of the first inhibit element, the second input of which is connected to the output of the pulse generator and the second input of the second inhibit element, the first input of which is connected to the inverter output, and the output - with the input of the counter of the exact stage, the output of the first inhibit element is connected to the input of the counter of the coarse stage, the output of the amplifier-former is connected to the input of the pulse generator.