SU410405A1 - - Google Patents

Description

one

The invention relates to the field of automation and computing.

Time-impulse function converters are known that contain input sources, the output of the first of which is connected to one of the inputs of a linear pulse divider, a DC amplifier, an adder, a limiter filter and a voltage divider through a control signal generator.

The proposed device differs from the known ones in that the input of the voltage divider is connected to the output of the first input source, and the output of the voltage divider is connected to another input of the linear pulse divider and through the filter limiter is connected to the first input of the adder. The second input of the adder is connected to the output of the second input source, and the output through the DC amplifier is connected to the control input of the voltage divider.

In addition, a voltage divider is provided on a capacitor in series with a photoresistor optically coupled to a light source. The latter is connected to the control input of a voltage divider, the midpoint of which is connected to its output, and the input is connected to a capacitor.

This allowed us to simplify the design of the converter.

The block diagram of the device shown in the drawing.

The device contains input sources 1, 2, the output of the first of which is connected through one of the inputs of a control signal 3 to one of the inputs of a linear pulse divider 4, a DC amplifier 5, an adder 6, a filter limiter 7 and a voltage divider 8, a capacitor 9 connected in series with the photoresistor 10, optically coupled to the light source I.

The device works as follows.

The alternating voltage from the photoresistor 10 enters the filter limiter 7, where it is limited and averaged. Then this voltage is applied to the input of the adder 6, to the other input of which the input voltage is supplied. The difference of these signals is amplified by amplifier 5 and fed to a light source 11, which changes the resistance value of the photoresistor 10 so as to reduce this difference. With a sufficiently large gain factor of amplifier 5, the difference is approximately zero, and the voltage at the input of the filter limiter 7 is equal to the input voltage. The phase difference f of the voltage source of the input signals 1 and the voltage across the photoresistor 10 is equal to f .-- arccos - arccos where Ui is the amplitude value of the voltage source of the input signals 1; t / H is the amplitude value of the interlaced voltage on the photoresistor 10; f / 2 is the input voltage; ki-transfer coefficient of the filter-limiter 7. The generator of control signals 3 receives the voltage of the input signal source 1. From the positive half-wave of the sinusoidal voltage, oi forms pulses of duration G / 2 (where T is the oscillation period). These pulses control the linear pulse divider 4, to the other input of which voltage is supplied from the photoresistor 10. At the output of the linear pulse divider 4, the voltage varies according to the law g / 2 / 2l. . Tf "(Taking into account expressions (1) and (2), we have; and - - r. I.e., we obtain a voltage proportional to the square of the input voltage of a constant current and inversely proportional to the amplitude of the sinusoidal current. Invented invention 1. A time-pulse functional converter containing input sources, the output of the first of which is connected to one of the inputs of a linear pulse divider, a DC amplifier, an adder, a filter limiter and a voltage divider through a control signal generator, distinguishing In order to simplify the converter, the input of the voltage divider is connected to the output of the first input source, and the output of the voltage divider is connected to another input of the linear pulse divider and through the filter limiter is connected to the first input of the adder, the second input of which connected to the output of the second input source, and the output of the adder is connected to the control input of the voltage divider via a DC amplifier. 2. The converter according to claim 1, excluding the fact that in it the voltage divider is made on a capacitor, one lining of which is connected to the output of the divider and to a photoresistor optically connected to a light source that is connected to the control input the voltage divider, and the other capacitor plate is connected to the input of the divider.