SU447575A1 - Illuminance recorder - Google Patents

Description

(54) DEVICE FOR REGISTRATION OF ILLUMINATION

one

The invention relates to instrumentation and can be used in solving problems of photometry, optoelectronics and navigation technology. : Known device dp registration. illumination containing a NIN source of pita, two photoresistors, one of which is measuring, and the other serves: to compensate for a dark background, a threshold and actuator., j However, a strong change in the sensitivity of the photoresistor as a function of temperature does not accurately measure the illumination in a wide temperature range .

The use of thermo-dependent resistances to compensate for temperature effects is limited by the fact that the synthesis of a thermal two-port network with a given temperature is possible only in a narrow temperature range, respectively, high-quality temperature compensation is possible only in a narrow temperature range. I The thermal sensitivity of the photoresistor is strongly dependent on the light, especially in the mode of low intensity.

The aim of the invention is to improve the accuracy of measuring the illumination. In the proposed photoresis device, the optocoupler and the measuring photoresistor 5: are connected in series, connected by a common point to the gate of the field-effect transistor, another output of the photoresistor of the optocoupler; connected to the source pole of the power supply. “L

ten ; The drawing shows the electrical scheme proposed by the device;

It contains a measuring photoresistor 1, an optocoupler 2, made using 15: a source of radiation 3 (for example; measures of a diode) and a photoresistor 4, optically interconnected. The source of radiation 3 through the limiting p &: The resistor 5 is connected to the source 6 of direct current voltage. Photoresistors 1 and 4 are selected with identical characteristics or are made in a single techno m: logical process. The point of the measuring photoresistor 1 and the photoresistor2 $ of the torus 4 has been sheathed by the optici 2 connected to the gate

field-effect transistor 7, and another photoresistor 4 is connected to the source pole of the power supply. The field-effect transistor 7 is switched on according to the source follower circuit and contains the load 8. At the output of the transistor 7, the threshold circuit 9 and the actuator are connected.

When adjusting, the measuring photoresistor 1 is illuminated by the luminous flux, while the device is triggered and a current is transmitted through the radiation source 3 through the radiation 3, causing the radiation of the radiation source 3 to glow. By adjusting the resistance value of the resistor 5, the luminous flux of source 3 is equal to the luminous flux illuminating the photoresistor 1. Since the characteristics of photoresistors 1 and 4 are identical, the resistance of the photoresistor 4 to which the light flux of source 3 falls is equal to the resistance of the photoresistor 1. The fact that the resistances of photoresistors 1 and 4 are the same leads to the fact that the voltage of the power supply is divided in half by a divider formed by photoresistors 1 and 4.

Consider the operation of the scheme after tuning. Suppose that the measured light flux is absent, in this case, photoresistor 4 is illuminated, and photoresistor 1 is not illuminated, as a result, the voltage on the latter drops and there will be no signal at the input of the source follower. As illumination increases, the resistance of the photoresistor 1 clears and on the photoresistor 4, which is used as a load resistance, the signal increases. When the detected luminous flux becomes equal to the flux of source 3, the supply voltage is divided between

 photoresistors 1 and 4 in half. If .i the threshold device 9 is set to lead & g / k K E / 2, where K is the coefficient

. transmitting the source follower, and E is the voltage of the power source, the threshold device is triggered and the actuator accordingly operates. 10, When changing (for example, decreasing) the temperature, each of the photoresistors increases the resistance of K. As the resistances of the photoresistors to the effect of temperature were the same; and are equal to R,. to drop Hanps-Kenya on photoresistor 4, we have:

E (RtAR) E (Rl: AR E

to ± ln-K1dk) -

I Thus, a change in temperature does not change the triggering threshold of the entire device.

Subject invention

A device for recording illumination containing a power source, measuring

A 30 photoelectric resistor, an iptron, made of optically coupled photoresistor and a radiation source, a threshold and actuating device, characterized in that, in order to increase

35 measuring accuracy, the photoresistor of the optocoupler and the measuring photoresistor are connected in series and connected by a common point to the gate of the field-effect transistor, while the other output of the photoresistor

The optocoupler is connected to the source pole of the power supply.

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