SU531258A1 - Photosensor - Google Patents

Description

(54) PHOTO

one

 The invention relates to radio engineering and can be used in converters of light signals into electrical ones.

A photo sensor is known that contains a power source, an auto-oscillator assembled on the first and second transistors, the first and second photodiodes (11 ..

However, the known photo sensor has insufficient sensitivity, and there is no compensation for the effect of background radiation.

The aim of the invention is to enhance; sensitivity of the photo sensor and compensation of the influence of background radiation.

For this, the collector of the first transistor of the auto-generator is directly connected to the base of the second transistor of the auto-generator, the collector of which is connected to the base of the first transistor by a capacitive coupling formed by the first capacitor, the second capacitor and the first photodiode, the junction point of the second capacitor and the first the photodiode through the counter-connected second photodiode and the third capacitor is connected to the collector of the first transistor and

through a resistor to the power source pole, and the connection points of the first photodiode and the first capacitor, the second photodiode and the third capacitor are connected via resistors to the common bus.

The drawing shows a circuit diagram of a photo sensor implemented in accordance with this invention.

The photo sensor contains a power source connected to terminals 1 and 2, an auto-oscillator, made on transistors 3 and 4, photodiodes 5 and 6.

The oscillator is implemented as a multivibrator with galvanic coupling between the collector of transistor 3 and the base of transistor 4 and capacitive coupling between the collector of transistor 4 and the base of transistor 3. Capacitive coupling is formed by a capacitor 7, a photodiode 6 and a capacitor 8. The connection point of the photodiode 6 and capacitor 8 through the counter-connected photodiode 5 and the capacitor 9 is connected to the collector of the transistor 3, and through a resistor 10 to the terminal 1 of the power supply.

The connection points of the capacitor 7 and the photodiode 6, the capacitor 9 and the photodiode 5 through resistors and and 12, respectively, are connected to a common bus (terminal 2) power supply.

The photo sensor is working down (in a clever way.

The photosensor can operate in three modes: in photorelay mode, operating at photodiode, as a photorelay, operated at photodiode illumination, in fomocomparator mode, triggered at “1” photodiodes.

In the photosensor, there is a positive feedback and a negative feedback.

Polyscale feedback is supplied from the collector of a transistor 4 through a capacitor 7, a photodiode 6, a capacitor 8, to the base of the transistor 3, from the collector of a transistor 3 to the base of the transistor 4.

Negative feedback is supplied from the collector of transistor 3 through a capacitor 9, a photodiode 5, a capacitor 8 to the base of transistor 3.

Changing the resistance of the reznstor P HJBI 12 auto-oscillator is transferred to the standby multivibrator mode or to the self-oscillation mode. When the auto-oscillator is set in the photodatum mode, it works when the photodiode 5 is darkened, HN myabcbi appears at output 13.

If the oscillator is set to self-oscillations by changing the sonotransistors of resistors 11 and 12, then at) Shesh1 and illumination of the photodiode b the generator becomes tired in day mode.

As a photococharator, the feeder works as follows.

A change in the sonrota of the effects of resistors 14 and 15 with darkened photodiodes 5 and b and equal resistances of the resistors 11 and 12 is set in the multivibrator mode.

By varying the resistances of the resistors 11 and 12 with the same illumination of the photodiodes 5 and b, the scatter of the photo-iodine parameters is compounded and the mode of the start of generation is set.

With a small increase in illumination of the photodiode 5 but comparing with the illumination of the photodiode 6, the co-negative feedback starts to decrease in the series negative feedback circuit, the optical feedback starts to dominate, the generation stops and at the output 13 the pulses disappear.

With a slight increase in light

photodiode 6 compared with the illumination of the photodiode 5, the resistance in the positive series feedback circuit will be less than the resistance in the series

decisive feedback, and due to the prevalence of positive feedback, the multivibrator generates pulses. With increasing illumination of the photodiode 6, the frequency of the pulses at output 13 increases.

Claims (1)

1. USSR author's certificate N 278884, MKI N01 N 47/24, 04/28/67 (prototype). 0f 4010 hhh 3 eleven