SU769740A1 - Photodetector - Google Patents

Description

The invention relates to the automation of technological processes in the steel industry, can be used, in particular, to indicate the presence of heated metal in automation systems for rolling and pipe production.

A known photosensor containing a photodiode connected to the inputs of an AC amplifier and to the outputs of a chopper, as well as a former connected through a demodulator to the output of the amplifier [1].

This device has low sensitivity and thermal stability.

Also known is a photosensor containing a generator, the first output of which is connected to the key input, a photodiode, the first output of which is connected through the capacitor to the input of the amplifier, and a series-connected demodulator, the control input of which is connected to the second output of the generator, and an output amplifier [2].

The disadvantages of this photosensor are also low sensitivity and thermal stability.

The goal - increasing sensitivity and thermal stability - is achieved by the fact that the photosensor contains a generator, the first output of which is connected to the key input, a photodiode, the first output of which is connected via a capacitor to the 30 inverting input of the operational amplifier, the non-inverting input of which is connected to a common bus, and the inverter through the resistor is connected to its output, and in series connected demodulator, the control input of which is connected to the second output of the generator, and the output amplifier, characterized in that in order to improve the sensitivity and temperature stability, a first terminal of the photodiode is further inputted through a resistor, and a second terminal connected through a switch to the common bus; the output of the operational amplifier through an additional capacitor is connected to the input of the demodulator.

The drawing shows a diagram of a photosensor.

The photosensor contains a key 1 on the field-effect transistor and a photodiode 2 connected in series with it. A resistor 3 is connected in parallel with this circuit. A photodiode 2 is connected through a capacitor 4 to the inverting input of the operational amplifier 5, the feedback circuit of which includes a resistor

6. The output of the operational amplifier 5 through a capacitor 7 is connected to the input of the demodulator 8. The generator 9 controls the operation of the key 1 and the demodulator 8. The output amplifier 10 is connected to the output of the demodulator 8.

The sensor works as follows.

When the modulator is operating on the field effect transistor 1, the photodiode 2 can be in two states. When the field-effect transistor is turned on, the photodiode 2 is in a close to short circuit mode, since the resistance of the transistor 1 and capacitor 4 at the selected modulator frequency are small, and the input resistance of the amplifier 5 is close to zero due to the feedback. When transistor 1 is turned off, its resistance is hundreds of megohms, and the current does not flow through the circuit of photodiode 2. We will consider the working half-period the one in which the transistor 1 is open. If photodiode 2 does not accept radiation, the current in the circuit field-effect transistor 1 — photodiode 2 — capacitor 4 does not flow, since there are no current sources here, and the voltage U _{A of the} inverse input of amplifier 5 is close to zero.

When radiation enters photodiode 2, there is no photo-emf in the working half-cycle, since it is bridged between the common wire and point A. In this case, the transistor 1 — photodiode 2 — capacitor 4 flows through the photocurrent / f.

The magnitude of the photocurrent / f is proportional to the light flux incident on the photodiode and, as studies have shown, is practically independent of the temperature of the photodiode.

After locking the transistor 1, the capacitor 4 is recharged through the resistor 3. After the transistor is turned on, the next working half-cycle begins.

The voltage (pulse amplitude) at the input of the amplifier is 5 dB = /? ₆ - / f, where /? ₆ - the value of the resistor 6.

The voltage Jb is then demodulated by the demodulator 8, and only the variable component passes through the capacitor 7.

In the absence of a light signal, there is no signal at the output of the photosensor.

In the presence of a light signal, the photodiode is a source of photoEMF; moreover, the magnitude of the photoEMF depends on the intensity of the light signal. In this case, when the key 1 is open, the photoEMF does not create a current in the input circuit of the amplifier 5. In case 5, when the key 1 is closed, the photoEMF creates a current in the input circuit of the amplifier 5, and the voltage U ₅ = 7f- /? b> where / f is the current in the input circuit of the amplifier 5 created by the photo-emf, R ₆ is the nominal value of the resistor 6. The frequency U ₅ is equal to the frequency of the generator, the amplitude is proportional to the value of the light signal. The received signal is demodulated and, with the help of an output amplifier, converted to a standard voltage drop.

Experimental data confirm an increase in the sensitivity and thermal stability of the photosensor.

ABOUT

Claims (1)

Claim A photo sensor containing a generator, the first output of which is connected to the input 5 of the key, the photodiode, the first output of which is connected via a capacitor to the inverting input of the operational amplifier, the non-inverting input of which is connected to the common bus, and the inverting input through the resistor is connected to its output, and the demodulator connected in series whose control input is connected to the second output of the generator, and an output amplifier, characterized in that, with the aim of increasing the sensitivity and thermal stability, the first output of the photodiode is additionally introduced resistor and the second terminal through a switch connected to the common bus, the output of the operational usilite0 A through an additional capacitor connected to the input of the demodulator.