SU468266A1 - Optical electronic multiplying device - Google Patents

Description

(54) OPTICAL ELECTRONIC POSSIBLE DIVIDING DEVICE If photoresistors 1, 2 are not included in the AC target, then the output to the voltage removed from terminal 16, equal to 8biX 7 JF2 is the photoreistor transfer coefficient 2. Photoresistor 1 cottages is equal to K NF1. U5 Tak.-as both photoresistors 1, 2 are controlled by one light source 12, then in the case of Ksch - TL it is possible to GET 7 and 5 However, the equality of the CSR is possible only with the equality yo-Vy H and with absolute identity of the photoresistivity 1 and 2, i.e., at Cf CpZ In the real case, due to non-residency of photoresistors 1 and 2 Hp1 7 pg or R F1 Cf2 - Rcpi. R-t. 1 de 5 - an error introduced by non-identity. The inclusion of photoresistors 1, 2 in the AC alternating current circuit (with equal resistors 3 and 4) allows the voltage drop to Rm and Rm to drop, and for a sufficiently large laziness factor of the latter, to ensure that b is. This is: fioctigs due to the fact that between the light source 12, the photoresistor 2 (R f) is placed a controlled optical filter 14 (for example, a liquid crystal cell), which is acted upon by a variable diffuser coming from a differential 11 its coefficient is n dusaani so as to fall. The pinhole on the inputs of the differential usi ««, ditel 11 would be equal to Q Uft 5, therefore, qb, (since Rs-Hi). The differential amplifier 11 is unbalanced in such a way that, with equal voltages at its inputs, a variable optical bias voltage y is applied to the controlled optical filter 14, which determines its operating point. At the same time, the transmittance of the optical filter 14 should be approximately equal to the transmittance of the light-absorbing optical filter 13 placed between the light source 12 and the photoresistor 1; This uninterrupted auto-compensation scheme allows to compensate for the instability of the characteristics of the photoresistor 2. During operation of the device, the differential amplifier 11 should not react to changes in the constant voltages of the scientific research institutes at its inputs, and the gain of the differential amplifier 10 should be zero in the variable component. Subject to the image of a shadow Optoelectronic multiplying-dividing device containing two photoresistive voltage dividers, to the midpoint of the first of which is connected via a resistor to the first output - an input source and one differential amplifier input, the second input to which is connected to the output of the second input source signal and the output is connected to a light source optically connected to the photoresistors of the voltage dividers, the middle point of the second voltage divider is connected to the output of the third source a signal through a resistor, and a yield. devices - directly, because they have, in order to increase the accuracy of the device, an additional differential amplifier, the inputs of which are connected to the middle points of photoresistive voltage dividers, optical filters, one of which is made in the form of light, is introduced

absorber filter and is installed between the resistor first and the light source, and the second is made in the form of a liquid crystal and is located MeiKj3y light source and the photoresistor of the second voltage divider, the source pi

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AC power, connected to the blue-: additional resistors with the medium. 1 points of photoresistive voltage, and the output of the additional differential: amplifiers are connected to the control r (v.i. house of the liquid crystal cell.

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