SU830115A1 - Coordinator - Google Patents

Description

(54) COORDINATOR

The invention relates to optoelectronic and computer technology and can be used as a sensor for the position of a source of light based on photopotentiometers and photoresistors. A two-coordinate light source position sensor is known based on longitudinal photo potentiometers with crossed resistor fields. It contains a transparent dielectric substrate, on which transparent conductive layers (collectors) are applied on both sides, then photoconductivity layers and then resistive layers, the latter having mutually perpendicular equipotential electric field lines}. The disadvantage of the co-ordinate sensor is the need to use transparent collectors and substrates, which complicate the design of the sensor and reduce their light sensitivity. A two-coordinate sensor based on a glass fiber faceplate with an infinitely small angular aperture is also known. This sensor contains photoconductive layers on both sides of the transparent collector, and resist layers are applied to the photo layers. The resulting layered structure is mounted on a glass fiber faceplate, which in analog is a transparent dielectric substrate 2. A disadvantage of the described coordinate-sensitive device is the need to use a transparent conductive collector, which reduces sensitivity. And the need to use proz. The cancer collector is explained by the constructive implementation of resistive layers one above the other in different planes for their discharge in electric current. The purpose of the invention is to increase the light sensitivity and simplify the design. This goal is achieved by the fact that in a device containing a photoconductive layer on a conductive base and resistive layers with intersecting electric fields, the resistive layer is made directly superimposed on each other. The drawing shows the coordinator, the appearance.

Claims (1)

Formula of the invention, the spot moves parallel to the / axis, the current in the voltage source circuit U ^ changes, if the light spot moves parallel to the X axis, the current in the voltage source circuit changes. The resistance per unit square of the resist layer and its length from the coordinate axes to the electrical terminals 5 is determined by the accuracy of the linearity of the transformation of the position of the light spot into electrical signals. The higher the accuracy of the linear transformation, the greater should be the resistance per unit square of resistive strips relative to the illuminated resistance of the photoconductor and the distance from the coordinate axes to the electrical terminals 5. To increase the resistance, a resistor containing a photoconductive layer on a conductive base and resistive layers with intersecting electric fields , due to the fact that, in order to increase the light sensitivity and simplify the design, the resistive layers are not made directly superimposed on each other.