SU374766A1 - OPTOELECTRONIC PANEL - Google Patents

Description

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The invention relates to the field of radio electronics and can be used in information display systems.

Optoelectronic transducer panels used for amplifying light and containing two main working layers, electroluminescent, and photoconductor, deposited in series, are known.

In the proposed panel, two photoconductive layers are additionally introduced between the photoconductor and electroluminescent layers to extend its functionality. The spectral sensitivity of the three photoconductor layers is different and is determined by the spectrum of the radiation sources, and the emission spectrum of the electrolyte of the luminescent layer coincides with the spectral sensitivity of the photoconductor layers.

The drawing shows the proposed optoelectronic panel consisting of photoconductor layers 1, 2, 3, electroluminescent layer 4, transparent substrate 5, transparent conductive layers 6, 7.

The analyzed image (source 5) and supporting radiation (source 9}, which is a system of discrete rays, are projected onto the panel. The sources of the analyzed image and supporting radiation are selected with different

radiation spectra so that the emission spectrum of the first one coincides with the spectral sensitivity, for example, the photoconductor of the skirt layer 1, and the emission spectrum of the second one, respectively, with the spectral sensitivity of the photoconductor layer 2. The analysis is carried out by scanning the panel, for example, with a thin light beam, the radiation spectrum of which coincides with the spectral sensitivity of the photoconductive layer 3 and the emission spectrum of the electroluminescent layer 4.

Scanning beam consistently runs around the panel. Under his influence plots

panels irradiated simultaneously by informational and supportive studies are excited and remain in this state after the termination of the scanning effect due to the optical connection and electrolumines of the medium layer with the elementary photoconductors of the photoconductor layer 3.

Thus, the panel induces an image in the form of a set of luminous points, which is caused by the discreteness of the supporting irradiation. The current consumed by the panel depends on the area of the excited areas. Therefore, the achievement of a scanning beam illuminated by the information (and supporting) irradiation of the site can be judged with the help of differentiation3

device included in the power supply circuit of the panel, by abrupt changes in current.

When rescanning, no signal appears at the output of the differentiating element if no changes have occurred in the information exposure. In the case of image displacement, a part of the previously illuminated areas of the photoconductor layer / will be darkened, their resistance will increase, which will lead to a shrinkage of the corresponding areas of the electroluminescent layer. At the same time, new areas of the layer / will be illuminated and a subsequent scan at the output of the differentiating element will show a signal indicating that changes have occurred in the image under study. A similar result is observed when new objects appear in the image.

Obviously, with "continuous supporting irradiation (i.e., in the case when supporting irradiation affects the entire surface of the photoconductor layer 2) image displacement is accompanied by simultaneous mixing of the excited zones, since the electroluminescent emitter of each elementary section of the photoconductor layer 2 illuminates the photoresistors as its and neighboring areas. At the same time, the differentiating element does not select the signal of changes that occur in

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images between two scans. To eliminate this drawback, it is necessary that the supporting irradiation is a system of discrete rays, and each section of the screen, illuminated by a discrete beam, is distant from the neighboring similar areas by a zone that is not illuminated by a source of supporting irradiation. The permissible density of the areas under the influence of supporting irradiation determines the resolution of the panel for a given size of the panel.

Subject invention

An optoelectronic panel containing a transparent substrate on which a transparent conductive is successively applied

photovoltaic, electrically: rotumi-nescent and second transparent conductive layer, characterized in that, in order to extend the functionality of the optoelectronic panel, two photoconductor layers are added between the photoconductor and electroluminescent layers, and the spectral sensitivity of all three photoconductor layers is different and spectrum of radiation sources, and the radiation spectrum of the ectroluminescent layer coincides with the spectral sensitivity of one of the photoconductor s layers.