DE1437113A1 - Screen device - Google Patents

Description

DIL E. WIEGAND

MDNCHEN DIPL-ING. W. NIEMANN

HAMBURG VATfNTANWXLTE

8000 MÖNCHEN 15, £ 8 OWt 196Ί

NUSSBAUMSTRASSE if,

NUSSBAUMSTRASSE '
TELEPHONE: 55547 «

W, 11 991/64 12 / tfe

Electro-IEC Corp =
Burlington, Massachusetts (V.St.A.)

Screen gate direction

The invention relates to a device having a screen for generating an image and in particular on a flat, two-dimensional screen for generating an image o

One purpose of the invention is to provide a flat screen to form an image, a plurality of responsive conditions, extending in the same direction or layers

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Has layers in a predetermined ratio, so that a flying dot matrix is generated and then through a Image signal can be modulated to produce a picture in the manner of a television picture.

Another purpose of the invention is to provide a flat screen for creating an image with a Majority of vo * i responsive to conditions, themselves in the same To create direction-extending layers in which each of the layers is either an electroluminescent, photoelectric conductive (photoconductive) or ferroelectric ^ layer, which are arranged in a novel sequence.

Another purpose of the invention is to provide a planar screen for generating an image which has an optimally small number of components or parts which take up an optimally small amount of space.

Another purpose of the invention is to provide a flat screen for generating an image which the use of cathode ray tubes in television displays and provides a screen that has a significant useful life.

Another purpose of the invention is to provide a ventilator To create a scanning device which has a flat screen

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having a plurality of condition-responsive, has layers extending in the same direction and a plurality of puncture generators, which singing functions for the layers feed optionally, whereby a flying dot matrix can be produced, which can be found in each can be started from two directions running at right angles to each other.

Another purpose of the invention is to provide a To provide a scanning device comprising a flat screen having a plurality of layered, condition-responsive Layers and a plurality of function generators which optionally supply input functions to the layers, the layers having complementary physical properties have that through selected punctures of the üingaiigsfunktion alternatively disturbed v / ground in such a way that adjacent areas of the screen are increasingly excited in a scanning pattern that is determined by the input functions.

Further purposes and advantages of the invention are apparent from following description of the embodiments in which of the invention with reference to the drawing as an example are explained.

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_ 4- -

Pig. 1 is a schematic end view, on an enlarged scale, of the screen according to FIG Invention.

I ¹ Ig. Figure 2 is an enlarged view of the lower pair of condition responsive plies according to Pig. T, where puncture generators are connected to the layers in a circuit.

Pig. 3 is a diagrammatic view showing the lower condition responsive layers and the three next higher conditions-responsive layers according to Pig. 1 are shown with which puncture generator are connected in a circuit.

Pig. Figure 4 is a perspective view of all of Pig's condition responsive plies. 1, with which puncture generators are connected in a circuit.

Pig. Fig. 5 is a graph of the voltage characteristic characteristics of the puncture generator according to Pig. 2 depending from the time.

Pig. Fig. 6 is a graph of the field position versus time characteristic for the combination according to Pig »2.

Pig. Figure 7 is an enlarged-scale end view of another embodiment of the apparatus

809805/037 ^ ^feU \ ^öO8eo -

according to the invention ..

The embodiment according to the invention has three components or "component groups of condition-sensitive or on Layers or layers that are appealing to the conditions and that are opposite and equal within the groups Are arranged extending in the direction, wherein the groups over extending in the same direction, opposite arranged transparent conductive and / or transparent insulating layers are connected to one another »

The described device according to the invention, for generating an image is by a plurality of Function generators completed across an area and / or across each of the groups of condition responsive Layers are arranged, resulting in each of the condition-responsive layers in one or more Directions an electric field that changes over time results.

The conditions-responsive layers are made of three different types of material, namely light-elec- ' electrically conductive (photoconductive) material (hereinafter referred to as PO layer), electroluminescent material (hereinafter referred to as EL sheet) and made of ferroelectric material (hereinafter referred to as FE sheet).

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According to the drawing and in particular according to FIGS. 1 and 4, a screen 10 is provided which is shown in FIG divided into three groups 1, 2 and 3. ·

The group 1 is arranged on the rear side of the screen 10 and has a straight, flat first base electrode 12 with low conductivity, which is the back of the screen 10, a rectilinear planar second Electrode 14, which is arranged parallel to the first electrode 12 and at a distance therefrom and made of highly conductive transparent material is composed, one between the first electrode 12 and the second electrode 14 arranged, extending in the same direction as the first flat electrode 12 ΈΈ-layer 16 and an EL layer 18, which is arranged opposite the PE layer 16 and the second flat electrode and facing in the same direction like this extends.

Group 2 is attached to group 1 and points. a PC sheet 20 that of the second electrode H of the group is arranged opposite and, in the same direction. like this one extends, furthermore a second 1E layer 22, which the BO layer 20 is arranged opposite and is in the same Direction like this one extends, a second EL layer 24, /

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which is arranged opposite the second FE layer 22 and extends in the same direction as this, as well as a straight, planar third electrode 26 which is arranged parallel to the first electrode 12 and the second electrode 14 and opposite the second EL layer 24 The third electrode 26 is composed or formed from a transparent material of low conductivity for a purpose to be described below. -li

The group 3 is placed on the group 2, from this through a transparent insulating layer 28, one side of ^{which is arranged opposite the third electrode ^ 26, opposite Megend- 1} and extends in the same direction as "dieäe-- · ej- . The group 3 denotes a straight 'plane electrode 30, which is arranged to the electrodes *, 12 ^: 14:, as well as the transparent insulating layer 2S-opposite'>;: ".. · and is arranged in the same direction as this * streo and composed of a highly conductive transparent material, a second; PC layer 32v ^ which is arranged opposite the fourth electrode 30: .- .. /. ■ iat and _; siqh. jl in the same direction as this .eT.atstretch, ■ ©! «©» n. opaque _; £ ichtperrlage 33 lower

809805/03783 \ £ C \ u0e ?; Often

which is arranged opposite the second PO layer 32 and extends in the same direction as this, a third EL layer 34, which is arranged opposite the light blocking layer 33 and is in the same direction as this extends, and a highly conductive, straight, "clear, planar fifth electrode 36, which is on one side of the third EL layer 34 is arranged opposite one another and extends in the same direction as this, and the one on their the other side is the viewing or viewing side of the screen 10 forms.

Fairly Pig. 2 becomes group 1 through a first Puncture generator G1 and a second puncture generator G-2 excited »

The first puncture generator G1 is of low conductivity over the length of the first electrode 12, as it is is indicated in the drawing by the dimension L, by means of a first connection 38 and a second connection 40 connected, which are arranged on opposite sides of the first electrode 12 at the L dimension are. These connections 38, 40 can be of appropriate design and are for example plated or "~" stripes arranged in a different way.

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The second puncture generator G2 is on one side connected to earth and connected on its other side to the second connection 40 on the first electrode 12. Of the The output of the second puncture generator G2 is via the thickness dimension of the PE layer 16 and the II layer 18 of the group connected by a ground connection or by grounding a connection 42 on the highly conductive second electrode 14 »whereby this electrode 14 and said one side of the second puncture generator G2 have a common potential are exposed.

According to FIG. 3, the group 2 is similar to the group .1 by a third puncture generator G3 and energized a fourth puncture generator G4, the However, excitation is perpendicular to that of Group 1, as will be described below.

The third puncture generator G3 is connected to the third low-conductivity electrode 26 by means of a first terminal 44 and a second terminal 46, which are arranged on opposite edges of the third electrode 26 along a dimension which _{corresponds to the dimension L 0} above which the first. Puncture generator G1 is connected ^ runs at right angles.

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- ίο -

The fourth puncture generator G4 is on a " Connected to earth on one side and to the fourth band terminal 46 of the third electrode on its other side connected, whereby said one side of the fourth puncture generator G-4 and the second electrode H one are exposed to common potential o

In Pig. 4 are all exciter connections for the groups 1 and 2 as well as those for group 3 are reproduced. Group 3 is excited by a fifth puncture generator G5, which creates a modulating output function that will be described below o

The fifth puncture generator G5 is connected to the group 3 via the thickness dimension, with its one side is grounded and its other side with a connection 48 to the fifth electrode 36 and a connection 50 is connected to the fourth electrode 30, which in turn is connected to ground, whereby the fourth electrode 30 and one side of the fifth function generator 05 are exposed to a common potential.

In Pig. 7 is another embodiment of FIG. invention reproduced which modulates an imaging screen for ^ has easily changeable 'or »one-dimensional representations.»,

■ - ■■ -τ *

801805/0378 ■ ■ · ■ \ '-. ^:: -. .. * ■ "'' ■ * ■ * ■" -.

and this embodiment is by stacking the Groups 1 and 3 formed like this; that the second electrode and the fourth Elektdpde 30 a single highly conductive and Form transparent common electrode 52 between groups 1 and 3.

Way of working

The following is based on FIGS. 2, 5 and 6
Operation of the basic device for generating the scan according to the invention explained.

The group 1 of the three layer groups 1 to 3 can generate a line of light which "runs at right angles to the dimension L in the EL layer 18. This is achieved by the concatenation
or the ratio of puncture signal voltages V ^ and Vp achieved by the first puncture generator G1, the
second puncture generator G2 and the hysteresis characteristic of the PE layer 16 are generated when it is switched from one polarity state to the other.

The puncture generator G1 generates a gradient in an electrical level along the dimension L _Q , specifically through its connection across the first electrode 12 of low conductivity, whereby the field strength in the through

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the PE layer 16 and the EL layer 18 formed-double layer changes as a puncture of the position along the dimension L ₀ «

The puncture _{signal voltage V 2 of} ^the second puncture generator G2 has a triangular waveform with the same period ^ and half-period TV2 as the puncture signal voltage V- of the first puncture generator Gl, which has -square waveform o The effect of the second puncture V2 is thus an electrical that changes over time To generate PeId in the double layer of group 1, which acts progressively to drive the reference height or the traction level of the Peldgraäienten generated by the first puncture V1 upwards fezw ₀ , v / whether the puncture generators G1 and G2 are synchronized.

The one in Pig. 6 reproduced four curves show the course of the electrical field E over the thickness of the PH layer 16 and the EL layer 18, which represent the active layers of group 1, as a puncture of the position along the dimension L _Q , v.-obei χ is the position that can be changed _{along this dimension I 0.} The time sequence of the curves is (1), (2), (3) and (4), with the corresponding times (t) indicated on each curve at which / an opposite

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is small interval and represents the time required for V. is to go from V1 to 0 or from 0 to -Vl.

The first puncture V1 is chosen so that at the point χ = i the electrical field in the layers of the group is equal to the coercive field which is necessary to switch the polarization of the PE layer 16. Now, since the second puncture voltage V _{2 of} the second puncture generator G 2 builds up increasingly over time, the edge of the area in which it passes through the layers 16, 18 of group 1 across the first electrode 12 and the second electrode 14 applied PeId is equal to the coercive field for switching the PE layer 16, an increasingly changing position χ along the dimension L, up to a point in time at which a complete scanning of the entire dimension I is carried out.

The increasing achievement or maintenance of a coercive field strength along the dimension I causes an increasing switching of the polarity state of the PE layer 16 in all positions χ along this dimension L _Q. During the switching or the change in the state of the PE layer 16, the dielectric constant of the PE layer 16 increases to a considerable extent and causes a corresponding redistribution of the

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Voltage applied to the PE layer 16 and the EI layer 18 via the first electrode 12 and the second electrode 1.4. This increases the voltage drop across the EL layer 18, which "causes it to light up brightly, namely along a _{line at right angles to the dimension L Q} at a position x which corresponds to the arrangement of the discrete area - in which ' the switching or changing of the state occurs at this point in the] FE layer 16. Therefore, by applying the first puncture Y ₁ and the second puncture V ₂ q.uer over the dimension L of the first low-conductivity electrode 12 and between the first Electrode 12 and second electrode 14 and furthermore by properly selecting the final size of the time varying voltage function V ₂ at the end of each half-cycle ^ "/ 2 a line of light running perpendicular _{to the dimension L Q is generated in group 1,} which scans the entire area of the EL layer 18 between the end or connection points χ = L _{Q and χ = 0.} The frequency or the speed of scanning or stripping is determined by the frequency of the first voltage function V and the second voltage function Vp.

3805/0373

The first puncture generator G-1 and the second puncture generator G 2, when used in the manner described above with reversed polarities in the second half period, use the return half of the hysteresis loop characteristic of the PE layer 16 to produce a second trace of a line of light whereby switching or a change in the state of the PE layer 16 is avoided, which would otherwise be necessary in order to cause the light line to return or move back. The polarity reversal voltage functions Y and V ₂ are applied during the period from t = ί / 2 seconds to t = C seconds, at which point a full scan cycle of the line trace is completed and the PE layer 16 is in the same state, in which it was at the time t = 0.

Because both sides of the hysteresis curve characteristic of the PE layer 16 are used, the current capacity of the puncture generators G-1 and G-2 is noticeably reduced, because the excessive currents that cause the PE layer 16 to switch during return the line of light required are avoided.

From Pig. 3 it can be seen that once the line of light has been generated in the EL-La ^ e 18, it passes through the

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visible second electrode H is transmitted therethrough, and hits the PC layer 20 in group 2. The PC location becomes highly conductive in the area in which it is touched by the light line, making a scanning line higher Conductivity across the PC layer 20 along the L dimension is generated.

In group 2 the third puncture generators correspond G3 and the fourth puncture generator G4 in their puncture or effect of the first puncture generator G1 and the second Group 1 puncture generators G2. However, the third and fourth puncture generators G3 and G4, respectively, are related to the second PE layer 22, the second SL layer 24 and the first PC layer 20 switched so that the output signals from pass this through all of these layers 22, 24 and 20. Since the first PC layer 20 in the area which is in aer first 3üL layer 16 generated light line corresponds to a high has specific (electrical) resistance, a second one becomes Gradient with progressive enlargement or enlargement dea Scanning perpendicular to the dimension L is generated to a Scan, perpendicular to the line or area of high Causing conductivity, and due to the high resistance of the first PC layer 20, a high voltage drop and danit

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a coercive force that is or are sufficient to to excite second ΙΈ-layer 22 and a fluorescent or Causing glow in the second EL layer 24, only over the or in the last two layers in the area of Line of high conductivity caused. This leads to a point of light in the area which is higher than the norm Conductivity and the second lying at right angles to it

position-modulated field gradients that change over time is common.

The fact that the prequeni of the voltage function of the fourth function generator G4 can be much greater than the frequency of the corresponding voltage function Yp ^ es second Puncture generator G 2 is made, the light point formed in the second EL layer 24 in group 2 or discrete Light area can be caused to sweep completely over the screen 10 before the line of light in group 1 and thus the high conductivity line in group 2 PC layer 20 has moved a distance along dimension L, which is greater than its own width.

As can be seen from FIGS. 1 and 4, the flying or running point is once in the second EL position 24 of group 2 is generated by the transparent third

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Electrode 26, the transparent insulating layer 28 and the
The fourth transparent electrode 30 of high conductivity is transmitted through it and hits the second PG layer 32, which represents the lower active layer of group 3 "

The group 3 has a modulating light amplifier, which causes the extent of the in the EL layer 34
generated illumination or * lighting itself as a combined puncture of the initial intensity of the flying or
current point that has hit the second PO layer 32 and a superimposed modulation voltage function
changes that of the fifth function generator. G5 is removed or derived.

The floating point creates a corresponding point of high conductivity in the second PO layer 32, which causes a redistribution of the voltage applied via the fourth electrode 30 and the fifth electrode 36 to the second PC layer 32 and the third insert 34, see above that the El-position 34 is essentially the full modulation voltage of the fifth
Function generator G5 is exposed and is forced to be in the same position as the conductive «. Point in the
second PC position 32 to light up. By modulating the
Voltage output of the 'fifth puncture generator S5 can

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the brilliance of the flying point in the third EL layer 34 can be modulated in order to produce the contrasts that - are necessary to produce an image on the third EI layer 34 of the screen 10 when the frequency of the scanning and the luminescent memory of the luminous third EL sheet 34 are sufficient.

Thus, when the fifth puncture generator G-5 is a source% of image signals, which are synchronized in correct manner with the scanning of the first, second, third and fourth function generator GM, Gf2, GF3 and GH can be applied to the third EL layer 34 of the Screen 10, a television image is produced which is visible and can be viewed through the fifth transparent electrode 36.

The operation of the Gfruppe 1 shown in Fig. 7 modified embodiment of the invention is DER _Λ jenigen operation of the same, the Figures has been described 1-6 according to in connection with the embodiment such that a flying Linienabtasten is caused, whereby the Line of light generated in the first EL sheet 18 in Group 1 moves in a direction across its own width along the L dimension.

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The fifth signal generator G5 operates in the embodiment according to Pig ο 7 that the PC-EL combination of group 3 the intensity of the scanning light line, which in the EL layer 18 of group 1 is generated, modulated, and it can even contain the only variable to be represented as an intensity function on the EL layer 34 of group 3, The Intensity modulation is effected in a manner identical to that described with respect to the embodiment according to Figures 1 and 4 has been described.

¥ ie can be seen from the above description and the drawing, the invention creates a new device for Scanning a line of light, a new screen to display a single variable or variable, the combination a device for scanning a line of light and a modulating light amplifier on v / eist, a new one Device for touching a flying point of light, the a combination of a first and a second device for scanning a line of light, - as well as a new, image-generating screen, which the new iii & direction to Scanning a flying point of light in combination with a modulating light amplifier. the layered embodiment according to the invention, which has a plurality of uniform, extending in the same direction.

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Layers and the new excitement of the active ones lay this one
A plurality of layers comprised by preselected voltage functions, fulfills or satisfies a need that has long existed in technology to create a thin, flat device for producing a television picture which takes up an optimally small space and has an optimally long useful life.

Various modifications are within the scope of the invention possible"

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Claims (1)

Claims 1o) screen device, characterized by a plurality of active layers or plies extending in the same direction, which are optionally separated into effective groups by means of electrode layers extending in the same direction, which are a first group that generates a first line of light which defines the layers in the periodically scans the first group, a second group optically coupled to the first group, which generates a second line of light which periodically scans the layers in the second group with respect to the first line of light at right angles (orthogonally) and in an area with the first line of light of the second group, which coincides with the first and the second line of light, in order to generate a light point 'with a higher relative intensity than that of the light lines,' the light point periodically scanning the positions of the second group, and having a third group which optically coupled to the second group and from the L ichtpunkt is scanned, whose intensity is optionally modulated and amplified when it scans the layers of the third group to produce an image in the third group,. ' SÖS805 / Q378 2.) Device according to claim 1, characterized in that the electrode layers between-the first, second and • third group are transparent. 3.) Device according to claim 1, characterized in that the first effective group having a ferroelectric layer and extending in the same direction and opposite arranged electroluminescent able% and that these layers associated electrode layers, a first electrode layer of low conductivity, which the ferroelectric Layer is arranged opposite, and have a second transparent electrode layer of high conductivity, which is arranged opposite the electroluminescent layer. 4.) Device according to claim 1, characterized in that the effective first group has a lower first electrode layer Conductivity and a second electrode layer of high conductivity extending in the same direction as this, a bistable non-linear dielectric layer which is arranged opposite the first electrode layer and extends in the same direction as this, and has an electroluminescent layer that of the second Electrode layer and the bistable non-linear dielectric Position is arranged opposite and extends in the same direction as this. 809805/0378 5.) Device according to claim 1, characterized in that the second effective group is a photoelectric conductive layer, which is coupled with the first effective group, a ferroelectric layer, that of the photoelectrically conductive layer is arranged opposite and extends in the same direction as this, and a electroluminescent ^ layer that of the ferroelectric Position is arranged opposite and extends in the same direction as this, and that these layers are assigned Electrode layers a first transparent electrode layer of high conductivity, that of the photoelectrically conductive Position is arranged opposite and the first and the second effective group is common, and one second transparent electrode layer of low conductivity have, which is arranged opposite the electroluminescent layer. 6.) Device according to claim 1, characterized gekennaeichnet, that the second effective group is a photoelectrically conductive layer which is optically coupled to the first effective group is, a bistable, non-linear dielectric layer, which is in the same direction as the photoelectrically conductive Layer extends, and has an electroluminescent layer, SAD 309805/0378 which extended in the same direction as the bistable, non-linear dielectric layer 7.) Device according to claim 1, characterized in that the first effective G group is a first ferroelectric Layer and a first electroluminescent layer, which the first ferroelectric layer opposite is arranged and facing in the same direction as this ™ extends, the electrode layers assigned to these layers have a first electrode layer of low conductivity, which is arranged opposite the first ferroelectric layer, and a second transparent electrode layer of high conductivity, which is arranged opposite the electroluminescent layer, the second effective group furthermore a first photoelectrically conductive layer, which is arranged opposite the second transparent electrode layer and in the same direction as this. Λ extends, whereby the first photoelectrically conductive layer is optically coupled to the first electroluminescent layer via the second electrode layer, a second ferroelectric layer which is arranged opposite the first photoelectrically conductive layer and extends in the same direction as this, and a second electroluminescent layer having that of the second BATH 809805/0378 ferroelectric layer is arranged opposite. and extends in the same direction as this, andcass the the second, transparent, high-conductivity metal electrode layer assigned to this second effective group, which is arranged opposite the photoelectrically conductive layer, and a third transparent electrode layer have low conductivity, that of the second electroluminescent Position is arranged opposite. 8.) Device according to claim 1, characterized in that the third effective group is a photoelectrically conductive Position and an electroluminescent layer extending in the same direction with this, which the electrode layers assigned to the third group have a first and a second transparent layer of high conductivity, that of the photoelectrically conductive or electroluminescent Layer are arranged opposite one another, and that the first electrode layer is a transparent insulating layer opposite is arranged, which is arranged between the second and the third effective group. 9.) Device according to claim 1, characterized in that the third effective group is a photoelectrically conductive. capable layer and an electroluminescent layer extending in the same direction with it, which "the" 8 0 9805/0378 Third group associated electrode layers have a first and a second transparent layer of high conductivity, which are arranged opposite the photoelectrically conductive "or the electroluminescent layer, a light blocking layer between the photoelectrically conductive layer and the electroluminescent layer opposite and extending in the same direction as this d , and that the first electrode layer is arranged opposite a transparent insulating layer which is arranged between the second and the third effective group. 10.) Device according to claim 1, characterized in that d -: the harvesting group eats a first ferroelectric Layer and a first electroluminescent layer arranged opposite the ferroelectric layer is and extends in the same direction as this, has the electrode layers associated with these layers a first electrode layer of low conductivity, which is arranged opposite the first ferroelectric layer, and have a second transparent electrode layer of high conductivity, which is opposite to the electroluminescent layer is arranged, the sv / eite effective group one photoelectrically conductive layer, which is the second transparent 809805/0378 gen electrical system is arranged opposite and in extends in the same direction as this, whereby the first photoelectrically conductive layer extends over the second electrode layer optically coupled with 'the first electroluminescent layer is, a second layer of titration, a second ferroele'ttric Location that of the first photoelectrically conductive Is arranged opposite one another and is in the same, seal like this one extends, and an aveite electroluninescent Layer aufv / eist, which is arranged opposite the second ferroelectric layer and is in the same In the same direction as this, the electrode layers assigned to the second effective group, the second transparent sheet metal electrode layer high conductivity, which is arranged opposite the first photoelectrically conductive layer, -xide a third transparent low conductivity electrode exhibiting the de. second electroluminescent layer opposite is arranged, the third effective group a second photoelectrically conductive layer, which with the wide electroluminescent layer is optically coupled, une has a third elektroluminos ^ ierenae layer, which is in same direction as the second photoelectrically conductive Position extends, assigned to the third effective group A fourth and a fifth transparent electrode layers 809805/0378 Have electrode layer of high conductivity, which are arranged opposite the second photoelectrically conductive layer and the third electroluminescent layer, the fourth transparent electrode layer is arranged opposite a transparent insulating layer and extends in the same seal as this, 'the insulating layer of the third; transparent electrode layer is disposed quietly gegenüberlie-%, is optically coupled whereby the second light-electroconductive layer with the second electroluminescent layer " 11.) Device according to claim 10, characterized in that that the third effective group has a light blocking layer between the second photoelectrically conductive ■ Layer and the third e ectrolumirieszierenden layer arranged is and extends in the same direction v / ie this. 12.) Screen, characterized by a first Electrode layer, one of the first ferroelectric layer adjacent to the first electrode layer, one of the first ferroelectric Layer adjacent first electroluminescent layer, one of the first electroluminescent layer adjacent second electrode layer, one of the second electrode layer adjacent first photoelectrically conductive layer, a second adjacent to the first photoelectrically conductive layer 809805/0378 ferroelectric layer, one of the second ferroelectric layer ' adjacent second electroluminescent layer, a dj + rtte adjacent to the second electroluminescent layer Electrode layer, a transparent insulating layer adjacent to the third electrode layer, one adjacent to the insulating layer fourth electrode layer, a second photoelectrically conductive layer adjacent to the fourth electrode layer, a the third electroluminescent layer adjacent to the second photoelectrically conductive layer and through one of the third electroluminescent layer "adjacent fifth electrode layer.. ■ 15.) Screen according to claim 12, characterized in that all adjacently arranged layers are opposite one another are arranged and striked in the same direction. '' 14 ·) Screen according to claim 12 and 13, characterized in that the second, third, fourth and fifth The electrode layer and the insulating layer are transparent layers. 15o) device for generating a line of light, which periodically scans a preselected area in a direction transverse to the length of the line, indicated by a \ 809805/0378 * first and second puncture generator, a first and a second electrode layer of low or high conductivity, which extend in the same direction as the preselected area, a bistable non-linear dielectric layer, which extends in the same direction as the first electrode layer, and is by an electro-luminescent layer. the second electrode layer extends in the same direction as the dielectric sheet, and%, wherein the first puncture generator transverse lektrodenlage over a preselected dimension of the first ^, and connected in the second puncture generator between the first and second ülektrodenlage . 16.) Device according to claim 15, characterized in that the first puncture generator applies a first voltage function of alternating polarity and constant amplitude across the preselected dimension of the first low conductivity electrode layer, whereby a gradient of alternating direction along the preselected dimension is generated in an electrical * PeId the second puncture generator applies a second voltage function of alternating polarity and variable amplitude, which is synchronized with the first voltage function and has the same frequency, between the first and the second electrode position, whereby the gradient of the electrical field changes over time 809805/0378 changing electrical PeId is superimposed and by the dielectric and eleftroluminescent layer applied through it where the electric field, which changes over time, and the field gradient have an additive effect in order to increase the strength of the electric field between the electrode layers of the one end of the preselected dimension to the other during each half cycle of the first and second AC voltage functions to increase continuously. 17 ·) Device according to claim 15 »characterized ', that the first function generator across the preselected dimension of the first electrode layer of low conductivity apply a first voltage function, any one symmetrical square waveform of constant amplitude and that the second function generator applies a second voltage function, the symmetrical triangular one Waveform with constantly increasing amplitude during each half cycle and the same frequency as the first Has voltage function and is synchronized with it. 18.) Device according to claim 15, characterized in that the bistable, non-linear dielectric Layer is formed from ferroelectric material. 19 ·) Device for generating a running or flying Point grid, characterized by a first device 809805/0378 device for generating a line of light which periodically scans a preselected area in a direction transverse to the length of this line, a second device optically coupled to the first device for generating a
characteristic line area, which is the light
line corresponds and for generating a second characteristic line area, v / which the preselected area ™ with respect to the first line area at right angles
periodically scanned, the second device the
second line area given a scanning speed which is sufficiently greater than that of the first line area, such that the second line area the
Length of the first line area scanned before the first line portion has moved to one of its own width corresponding distance, whereby the two side line portions common area at the interface forms an vollständi- έ gen grid on the preselected range, and generates a light spot in the second device, whose size corresponds to the common area. 20.) Device for generating a flying
Dot grid, characterized by a first electrode layer, one of the first electrode layer adjacent ferroelectric 809805/0378 see layer adjacent first electroluminescent layer, one of the first electroluminescent layer adjacent second electrode layer, a first photoelectrically conductive layer adjacent to the second electrode layer, a the second ferroelectric layer adjacent to the first photoelectrically conductive layer, one of the second ferroelectric Layer adjacent second electroluminescent layer and one of the second electroluminescent layer adjacent third electrode layer. 21.) Device according to claim 20, characterized in that the second and the third electrode layer are transparent are. 22.) Device according to claim 20, characterized in that the adjacent layers are opposite one another are arranged and extend in the same direction. 23.) Device for generating * 'a flying dot matrix on "a preselected area, characterized by first means for generating a line of light which traverses the preselected area in a direction transverse to the length of the line, said first device having a first and a second function generator, a first and a second electrode layer with low or high conductivity 809805/0378 ability to aa? first bistable, non-linear dielectric Layer which is arranged opposite the first electrode layer and extends in the same clearing as this, a first electroluminescent layer, that of the first dielectric layer and the second electrode layer opposite is arranged and extends in the same direction as this, wherein the first function generator ™ is connected across a first selected dimension of the first electrode layer and the second function generator is connected between the first and the second electrode layer, a second device for generating a first characteristic line area, which corresponds to the light line, and for generating a second characteristic line area, which the scans preselected area at right angles with respect to the light line, this second device having a third λ and a fourth function generator, a third electrode layer low conductivity, which extends in the same direction as the preselected area, a photoelectric conductive layer that of the second bistable, non-linear dielectric layer is arranged opposite and extends in the same direction as this, with the dielectric layer opposite the photoelectrically conductive layer 809805/0378 is arranged horizontally and extends in the same direction as this,. a second electroluminescent La ^ e, the second dielectric layer and the third Ülektrodenlage, ^ e, is arranged and extends in the same direction as these, wherein the third puncture generator across a second preselected dimension of the third i; lektrodenlage is connected, oils: ^v iit respect to the first preselected dimension of the first ilektrodenlage runs at right angles, and said fourth puncture generator between the second and CIIE third lilektrodenlage is connected. 24.) Device according to claim 23, characterized in that the first and the second bistable nonlinear dielectric layer made of ferroelectric ^! Material are formed. 25.) Device according to claim 23, characterized in that that the first and the third puncture generator a first and a third voltage si unction with symme-. tric quadratic shape of constant amplitude transversely about the first and second selected dimensions of the first and third electrode layers of low conductivity apply, and that the second and the fourth puncture generator SAO 809805/0378 a second and a fourth voltage function with a triangular shape Waveform and constantly increasing amplitude between the first and second and during each half cycle of the second and third electronic devices, whereby the first and second spaiming functions are synchronized and have the same frequency, and the third 'and the fourth Voltage function are also synchronized and are the same Have frequency. 26.) Device according to claim 23, characterized in that the scanning speed of one line area is larger than that of the other line area. 27.) Device according to claim 23, characterized in that the second and the third electrode layer are transparent, the photoelectrically conductive layer thereby optically with the first electroluminescent layer is coupled and creates a line area of high conductivity ^ in this, soft the second device at right angles to the line area in accordance with the first light line scanned. 28.) Device for generating a line of light, the intensity of which is modulated by a freeze-determined variable, _ and the one selected area in a horizontal direction 809805/0378 to the length of the line, characterized by a plurality of extending in the same direction active layers, which are optionally separated into effective groups by electrode layers extending in the same direction are the a first group that generates a first line of light that periodically defines the positions in the first group samples, and have a second group which is optically coupled to the first group and the intensity the light line is optionally modulated and amplified when scanning the layers of the second group. 29 °) Device according to claim 28, characterized in that the active groups separating electrode layers are transparent. 30.) · Device according to claim 28, characterized in that the first effective group is a ferroelectric Layer and having an electroluminescent layer which is arranged opposite to the ferroelectric layer and extends in the same direction as this, and that the electrode layers associated with these layers have a first Electrode layer of low conductivity, which is arranged opposite the first ferroelectric layer, and a second transparent electrode layer with high conductivity 809805/0378 ability that of electroluminescent Position is arranged opposite one another. 31.) Device naoh claim 28, characterized in that that the second effective group is a photoelectrically conductive layer and one in the same Direction like this extending electroluminescent Position. 32e) Device according to claim 28, characterized in that that the second effective group is a photoelectrically conductive layer, one facing in the same direction like this extending electroluminescent layer and a light blocking layer between the electroluminescent and the photoelectrically conductive Position is arranged and extends in the same direction as this. 33.) Device according to claim 28, characterized in that the first effective group is a first and a second electrode layer of low or "high conductivity, which extend in the same direction, a "bistable, non-linear dielectric layer, that of the first Elek Trodenlage is arranged opposite and in gl'ei Cher direction like this extends, and an electroluminescent La ^ each has that the second ülektrodenlage and 809805/0378 opposite the bistable non-linear dielectric layer is arranged and extends in the same direction as this. 34 «) Device according to claim 28, characterized in that the first effective group has a first and a second electrode layer with low or high conductivity, which extend in the same direction, a bistable, non-linear dielectric layer, that of the first electrode layer is arranged opposite and extends in the same direction as this, an ele: troluminescent position, which the second electrode layer and the bistable, non-linear dielectric layer are arranged opposite one another is and extends in the same direction as this, and that the second effective group is a photoelectric conductive layer and a second electroluminescent layer which extends in the same direction as cie photoelectrically conductive layer extends. 35.) Device according to claim 34, characterized in that the second effective group has a light blocking layer, which is arranged between the photoelectrically conductive layer and the second electroluminescent layer and extends in the same direction as this. 80.9805 / 0373 36.) Device according to claim 28, characterized in that the first effective group has a ferroelectric layer and an electroluminescent layer extending in the same direction as this and arranged opposite it, that the electrode layers assigned to these layers have a first electrode layer of low conductivity, the first ferroelectric layer is arranged opposite, and have a second transparent electrode layer of high conductivity, which is arranged opposite the first electroluminescent layer, the second effective group is a photoelectrically conductive layer that extends in the same direction as the second electrode layer, a second electroluminescent layer, which extends in the same direction as the photoelectrically conductive layer, and has a third transparent electrode layer which extends in the same direction as the electroluminescent layer ( . 37.) Device according to claim 36, characterized marked j - i net that the second effective group has a light blocking layer which is arranged between the photoelectrically conductive layer and the second electroluminescent layer and ,. '· Extends in the same direction as this. . ; 809805/0378, ί 38.) Screen, characterized by a first electrode layer, one of the first electrode layer adjacent bistable, non-linear dielectric layer, one of the bistable, Non-linear dielectric layer adjacent first electroluminescent layer, one of the first electroluminescent Layer adjacent second electrode layer, one of the second electrode layer adjacent photoelectrically conductive layer, a second electroluminescent layer adjacent to the photoelectrically conductive layer and one of the second electroluminescent layer adjacent third electrode layer ·. 39.) Screen according to claim 38, characterized duroh a light blocking layer between the photoelectrically conductive and the second electroluminescent layer is arranged. 40.) screen according to claim 38, characterized in that that all adjacent layers are arranged opposite one another and extend in the same direction. 41.) Screen according to claim 38, characterized in that all adjacent layers are arranged opposite one another and extend in the same direction, and that the second and third electrode layers are transparent. - \ ■ are. 809805/0378 42.) Screen, characterized by a device to create a light area which the area . of the screen scans, this device having a non-linear, bistable dielectric layer, which is in the same Direction as the screen extends, and is electroluminescent Has layer that extends in the same direction as the bistable dielectric layer, and by a with this device optically coupled device for modulating and amplifying light, the one photoelectrically conductive layer and an electroluminescent layer, both in the same direction as the Extend the umbrella. 43) screen according to claim 42, characterized in that the non-linear bistable dielectric layer ferroelectric material is formed. 44 ·) Screen according to claim 42, characterized in that the device for modulating and amplifying Light has a light blocking layer between the photoelectrically conductive and the electroluminescent layer is arranged. 45.2 Device for creating a return-free, scanning process running continuously in one direction across a material layer of a line area 809805/0373 high dielectric constant in a line across the length of the line area,. ^ denotes by a bistable, non-linear dielectric layer and oil Signaling device, which through the location a applies the first signal energy with constantly changing magnitude and with a constant gradient across the layer, to cause a first scan of the position, and which has a second signal energy similar to the first signal energy, but reverse polarity, applies through the layer, a second scan of the location in the same direction how to cause the first scan. 46.) Device according to claim 45 »characterized in that that the bistable, non-linear dielectric position a-us ferroelectric material is formed. 47.) Device according to claim 45 »characterized in that that the signaling device has a first and a second electrode layer of low and high conductivity, respectively has, which is in the same direction as the Fiateriallage also extend a first puncture generator extending across a preselected dimension of the first membrane layer is connected, and a second puncture generator between the electrode layers are switched. 809805/0378 48.) Device according to claim 45, characterized in that that the first and second signal energies alternate half-cycles of the combined outputs of the first and second puncture generators. 49o) Device according to claim 45, characterized in that that the first and second signal energies have alternating half-periods of the composite signal energy, a signal of alternating polarity and constant amplitude of the first puncture generator and a signal of alternating Contains polarity and variable amplitude of the second puncture generator. 50.) Device according to claim 45 _? characterized in that the first and second signal energies have alternating half-cycles of the composite signal energy having a symmetrical square waveform of constant amplitude of the first puncture generator and a symmetrical triangular waveform with constantly increasing amplitude during each half cycle and having the same frequency as the square waveform and is synchronized with it. 809805/0378