DE1414963C - Optoelectronic circuit and solid image intensifier built from it - Google Patents

Description

1 2

The invention relates to an optoelectronic The desired amount of feedback is, a

nical circuit for converting optical depending on the intended purpose, is different output signals into optical output signals with opti- Normally the photoconductive element are ur shear feedback, consisting of three to one the radiating element, for which usually an electric common star point connected and used by 5 luminescent element to eim a main voltage source fed branches, structural unit joined together. Without special namely an input branch with a photoconductor measures can then measure the feedback line and one optically coupled to the photoconductor only changed by changing the supply voltage Feedback branch and an optical of the will. This has the disadvantage that the output; Photoconductor shielded output branch with one IO signal each can no longer be optimal. Under certain electric light source. In the tenth circumstances, the largest output signal will be ei

There are arrangements with one through one if the supply voltage is as high as possible tric supply source-fed circuit of a photo-bistable electro-optical circuit arrangement;

conductive element and a radiation element and their mode of action are z. B. in Zeitschrii 15 "RCA Review", December 1959, pp. 715 to 743 Depending on the intensity of the emitted radiation, see in particular p. 737, FIG. 23 and p. 725, FIG. 9 known in which a change in the impedance of the described in detail .. Solid-state image amplification photoconductive element, the supply of electrical or the assembly of a photoconductor or Affects energy to the radiating element. a photoconductive element with a light source f

Such optoelectronic arrangements 20 or a radiation element are known from the French an optical feedback in the sense provided by patent specification 1 237 971 is known, be applied that a larger or smaller part of these known arrangements could the

the beam emitted by the radiation element - so-called feedback only with simultaneous exposure captured by the photoconductive element, the influence of the emitted useful radiation is changed and thereby the impedance of this element controls 35. However, this was true for many use cases or participate. This feedback can be a significant disadvantage, and if so, that disadvantage being positive, whereby the arrangement can be remedied more strongly, is an application of Erihr supplied electrical or optical signal finding very largely possible, z. B. for measurement reacted. With sufficiently strong positive feedback purposes for devices for electronic data processing An instability can occur with the processing mentioned for shift registers in this arrangement Elements to be implemented as tilting formwork or as a solid-state image intensifier processing arrangements is used. These circuits par excellence.

can be used in shift registers or other circuit The disadvantages mentioned are discussed in the introduction

arrangements for the shorter or longer holding called optoelectronic circuit by the used by information. 35 invention avoided by in the feedback branch

So is z. B. a bistable relaxation circuit arrangement in series with the electric light source known, which consists of two switched to the same adjustable impedance and / or an elek voltage source connected series circuits tric auxiliary voltage source is arranged, whose consists, each with a photoconductive element and voltage without affecting the voltage of the an electroluminescent 4 ° main voltage source optically coupled with this can be set. decorative element are provided, in which all of these This makes it now possible to control the feedback

Let elements with the same star point of the scarf act positively or negatively and the dimension processing arrangement are connected. this feedback exactly as required.

It is also known to provide a picture display panel. By controlling the impedance or the mutually associated photoconductive and luminescent voltage of the auxiliary voltage source can according to Ending, especially electroluminescent EIe desire the amount of feedback in the first branch ments to put together. These so-called are set without the part of the food-solid image intensifiers is due to a limited voltage of the star connection, which is maximum in the The amount of optical feedback between the one third branch results, needs to be changed, on the other associated elements an additional control 50 This is in contrast to the known control To get strengthening. In the case of a stronger positive feedback, by means of a change in the supply voltages, a larger one Coupling can have the reproduced benefit due to instability. More details on this can be found on the basis of the figure image be held for a long time. description explained.

The amount of feedback, either positive or

negative, in such optoelectronic arrangements 55 feedback branch and the output branch from the The main voltage source is electrically parallel as seen from several factors it's correct. In addition to the overlap the spectral can be switched. Also can be from the main sensitivity curve of the photoconductive element voltage source from the point of view of the input branch and the spectral emission curve of what is hereby optically electrically coupled to the parallel connection of feedback Radiant element and the size of the 60 branch and output branch connected in series Share that are emitted by the radiation element. The feedback branch can be used Radiation through the photoconductive element on the one hand with the star point and on the other hand with a is caught, the frequencies or the adjustable contact of one play the main voltage source Frequency spectrum and the amplitude of the supply bridging voltage divider must be connected, tension plays a role. The proportion of the beam is 65 Furthermore, it is possible in the case of the feedback not only through the arrangement of the elements in series with the elements in this branch towards one another, but also from the first electrical light source that has been made transparent depending on the media located between them. to switch controllable impedance and after the

3 4

Finding this controllable impedance consists of a contains a photoconductor 2, z. B. a cadmium second photoconductor whose impedance is controlled by sulphide cell. A feedback branch contains a lighting device that can be set by external means, that is to say not included in the star connection consisting of an electroluminescent cell. electrical light source 3, which is electrically connected in series with the Irish light source connected in the feedback branch. The light source 3 and the photoconductor 2 are at a maximum at a wavelength which is arranged in such a way that the radiation of the photoconductor in the input branch can have a penetration depth of the light source 3 on the photoconductor 2, less than 5 μm. as in Fig. 1 indicated by an arrow. The one-one solid image intensifier according to the invention 10 adjustable impedance 4 can consist of a controllable one, which is characterized in that the power supply resistance consists. Another type of electrodes of the corresponding branches of this circuit can also be used with a controllable impedance, e.g. B. lines are mutually through-connected and have a controllable self-induction or capacitance or through-connected feedback electrical a combination of impedances, one of which is or are adjustable light sources with a common adjustable 15 or more.
Auxiliary voltage source, a voltage divider or the output branch contains one from an electro-an impedance are connected. In this case, parts of a luminescent cell can be a light source 5, a light source 5 formed via truncated pyramids from sintered radiation U of which forms the output signal. A glass with aluminum oxide extending photoconductive optical shielding 6 prevents the radiation layer from hitting corresponding parts of two parallel 20 of the light source 5 on the photoconductor 2 in the input luminescent paths in the support layer for this branch. Control from the main voltage source 1 from truncated pyramids, the radiation of which is seen the parallel connection of the feedback a luminescent path can react on the controlling and the output branch with the light sources 3 photoconductive parts and the other and 5 electrically with the input branch with the luminescent path optically from the photoconductive a5 photoconductor 2 connected in series.
Layer is shielded. It is also possible that the operation of the circuit arrangement according to the photoconductor parts of an electroluminescent layer F i g. 1 is as follows: Without irradiation of the photo control, which consists of two parallel, mutually through conductor 2, its resistance is so high that the partial layer separated by an optical shielding layer contains essentially the entire voltage of the main ribs, one of which is connected to the photoconductor The voltage source 1 is located on this photoconductor 2 and is turned and is optically coupled to it and light sources 3 and 5 do not or hardly any light from the other is intended to send the enhanced image. The photoconductor 2 is now irradiated, thereby making it visible. that one for this purpose with this photoconductor 2 Under photoconductor is to be understood here an element, only optically coupled, further electromagnetic or body electrical signal from an electrical impedance through a suitable light source 7 existing on the luminescent cell is supplied to an element, so the kulare radiation is changed, e.g. B. by changing the voltage on the photoconductor 2, while that on in the resistance or in the capacitance, after which the light sources 3 and 5 increases. The increase in the cessation of this irradiation to its origin - the voltage on the light source 3 will thereby return to the value borrowed. The electromagnetic 40 can be smaller, the higher the set value of the Impe radiation in the visible part of the spectrum is danz 4. If the radiation from the light source 3 is on, however, radiation with a longer length can also react back to the photoconductor 2 and thereby the effect or shorter wavelength, for example ultrared or the one from the light source? generated radiation X-rays, be suitable. . · Supported, the feedback is positive. The measure The invention is explained in more detail for exemplary embodiments at 45 the feedback is from the set value of the hand of the drawings. It shows impedance 4 dependent, so that by setting this F i g. 1 the electrical circuit arrangement with impedance 4 also includes the amount of feedback; the three can be connected to a common star point. The transmitted by the light source 5; closed and given by a main voltage source, the highest output signal that occurs when branches are fed, 50 by sufficiently intense irradiation of the photo. 2 shows a cross section through one of the circuit conductors 2, the resistance of which no longer plays a role; arrangement according to FIG. 1 corresponding arrangement is not affected.

j F i g. 3 shows a cross section through an optoelectronic very suitable for a practical structure

j niche bistable relaxation circuit, with the two formation of the impedance 4 as a photoconductive element,

j different ways of obtaining a controllable 55 which then for the indicated control of the reverse

! optical feedback are indicated, coupling separate, adjustable lighting means

'F i g. 4 shows a circuit arrangement in which the are assigned.

\ Control of the feedback through an adjustable A possible structure of a circuit arrangement

! able contact, at which the voltage is removed according to Fig. 1, Fig. 2 shows in a cross-sectional view

is, takes place, 60 position.

j F i g. 5 shows a circuit arrangement with a different photoconductor 2 from FIG. 1 is replaced by a

j circuit of the branches, layer 12 formed of photoconductive material that

6 and 7 each show a partial cross section of a transparent, preferably made of glass,

j solid image intensifier with adjustable positive standing support 20 is arranged. On the shift

j optical feedback. 65 12 are interlined comb-shaped electrodes 21

j The circuit arrangement according to FIG. 1 contains three and 22 arranged. On the other side of the

connected to an alternating main voltage source 1 carrier 20 is a transparent sheet-like

those branches connected in a star. An input branch electrode 23, which is preferably made up of one layer

conductive tin oxide. On the electrode 23 a clektroluminescent layer 13 is applied, which corresponds to the light source 3 according to FIG. 1 corresponds. The radiation of the layer 13 can through the electrode 23 and the carrier 20 through the resistance affect the layer 12.

On the other side of the layer 13 is a second electrode 24, which is preferably opaque is. This electrode can e.g. B. from a relatively thick, vapor-deposited onto layer 13 Consist of a metal layer, e.g. B. aluminum. A second insulating support, e.g. B. through a glass plate 25 formed, rests on the electrode 24, and on the other side thereof are two interlining comb-shaped Electrodes 26 and 27, which are preferably made of a locally transparent tin oxide skin of the plate 25 exist. A photoconductive layer 14, which has the impedance 4, extends over these electrodes 26 and 27 according to Fig. 1 corresponds. On this layer 14 is another glass plate 28, which is on the other side a conductive sheet-like electrode 29 carries. This electrode 29 is not transparent and consists preferably made of a reflective metal layer, e.g. B. made of vapor-deposited aluminum. On the electrode 29 is a second electroluminescent layer 15, which is a transparent one on the other side has sheet-like electrode 30 on the surface of a further transparent carrier 31. The electroluminescent layer 15 corresponds to the light source 5 according to FIG. 1.

The structure is on the side edge with the exception of itself in the direction perpendicular to the plane of the drawing extending channels 32 and 33 at the level of the photoconductive layer 14 and those on both sides reflective electrodes 24 and 29 located therefrom surrounded by an opaque insulating jacket 34, the z. B. can consist of a cured epoxy resin. The electrical circuit arrangement of the structure is the same as that of FIG. 1 identical.

The main electrical voltage source 11 is on one side with the comb-shaped electrode 21 the photoconductive layer 12 and on the other side with the transparent electrode 30 of the layer 15 and connected to the comb-shaped electrode 26 of the layer 14. The other comb-shaped Electrode 27 of this layer is conductive with the upper transparent electrode 23 of the electroluminescent Layer 13 connected. The second electrode of this layer, namely the reflective metal layer 24, like the reflective electrode 29 of the electroluminescent layer 15, is conductive to the second comb-shaped electrode 22 of the photoconductive layer 12 connected. The resistance of the photoconductive Layer 14 can be adjusted by incandescent lamps 35 and 36 arranged in channels 32 and 33 are, of which the laterally falling into the glass plates 25 and 28 light by reflection at the Electrodes 24 and 29 hit the layer 14. The radiation intensity of the incandescent lamps 35 and 36, the are preferably rod-shaped, can be adjusted in a known manner, e.g. B. by one in series with them recorded ordinary adjustable resistance.

With regard to the development of heat, it can be advantageous to illuminate the photolcitcnden Layer not by incandescent lamps, but by one extending parallel to this layer 14 further electroluminescent layer, which is shown in FIG. 2 is not shown to be done. This layer is then connected to an adjustable voltage, so that by controlling this voltage the resistance of layer 14 is adjusted. This further electroluminescent layer is intended to be three-dimensional be arranged between the electrodes 24 and 29. For proper electrical contact between the layer 13 and the electrode 24 and also between the layer 15 and the electrode 29 can these each consist of two conductive layers in contact with one another, one on top of the Carrier 25 or 28, the other on the electroluminescent layer 13 or 15. The conductive layer on an electroluminescent layer can, for. B. be applied by vapor deposition.

F i g. Figure 3 shows a cross section of a bistable relaxation circuit arrangement according to the invention. The arrangement consists of two in the same way

Sections structured in this way, in which one each with external Means to be regulated optical feedback takes place. Together for the two sections, one of which in the left half and the other in the right half of the figure in cross section

As shown is an opaque one, preferably reflective metallic electrode plate 40 arranged. This plate is one in each section common electrode for two electroluminescent ones arranged on either side of the plate Layers 43 and 45 or 63 and 65. The second electrode of layers 43 and 63 is through a conductive layer 41 and 61 formed on the surface of a transparent support 46 and 66, respectively. This Carriers are provided on the other sides with a photoconductive layer 44 or 64, on which interlining comb-shaped electrodes 47 and 48 or 67 and 68 are.

The second electrode of the electroluminescent layer 45 or 65 is by a sheet-like transparent electrode 49 and 69 formed on a transparent support 50 and 70, respectively. The described Arrangement is fed by a main voltage source 39, one terminal of which with the comb-shaped Electrode 47 in the left section and the sheet-like electrode 69 in the right section is connected, while the other terminal is connected to the comb-shaped electrode 67 in the right Section and the sheet-like electrode 49 is connected in the left section. The comb-shaped Electrode 48 or 68 of the photoconductive layer 44 or 64 is connected to the common electrode plate 40 connected.

In each of the sections, the upper photoconductive layer 44 or 64 can be influenced by the light are emitted through the underlying electroluminescent layer 43 or 63 will. In this way, an optical feedback is obtained in each of the sections, analogous to the feedback between the electroluminescent cell 3 and the photoconductive cell 2 in the array according to Fig. 1.

The amount of feedback can be adjusted in each section in that between the electrodes 41 and 45 in the left section a controllable voltage source 51 and between the electrodes 61 and 65 an identical voltage source 71 is connected in the right-hand section. The auxiliary voltage sources 51 and 71 supply an alternating voltage, the preferred

wise has the same frequency as the voltage supplied by the main voltage source 39. Through Adjustment of the amplitude and the phase of the alternating voltage of the source 51 can take care of this i will that the voltage across the electroluminescent; end layer 43 lower to a certain extent, possibly higher than that on layer 45, so that by regulating the voltage of the source 51 arbitrarily set the amount of feedback; can be.

The same applies to the voltage of the source 71, with which the amount of feedback between the electroluminescent Layer 63 and the photoconductive layer 64 can be regulated. The purpose of the optical feedback is that each section has two , has stable states, in one of which the photoconductive layer 44 or 64 has a high resistance : has and consequently the electroluminescent; Layers underneath do not emit light while in the other state the electroluminescent: layers probably emit light and the resistance i of the overlying photoconductive layer is low. ; By having the electrode 40 for the two sections is common, the two sections are in a different stable state. As a result is always one of the two electroluminescent layers 45 and 65 emitting light, while the other emits no light. The transition of the arrangement from one stable state to the other can be achieved by irradiating the photoconductive layer, which is located above the non-luminescent electroluminescent Layer is located, so that the resistance of this photoconductive layer I decrease enough. The latter depends on the amount of feedback between the photoconductive layer 44 or 64 and the underlying electroluminescent that emits light to this layer Layer 43 or 63 depending. This amount of feedback is, as described above, by the The amplitude and the phase of the voltages supplied by the sources 51 and 71 are determined.

In the case of very strong feedback, switching from one to the other is stable State of the arrangement a relatively strong irradiation or a relatively strong light pulse to the high resistivity photoconductive element 44 at that moment or 64 required. This control radiation or this control pulse can be smaller or smaller, depending on the voltage of the sources 51 and 71 is set so that a lower voltage at the associated electroluminescent layer 43 or 63 results. The smaller difference in the resistance of the photoconductive elements in one and the other stable state of a section, the transition from this one to the other while maintaining the same strength of the Control radiation or the control pulse can take place faster.

Because the electroluminescent elements 43 and 63, which accomplish the optical feedback in a section, are different from the electroluminescent layer 45 and 65, which provide an output signal of the arrangement, the amplitude of the voltage source 39, without the possibility of setting the desired amount of feedback to impair, always be chosen in such a way that in a stable. State, the maximum permissible voltage is obtained at the electroluminescent layer (45 or 65) which then emits light and supplies the output signal, so that the arrangement has an optimal output intensity.
The output signals of the arrangement are of an optical type and can e.g. B. can be used to control a further similar arrangement, the layers corresponding to the photoconductive layers 44 and 64 are arranged opposite the electroluminescent layers 45 and 65. The. Input signals, that is, the external irradiation of the photoconductive layers 44 and 64, can be obtained by the same arrangement as above. Of course, it is possible to control the arrangement in other ways, e.g. B. in that an electroluminescent cell or another radiation element is arranged over each of the photoconductive layers 44 and 64, which cell or which radiation element electrically controllable pulses are fed.

Instead of using separate controllable voltage sources 51 and 71, electrically on the same place as desired adjustable impedances, z. B. variable resistors added that each exercise a function in the associated section, the same as that of the adjustable ones Impedance 4 of the arrangement according to FIG. 1.

In Fig. 3 is another one with dashed lines other possibility indicated. Instead of the interposition of separate voltage sources 51 and 71, the voltage across the electroluminescent layers 43 and 63 is controlled in that in the branch with such a layer, as it were, a controllable part of the main voltage source 39 was added will. In Fig. 3 this is possible by connecting the electrode 41 or 61 to an adjustable one Contact of an impedance 55 bridging the main voltage source 39, e.g. B. a resistor or a self-induction. It is easy to see that by shifting such a Contact further from the end, which is connected to the same terminal of the main voltage source 39, with the electroluminescent under the related feedback layer 43 or 63 Layer 45 or 65 is connected, the amount of positive feedback is decreased.

In order to have the feedback effect in the two sections of the arrangement according to FIG. 3 on the relevant Section and also that of the electroluminescent layers 45 and 65 Keeping generated optical output signals separate is above and below the common electrode 40 an opaque wall 56 is provided between the two sections. The arrangement is also surrounded by an opaque insulating jacket 57 at the side edges. The partitions 56 and the jacket 57 can, for. B. made of an opaque hardened plastic, e.g. B. a Epoxy casting resin.

F i g. 4 shows the circuit arrangement similar to an arrangement according to FIG. 3, which also has a controllable Part of the supply voltage is the voltage across a cell that is optically coupled to a photoconductive cell electroluminescent cell. The supply voltage is applied to the end terminals of the secondary winding 101 of a transformer 100 taken and placed in a series circuit of a photoconductive Element 102 and an electroluminescent

209Α1Λ / 15

9 ίο

Cell 105 pressed, which uses the output signal U output signal, this feedback or supplies. With the connection point of the photoconductive the signal reverses its sign. Also element 102 and output cell 105 is one, the electro-coupled cell optically coupled back optically to element 102 on a photoconductive cell can be of a different type than luminescent cell 103, the other cell of which supplies the output signal.
Electrode with an adjustable sliding contact 107. The two light sources can also be of the same type on the secondary winding 101 of the transformer, e.g. B. both electroluminescent,

100 is connected. The shifting of this contact, however, changed with a different color of the sanded out the amount of feedback. The first to be positive. With regard to sensitivity tive feedback becomes smaller, depending on the io it is advantageous to use the spectral emission curve of the Contact 107 further from the end of the winding 101, the light emitted by the feedback cell connected to cell 105 is removed. to the spectral sensitivity curve of the photoconductive

The feedback is positive or negative to the element on which this cell acts back.

called when the change that one can fit from the outside. To get a quick response from a photoconductive

supplied signal in the state of the arrangement, for 15 the cell on the radiation of the optically

in the event that no optical feedback of the pre-coupled radiation element is to be obtained, it is pre-

which is caused, partly by the presence, by the choice of the radiating element and /

such feedback increases or decreases or the medium between the two for it

will. If, in the arrangement after the circuit, ensure that the feedback radiation in the photoconductive

arrangement according to fig. 4 the contact 107 far after ao border material has a small depth of penetration, z. B.

is shifted to the left, d. H. to the end of the coil smaller than five microns when using

101, to which the photo conductive cell 102 is connected- cadmium sulphide cells are therefore essentially sen, this cell and the electroluminescent cell are in the blue part of the visible spectrum.
Cell 103, seen from the transformer 100, is essentially electrically connected in parallel in the adjustable feedback according to the invention. A 35 can advantageously be used in a solid-state image intensifier voltage drop across cell 102 as a result of a. An example is shown in FIGS. 6 and 7 explained reduction of its resistance by an external, each representing a part of a cross section. The result of the light signal is that the voltage across the cell 103 also decreases. 6 shows a cross section along the line of photoconductive cell 102 less strongly irradiated and VIII-VIII in FIG. 7, while FIG. 7 shows a cross section along the line IX-IX in FIG. 6th
is counteracted. In this case, there is a negative flat or feedback made of a sheet of glass. This has a linearizing effect on the slightly curved support 500 is on the top with a characteristic that the ratio between a number of parallel extending mutually external illumination intensity of the photoconductive 35 separate electrode lines (511 and 512) provided, cell 102 and the luminosity of the output cell, which alternates are connected so that 105 indicates. In order to obtain the desired voltage distribution over different electrodes 512 in the same electrical cells 103 and 105 without an external light signal on the various electrodes 511 and likewise the cell 102, it is advantageous to form a group having a tric potential. Which the capacity of the cell 103 smaller, z. B. to choose a 40 electrodes 511 and 512 consist in a known manner, a factor of two smaller than that of transparent conductive tin oxide on the electroluminescent cell 105. surface of the support 500. On the electrodes 511

In the circuit arrangement according to FIG. 5 are an electroluminescent sheet following them photoconductive cell 402 and an electroluminescent 503 arranged, which consists of a red electroluminescent Output cell 405 electrically connected in parallel 45 made of decorative material and sintered glass powder, and in series with these two branches is a The electroluminescent material can e.g. Ballast impedance 408 added. In this Cu and Al activated ZnSe exist. On the Arrangement occurs again signal inversion. The electrodes 512 are also made of an electro-optical one Feedback that is via the attached to the luminescent material and a sintered glass bond point cells 402 and 405 and 50 powder electroluminescent tracks Impedance 408 attached electroluminescent 505 attached. The electroluminescent substance Cell 403 is obtained, however, is now a positive one, e.g. B. made with copper and because the adjustable impedance 404 that is in series with aluminum activated zinc sulphide. The lanes 505 of cell 403 is connected to another terminal are on top with a thin layer 513 the main voltage source 401 is connected as 55 made of white reflective material, e.g. B. titanium oxide the one with which the parallel connection of the two in glass powder, covered. Extends over this layer Branches with cells 402 and 405 immediately form an opaque metal layer 514. The is bound. Space between lanes 503 and 505 is with

When discussing the circuit diagrams according to Fig. 1.4 a preferably opaque insulating material and 5 was always from electroluminescent cells 60 515, e.g. B. sintered black glass, filled,
the speech. Other radiation elements can also be used. There are two adjacent layers above a layer mapped by the paths 503 and 505 with the supplied electrical energy and the insulating material 515 applied between them. B. incandescent lamps, gas discharges mutually lying tracks 503 and 505 bridging and field quenching cells. In the case of 65 parts 516 of an originally closed current cell which has field extinction, increasing voltage has increasing on the element diffusing layer. The parts 516 consist of increasing the luminance, so that if a conductive cadmium sulphide (e.g. only with chlorine actisolche cell for the feedback or the fourth cadmium sulphide) in glass powder. This layer

11 12

is sintered. The layer contains about 30 volume - other terminal conductive with the through-connected

percent glass and about 70 percent by volume conductive electrode lines 512 on the carrier 500 connected

Cadmium sulphide. On the parts 516 which is just on. The through-connected electrodes 511 are with

The indicated conductive layer is located near the same terminal of the main voltage source 501

Truncated pyramids 517 made of glass connected with aluminum oxide 5, with which the electrodes 512 are connected

as a filler. The sheet-like parts 516 and are, but with the interposition of an adjustable

Truncated pyramids 517 are obtained in that auxiliary voltage source 504 ble.

over the layer consisting of lanes 503 and 505 of the solid-state image intensifier described

with the intermediate insulating parts 515 consists essentially of an identical structure

first a layer of conductive cadmium sulphide, io element groups, each with a photoconductive element and

Glass powder and a binder with a starch have two electroluminescent elements that

of about fifty microns and then according to the circuit diagram of FIG. 1 are switched in

a layer of glass powder with aluminum oxide and the sense that the adjustable impedance 4 this

a binder is attached. The circuit diagram is then generated by the auxiliary voltage source 504

in the two layers in the direction of the elec- tric and the auxiliary voltage source for

Troden 511 and 512 parallel and equidistant grooves are common to all element groups.

518 provided. These grooves are V-shaped, the photoconductor 2 from FIG. 2 in one element the walls will enclose an angle of about 60 °. group of the solid image intensifier according to FIGS. 6 The depth of these grooves is such that they are essentially formed through the part of the photoconductive layer 502 up to the layer with the electroluminescent ao, which extend over the sides and the tip of the strips 503 and 505 . The bottom of a truncated pyramid 517 extends. The on top of these grooves is at the point of insulation. optically fed back electroluminescent cell 3 515 between a luminescent path 503 and according to FIG. 1 corresponds to the part of the path 503, that of a luminescent path 505, while further that is located under the planar part 516 on which the mutual spacing of these grooves is such that 25 relevant truncated pyramids rests. The between two successive grooves of each output cell 5 of the circuit diagram according to FIG. 1 along with a track 503 and a track 505. speaks to one under the pyramid in question

A second set of parallel and equidistant grooves butt 517 located part of the electroluminescent

519 (FIG. 7) is now to be rendered path 505 in the direction perpendicular. Only the elements of the paths 503 of those of the grooves 518 are provided. These also 30 are optically coupled with the overlying parts of the V-shaped grooves are coupled to such a depth of photoconductive layer 502 that arranges the elements that they are at the bottom which originally extends over paths 505 in the direction of the overlying entire length of the Visually cut through traces 505 of extending parts of the photoconductive layer 502 by tending coverings 514 . With this and by the reflective layers 513 and the metal, the incision of the grooves 518 in the original layers 514 is shielded. The measure of the feedback-closed layer 516 , the tracks 503 and development between the elements of the tracks 503 and 505 are divided into a pair of related elements each, the electrically assigned parts of the photo-divided, which is located under a truncated pyramid 517 conductive layer 502 for all element groups and which have a common electrode on the top in the form of a sheet-like 40 to set by selecting the voltage of the source 504. By increasing the amount of the element 516 of the originally closed feedback, ie, increasing the voltage provided by the source layer over the traces 503 and 505 at 504 when it extended at least in the intermediate insulation 515 . Through the phase or in the phase with the tension sintering of the structure, the pyramids are now the main voltage source 501 , stumps 517 can be achieved to solidify and with the underlying layers that the reinforcement increases and finally the layers lying below are united. Instability occurs, which can be used to

The walls of the grooves 518 and 519 are to be held in place with a closed layer 502 of photoconductive material projected onto the photoconductive layer 502 , longer or shorter,
fabric covered. The layer 502 may e.g. The output conductive cadmium sulphide and a binding agent 50 supplied by the image intensifier is composed of both the elements of or of vapor-deposited photoconductive cadmium electroluminescent tracks 505 and sulphide. Each current diffusing part 516 forms those of the paths 503 emitted light. forms a more or less conductive connection. In the case described, this light is of different color for the paths between the layer 502 at the bottom of a groove 518. At and 519 and the EIe covered by this part change the value of the pathways 503 and 505 gementen by the source 504. The photoconductive voltage supplied is usually a change is a change on the top of the truncated pyramid in the ratio of the luminance of the layer 502 by the 517 in contact with an electrode which is formed by an equal part of the photoconductive layer 502 conductive tin oxide layer 520 on the underside of a th element of the tracks 503 and 505, thin flexible glass sheet 521 , the 60 whereby color changes of the output light are noticeable on the tips the layer 502 is laid and can be borrowed thereon. The latter can thereby be kept depressed. Instead of a glass film with the fact that under the electrode lines 5ll a conductive surface layer, a metal, an opaque layer is arranged, for. B. wire mesh as a power supply electrode for the black glass, so that only the elements of the tips of the photoconductive layer 502 are used 65 tracks 505 make the enhanced image visible. Of course, for the electroluminescent

The electrode 520 is connected to the one terminal of an ornamental track 505 and 503 with the same electrical

AC main voltage source 501 connected, choose their luminescent material, provided that

the photoconductive layer 502 is sensitive to the luminescent light of this material. When using different electroluminescent materials for the feedback light and the output light, a simplification of the shielding measures can be obtained in that the electroluminescent tracks 503 and 511 are formed identically, namely by the fact that they are made of two by a thin opaque layer, for. B. a layer of black glass enamel, separate layers of which the one on the side of the pyramids 517 is suitable for the optical feedback and that on the side of the support plate 500 provides the output light. It is even easier to also fill the spaces 515 between the tracks 503 and 505 so that an electroluminescent layer consisting of two optically shielded parts with different material extends over the entire glass plate 500 with the electrodes 511 and 512, the upper part z. B. can consist of red-luminescent material and the lower part of yellow-green-luminescent material.

Instead of an auxiliary voltage source 504 , a voltage divider bridging the voltage source 501 , in which the adjustable contact is connected to the electrodes 511 of all feedback electroluminescent elements 503 , can be used. It is also possible to replace the auxiliary voltage source 504 with a controllable impedance common to all elements 503; However, this can be less favorable because the energy consumption of one feedback element then influences that of another feedback element.

Claims (9)

Patent claims: 1. Optoelectronic circuit for converting optical input signals into optical output signals with optical feedback, consisting of three branches connected to a common star point and fed by a main voltage source, namely an input branch with a photoconductor and a feedback branch optically coupled to the photoconductor and one optically from the photoconductor shielded output branch, each with an electrical light source, characterized in that an adjustable impedance (4) connected in series with the electrical light source (3) and / or an electrical auxiliary voltage source (51, 71, 504) is arranged in the feedback branch, the voltage of which is not influenced the voltage of the main voltage source (1, 11, 39, 401, 501) is adjustable. 2. Optoelectronic circuit according to claim 1, characterized in that the feedback branch and the output branch are electrically connected in parallel as seen from the main voltage source (1). 3. Optoelectronic circuit according to claim 2, characterized in that of the Main voltage source (1) seen from the electrical input branch with the parallel connection of the feedback branch and output branch is connected in series. 4. Optoelectronic circuit according to claim 1, characterized in that the feedback branch is connected on the one hand to the star point and on the other hand to an adjustable contact (107) of a voltage divider bridging the main voltage source (1, 100). 5. Optoelectronic circuit according to claim I, in which in the feedback branch in series with the The first electrical light source recorded in this branch has a controllable impedance is switched, characterized in that this controllable impedance (4) consists of a second photoconductor exists whose impedance is controlled by external, i. H. not in the star connection included means, is adjustable. 6. Optoelectronic circuit according to one or more of the preceding claims, characterized in that the spectral emission curve of the electric light source (3) im Feedback branch has a maximum at a wavelength that is in the photoconductor (2) Input branch a penetration depth less than 5 μπι has. 7. Solid image intensifier which is constructed from identical optoelectronic circuits according to one or more of the preceding claims, which are assembled to form a substantially two-dimensional body, characterized in that the power supply electrodes (21, 22, 23, 24, 26, 27, 29, 30 ; 40, 41, 45, 47, 48, 49, 61, 67, 68, 69) of the corresponding branches of these circuits are mutually through-connected and the through-connected feedback electrical light sources (13, 15, 43, 45, 63, 65) with a common adjustable auxiliary voltage source (51, 71), a voltage divider (101) or an impedance (4) are connected. 8. Solid image intensifier according to claim 7, characterized in that parts of a photoconductive layer (502) extending over truncated pyramids (517) of sintered glass with aluminum oxide correspond to parts of two parallel luminescent tracks (505, 503) in the support layer for these truncated pyramids (517) , the radiation of one luminescent web (503) being able to react back to the controlling photoconductive parts (502) and the other luminescent web (505) being optically shielded by the photoconductive layer (502). 9. Solid image intensifier according to claim 7 or 8, characterized in that the photoconductors (502) control parts of an electroluminescent layer (503, 505) which consist of two parallel sub-layers mutually separated by an optical shielding layer (513, 513), one of which (503) faces the photoconductors (502) and is optically coupled to them and the other (505) is intended to make the intensified image visible. 1 sheet of drawings