NO128666B - - Google Patents

Description

Rendering grids for transforming electrical signals into a radiation pattern.

The present invention relates to a rendering grid for transforming electrical signals into a radiation pattern and comprising a support body which is provided with voltage-dependent photo-emitting and photo-conductive elements which are united in a planar pattern and provided with electrodes, which photo-emitting elements contain a substance which, under the effect of an imprinted voltage lights up or goes out, and where the photoconductive elements are assigned to the photoemitting elements in such a way that the radiation produced by the photoemitting elements only hits the photoconductive elements to a limited extent, which grid is supplied with a signal via at least one delay circuit with an outlet.

Such rasters are used, among other things, in the reproduction of television images, where the television signal, after detection as a video signal, is added to the reproduction raster.

With the previously known grids of this kind, it is common to arrange two groups of wires in the grid, one below and one above the aforementioned material that lights up or goes out, as the different control voltages e.g. the video signal, must be supplied to the two groups of wires. This requires a bulky and expensive coupling device.

The rendering grid according to the invention avoids these disadvantages in that two coherent photo-emitting and photo-conducting elements are connected in series, that

the delay circuit is arranged directly on or next to these series connections, as

an outlet from the delay circuit is connected directly to one end of each of the series connections, and that the photoconductive elements are placed on the grid in such a way that they can be irradiated from a special radiation source that changes their conductivity, and which is disconnected for a short time, when the signal, after a time determined by the delay circuit, has distributed along the outlets.

Some practical examples of a rendering grid and a device according to the invention will be explained in more detail with reference to the drawing. Fig. 1 shows a ground plan of a rendering grid for television format. Fig. 2a shows the grid in perspective. Fig. 2b shows a section through part of

the grid in fig. 2a.

Fig. 2c shows a modified device

of the individual parts.

Fig. 3 shows an equivalent diagram for

the grid in fig. 1.

Fig. 4 shows a diagram.

Fig. 5 shows a grid applied to another

way for television.

Fig. 1 shows the rendering raster 3 with scanning device. Here .... an denotes the scanning system, 4 the video signal source, 2 a transparent electrode, z, the terminating impedance and the connections 13, 13'... the non-delayed mutual connections between the systems a,... an.

Fig. 2a shows the same rendering grid in perspective, where the position is rotated 90° in relation to fig. 1. From fig. 1 shows that each system a consists of a delay circuit 10, islands 9 of electrically conductive material, e.g. metal islands, a photoconductive strip 8, e.g. of activated CdS, CdSe powder with a radiation-absorbing layer, e.g. a varnish on the underside, islands 7 of electrically conductive material, e.g. metal islands, a galvanically insulating strip 11, which is high-resistive and has a small capacity, and a strip 6 which contains material that lights up or goes out, and which, e.g. consists of chlorine, manganese-activated zinc sulphide powder ZnS (Cl, Mn).

A photoconductive material is understood to mean a material whose specific electrical impedance is reversibly changeable with the help of corpuscular or electromagnetic radiation.

Beneath this composite system there is a transparent electrode 2, which forms an image with the strips 6. The strips 11 serve to repel the strips 8, and the delay circuits 10 lying above them and also to prevent a direct galvanic connection between the delay circuits and the electrode 2 above the strips 8.

It is clear that many other configurations are possible.

Another solution consists, for example, of in that the strips 11 are looped, and the strips 6 are turned 90°. The strips 6 are then superimposed by the strips 8, so that they are sufficiently supported. The delay circuits 10 are similarly rotated 90° in relation to the position in fig. 2a, while the islands 7 and 9 must be arranged so that the strips 8 are not short-circuited. Optionally, both the strips 8 and the strips 6 can be united in layers which are arranged in mosaic form, in order to avoid possible electrical conductivity in the layers themselves.

A further solution is shown in fig. 2c, where the strips 11 are omitted, and the strips 8 are bent so that on one side they rest on the plate 5 and on the other side on the strips 6. The delay circuits 10 are placed on the sides of the strips 8 that rest on the plate 5 for islands 7 and 9 they correspond to those in fig. 2a and is indicated in fig. 2c. In order for the circuits 10 to have no connection with the electrode 2, this also has the form of a strip, and these strips are connected to each other in such a way that they can be perceived as a single transparent counter electrode. From the last example, it appears that the strips can lie geometrically in whole or in part in the same layer.

The above-mentioned construction is fixedly placed on a support body permeable to radiation, e.g. a glass plate

5 which carries the entire system. This plate

also enables the radiation produced by the strips 6 to be observed. When the strips 6 consist of a material which produces radiation after being irradiated by a special radiation source and is extinguished more or less as soon as a greater or lesser voltage is applied, the television signals must be supplied negatively to obtain a positive image.

It is also possible to reverse an image using an image intensifier (so-called amplifier), if the television signal is fed positively. In addition, the radiation produced is thereby additionally amplified. The latter also applies when a luminescent substance is used and the positive image is amplified by an image intensifier and not reversed.

Each system a needs a width d, as e.g. the delay circuit 10, the strip 11, the strip 6, the metal lenses 9 and 7 each have a width of y3 d, and the strip 8 a total width d. This is shown in fig. 2b. The mutual distance of the system a is kept as small as possible in order to achieve the greatest possible sharpness in the image to be reproduced.

Each delay circuit 10 is provided with a number of outlets which are connected over islands 9 with narrow cross strips of the strips 8. These strips are again connected over the islands 7 with narrow cross strips of the strips 6. The islands 7 and 9 thereby serve to provide a good contact between strips 10, 8 and 6, as they also serve as electron containers.

Does it become part of a cross strip of strip 8 that is not short-circuited by islands 7 and 9 (the

in fig. 2b with y3 d specified part of the strip 8, which part lies between 7 and 9) considered as a variable resistance and the corresponding parts of the strip 6 considered as capacitor, then at separate points with the same distance from each other, series connections can be considered of R and C between the delay circuit 10 and the transparent electrode 2. The number of these series connections in each

system is equal to the number of islands 7 and 9 between the delay circuit 10 and a strip 6. Moreover, this number of islands must be equal to the number of pixels per line in the image to be rendered. If there e.g. is 833 pixels per line, there must also be 833 islands 9 and 833 islands 7 per system a.

Based on the above description, one can set up the equivalent core in fig. 3 in that corresponding parts have the same designation as in fig. 2. The resistance value of the one in fig. 3 shown resistance 8, can be changed by irradiating the strips 8 from a radiation source, which radiation is indicated in fig. 2 using arrow 12. In this case, radiation can be understood as both visible light and invisible light (ultraviolet and/or infrared light), as well as corpuscular radiation and electromagnetic radiation.

If necessary, measures can be taken so that this slide cannot be observed on the underside of the glass plate, and the radiation produced by the elements in the strips 6 only penetrates to a limited extent through the strips 8 to prevent a back-effect. For that purpose, a layer can be placed on the underside of the strips 8 which absorbs the radiation. The radiation from the radiation source for the strips 8 can thereby also be made invisible to an observer. The photoconductive material can also be made sensitive only to radiation from the extra radiation source, so that the radiation produced by the elements in the strips 6 does not affect the photoconductive elements.

The delay circuit 10 can be designed in different ways. It can e.g. take the form of a wire which is wound in helical form on a core, and which, after the core has been etched away, can be placed on a material with a high E-value to achieve the required delay time per delay circuit time. If necessary, the whole can be rolled up in a helical shape or in a zigzag pattern, with sockets forming contact with the metal eyes 9 placed in the desired points on the delay circuit achieved in this way.

Another possibility is to use acoustic delay circuits. Electrical signals supplied to the delay circuits are converted into acoustic signals at the input and converted back into electrical signals at all outlets and outputs. This can e.g. happen with the help of piezo-electric or piezo-magnetic elements.

For the sake of simplicity, only a single device with an electrical delay circuit is described.

In the event that such delay circuits cannot be made transparent, the irradiation surface per strip 8 is limited to the surface between two delay circuits 10. The part acting as resistance is thereby limited to the non-shorting part of the narrow strips between islands 7 and 9 (see fig. 2b).

The operation of the scanning mechanism can be described with reference to fig. 1, fig. 2 and the equivalent diagram in fig. 3. The combined video signal is fed from the source 4 to the delay circuit 10 in the first row a, and runs through the sequence of delay circuits in the system a,, a,....aM and returns to the source 4 across the specific termination impedance Z,. This impedance Z serves to make the overall delay circuit according to fig. 2 as real as possible, so that reflection or absorption of the supplied signal is avoided in the delay circuit.

Does the system e.g. 625 lines and 25 images per second, then the line period becomes

625 x 25<«> 64 hiisek. For such a system must

625 systems a are placed there, and when the delay time per delay circuit 10 is

64 [xsec., has the overall video signal after

1/25 sec. distributed over the rendering grid 3.

At this moment, a flash of radiation is produced which hits the strips 8, so that

the resistance value of the photoconductive material decreases, which means that those in fig. 3 showed resistance 8 decreases significantly. The resistance of the material, when not irradiated, is greater than 10<8> ohm.cm. and with stronger irradiation less than IO<3> ohm.cm.

With this resistance change, the resistance pattern along the delay circuit 10 is ready to charge up the capacitors 6.

1 dependence on the voltage difference

which in this way occurs between the capacitors' electrodes, the electroluminescent material between the coatings is brought to light up. If a

height-width ratio of 4:3, there must be 4/3 x 625,833 pixels per line, which number corresponds to the supposed number of islands 7 and 9, so that the stripes 6 are likewise

divided into 833 pixels, so that these pixels light up in the above manner in dependence on the supplied video signal. During the information, a small current flows so that one can imagine a resistance parallel to the capacitor 6, through which the charge supplied by means of the delay circuit can flow away. This diversion must take a time of approx. 1/25 sec., when the next voltage pattern has spread over the grid, so that the capacitors are charged again at the next radiation flash.

Without radiation, the resistance 8 is relatively high, so that the capacitors 6 are hardly charged. The small voltage difference between the coatings (as a result of remaining parts of the previous charge and the small charge produced between the two flashes of radiation on the coatings) is not capable of providing electroluminescence, as a certain voltage difference (threshold value) is always required before the substance light up. This is shown in fig. 4, where luminous flux cp is plotted as a function of the applied voltage V. It follows that up to the threshold value V, practically no light is emitted. In the case shown where ZnS-pul-

is activated with Cl or Mn, a direct voltage can be used for V, but if a copper or manganese active

vator can only be used with alternating voltage

nothing. For television purposes, assets are therefore

tor that uses direct voltage the most desirable. Moreover, by placing the Mn, Cl activator, the diversion counter-

condition which is assumed parallel to conden-

sator 6 smaller, so that the derivation of the charge from 6 takes place with the

sheath speed.

During the discharge of the charge from the capacitor 6, light is emitted, so that the total light yield per pixel approx.

met is equal to the mean value of the time-varying luminous flux cp multiplied by the time between two light flashes.

Another method is possible by

that the 625 systems are divided into two groups, i.e.

in a group of different systems a,, a.,, etc. and a group of similar systems a„, a4 as in-

time of a delay circuit of the different group is connected to the output of the preceding delay circuit of this group, and in the same way the input and output

time of the delay circuit in the same group connected to each other, and so that the different and equal delay circuits formed in this way are terminated with their spe-

cific impedance.

The source 4, which supplies a video signal

which is assembled according to the staggered television system, is supplied to system a, in the first group, and after 1/50 sec. the system aP of the second group. The desired voltage pattern has after 1/50 sec. distributed over the group, after which a flash of radiation causes the associated pixels to light up. During the next 1/50 sec. for-

the voltage pattern is shared over the other group, and another radiation flash receives the pixels belonging to this group,

to light up.

It should be noted that the weakening of

the signal, after it has passed through a delay circuit, can be equalized, e.g. by placing amplifier stages in the inter-

its connections between delay circuits

tendon. Such small amplifier stages can, among other things, be realized with the help of transistors

rer.

Another precaution for equalization

of losses in the delay circuit consists in an-

bring a filter on the strips 8 in such a way that the strength of the radiation in the direction of in-

time until the output increases in a delay

circuit, so that the photoconductivity in this

direction increases, and despite the voltage loss in the delay circuit, the voltage transferred to the capacitor 6 is approximately proportional to the supplied video signal.

The sensitivity of a strip 8 can be changed

by changing the thickness of the strip, so that losses in the delay circuit can also be compensated in this way. If light output

tet is also then insufficient, can as above

as mentioned, the image is amplified using an image intensifier.

A third method of scanning is shown in fig.

5. Here corresponding parts have the same designation

nelse as in fig. 1, and each system a is successively connected during a single line period to the source 4 by means of a ven-

where 14. Information for the relevant system (e.g. system a/) is distributed there-

by during a single line period over the associated delay circuit 10, which is also terminated with its specific impe-

dance Z,. After a line period, i.e. in this case after 64 ^sec., a radiation flash is produced to cause the pixel belonging to the system a^ to light up.

Then the inverter 14 connects the source 4

with the system a^,, after which the operation is repeated.

Also in this case there can be on simple

way, line shuffling is introduced, as the turner 14 first scans the various systems a,, a.,....

and then the equal systems a.„ a,.... Self-

said must also here as in the other ex-

signal is applied to a video signal for line

ket scan according to the line shuffling principle

pet.

A spiral scanning mode is

also possible, as the composite lines are arranged spirally on the transparent

tige electrode 2. A simple system a can also be used, which is supplied to the entire remote

the visual signal, and which after each line period receives a radiation flash. The light produced in this way can be projected onto a screen line by line by means of a rotating lens or mirror system.

Claims (9)

1. Rendering grids for transforming electrical signals into a radiation pattern and comprising a carrier body which is pre- synthesized with voltage-dependent photo-emitting and photo-conducting elements which are united in a planar pattern and provided with electrodes, which photo-emitting elements contain a substance which lights up or extinguishes under the action of an applied voltage, and where the photo-conducting elements are assigned to the photo-emitting elements in such a way that the radiation produced from the photo-emitting elements only hits the photo-conducting elements to a limited extent, which grid is supplied with a signal via at least one delay circuit with an outlet, characterized in that two and two contiguous photo-emitting (6) and photo-conducting (8) elements are connected in series, that the delay circuit (10 ) is arranged directly on or next to these series connections, with an outlet from the delay circuit being connected directly to one end of each of the series connections, and that the photoconductive elements are placed on the grid in such a way that they can be irradiated from a separate radiation source (12) which changes their conductivity, and as copl es out for a short time, when the signal has spread along the outlets after a time determined by the delay circuit. 2. Rendering screens according to claim 1, where the support body consists of a plate that is permeable to radiation, e.g. a glass plate on which is placed at least one electrode that is permeable to radiation, characterized in that a first group of galvanically insulating strips is placed on the electrode permeable to radiation and that between the strips in the first group another group of strips with photo-emitting elements with a substance that lights up or goes out, as islands of electrically conductive material are arranged on the strips in the second group, and that there is a third group of strips that rests on a strip in the first group and a strip in the second group and which contains the elements with photoconductive material, as each strip on the underside is provided with a layer that absorbs radiation, and on the parts of the upper side that lie above the insulating strips are provided with islands of electrically conductive material, on which are arranged delay circuits with outlet for these islands. 3. Rendering screens according to claim 2, characterized in that the radiation-permeable electrodes are placed in places with the same mutual distance on a plate serving as a support body which is permeable to radiation, with a strip placed on each electrode of the third group and the strips of the third group rest, instead of on a strip of the first group, on the one side on the strips of the second group and on the other side on the carrier body, and the delay circuits are located on the side of the latter stripes where these are located on the carrier body. 4. Rendering grids according to claim 2, characterized in that the strips in the first group consist of high-resistance, low-capacitance material. 5. Rendering grids according to one of the preceding claims, characterized in that the said delay circuits are acoustic, and that the electrical signals are transformed by means of piezo elements in the input into acoustic signals which are transformed into electrical signals again in the outlets and the output. 6. Rendering grids according to claims 1-4, where a television signal in the form of an electrical signal is supplied to at least one delay circuit with proper adaptation, characterized in that the delay circuits are electrical circuits arranged on the rendering grid, whose delay time is equal to a single line period of the supplied television signal . 7. Rendering grids according to claim 6, characterized in that the input of a delay circuit is connected to the output of the preceding circuit, the television signal being supplied to a delay circuit which is formed in this way and which is terminated with its specific impedance, while the photoconductive stripes after one image period in during a short moment is irradiated with light. 8. Rendering rasters according to claim 6, characterized in that the delay circuits on the rendering raster are divided into two groups, the circuits in the second group being located between the circuits in the first group, and the input of a delay circuit in the first group is connected to the output of the preceding one delay circuit in the same group, and that the input and output of the delay circuits in the second group are connected to each other in the same way, and that the television signal composed according to the principle of jumbled lines is first supplied to the properly terminated delay circuit formed in this way in the first group and after half a picture period the correspondingly formed, properly terminated delay circuit in the other group, while after half a picture period the photoconductive elements are irradiated for a short moment from a radiation source. 9. Rendering grids according to claims 6-8, characterized in that the strips with the photoconductive elements are covered with a filter in such a way that in the direction from input to output in one of the delay circuits, the strength of the projected radiation will increase.