DE2742555A1 - Image reproducing device with flat electron gun - has electron extracting electrodes, electron beam deflection system and imaging screen - Google Patents

Abstract

The electron beam extracted by the electrodes from the electron gun is deflected by a control device. The deflected electron beam energises light emission on the image screen of the device. The electron beam deflection system contains electrode groups. The control unit consists of an insulating substrate with a number of bores and beam controlling electrodes on the wall surfaces of the bores. The insulating substrate is typically a silicon semiconductive material. Alternately it can be formed by photo sensitive crystallised glass. The deflection system is formed in a similar manner and from similar materials. Alternately the beam deflection can be provided by tensioned conductive wires or strip.

Description

Image display device

Summary of the Disclosure The present invention relates to an image display device having a control electrode which emits an electron beam from a flat electron source and a display panel that emits light emits according to the impinging electron beam. The image display device Assigns as a control to deflect the electron beam before hitting the display panel achieved a number of through holes in strip shape in an insulating Substrate on whose inner surfaces the electron beam controlling electrodes are trained.

The present invention relates to an image display device, in which the electron beam emerging from an essentially flat electron source before hitting the Fluorescent surface where the image is created, is controlled and accelerated by control electrodes.

Up to now, flat picture display devices have been constructed as a liatrix developed in which the electroluminescence, plasmon, liquid crystals and the like were exploited.

With these arrangements it was not yet possible to achieve a sufficient Brightness, emission efficiency and color reproduction and the like to achieve and the playback of, for example, FS images with them is from it is still a long way from practical application.

On the other hand, attempts have also been made to use a flat picture display device using an electron beam.

Fig. 1 shows the structure of the essential part of an exemplary one Display device of known type. In this sketch, the reference number denotes 1 a flat plate-shaped electron source, for which, for example, Iieizkathoden, Have field discharge cold cathodes or the like used. The reference number 2 denotes a grid-shaped electrode plate having a large number of through holes 6, at which there is a positive potential compared to the flat metal electron source 1, to attract the electron beam. Part of the electron beam passes through the holes 6 and reaches a surface of a first control electrode plate 3. In the first control electrode plate 3 and a second control electrode plate 4th for the electron beam there are a large number of holes oa, 6b, the are provided in a regular longitudinal and transverse arrangement. On every row and each column are long strip-shaped electrodes 7, 8 arranged so that they cross each other at a suitable distance; the holes 6s, 6b are in the two electrodes at these interfaces and are aligned with each other. If it reaches the surface of the first beam control plate 3, the electron beam modulated in its current intensity according to the voltage applied to each electrode 7, while passing through the hole 6a, and then reaches the surface of the second jet control plate 4.

In the second beam control plate 4, the electron beam is at Passing through the hole 6b modulated in a similar way as by the control plate 3.

The electron beam that has passed through the hole 6b is from a Accelerating electrode 5 accelerates, to which there is a high voltage, and hits then onto a phosphor layer 9 on the surface of this accelerating electrode 5 so that it emits light. Since the brightness of the emission is proportional to the Electron beam current is on each picture element, an image can be made accordingly the signal voltage applied to the control electrodes on control plates 3 and 4 produce. Serves as the substrate 5 on which the acceleration electrode is located a transparent insulating substrate, for example Glass, a transparent electrode is arranged on its surface; of the same can the metal back system is applied like that of an ordinary cathode ray tube be.

In general, it is determined in display systems of this type which represent a kind of matrix, the resolution of the image from the size and division the through-holes in the electrodes for controlling the electron flow or their substrate.

Consequently, the higher the desired image resolution and the clearer it must the reproduced image, the smaller the area of the respective hole and the hole division can also be made.

To get a clear picture on a screen of finite size, the holes 6a, 6b and the electrode group 7, 8 must be arranged very close to each other so that the number of holes and the number of electrodes can be very high got to. For example, if you want to reproduce an FS image, a minimum of 500 x 500 holes are required and 500 electrodes are required for each electrode plate. Should be a parabola reproduction three times as many holes and electrodes have to be provided.

The number of electrodes that can be made possible depends on the currently available materials and manufacturing processes and is on 2 to 3 limited per millimeter, so that the required resolution cannot be achieved leaves. As the number of holes and electrodes increases, so does the number of Control circuits and the connections between the control circuits and the respective electrodes increase considerably, so that the problem of assembly required in practice and susceptibility to failure. These individual problems however, are only a few of many.

It is the first object of the present invention to achieve the above To solve problems with an image display device with which an image is displayed an optical disc with high resolution and clarity.

The second object of the present invention is to provide an image reproducing apparatus indicate the number of holes in the control electrodes and those of the electrodes can even be reduced significantly while maintaining the resolution.

These objects of the present invention can be achieved by an image reproducing apparatus achieve in which the deflection electrodes for deflecting the controlled electron beam are arranged on an electron beam control plate in such a way that they control the electron beam either vertically or horizontally or in both directions so that the Image is generated on the image display panel with a fluorescent coating is provided.

Other aspects, features, and advantages of this invention are intended will be described in detail below with reference to the accompanying drawings.

Fig. 1 is a diagram showing the construction of a conventional arrangement; Fig. 2 shows in a perspective view a disassembled image display device as an embodiment of the present invention; Fig. 3 shows as a perspective view and in section, an electron beam control electrode plate of Fig. 2; Fig. 4 Fig. 13 is a perspective sectional view of the electron beam control electrode plate of Fig. 2; Fig. 5 shows in perspective the parts of the image display device according to a further embodiment of the present invention; Fig. 6 shows a Block diagram of the picture display circuit for displaying FS pictures; Fig. 7 Fig. 6 shows timing and waveform diagrams for the circuit of Fig. 6; and Fig. 8 shows a diagram of a vertical deflection voltage.

Fig. 2 shows an embodiment of the image playback device according to the present invention.

Numeral 10 denotes a plane flat electron source. It can be a flat hot cathode or a field discharge cold cathode Act. For reasons of economy and reliability, however, a pseudo flat cathode is used sn, which from a large number of spanned parallel to each other at suitable intervals Tungsten wires are made of which are coated with an electron-emitting oxide material are. The reference numeral 11 denotes an anode substrate, which is on a certain Part of itself carries a grid electrode 16. To the grid electrode 16 is a positive voltage applied to the cathode, so that an electron beam with almost uniform current density can be extracted from the flat electron source 10 can. In order to increase the Strehlstrom strength, the grid electrode 16 should be the largest possible have effective area. In the grid electrode 16 holes are provided where them with the through holes of a first electron beam control electrode plate 12 align.

This grid electrode 16 can be made from a sheet of grid electrode material exist. However, in order to obtain the required electron beam density, a positive acceleration voltage of several tens of volts is applied across from the cathode will.

There is an acceleration voltage of several tens of volts on the grid electrode overall, there is not only a power consumption of tens of watts; simultaneously the electrode heats up to red heat due to the continuous flow of current.

To overcome these difficulties, the grid electrode becomes too a multitude of long strip grid electrodes to which the voltage is distributed is placed one after the other.

A sectional perspective view of the first electron beam control electrode plate 12 or the second electron beam control electrode plate 14 is shown in FIG. Through holes 22 are provided at certain intervals in the insulating substrate, the electrodes 17 are arranged on the inner wall surfaces, each of which is connected to a associated control circuit are connected. The individual electrodes are against each other isolated. The electrode can be deposited by vapor deposition, sputtering, not galvanically (non-electric field plating ") or in some other way. A Plate made of ordinary glass, ceramic, semiconductor material and the like into the the through holes can be introduced, for example, by photoetching. When the elongated holes were made by photo-etching, a strong one resulted Fluctuation in the slot width and, as a result, bright points and color shifts especially when used as an FS picture display device, which also uses intermediate tones must be reproduced. In order to overcome these difficulties, photosensitive materials have been made crystallized glass is used, as it is known under the trade name "Photoceram" is. If such glass is heat-treated after exposure to UV rays, it crystallizes the UV-exposed parts, so that the elongated holes by taking advantage of the different Establish etching speed between these and the non-crystallized parts can. In this way, precise through holes can be made regardless of the thickness of the substrate. Furthermore, this method is particularly effective in Formation of through holes in Step shape to a sufficient Ensure mechanical strength & u, as well as during the manufacture of the electron beam deflection electrode 13. The reason for this is that, due to the high accuracy of the shaping, the parallelism between the deflection electrode pairs is very good, so that the electron beam with is deflected at an even angle. This property can be traced back to usual Wise, photo-etched glass plates can only be achieved with difficulty. If you use If a silicon semiconductor material is used as the insulating substrate, the substrate surface is oxidized for example thermally and then forms the electrodes on the insulating silicon oxide layer the end.

The electrodes of the electron beam control electrode plates mentioned above 12, 14 are each connected to a control circuit for controlling the electron beam connected. This control circuit and others needed to be described later Circuits can take the form of integrated circuits in the insulating substrate Control electrode are integrated, for which a semiconductor substrate is used. The individual electrodes of the pair of electron beam control electrode plates are arranged crossing each other.

Between the two electrode plates 12, 14 is the electron beam deflection electrode plate 13 provided. A cut perspective view of the electron beam control electrode plate 13 is shown in FIG. In an Isoliersubatrat elongated holes 23 are in certain Arranged at intervals. The distances are between the elongated holes coordinated with the elongated holes in the electron beam control electrode plate.

On the inner wall surface of the elongated holes 23 are the electrodes 18a, 18b arranged for deflecting the electron beam by an electric field. the Electrodes 1ba, 18b are alternately connected in a comb arrangement and form a pair of deflection electrodes with each other.

In the embodiment explained above, as described, the electrode is formed in the through holes in the insulating substrate. she can but can also be constructed from stretched metal wires or metal strips.

An image display panel 15 can be made by making the necessary Conductivity according to the so-called "metal back formula" C'metal back formula ') provides, after which a phosphor layer 20 on a transparent substrate - for example Glass and on its surface a conductive layer, for example made of vapor-deposited Aluminum is applied.

Likewise, you can put a transparent conductive film on top of it Glue on the glass substrate and then apply a layer of fluorescent material to its surface.

The phosphor layer can be designed into a color display panel, by periodically applying phosphors in successive strips which Emit red, green and blue light.

The functional principle is described below.

The electrons emerging from the flat electron source 10 become accelerated by the electrode 16 acting as an anode.

The electron beam passing through the grid electrode almost occurs at right angles in the first electron beam control electrode plate 12 a. To everyone Electrode 17 of the first electron beam control plate 12 is a plate cathode negative voltage applied. As a result, the incident electron beam flows into the Electrode 16 and cannot use the through holes 22 of this control electrode plate penetrate. In this way the so-called blocked state is created.

If now to the m-th electrode, i.e. one of the electrodes 17, the voltage Zero or a positive voltage is placed, the electrons can go through just this Pass the elongated hole of the m-th electrode, so that a strip-shaped electron beam results, the width of which corresponds to that of the through hole. This strip-shaped profiled electron beam occurs between the m-th pair of electrodes of the deflection electrode plate 13 corresponding to the above-mentioned m-th electrode. Depending on whether that the voltage between the electrodes 18a, 18b of this pair of electrodes is zero, is positive or negative (assuming either 18a or 18b is positive is), the electron beam exits as 21a or 21b or 21c. So it appears one of these three luminous lines on the screen 15. The angle of deflection of the electron beam naturally changes with the Changes in potential between the Deflection electrodes of the pairs; For this reason, as can be seen in Fig. 2, create a multitude of luminous lines in different levels on the screen, and by continuously changing this potential difference, one obtains the screen also has image lines with continuously changing luminance.

The preceding description concerns a situation in which none second electron beam control electrode plate 14 is present or if they is present, a free passage of the electron beam is allowed everywhere. Hereinafter is therefore intended to have the effect of applying a signal voltage to the electrode plate 14 will be described. This control electrode plate 14 has a similar function like the first electron beam control electrode plate 12. If you look at the second Control electrode plate 14 applies a more negative voltage than to the flat cathode 10, the electron beam incident through the deflection electrode plate 13 can not pass through the respective through hole in the control electrode plate 14. If one applies the voltage iiull or to the nth electrode of the control electrode plate a positive voltage, the electron beam reaches the surface of the screen 15 by passing through only the through hole on the nth electrode, one of the electrodes the control electrode plate. If the voltage is zero or a positive voltage is applied to several electrodes 17, is obtained on the Screen a multitude of bright points. Because the through holes in the electrode plate 14th to those in the control electrode plate 12 and the deflection electrode plate 13 are transverse, the electron beams 21a deflected by the deflection electrode plate 13, 21b, 21c reach the screen through the through hole. For this The reason for the through hole is not, as usual, circular, but oval or strip-shaped educated.

The same principle can be used to achieve a similar effect, by placing another deflection electrode plate between the second electron beam control electrode plate 14 and the screen 15 inserts. By continuing to sandwich both deflection electrode plates exploited, the electron beam can be deflected two-dimensionally, i.e. horizontally as well as vertically, as can be derived directly from this principle.

Fig. 5 shows a further embodiment of the present invention, in which such an additional deflection electrode plate is provided; mark here the same reference numerals the same elements as in FIGS. 1 and 2. In the picture display device According to FIG. 5, the first and second 8 control electrode plates, which 1, between the grid electrode plate 2 and a first deflection electrode plate 13 arranged, which deflects the electron beam vertically. It is still one second Äblenkelectrode 30 provided that the electron beam horizontally accordingly one deflection voltage applied between the electrodes 31a, 31b deflects, which are formed like the electrodes 18a, 18b. In this embodiment the electrode beam emerging from the control electrode 3 is not only vertical, but also deflected horizontally.

The picture display device according to the present invention has best effect when used to display an FS picture. Hereinafter this arrangement shall therefore be explained in the application as an FS picture display device will.

The concept of driving this embodiment for reproduction of television pictures is shown in FIG. This arrangement itself has the in 5 with 250 vertical and 250 horizontal control electrodes. In This device uses the single line scanning system with simultaneous display, as is commonly used in matrix displays. Furthermore are coordinates with the first and second electron beam control electrode plates 4 and 3, first and second deflection electrodes 13 and 30, respectively, are provided. Both Electrodes are constructed as shown in FIG. 4, with the Vedikai and horizontal deflection takes place with deflection voltages, which via the electrode pairs 18a, 18b and 31a, 31b be placed.

As shown in Fig. 6, a BAS signal is applied to the synchronous separation circuit 51 given, which separates the video from the Syrichron signal, which is then fed into the control signal conditioning circuit 52 and the video signal conditioning circuit 53 go. In the video signal conditioning circuit 53 is derived from the control signal latch 52 with the aid of the sampling pulses Sync signals are the video signal for one line to a series of 750 signals which are saved: -End of a line period are the 1st, 3rd, 7th, ... and 748.

Signal in an analog tape recorder 54a, the 2nd, 5th, 8th, ... and 749th signal in an analog memory 54b and the 3rd, 6th, 9th ...

750th signal stored in an analog memory 54c. In this way the signal is converted to a series of parallel signals. With the analog memories 54a, 54b, 54c can be capacitor storage or charge transfer arrangements (CCD, BBD) or the like act, the 250 outputs of which to a switching arrangement 55 lead.

In the control signal circuit 52, the line sync signal with a period of 63 / U5 (see Fig. 7a) a pulse signal with a third derived from the line period (21 / us) by means of a phase control (PLL) circuit, the same (See. C in the same figure) the line control signals C1, C2 and C3 with a Pulse width of 21 / U5 that occur in different places and the line period thirds. From the image signals present in the respective memories, the Output signal of the memory 54a in the switching arrangement 55 with the line control signal C1, the output signal of the memory 54b with the control signal C2 and the output signal of the memory 54c is switched to the control signal C3, namely to a line drive circuit 56, in which these signals are amplified and then parallel to the 250 horizontal electron beam control electrodes are given.

On the other hand, the line control signal C from the circuit 52 goes into FIG a Yeilenablenkaltung 57, where from the signals Ci, C2 and C3 the deflection voltages with the three levels V, 0 and -V are generated by using these line control signals selects one of three voltage sources (including one with zero volts). the Deflection voltage (d) is applied to each of the 250 electrode pairs of the second at the same time Deflection electrode plate 30.

As a result, for example, the electron beam becomes within the first 21 µs to the left (looking at the front face of the screen), in the second 21 / us deflected with a deflection angle of Oo and in the third 21 / µs to the right. The time sequence of these deflection movements is with the switching function the switching arrangement 55 synchronized. So the signal goes into the first 21 / U5 from the memory 54a to the control electrodes 3 and in the other time periods the signals from the memories 54b and 54c, the one passing through the electrodes 3 Beam is modulated by the applied signal levels, so that an image is reproduced results on the screen.

The image deflection is described below. A vertical control circuit 60 of this picture display device consists of a shift register from which the Vertical scanning pulse, the the line selection at the rate of the line period in the vertical transition from line to line from which Line sync signal of the circuit 52 or a line synchronous with this line signal Signal is derived. The vertical scanning pulse goes to one of the electrodes 8 of the first control electrode plate 4 (for example Fig. 5) so that the line arriving beam can pass during a horizontal scanning period.

On the other hand, when the first deflection electrode 13 of FIG in the first time segment of about 16.6 ms with a positive level + V and in the next 16.6 ms with a negative level -V, as in Fig. 8, is obtained a 2: 1 comb. The deflection voltages are generated by using different Voltage sources in the vertical deflection circuit 58 by means of two-valued signals which synchronizes with the vertical sync signals generated by the circuit 52 and have different levels in the first and second half fields. By means of this The electron beam can be deflected vertically, for example in the first field deflect upwards and downwards in the second field.

This description shows that when using 250 x 250 control electrodes and the electron beam as well as 2 deflecting elements with 500 x 750 picture elements can get. Compared to an ordinary matrix display that has is not provided with two deflection electrode plates, one obtains 8o the double resolution in the vertical and triple resolution in the horizontal. It also allows reducing the number of electrodes to 1/6 for the same Resolution a considerably simpler manufacture of the electrode plates, simplified Control circuits and the corresponding cost reduction and thus a simpler one lViontage and lower error rate.

In the picture display device of FIG. 6, with the aim of producing a to achieve high resolution in black / white I) arenation, the image signal for a horizontal line divided into thirds and the signal for each third line given one after the other to the second control electrode. The same procedure lets can also be used for color reproduction. In this case - compare Fig. 6 - the demodulated red, blue and green signals are stored in the three analog memories 54a, 54b, 54c are stored and the luminous area that is generated by the second deflection electrode picks up deflected rays during each line duration, with red, blue and green fluorescent material coated.

The previous example was where vertical scanning was concerned and vertical deflection, the vertical deflection in two steps (up- and down) to enable field interleaving. It can be however, you can also perform a deflection in three or more steps as required.

According to one of these methods, the first electron beam control electrodes, which cause the line selection, signal voltages in several horizontal scanning periods - for example four - and deflection voltages in on the vertical deflection electrodes several - for example four - voltage levels in synchronism with the vertical scanning signals given. By doing these functions sequentially with the vertical electron beam control electrodes and the deflection electrodes, you can build up a field. This scanning method is particularly effective where the display device has a small screen area and therefore requires high resolution.

Another method is to apply a set of electron beam control electrodes a sawtooth, not a stepped, deflection voltage in a multitude of horizontal sampling periods - for example four - applied; after that the following vertical electron beam control electrodes are treated accordingly. After this process, the entire screen surface is covered, so that the image reproduction can be done with a smaller number of lines than one would expect from the screen size would. For example, in the case of a large display panel with meter dimensions achieve a uniform image reproduction without noticeable individual image lines.

As can be seen from the above description, the image reproducing apparatus according to the present invention a high density and high resolution on the screen, a significant one Reduction in the number of electrodes in comparison to conventional arrangements and thus simplified control circuits, lower Costs, easier assembly and low error rate due to the lower Number of connections too.

L e r s e i t e

Claims (12)

Claims 1. Image display device, P: e characterized by a substantially planar electron source, an electrode array Pulling electrons out of the electron source, an electron beam control arrangement, to control the selective passage of the electron beams thus drawn out, and by a light device which, when excited by the electron beams, generates light emits, wherein a device deflecting the electron beams is provided, contains groups of electrodes that deflect the electron beams before they reach the Reach viewing facility. 2. Image display device according to claim 1, characterized in that that the electron beam controlling device consists of an insulating Substrate with a plurality of through holes as well as the electron beams controlling electrodes on the sand surfaces of the elongated through holes. 3. Image display device according to claim 2, characterized in that that the insulating substrate is a Silicon semiconductor substrate acts. 4. image display device according to claim 2, characterized in that that the insulating substrate is photosensitive crystallized glass acts. 5. Image display device according to claim 1, characterized in that that the electron beam deflecting devices each consist of an insulating substrate with a plurality of through holes and pairs of deflecting the electron beams Electrodes exist on the inner wall surfaces of the through elongated holes. 6. bilawager according to claim 5, characterized in that that the insulating substrate is a silicon semiconductor substrate. 7. BildwieaergabevoLrrichtung according to claim 5, characterized in that that the insulating substrate is made of a photosensitive crystallized glass. 8. Image display device according to claim 1, characterized in that that the electron beam deflecting device each stretched out conductive wires or strips. 9. Image display device, characterized by an essentially flat electron source, an electrode device that collects electrons from the Electron source pulls out, a device that controls the electron beams causes a selective passage of the electron beams so drawn out, and a light equipment which, when excited by the electron beams, emits light, whereby the electron beam deflecting device, electrode groups for deflecting of the electron beams before they reach the viewing arrangement, as well as a control device has, the electron beams by applying a deflection voltage with several bricks or in a sawtooth shape to each of the deflecting electron beams Distracts facilities. 10. Image display device, characterized by an essentially planar electron source, an electrode arrangement to collect electrons from the electron source to pull out an electron beam controlling device, one optional Causes the electron beams so drawn out, a deflection device, that of the electron beams corresponding to the device controlling the electron beams deflects, a Uichteinrichtung that, when excited by the electron beams, light emits a control device, the deflection voltages stepped to the deflection device in m steps (m = whole number> 2) which is synchronized with the line scan are, through an institution, the image signals for a single line period converts to (m x n) image signal groups (n> 1 and integer), m storage devices, each of the (m1 - m + 1) th, Cml - m + 2) th, ... and the m1 th signal (0 integer 1, 2, ..., n) of the m signal groups converted in this way, as well as through a control device which individually sends the signals from the memory arrangement accordingly represents the levels of the deflection voltages mentioned above. 11. Image display device according to claim 10, characterized in that that m = 3 and the image signals are divided into red, blue and green color signals which are stored in three memory arrays. 12. Image display device, characterized by an essentially plane electron source, an electrode arrangement to collect electrons from the electron source to move out, a device controlling the electron beams, which the elections The passage of the electron beams drawn out in this way causes first deflection electrodes to deflect the electron beams in the horizontal direction according to the Electron beam controlling device, second deflection electrodes for beam deflection vertically, a control device attached to the first deflection electrodes in the line scanning periods, first stepped deflection voltages applied between the three stages are switched, and second stepped deflection voltages between the levels be switched at each vertical deflection to the second deflection electrode places, through three different memory arrays, the store the image signals divided into red, blue and green signals by a Means to keep the output signals from the memory array in synchronism with the stages to read out the first deflection voltages and the strength of the electron beams by means of to control these signals, and by one with red, blue and green phosphors coated viewing assembly that associates light in each of the voltage levels Time segment of the first deflection voltage according to the strength of the controlled Emit electron beams.