DE2217402C3 - Electron beam image display device for different frame rates - Google Patents

Description

The invention relates to an electron beam image reproducing apparatus having a receiving device for receiving a video signal of successive images and a cathode ray tube connected to the Receiving device is coupled to reproduce the images as a function of the video signal, the The fluorescent screen of the cathode ray tube is formed by several different fluorescent materials that have different afterglow times, which differ significantly from each other, the fluorescent material having a longer afterglow time is excited at a lower frame rate.

In general, considerably higher resolution is required when transmitting static images than when moving pictures, e.g. B. those of moving objects are transmitted. It depends from that static images can be very precise and exact, such as documents, plans and the like., And also of the property of the human eye, since the visual acuity is considerably greater in static images is.

The resolution of a video signal can be improved by increasing the number of lines in an image. However, since the frequency bandwidth that for the transmission of the video signal is required, proportional to the product of the number of images per Second and the square of the number of lines per second, the number of lines can be increased a picture if the number of frames per second is constant, do not simply perform. It must therefore the number of frames per second can be reduced to improve the quality of static images at one Image transmission system in which static images and moving images alternate or in to be transmitted in any order. In this case, the flicker must be that with the decrease related to the images per second, can be eliminated in the receiving unit.

Two methods have become known to deal with this problem. In one of the two Method, the brightness of the picture on the display screen is reduced in view of the Ferry-Porter law. An improvement in flicker of the image can only be determined if the brightness is reduced particularly strongly. Since a large decrease in brightness deteriorates the image quality, this method is unsuitable for practical use

In the second known method, a video signal is stored for each picture during the duration of a video signal for the immediately following picture and the stored video signal is read out after its duration and inserted between two adjacent pictures so that the number of pictures appearing is not reduced however, an entire image memory is required to perform this procedure. When a video signal of an image is to be digitally stored, a storage capacity of more than 10 ⁶ bits is required. This requirement cannot be realized economically.

In the German Offenlegungsschrift 1 437 645, an economically operating picture display system is disclosed described, which can be used in the transmission of static and moving images and static Pictures without flicker reproduces even if the number of frames per second when transmitting the static Images is reduced.

For this purpose, composite layers made of fluorescent materials that have afterglowing for different periods of time are used and one or the other layer made to light up by the fact that the energy of the electron beam of a single one is present Beam generating system is changed. The existing fluorescent substances must therefore be made to light up using different excitation energies. The fluorescent substances that can be used are therefore limited to those that have this required property.

The invention is therefore based on the object with fluorescent materials of different To create a system that works afterglow times, in which one gets by with constant electron beam energy and in which the phosphors therefore do not have to have different excitation energies.

This object is achieved in that the substances have different afterglow times cover adjacent areas of the fluorescent screen and the areas with the same afterglow time are each excited by their own electron beam system. From the description below The invention becomes clear from exemplary embodiments in conjunction with the drawing. Show it

F i g. 1A, 2 and 3 are schematic perspective views showing the structure of cathode ray tubes which be used in the system according to the invention,

Fig.! B is a schematic illustration to explain the structure of a shadow mask that is used in the

Embodiment according to Fig. IA is used,

ρ j g.4 and 5 block diagrams to explain a Embodiment of the invention and

ρ i g. Fig. 5B is a characteristic curve for explanation the operation of the invention.

In FIG. 1A, a possible variant of the cathode ray tube is shown which can be used in the system according to the invention and which has a front screen made of glass 3 with a fluorescent coating and a shadow mask 4, moreover from two electron beam guns 5 and 6, one for moving pictures, the other for static pictures. The fluorescent screen on the front of the screen 3 is made up of parallel strips 1 and 2 of fluorescent materials which have different afterglow times that differ considerably from one another, these strips being applied in alternating succession. The fluorescent material 2 has a short afterglow time (for example a few 'than a few milliseconds). The fluorescent material I has a relatively long afterglow time (for example several tens of milliseconds to several hundred milliseconds). It is desirable that the two fluorescent materials 1 and 2 have approximately the same color. The afterglow times of the fluorescent materials 1 and 2 are determined so that the flicker is as low as possible for the respective number of images per second. If the number of lines when receiving and displaying a static image is Ns , then fluorescent materials 1 and 2 must be Number M parallel stripes attached, is z. B. the number NsSOO for a cathode ray tube of 30 cm, then the width of each strip 1 or 2 of the fluorescent material is about 0.2 mm.

The shadow mask 4 has a number of holes made on lines corresponding to the fluorescent stripes 1 and 2 with respect to the electron beams 7 and 8 from the electron guns 5 and 6, as shown in FIG. IA and IB show. A distance ώ between adjacent rows of holes is determined by the distance between shadow mask 4 and luminescent screen 3, the distance between luminescent screen 3 and electron beam guns 5 and 6 and the vertical height of luminescent screen 3, etc., while the distance ώ between adjacent holes of the same line is determined by the desired horizontal resolution is determined. Since a cathode ray tube is generally designed so that it has the same resolution in the vertical direction as in the horizontal direction, the distances ώ and ώ are approximately equal to 0.6 mm. while the diameters 2r of each hole are about perhaps 0.2 mm for a 30 cm cathode ray tube.

In operation, the video signal is provided by a video amplifier (not shown) of the electron beam gun 5 so that the electron beam 7 from the electron beam gun through the shadow mask 4 is sent through, and line by line excites the fluorescent strips 2 with a short afterglow time. the Deflection of the electron beam 7 in the horizontal direction and in the vertical direction is by a Deflection circle causes, which is not shown in detail, but in the usual way by deflection coils or static deflection electrodes is formed. For moving pictures where the number of lines per picture JVm is half the number M of fluorescent strips 1 and 2, the vertical deflection voltage is controlled so that only every next but one line 1 and 2 is scanned. When imaging static images, the video signal is fed to the electron beam gun 6 via a video amplifier (not shown), so that the electron beam 8 through the shadow mask 4 line by line describes the fluorescent strips 1 with a long afterglow time. In this reproduction case the vertical deflection voltage is controlled so that the electron beam 8 successively all fluorescent strips 1 coated

The assumed ratio of the number of lines in static images to the number of lines in moving images Images here is 2: 1. However, this ratio can have any other value if the Fluorescent strips 1 and 2 are arranged to match with this ratio, and if the vertical deflection voltage is controlled so that the electron beam has the associated type of fluorescent strip 1 or 2 coated in the formation of an image

In FIG. 2 there is shown another embodiment of a cathode ray tube used in the invention is used and in which a shadow mask 9 is used in the manner of a converging grating whose parallel slots are arranged so that they are connected to the associated fluorescent strips t and 2 in with respect to electron beams 7 and 8 from the electron beam guns according to the procedure described in connection with FIG. 1A cooperate in the manner described. The shadow mask 9 is used to diffuse the spot of the Electron beam 7 or 8 on the adjacent fluorescent strip 1 (or 2) of the fluorescent screen 3 in one Assign similarly to the shadow mask 4 from Fig. 1A avoid.

In FIG. 3, there is shown yet another embodiment of a cathode ray tube used in the invention having a front screen 32 of glass and flakes 33, 34 and 35 of fluorescent material applied to the front screen 32. Three electron beam guns 6a, 6b and 6c and a shadow mask 4 with a number of holes, which are made line by line, are also located in the tube. The respective assignment of the electron beams from the electron beam guns 6a, 6b and 6c of the holes of the shadow mask 4 and the spots 33, 34 and 35 of the fluorescent materials is the same as in the known three-color tubes with shadow masks. The spots 33 and 35 are formed by fluorescent materials of different persistence times, these persistence times differing sufficiently from one another. In each case one of the spots 33, 34 or 35 is selected from one of the electron beam guns 6a, 6b and 6c by switching on the corresponding electron beam, just as happens in the known three-color picture tubes in conjunction with the shadow mask.

The block diagram according to FIG. 4 shows a schematic representation of the mode of operation of the invention. A pickup tube 41, a video transmitter 42, and a transmission link are interconnected on the circuit diagram 43, a video receiver 44 for receiving the video signal from the transmission link and for forwarding the video signal via a switch 45 to an electron beam gun 46 or 47 of a Cathode ray tube 49, as described in FIGS. 1A to 1, a switch 54 for turning on the state for moving pictures or static pictures, a control circuit 53 for setting the number of pictures per second and the number of lines per image of the pickup tube 41, a transmission link

for a switching signal from the control circuit 53, a control signal receiver 51 and a deflection circuit for generating the deflection voltages depending on the switching signal, which is received by the control signal receiver 51, the control voltages being a deflection coil 48 of the cathode ray tube 49 are supplied.

In operation, moving pictures are displayed on the screen of the cathode ray tube 49. In this Case is the pickup tube 41 with a certain number of images and lines that are movable Images are apt to be sampled. The video signal from the pickup tube 41 is modulated and given to the transmission link 43 via the video transmitter 42. The transmitted video signal becomes received and demodulated in the video receiver 44 and then the electron beam gun 47 by the Switch 45 supplied as a brightness signal. The electron beam emanating from the electron beam gun 47 is thus controlled in such a way that it shows the fluorescent material on the fluorescent screen with a short afterglow time the cathode ray tube 49 energized. Since no switching signal is transmitted in this case, the deflection circuit generates 50 voltages in sync with the video signal received by video receiver 44.

When a static image is to be transmitted, switch 54 is closed so that the image pickup tube 41 is controlled by the control circuit 53, so that they are in a certain number of images per Second and lines per image is scanned, which are particularly suitable for the static image. The video signal for the static image obtained from the pickup tube 41 is sent to the video receiver 44 transmitted by means of the video transmitter 42 and through the transmission medium 43. Besides, that will Switching signal generated by the control circuit 53 as a result of the closing of the switch 54 to the control signal receiver 51 is supplied via the transmission path 52, so that the switch 45 is switched to the electron beam gun 46 and thus the video signal received by the video receiver 44 is supplied to the electron beam gun will. The deflection circuit 50 also generates deflection voltages corresponding to the predetermined number of images depending on the switching signal from the control signal receiver 51, this number for the static image is particularly suitable. The beam from the electron beam gun 46 excites the fluorescent material with the longer afterglow time on the fluorescent screen of the cathode ray tube 49.

In the block diagram shown, the switch 45 is shown as a mechanical switch, for example as a contact of a magnetic relay. However, this switch 45 can also be a conventional semiconductor circuit or the like, as in connection with FIG. 5A will be described. The deflection coil 48 can also be replaced with electrostatic deflection plates. It is also possible to use the two electron beam guns Replace 46 and 47 with a single one. In this case, a control coil is then provided that the The distance of the focal point of the electron beam from this electron beam gun controls and that in addition to deflection coil 48 takes the place of the switch.

The transmission path 52, as is usually done, can be the same as the transmission path 43 if the switching signal can be distinguished from the other signals in terms of time or frequency.

The switching signal can also be transmitted as an audio signal over a telephone line, so that the deflection circuit 50 can be switched manually via a manually operated switch (not shown) when the tone signal is perceived.

The block diagram in Fig. 5A represents a different one Embodiment of the invention, is, however, that in F i g. 4 is similar to the circuit diagram shown. The switching signal however, is transmitted together with the video signal in the second embodiment, and the switching of the two electron guns 46 and 4V is effected by means of grids 55 and 56

F i g. 5B shows, like a video carrier signal 59, a sound carrier signal 58 and a subcarrier signal 57 for the switching signals within the frequency band on the transmission path 43 is transmitted, are arranged. The control signal detector 51 senses the transmitted Switching signal by demodulating the subcarrier 57, which was previously modulated with the sound signal was. The deflection circuit 50 generates a control signal which is fed to one of the two grids 55 or 56, whereupon a certain one of the two beams from the electron beam guns 46 and 47 is allowed to pass while the deflection voltages are supplied to the deflection coil 48. The distraction of the Electron beam from the electron beam gun 46 or 47 through the deflection voltages occurs at the Playback of moving pictures without the presence of a switching signal, whereas during playback static images, the processes are switched by the switching signal received from the control signal receiver 51 will. The other processes here correspond to those in FIG. 4. so further details are not listed here will.

It has heretofore been assumed that the switching signal was used to reproduce moving pictures to switch to the playback of static images. However, it can also render static images to the playback of moving images can be controlled with the help of the switching signal.

In the case of the FIG. 4 are the video receiver 44 and the deflection circuit 50 designed as in conventional monochromatic television sets. The video receiver 44, the deflection circle 50 and the control signal receiver 51 used in the embodiment in Fig. 5A correspond those of conventional color television receivers. The new image display system according to the invention is thus able to satisfactorily display both moving images and static images reproduce what is possible by a very simple modification of the conventional television technology. The invention can be applied to a wide range of image display technology such as video telephones, cable television and sending instructions with the aid of computers.

For this purpose 3 sheets of drawings

Claims (3)

Patent claims: Claims 1. An electron beam image reproducing apparatus comprising receiving means for receiving a video signal of successive images and a cathode ray tube, which is coupled to the receiving means, for reproducing the images in response to the video signal; The fluorescent screen of the cathode ray tube is formed by several different fluorescent materials which have different afterglow times, which differ significantly from one another, the fluorescent material being excited with a longer afterglow time at a lower image repetition frequency, characterized in that the substances with a lower afterglow time adjoining areas of the fluorescent screen cover and the areas with the same afterglow time are each excited by their own electron beam system. 2. Apparatus according to claim 1, characterized in that the fluorescent screen by a number of strips (I, 2) of two different Fluorescent materials is formed, which are arranged alternately parallel to one another, wherein two electron beams (7) from two different electron beam guns (5, 6) each scan one of the strip groups (1 or 2). 3. Apparatus according to claim 1, characterized in that the fluorescent screen by a number of points (33, 34, 35) of three different fluorescent materials is formed as Groups of each of the electron beam of one of three electron beam guns are excited.