DE708061C - Method for scanning television images for transmission and reception purposes - Google Patents

Description

It is well known that the quality of a received image transmitted by television does not set alone a sufficient number of pixels ahead. Rather, one must also focus on the Take flicker-free and image sharpness carefully, without too high demands to the frequency bandwidth of the transmission channel.

It is now known to reduce the picture flicker by increasing the apparent number of picture changes Reduce. This principle also applies to scanning in the form of the interlace method of television images application. Each individual image is divided into two interlocking line sequences of odd or even order disassembled; these are scanned one after the other so that the apparent image change time doubles. This is achieved without any widening of the transmission channel either while retaining the original total number of lines (e.g. 180 per image) a doubling of the number of changes in the partial images (e.g. from 25 to 50 per second) or if the old number of image changes is restricted (25 per see), the Number of lines in the composite image (from 180 to 360 per image). this means so that in the first case the flicker is reduced, in the second the resolution is increased will. Both factors at the same time · cannot be improved 3 «in this way. Even any improvement in just one of these factors are complicating the Scanning systemis limits. In this interlacing process, it has also changed a quite annoying interline flickering highlighted. Furthermore, an overlap reduces of the two line sequences for not

With completely correct beam guidance, the line sharpness is considerable. Finally it will be known with a certain position and direction of movement of an object on the image surface the doubling of the picture and line from Beo £> · eighth seen through as a subjective deception This deficiency of the interlace method are of a fundamental nature and are based on the fact that the line jumps as a whole. In accordance with the invention should therefore improve the interlace method to a point priming method be, d. H. a scanning scheme in which scanning is also discontinuous in the direction of the horizontal lines. The scanning is carried out in correspondence with one another by at least the pixel area Spaces separated points and selected according to any suitable scheme are made such that ao the omitted points are detected in one or more further scans until finally all points of an image are reproduced without gaps.

The point jump method according to the invention now leaves with the prescribed number of lines any increase in the number of frame changes without it being necessary to increase the frequency bandwidth, and without that a line flicker or a noticeable impairment of the image sharpness occurs. this is achieved primarily because there is a slight overlap in image lines, i.e. image strips, which are far more noticeable than with individual pixels. It is already known to erase a scanning beam periodically with consideration the afterglow blurring the contrasts. However, the skipped ones will be skipped Image points not made up in this process, and the apparent number of image changes stays the same.

The discontinuous scanning according to the invention can be done in a manner known per se accomplish by igniting and extinguishing a cathode beam by the control electrode the cathode ray tube is impressed with an auxiliary voltage. Serves for example the Wehnelt cylinder, so the auxiliary voltage is superimposed on the modttlation voltage.

If the scanning beam is interrupted once at a time when scanning at constant speed, so the scanned points are equidistant. The frequency of the auxiliary voltage is best synchronized with the frame rate of the transmitter in such a way that all points the image area can always be scanned in the same arrangement. This frequency can moreover have a certain fixed ratio to the frequency of the lines; then finds one line has the same number of touched points for each scan. This relationship of the two frequencies need not be integers.

■ -. "^ If one chooses the scanning template so that

each of the scanned points in the individual lines are perpendicular to one another, so the result is a column jumping system analogous to the interlace method.

Each line of the image can be scanned several times in succession, each time having different Touches elements that complete a line. You scan the line without any gaps before you move on to the next transforms. You can also scan only part of the elements of a line and use Do the following in the same way, so that you first sweep over the entire picture surface. When this scan is completed, you go back to the first line to move a * o know number of omitted points to be scanned, etc. In this way one also scans several successive scans from all pixels of the entire area.

The enclosed figures explain the 8s Invention in some exemplary embodiments. Fig. I, 2 and 3 show schematically the Line routing in scanning methods according to the invention.

Fig. 4 shows a circuit, with which one can especially perform the scanning according to Fig. 1 can accomplish.

Fig.s shows schematically a transmission circuit based on the principle of the invention, Fig. 5 a the associated receiving circuit.

Fig. 6 gives, as a function of time, the currents flowing in the various parts of the Circuit according to Fig. 5, and explains the mode of operation of the device.

Fig. Ι illustrates a scanning scheme in which the electron beams in the direction move the horizontal lines of the image. The sampled points of each line lie with respect to the points of the neighboring so that they are continuous, vertical stripes form. In the first scan, the downtimes, in the second, the hatched ones Elementary squares recorded.

Fig. 2 illustrates a scanning scheme in which the inventive, in Fig. 1 The point jump method shown is combined with the well-known line jump method is.

Fig. 3 shows a checkerboard scan. The scanned pixels of the straight line Image lines are in this case by one pixel in each case compared to those of the odd ones postponed.

In addition to these simple scanning templates, more complicated ones can be provided. So can ta « For example, the entire image area can be divided into individual fields. Limited

with each scan, one now has to consider a single point from each subfield capture, the image is roughly sketched as a whole during the first scan and just refined by the following. This can be done during assembly considerably reduce such annoying flickering from individual lines.

Fig. 4 shows a circuit for performing the schematically recorded in Fig. Ι Scanning. The basic thing is to insert the Wehnelt cylinder of the Braun receiver tube through one of to control alternating voltage supplied to a superimposer and the phase between superimposers and reverse Wehnelt cylinders at the end of each scan. The television set consists of a receiver ι with the Braun tube 2, the Wehnelt cylinder 3 of which was transmitted by the recipient Receives modulation. The device 4 sifts the synchronization characters for line and picture, the tilting device 5 (lines) the horizontal baffles 7, the tilting device 6 (picture) the vertical baffles 8 of the Braun tube 2 is impressive.

According to the invention, the modulation voltage controlling the Wehnelt cylinder is superimposed an alternating voltage coming from a tube system 10, n across the transformer 9 is delivered. The tubes themselves are supplied with AC voltage of constant frequency from the oscillator 13 via the transformer 12 fed. The circuit of the tubes 10 and 11 provides a connection between the Transformer 12 and the transformer 9 ', whose phase changes periodically at the end every scanning train reverses. --This will e.g. B., as can be seen from Fig. 4, thereby achieved, that one lets five-pole tubes work as an oscillator and as an amplifier at the same time. Man connects the grid 14 of the tube 10 with the anode-near grid 17 of the tube 11 via the Capacitor 22 and the grid 15 with the grid 16 by means of the capacitor 23. The Grids 14 and 15 are above resistors 18 and 19 and the grid close to the anode 16 or 17 via resistors 20 and 21 in the immediate vicinity Link. Such a grid-anode coupling of two tubes is known to provide a series of very sudden current reversals, separated by longer spaces, during which the change in amperage is very slow. If one of the tubes is working, the other is out of order and vice versa. The periodicity of these reversals is established now on the frame rate z. B. with the help of

fio transformer 24, which is connected to the grid 14 the tube 10 is connected in series. The primary voltage of the transformer 24 is from the discharge current of the image tilting device 6 flowed through. The modulation of the superimposed 13 is thus alternately given to the transformer 9, with a corresponding phase shift, which results from the fact that the control grids 25 and 26 connected to the ends of the secondary coil of the transformer 12, which is tapped in the middle are. In contrast, the anodes in the tubes 10 and 11 feed the primary coil in parallel of the transformer 9. Thus, the superimposer 13 extinguishes during the first scan periodically the cathode rays with the help of the tube 10. ' During the next scan the superimposer continues to erase the rays periodically; but since the connection is made this time via tube 11, the phase of this extinction is half a period different, and that during the second Scanned dots are shifted by one elementary field. The frequency of the Overlay 13 can be almost anything, provided that it is high enough and remains constant over time. In order to have a favorable relative position of the during the successive However, in order to obtain scanned dots, it is more advantageous to use this frequency that of the temporal sampling to be adapted by z. B. the oscillator from Line tilt device controls her. One uses z. B. the discharge current of the gas discharge tube this tilting device for supplying the current impulse, which is used to stabilize the superimposer 13 is necessary. If you combine the circuit according to Fig. 4 with the interlace system, in this way a checkerboard-like scanning is obtained in the manner of Fig. 2 and in this way a much higher image sharpness is achieved and at the same time reduces the flicker. Instead of controlling the intensity of the cathode ray, you can also use a deflection or use dimming control. For this purpose a Braun tube is used, which is placed in front of its fluorescent screen Has grid that deflects the cathode ray from its path. This happens' either through rhythmic movements of a grid consisting of parallel cylindrical lenses (i.e. purely mechanical) or through an alternating electric field applied to a fixed grid and the fluorescent screen. It is also possible to use the cathode ray before it hits the fluorescent screen several, for example, to run through two purely electrically controlled grids. All the circuits described can of course also be transferred to the transmitter. If you use a storing image capture tube with cathode ray scanning, so can either the point according to the invention

Achieve selection by acting on the scanning beam itself or by influencing it the electrical circuit external to the tube; best of all by making this circuit periodically interrupts and ensures that the interruptions during the successive Samples are shifted.

The shift between the individual point sequences can also be implemented according to the invention by a suitable ratio between the frequency of the superimposed and that cause the line deflection. It is important to ensure that the superimposed an odd number of changes in the one between two line diversions Period executes. The periodic deletion of the Beams should now automatically perform a checkerboard-like scan corresponding to that of Fig. 3 without the contrivance of a phase inversion at the end of each line which one was forced in the example illustrated in Fig. 4. Is the number of sampled If image lines are odd, the second scan automatically brings the additional points of the chessboard. In this way the flicker is greatly reduced and the sharpness is increased.

In Figs. 5 and 5 a is a television set with a storing image catcher tube 25, on whose mosaic the image 46 to be transmitted is designed, and a Braunschweig receiver tube 26 shown. As usual, the cathode rays are deflected by pairs of plates 27 and 28, the are connected to two tilting devices 29 and 30 for the line or image deflection. Both tilting devices are fed by a common oscillator 31. The through the Sampling of the mosaic is achieved by modulation after amplification by the amplifier 32 transmitted to the transmitter 33. This is at the same time of the in amplifier 34 enhanced line and frame synchronization marks. The image stream will now periodically interrupted by a device 35 controlled by the superimposer, the superimposed itself is regulated by an organ 31 oscillating at a fixed frequency. After the receiver 37, the screen 40 separates the line from the image synchronization characters are then placed on the tilting devices 41 and 42, respectively. On the other hand, it controls the device 37 received modulation the Wehnelt cylinder of the receiving tube 26 via the amplifier 43.

The interrupter 44, from the superimposed 45

controlled, periodically interrupts the cathode rays at a frequency that is stabilized with the modulation supplied by the superimposed 36 of the image catcher. A small remainder is superimposed on the image modulation during transmission. This stabilization is z. B. achieved by placing an oscillating circuit at the output of the receiver 37 which is tuned to the frequency of the superimposer 36. FIG. 6a shows the brightness values of an image line, while FIG. 6b shows the image streams corresponding to these brightness values that an image catcher without the features of the invention generates. The superimposer 36 supplies a voltage which is shown as a function of time by the curve 60. This superimposer acts on the image stream by means of a suitable interrupter device 35. The image stream interrupted in this way is shown in curve 6d . As can be seen, the curve corresponds to the sampling of points of odd order. The curve 6 _L. Figure 11 shows the delay effect systematically exerted by the enhancer 32 on the icons. Instead of a complete current interruption between the scanned points, only a small current reduction is obtained. However, this small change is sufficient to ensure that the superimposed device 45 in the receiver is synchronized with the superimposed device 36 in the transmitter. When looking at the curve 6 _e it is clear that the bandwidth required is smaller than that for a system according to curve 6, *. Fig. 6f shows the voltage supplied by the superimposer 36 during the second scan, in which only the points of even order are scanned. 6 /, shows the image current during the scanning, FIG. 6, - the current which emanates from the amplifier 32 and is used to modulate the carrier wave. The recipient during the successive Abtastzüge alternately the image streams _e 6 and 6 - on. With the help of the superimposer 45, which acts on the interrupter 44, voltage curves 6j and 6 / * on the Wehnelt cylinder are obtained in the receiving device and in this way z. B. the chessboard-like scanning according to Fig. 3.

Claims (9)

^Claims : It0 i. Method for scanning television images for transmission and reception purposes, characterized in that the Scanning in spaces separated from one another by at least the pixel area corresponding to and after any suitable scheme selected points (point jump method) is made in such a way that for the iao omitted points require one or more additional scans to reproduce all points of an image without gaps. 2. A method for scanning television images according to claim i, characterized in that that the scanning is periodic at least in the cycle of a pixel area is interrupted. 3. A method for scanning television images according to claims 1 and 2, characterized characterized in that the point jump method with the interlace method is combined. 4. A method for scanning television images according to claim 1, characterized in that that the number of points skipped during the scan is different for each line or group of lines. 5. A method for scanning television images according to claim 1, characterized in that that the supplementary scanning is carried out after each line or a group of lines. 6. Arrangement for performing the method according to claims 1 to 5, characterized characterized in that the cathode ray beam is influenced in its intensity by mechanical and / or electrical means or is deflected and the desired scanning control through a phase shift the deletion is achieved. 7. Arrangement for performing the method according to claims 1 to 6, characterized characterized in that a grating arranged inside the tube and consisting of parallel cylindrical lenses Rhythm of the scanning sequence is moved in front of the fluorescent screen. 8. Arrangement for performing the method according to claims 1 to 6, characterized characterized in that the cathode ray has one or more AC voltage on its way to the luminescent screen passes through a lying grid. 9. Arrangement for performing the method according to claims 1 to 6, characterized characterized in that the shift on the pixel sample by a certain ratio in frequency of the reception superimposed on the line deflection frequency is brought about. 1 sheet of drawings