DE19913916C2 - Method and device for setting and / or adjusting the phase in flat screens - Google Patents

Description

The invention relates to a method and a device for Setting and / or adjusting the phase between the pixel clock of a graphic card te and the sampling clock of a flat screen with an ana lied interface in a flat panel graphics card- Computer system.

Flat screens with an analog interface must be on the graphics card of the connected computer can be adapted. If the phase or sampling frequency are set incorrectly, appears the image is out of focus and with interference. While for Stan dardmodi the values for image position, that means right-left and Top-bottom setting, and sampling frequency as default te values can be defined, this is for the phase not possible because the phase of the graphics card used and also depends on the video line.

With flat screens according to the prior art is common Lich a microprocessor provided the general control Flat screen display takes over. This microprocessor is configured so that it also matches the one set on the computer Can recognize video mode. If the mode is already factory or has been set by the user, the Flat screen with the saved settings for picture location, sampling frequency and phase operated. It is the mode, on the other hand, is one that is used in the microprocess sor of the flat screen is not yet implemented, so become the standard values for image position, sampling frequency and phase taken. These default values are not always applicable peaceful.

The setting of the sampling clock and the phase have an un indirect impact on image quality. An optimal ab  sampling frequency is given when the sampling of all Pixel, for example, a line of a video signal in one stable or characteristic area of these pixels, at follows in the middle of each pixel, for example. Then bring the Data conversion optimal results. The picture shown has no ne interference and is stable. In other words, it is optimal sampling frequency equal to the pixel frequency. When a wrong sampling frequency is set, for example if the sampling clock is too fast compared to the pixel clock, the pixels are initially in the allowable range that means in the middle between two flanks, sampled, the subsequent pixels, however, are more and more towards egg ner edge scanned until even the area between two pi xel is scanned, which obviously leads to an unsatisfied image quality. The area where the pixels are not in an optimal, characteristic range wrong sample values are derived. The picture shows then a strong vertical interference. The bigger the sub differed in frequency between the sampling clock and the pixel is clocked, the more areas with vertical interference visible on the screen.

However, also in cases where the sampling clock is identical with the pixel clock, the picture quality may suffer if the Phase is not set correctly. The reason is that the scan in a ge not ideal for the scan suitable area of a pixel takes place, for example to close to the leading or trailing edge of a pixel. The This problem can be solved in that the phase, the is called the sampling time, is shifted until the Scanning in a characteristic or permissible range the pixel is done. If the phase is not set correctly is, the image quality is through on the entire screen Noise signals impaired.  

There are already flat screens with an analog interface, where the phase setting is done automatically becomes. With an automatic phase adjustment mostly special test patterns with alternating white ones and black pixels, the test pattern of the graphics card must be displayed. This has the aftermath part that a software installed on the computer and ge must be started, and furthermore that software for all common operating systems must be available.

It is for satisfactory operation of the flat screen also desired that the phase adjustment also over time is stable. This is known for analog interfaces analog interface not 100% stable. So change at for example, the runtimes and other characteristics the temperature. This instability of the analog interface also affects the image quality of the flat screen out. In other words, even if the sampling phase is set correctly when the computer is switched on a certain time, for example 30 minutes, the phase ne has experienced drift, which then leads to a reduction in the Image quality leads, which also often leads to questions about the Hotline of the supplier leads.  

DE 39 14 249 A1 describes a method and a circuit known with the from a signal, in particular a signal for a data monitor that can be recovered clock with which the signal was generated. It will continue to be Described method and a circuit with which the Ori Final clock or the required partial ratio for the PLL can be generated automatically, as well as a PLL circuit adjustable phase position.

Furthermore, a signal processing is from the older application according to DE 197 51 719 A1 processing method for an analog image signal known. there the analog image signal comes from a computing unit in which the signal was generated according to a graphics standard and then converted to analog. The Ver driving is that the analog image signal of an Ana log / digital conversion with a first selected sampling fre quenz is subjected, then the scanned image Image interference is examined to find a corrected Ab to determine duty cycle. Further measures concern the Determining the optimal sampling phase and determining the exact position of the active image relative to the horizonta len or vertical synchronization pulses.

In view of this, the object of the invention is a method and a device for adjusting and / or adjusting the phase to provide flat screens, making a permanent precise setting of the phase is made possible.

The method according to the invention is used to achieve this object characterized in that an automatic adjustment of the Phase is carried out repeatedly. One is preferred continuous or periodic phase adjustment. With in other words, during the operation of the flat screen mes either continuously or periodically again adjusts the phase so that a drift due to Temperature fluctuations or other influences on the flat  screen is balanced. The flat screen is therefore there always available with optimal picture quality.

According to an advantageous embodiment of the invention The procedure for the current state of the Sy stems required phase adjustment only on single picture points determined, and the determined phase setting is then applied to the entire image. For the moment appropriate phase adjustment to the condition of the system the phase must be adjustable. So if one such setting during operation of the flat screen screen is to be carried out, the flat screen would stand temporarily unavailable during phase adjustment. However, if the ver shift of the phase only takes place at individual pixels, the image is only briefly at these individual pixels disturbed, which is not noticeable in practice. With the Water configuration of the method according to the invention can therefore the adjustment of the phase during the operation of the flat screen done.

Another advantageous embodiment of the invention Procedure is characterized in that a sufficient bright pixel selected and the rising edge of a Video pulse of this pixel is determined that an off sufficiently bright pixel selected and the falling edge a video pulse of this pixel is determined, and that the phase is adjusted so that a sampling time for the entire picture approximately in the middle between the stei and the falling edge of the video pulse becomes.

An advantageous embodiment of the inventive method rens is characterized in that the rising edge egg nes video pulse of a sufficiently bright pixel telt, and that the phase is adjusted so that the Ab  moment of scanning approximately half a pixel width in rich direction pixel center is shifted.

An advantageous embodiment of the inventive method rens is characterized in that the falling flank egg nes video pulse in a sufficiently bright pixel is averaged, and that the phase is adjusted so that the Sampling time approximately half a pixel width in Is shifted towards the center of the pixel.

While the image position and sampling frequencies are relatively one be determined by an algorithm and correspond can be adjusted accordingly, the phase position is difficult to determine. The three last-mentioned execution examples Games of the inventive method are simple and be peaceful procedures for setting the phases, ins special no test samples and no corresponding software are required to the automatic phase adjustment perform.

An advantageous embodiment of the inventive method rens, the image area with the pixels on the Flat screen in rows and columns between a back Porch area and a front porch area is arranged is characterized in that as a sufficiently bright picture a pixel for determining the rising edge in the first column next to the back porch area and as sufficiently bright pixel for the determination of the falling Flank a pixel in the first column next to the Front porch area is selected. The procedure can be perform particularly well if possible Flanks are evaluated or if next to each other the lying areas or points a very different Have brightness. Therefore a point in the first is suitable or the last column of the image is particularly good, since it is in Combination with the front or back porch area  the required conditions fully satisfied and with relatively ge little effort can be found.

An advantageous embodiment of the inventive method rens is characterized in that the brightness of several Pixels of the first or last image column measured and the pixels with the largest or sufficient the brightness in the first or last picture column for determining the rising or falling selected edge of the video pulse. So will ensures that pixels with sufficiently pronounced Edges are used for the measurement.

An advantageous embodiment of the inventive method rens is characterized in that first the pixels (n × k) with n = 1, 2,. . . N and k = constant, for example 10, and that if not sufficiently bright Pixel was found, the pixels (n + m) × k with m = 1, 2,. . . . N be measured until a sufficiently bright image point is found. This will start a search for suitable ones Pixels performed efficiently and in the shortest possible time. An advantageous embodiment of the inventive method rens is characterized in that to determine the Am the phase values of the selected pixel pixels are shifted until the measured ampli values no longer change significantly, and that the then determined amplitude values are processed further.

Alternatively, an advantageous embodiment of the inventions Process according to the invention characterized in that the at determining the amplitude value of the selected image phase used until the ge measured amplitude values less than a predetermined limit value, for example less than 50% of the amplitude value, are that the phase is delayed by half a point width, and that the then measured amplitude value is processed further becomes.  

The last two embodiments of the invention According to the procedure are simple solutions to the brightness of the pixel as a prerequisite for determining the position to determine the rising and falling pixels.

Another advantageous embodiment of the invention is there characterized in that to determine the rising flan ke of the selected pixels the phase on the selected Pixel shifted so far in the direction of the back-porch area until the measured amplitude value reaches a predetermined value Percentage, for example 50% of the previously determined Am value drops, and that this value of the phase as Location of the rising edge is buffered. Furthermore ren is an advantageous embodiment of the invention characterized in that to determine the falling edge of the selected pixels the phase on the selected image point so far in the direction of the front porch area until the measured amplitude value reaches a predetermined value Percentage, for example 50% of the previously determined Am value drops, and that this value of the phase as Location of the falling edge is buffered. To this Way, the rising and falling edge of two pixels in a simple manner, and the phase can then be set so that it is between the stei and the falling flank approximately in the middle of a Pixel lies.

Another advantageous embodiment of the invention is there characterized in that the phase or Ab tactile point towards the middle between the rising and the falling edge by a predetermined amount, for example as 10% of the pixel width, is delayed. This is ins especially with fast video signals with overshoots partial, since it is avoided that the scanning in the area of Overshoot occurs.  

To solve the above problem is the device for input and / or Readjusting the phase between the pixel clock of a graphic card te around the sampling clock of a flat screen with an analog interface in a flat screen graphics card Computer system, characterized by a device by which repeats an automatic phase setting preferably continuously or periodically.

Another advantageous embodiment of the invention Facility is characterized by a facility that the rising edge of a video pulse is sufficient bright pixel, a device that the fal lending edge of the video pulse in a sufficiently bright Pixel determined, and an adjustment device with which the phase is set so that the sampling time in et wa in the middle between the rising and the falling Edge of a video pulse is placed.

Further advantageous embodiments of the invention Method or the device according to the invention are evident from the remaining subclaims.

Embodiments of the invention are now based on the lying drawings described. Show it:

Figure 1 is a block diagram of a flat screen connectable via an analog interface to the graphics card of a computer system.

Fig. 2 schematically shows a horizontal synchronizing signal and a channel of a video signal, for example the R video signal (R = red color

Fig. 3 shows schematically the horizontal synchronizing signal and meh eral lines of a channel of a video signal;

FIGS. 4A and 4B are schematic representations of Videosigna len;

Fig. 5 is a schematic representation of the rising and falling edge of pixels of a video signal; and

FIGS. 6A and 6B schematically illustrate two ideal video signals and the effect of the location of the sampling pulse in Relati on to the video signal.

Fig. 1 shows a control circuit for a connectable via an analog interface flat panel, whose function le with reference to the various Eingangssigna and their preparation is illustrated. At the input of the control circuit are on the one hand the video signal consisting of the three color signals R, G, B and on the other hand the two synchronization signals H-sync and V-sync for horizontal and vertical picture synchronization. H-sync and V-sync are transmitted digitally, with the signal voltage being 0 V and <3 V, respectively. V-sync signals that the first line of an image is being transmitted. This signal corresponds to the refresh rate and is typically in the range between 60 and 85 Hz. H-sync signals that a new image line is being transmitted. This signal corresponds to the line frequency and is usually around 60 kHz.

The video signal consisting of the color signals R, G, B is an analog signal. The signal voltage is in the range of 0 V and 0.7 V. The pixel clock, i.e. H. the frequency with which the value of this voltage can change is 80 MHz. There transfer a certain number of pixels per image line the pixel clock is higher than the number of these points the line frequency (H-sync).

The three color signals R, B, G of the video signal are via ei NEN video amplifier VA each an analog-digital converter ADCR, ADCG and ADCB fed. The two synchronization signals H-sync and V-sync are in separate circuits HSy, VSy processed in such a way that the through the transfer and ground through various EMC measures  gnal flanks are refreshed again. To this extent riding synchronization signals H-sync or V-sync then fed to a microprocessor µP. That mic processor µP measures their frequency and determines the in the resolution of the graphics card of the computer system. The data saved for the resolution is displayed following a phase locked loop PLL and in parallel to a logic circuit implemented in the form of an ASIC for Preparation and processing of the digital data handed over.

The phase locked loop PLL multiplies the frequency of the syn Chronization signal H-sync with that of the microprocessor µP passed value. As a result, the sampling frequency (Pi xeltakt) won. Due to a in the phase locked loop PLL caused delay time results in a phase lower differentiated between pixel clock and sampling frequency. These two Parameters can be influenced via the OSD display on the screen rivers. The sampling frequency obtained in the phase locked loop is also the three analog / digital converters ADCR, ADCG, ACDB fed. These convert the analog data stream into egg digital data stream. The digitized data will be finally in the subsequent logic circuit ASIC with Hil the data contained in a video memory VM is working. In the simplest case, the data is sent 1: 1 to the Flat screen that can be connected to the logic circuit ASIC are transferred, the video memory VM is often used to a temporal decoupling between the coming and the to reach the flat screen D to be transmitted data. For the interpolation of low resolutions, too access to the data stored in the video memory VM.

Fig. 2 shows the horizontal synchronizing signal H-sync and a video signal of a channel, for example a red Farbka channel, R. The video signal is chosen in Fig. 2 so that bright and dark pixels are shown from alternating. The dashed lines on the video signal show the ideal sampling times or the ideal phase for the digitization of the analog video data. The dashed areas on the first two pixels represent the just admissible range of the phase for which a still correct sampling is achieved. After the phase has been adjusted, it is therefore on the dashed lines. With a resolution of, for example, 1024 × 768 pixels (XGA) and 75 Hz refresh rate, a fuzzy and very grainy display is obtained with a phase shift of 4 ns. Therefore, the phase adjustment is crucial for good image quality.

Fig. 3 shows how the information about the phase position, which is essential for the control, is obtained by determining the ideal sampling time for a shift of the phase. If the phase is determined continuously and the determination of the phase position would relate to the entire image, this would cause considerable image disturbances without additional effort. The image disturbances occur because the phase of the pixel clock has to be shifted in order to determine the cheapest from the various phase positions. If finally the phase of the image area to be examined, preferably a single image point, is changed while all other points are still scanned with a changed phase, an image disturbance is imperceptible since it is limited to this very small area.

In Fig. 3, several lines of the video signal are shown, the information about the ideal phase, for example by the method described below for automatic Pha senabgleich, takes place. The two pixels, on the basis of which the rising and falling edge are to be determined, are the first pixel in line B and the last pixel in line Y, lines A, B, Y and Z being intended to represent any image lines. The phase required to determine the ideal sampling time should be limited to one of these two points, while all other pixels are still scanned with the current phase setting. All that is required is that the control has access to the data supplied by the A / D converters, and that the phase can be selectively advanced or delayed for a single pixel to be determined by the control.

From the illustrations of FIGS. 4A and 4B can also be seen that the phase of the sampling of the video signal plays an important role in the image quality, and that the phase must be in many cases with different video signals to accordingly different locations. Thus, Fig. 4A shows a fast video signal with overshoot, the range of the loading between the rising and falling edge of the video signal is relatively narrow and is shifted towards the falling edge. In contrast, Fig. 4B shows an inert video signal without overshoot, where the area for the scanning between the rising edge and the falling edge is relatively wide and centered in union. When looking at the two signals it can be seen that there are phase positions, for example at the right edge in the area of the falling edge in the sluggish video signal, in which the measured amplitude values are no longer usable in the sluggish video signal, while in the same phase position in the fast one Video signal still usable amplitude values are measured. On the other hand, it can be seen that the ideal phase position lies approximately in the middle between the rising and falling edge of the video signal and must also be set to this value. This is why setting the phase depending on the system is so important.

As already mentioned, the automatic phase is on position more difficult to accomplish than the settings of the other parameters. Based on the other figures described how such an automatic setting before can be taken.  

As FIG. 5 shows, the edges of the video signals are used to determine the phase position. In order to be able to determine an edge, it is advantageous if it is as pronounced as possible. This is the case if the signal in front of the edge is as low as possible and strongly shaped behind the edge, or vice versa. The first requirement is ideally met by the scanning gap in the back and front porch area, the second by a bright pixel. A bright pixel at the beginning of a line is therefore very suitable for the rising edge, one at the end of a line to determine the falling edge.

That these are flanks of two different points that may be on different picture lines are irrelevant because the pixel and sampling clock be is known and can be taken into account accordingly. The selected pixels should be in at least one basic color (RGB) have a sufficiently high intensity that a a sufficiently large flank is found in its amplitude.

Basically, any combination of a bright one is suitable and a dark pixel that can be anywhere in the Vi deo signal can lie to determine the edges. By doing in most cases, the combination of front / back Porch area and a bright pixel in the first / last th edges of the image are determined. On Search the entire image content for two suitable ones Then pairs of points are dropped.

As already explained above, is the ideal area for the sampling of the video signal, the one in the target and The actual value of the signal largely match. The measurement the amplitude of the video signal in the area of the edge is dependent difficult to do. The reason for this lies in the jitter of the Video signals and the scanning pulse. Is this opposite the rise or fall time of the video signal can be large the edge was found by averaging several measurements  be a statement about the amplitude of the flank on the ge However, the measured point cannot be hit.

Figs. 6B and 6B illustrate the problem in the detection of the flanks. In the ideal video signals ge dashed lines are inserted, which represent the desired sampling point. The hatched area represents the area actually scanned by the jitter in various measurements. If the measured values were averaged, in the first case there is an average value of approx. 80%. This averaged value could be misinterpreted as being on the rising flank exactly where it reached 80% of the amplitude. However, this is not the case. In the second case, the statement would be 50%, which is more true.

From these results it is clear that because of the Jit It will hardly be possible to determine the position of the flank at which it has reached a certain value. The you will make the smallest mistake when you go through Averaging of the measured values comes to approx. 50% of the target value. Of course, other values can also be searched. For example, smaller values have the advantage that they did neuter amplitude of the pixel determined less accurately must become.

In the following it is assumed that the image position and the Sampling frequency are already set correctly. In addition, should access to the data of the A / D converter is possible. The rising edge and falling edge become as follows averaged using the following steps.

Rising edge

• 1. Find a point in the first column of the image, the one sufficiently high, maximum possible R, G or B value has.  
• 2. Since the phase in 1. could have been preset, that the measurement is incorrect can be the actual value the amplitude may be higher. The actual value of the amplitude de by measuring at a suitable sampling time by delaying the phase until the measured Am no longer increase the level of the is first advanced until the measured ampli values are very low and this value of the phase that marks the beginning of the flank by half the pixel width is delayed.
• 3. Shift the phase towards the back porch until the sample value averaged over several measurements to approx. 50% of the value determined in 2. falls. This value of the phase cache, since the rising edge is located here det.

Falling edge

• 1. Find a point in the last column of the image, the one sufficiently high, maximum possible R, G and B value has. To get the most accurate readings, the Phase before the scan is set to the value found in 2 be put.
• 2. Shift the phase towards the front porch until the averaged sample value to approx. 50% of that determined in 4 Value drops. At this point is the falling one Flank.

Alternatively, the sampling time can also be determined by determining the rising edge of a video pulse of a sufficiently bright pixel and by setting the phase so that the sampling time is shifted approximately half a pixel width towards the center of the pixel, or alternatively the falling one Edge of the Videoimpul ses is determined in a sufficiently bright pixel, and that the phase is set so that the sampling time is shifted approximately half a pixel width towards the center of the pixel. Then the steps 1 to 5 described above be simplified accordingly.

Theoretically, the ideal sampling time is exactly between the two flanks. In practice it can be an advantage not exactly in the middle between the two flanks, but sampling with a slight delay to avoid any overshoots to avoid the graphics card, as well as the often slightly exponential the elliptical character of the flanks.

The hardware implementation of the invention comprises a direction, the rising edge of a video pulse of a determined sufficiently bright, a facility that the falling edge of the video pulse in a sufficiently bright Pixel determines an adjustment device with which the Phase is set so that the sampling time approximately in the middle between the rising and falling edge a video pulse is placed, and a device to the Ver phase for determining the sample value of the pixel push until the measured amplitude values no longer differ differ significantly, with the Ab sample value is processed further.

Furthermore, a device is provided, which at Ascertaining the sample value prefers the phase used, until the measured amplitude values are smaller than a specified one ner limit, for example less than 50% of the sample tes and through a facility that then completes the phase delayed half a pixel width, which is then measured ne sample value is processed further.

Finally, a facility that is the investigative phase the rising flank towards the back porch Range shifts until the measured amplitude value reaches ei  a predetermined percentage, for example 50% of the previous determined amplitude value, which value falls Phase is temporarily stored as the location of the rising edge, and a device is provided to determine the phase the falling flank so far towards the front porch Range until the measured amplitude value reaches one predetermined percentage, for example 50% of the previous he average amplitude value, this value being the Phase is temporarily stored as the location of the falling edge.

Claims (25)

1. A method for adjusting and / or adjusting the phase between the pixel clock of a graphics card and the sampling clock of a flat screen with an analog interface in a flat screen graphics card computer system, characterized in that an automatic adjustment of the phase is carried out repeatedly. 2. The method according to claim 1, characterized records that the automatic adjustment of the phase is carried out continuously. 3. The method according to claim 1, characterized records that the automatic adjustment of the phase is carried out periodically. 4. The method according to any one of claims 1 to 3, characterized characterized that for the current Condition of the system required phase adjustment only on individual pixels is determined, and that the determined Phase adjustment is then applied to the entire image. 5. The method according to claim 4, characterized shows that a sufficiently bright pixel out selects and the rising edge of a video pulse this Pixel is determined that a sufficiently bright picture point selected and the falling edge of a video pulse this pixel is determined, and that the phase so is that the sampling time for the entire image roughly in the middle between the rising and the falling the edge of the video pulse is placed. 6. The method according to claim 4, characterized records that the rising edge of a video pulse a sufficiently bright pixel is determined, and that the phase is set so that the sampling time in et  wa by half a pixel width towards the center of the pixel is pushed. 7. The method according to claim 4, characterized records that the falling edge of a video pulse is determined in a sufficiently bright pixel, and that the phase is set so that the sampling time in et wa by half a pixel width towards the center of the pixel is pushed. 8. The method according to any one of claims 5 to 7, wherein the Image area with the pixels on the flat screen in Rows and columns between a back porch area and an egg nem front porch area is arranged, thereby ge indicates that as a sufficiently bright picture a pixel for determining the rising edge in the first column next to the back porch area and as sufficiently bright pixel for the determination of the falling Flank a pixel in the first column next to the Front porch area is selected. 9. The method according to any one of claims 5 to 8, characterized characterized that the brightness of several Pixels of the first or last image column measured and the pixels with the greatest brightness in the first or last image column for the determination the rising or falling edge of the Videoim pulses can be selected. 10. The method according to any one of claims 5 to 8, characterized characterized in that first the pixels (n × k) with n = 1, 2,. . . . N and k = constant, for example 10, be measured, and that if not a sufficiently bright picture point was found, the pixels (n + m) × k with m = 1, 2,. . . . N be measured until a sufficiently bright image point is found.   11. The method according to any one of claims 5 to 8, characterized characterized in that to determine the amplitude the phases of the selected pixels Pixels are shifted until the measured amplitudes values no longer change significantly, and that then determined amplitude values are processed further. 12. The method according to any one of claims 5 to 8, characterized characterized in that when determining the Amplitude values of the selected pixels used phase is advanced until the measured amplitude values less than a predetermined limit, for example small less than 50% of the amplitude value are that the phase by ei ne half point width is delayed, and that then measured its amplitude value is processed further. 13. The method according to any one of claims 5 to 8, characterized characterized that to determine the rise the edge of the selected pixels the phase at which selected pixel so far in the direction of the back-porch area is shifted until the measured amplitude value reaches one predetermined percentage, for example 50% of the previous he average amplitude value, and that this value is the Phase is temporarily stored as the location of the rising edge. 14. The method according to any one of claims 5 to 8, characterized characterized in that to determine the falling Edge of the selected pixels the phase at which selected image point so far in the direction of the front porch Range is shifted until the measured amplitude value to a predetermined percentage, for example 50% of the previously determined amplitude value drops and that this Value of the phase buffered as the location of the falling edge is saved. 15. The method according to any one of claims 5 to 8, characterized characterized in that the phase respectively  the sampling time is rising from the middle between the the and the falling edge by a predetermined amount, for example 10% of the pixel width is delayed. 16. Device for setting and / or adjusting the phase between rule the pixel clock of a graphics card and the sampling clock Flat screen with an analog interface in a egg a flat screen graphics card computer system, characterized by a facility by which an automatic phase adjustment is repeated leads. 17. The device according to claim 16, characterized by a device through which the automatic adjustment The phase is carried out continuously or periodically becomes. 18. Device according to claim 16 or 17, characterized by a facility by which necessary for the current state of the system che phase setting determined only at individual pixels and then the determined phase setting the entire image is applied. 19. Device according to one of claims 16 to 18, characterized by a facility that the rising edge of a video pulse of a sufficiently bright one Pixel, a device that detects the falling Edge of the video pulse in a sufficiently bright picture point determined, and a setting device with which the phase is set so that the sampling time in et wa in the middle between the rising and the falling Edge of a video pulse is placed. 20. Device according to one of claims 16 to 18, characterized by a facility  which is enough for the rising edge of a video pulse chend bright pixel, and a setting device with which the phase is set so that the Ab moment of scanning approximately half a pixel width in rich direction pixel center is shifted. 21. Device according to one of claims 16 to 18, characterized by a facility that the falling edge of a video pulse in a sufficiently hel len pixel determined, and an adjusting device with which the phase is set so that the sampling time in about half a pixel width towards the center of the pixel is moved. 22. Device according to one of claims 16 to 18, characterized by a facility to the Ver phase for determining the sample value of the pixel push until the measured amplitude values no longer differ differ significantly, with the Ab sample value is processed further. 23. Device according to one of claims 16 to 18, characterized by a facility that the phase used in determining the sample value so far prefers until the measured amplitude values are less than one predetermined limit value, for example less than 50% of the Are sample and by a device that the phase then delayed by half a pixel width, the then measured sample value is processed further. 24. Device according to one of claims 16 to 18, characterized by a facility that the Phase for determining the rising edge as far in the direction Back porch area shifts until the measured amplitudes  value to a predetermined percentage, for example 50% of the previously determined amplitude value, the This value of the phase as the location of the rising edge temporarily is saved. 25. Device according to one of claims 16 to 18, characterized by a facility that the Phase for determining the falling edge so far in the direction of the front porch area until the measured Am to a predetermined percentage, for example wise 50% of the previously determined amplitude value, this value of the phase as the location of the falling edge between is saved.