DE19833597A1 - Pulse width modulated image display device e.g. for plasma display - Google Patents

Abstract

The pulse width modulated image display device (2), for a plasma display has an arrangement (10,11,12) for controlling a display device (14) such that the time interval (TG) provided for representing an image comprises overlapping time intervals (TG1,TG2). These time intervals are divided into several time successive partial time intervals. A brightness signal (4) associated with a pixel is generated by converting into a predetermined number of activation sequences which are present during one or more of the partial time intervals. The image display device (2) has spot reducing means (10). These provide the sequence and/or the activation sequence of the partial time intervals such that the spots on the images to be shown on the display device are minimised.

Description

The invention relates to a pulse width controlled image display device in particular a plasma display with control means for controlling a Display device according to the preamble of claim 1 and a Process for reducing flicker in pulse-width-controlled image displays according to the preamble of claim 9.

Such a method and device come for example in color plasma displays, which will be used in the future For example, currently still used in higher quality televisions Supplement or replace color picture tubes. In connection with Color picture tubes has been the user of high quality televisions since the end of 1980s, for example, due to the 100 Hz technology on one accustomed to flicker-free display.

From the magazine Radio Fernsehen Elektronik RFE, volume 2, 1997, pages 18-20 a plasma display is known, which consists of two glass plates with a matrix arranged electrodes, between which there is a noble gas mixture located. The image information is not line by line in plasma displays, such as for cathode ray tubes, shown, but full frame. There with one The plasma display does not display the individual pixels at any time can be switched on and off individually, the activation of the Pixels for the entire display in one activation pass respectively.

The control of a plasma display consists of several phases, one Addressing or an initialization, a hold or display and a deletion phase.  

During the addressing or initialization phase, all cells of the Plasma displays preloaded, which in the following holding or Activation phase to be activated. In the last step, the Deletion phase, the preloaded cells are unloaded again Image information is deleted.

For the display, the television picture is divided into a series of sub-pictures disassembled in part-time intervals of different durations one after the other being represented.

The object of the invention is an apparatus and a method of Specify the type mentioned above, which is a significant Reduces flicker.

This object is achieved by a device with the features of Claim 1 and a method having the features of claim 10 solved.

Advantageous embodiments of the invention are in the dependent Claims specified.

The invention is based on the finding that it is based on the representation a pulse width controlled display device for flickering, especially in the 50 Hz range, although currently Representation of a full picture in a time interval of 20 msec Part time interval frequency is 400 Hz. The same applies to systems in the 60 Hz range. However, the following is based on a 50 Hz system Invention described. Simulations have confirmed this finding where it has been shown that such flickering, which this is particularly noticeable with slow moving images can be reduced or at least significantly reduced by the Order of the part-time intervals and / or the activation sequences of the  Part-time intervals can be varied in a certain way. Such a variation aims to reduce the flickering on the To minimize display device images to be displayed.

To achieve a flicker-free display, it has proven to be proven to be advantageous, the activation sequences of the part-time intervals in to be distributed substantially evenly over the part-time intervals.

Different grayscales are generated by a suitable one Selection of the activated part-time intervals.

In practical applications, the number has proven to be advantageous of the activation sequences generated in the part-time intervals to twelve and set the number of part-time intervals to eight. The part-time intervals are divided into two overlapping part-time groups.

In a preferred embodiment is to display a full image a time interval of 20 msec is provided and the part-time interval frequency is therefore 400 Hz.

The corresponding tasks of the picture tube television sets The intended deflection control takes place with the pulse width controlled Image display device in such a way that the control means for Control of the display device has a time control device, processes the vertical and horizontal synchronization signals and the Time control of the pulse width modulator and a Controls the horizontal driver device of the display device.

In the following, the invention is illustrated by the figures Exemplary embodiments described and explained in more detail.  

Show it:

Fig. 1 is a block diagram of a television receiver with a pulse-width-controlled plasma display,

Fig. 2 shows an embodiment of a non-optimized part time interval pattern as a function of input signal level and part time interval weighting,

Fig. 3 a corresponding to the part time interval pattern of Fig. 2, graph for identifying the 50-Hz flicker as a function of the brightness and the input signal level,

Fig. 4 is a diagram of an interval for a particular input signal level as a function of the average brightness of the partial time intervals,

Fig. 5 shows an optimized part-time interval pattern and

FIG. 6 shows a diagram belonging to the part-time interval pattern from FIG. 4 for identifying the reduced 50 Hz flickering.

Fig. 1 shows a block diagram of a television receiver with a pulse width controlled plasma display. The television receiver 1 , 2 consists of a television signal processing part 1 and an image processing part 2 . The television signal processing part 1 has a first input 17 , to which the signals of an antenna device 19 are fed. The signals of the input 17 are forwarded to a high-frequency and intermediate-frequency processing unit 4 and an audio signal processing unit 3 . At the output of the RF signal processing unit is a so-called FBAS signal, which is fed to an analog / digital converter 5 . An external CVBS signal can be fed in via a second signal input 20 . The output signal of the analog / digital converter 5 is then passed to a so-called feature box 6 . The feature box 6 performs certain functions such as demodulation of the CVBS signal, still picture, zoom, format adaptation, image sharpness optimization, picture-in-picture, etc. The resulting digital components Y, U, V of an image signal 21 are forwarded to a digital matrix unit 8 of the image processing part 2 . The feature box 6 is also used to convert the interlaced signal into a progressively scanned signal and the necessary adaptation of the signals to the display by line interpolation. This is done using the synchronization signals 23 , 24 for vertical and horizontal synchronization. The digital matrix unit 8 also has a connection 27 for supplying a VGA signal supplied via an external signal input 18 , which is converted by means of an analog / digital converter 25 . At the output of the digital matrix unit 8 there is an RGB signal 23 which is used to control a pulse width modulator 10 . The pulse width modulator 10 generates the control signals 26 for an address driver 11 . A memory 9 is coupled to the pulse width modulator 10 for this signal generation. The pulse width modulator 10 has a part-time interval weighting unit, which is used to weight the part-time intervals. The address driver device 11 controls the individual columns of a plasma screen 17 line by line. The timing is controlled with the help of the timing control device 13 , which defines the start of the part-time intervals and the times for the addressing and activation phase. The part time interval line control device contained in the time control device serves for this purpose. The timing control device 13 is connected to a horizontal driver 12 . This horizontal driver 12 is active during the activation phase. Power is supplied using a power supply 7 .

While the mode of operation and the construction of the television signal processing part 1 essentially corresponds to that of a conventional television receiver with picture tube, the construction of the display processing part 2 is fundamentally different. The main reason for this is that the plasma display device 14 can only have a digital relationship between the input variable and the luminance. There are therefore only two states - switched on or switched off. In order nevertheless to be able to achieve a wide range of different intermediate gray levels, in the display processing unit 2 shown in FIG. 1 the image is represented by a digital time division multiplex method. For this purpose, the digital image components of the image signal components 23 are broken down into several part-time intervals of different durations. This is done with the aid of the pulse width modulator 10 and the further units controlling the pulse width modulator, such as a timing control device and a memory 9 . Due to the inertia of the human eye, individual image changes no longer appear on the plasma display device 14 , but a gray value arises which depends on the average activation time. If this duration is weighted in the part-time intervals, then many gray levels can be displayed with just a few part-time intervals. With a binary weighting (1, 2, 4, 8,...) Two grayscales can be shown exponentially with the number of part-time intervals. In order to be able to display as many gray levels as possible, it is therefore desirable to use as many part-time intervals as possible, but this is not possible due to technological constraints. The pulse width modulator 10 determines the activation of the individual part-time intervals by means of an assignment in accordance with a digital input signal 23 . In the case of a binary weighting, this assignment is such that the longest part-time interval is assigned to the digitally highest weighted bit, the second longest to the second highest weighted bit, etc.

Simulations as well as subjective considerations have shown that, despite a part-time interval frequency of 400 Hz, flickering artifacts of 50 Hz, particularly at medium luminance levels, can occur. The amplitude of the detected 50 Hz flickering varies with the luminance to be displayed and depends on the luminance level of the activated partial time interval and on its sequence within the 20 msec frame period: For this reason, the pulse width modulator 10 of the image display device 2 is controlled in such a way that the sequence the part-time intervals and their activation sequence are specified in a special way. The aim of the special way is to minimize the flickering of images to be displayed on the display device 14 .

Fig. 2 shows a diagrammatic representation of a weighted part time interval pattern as a function of input signal level and part time interval weighting. L denotes the luminance input level of the RGB signal designated 22 in FIG. 1. TG1, TG2 characterize the time interval TG available for an image display. The time intervals TG1, TG2 are divided into several successive partial time intervals t1 to t8. During the part-time intervals t1 to t8, the luminance signal L assigned to a respective pixel is generated by converting an analog brightness value into a predetermined number of activation times which are present during one or more of the part-time intervals t1 to t8. The number of activation times generated in the part-time intervals t1 to t8 is 12 in the exemplary embodiment shown in FIG. 2 and the number of part-time intervals t1 to t8 is 8, the part-time intervals t1 to t8 being divided into two overlapping part-time groups TG1, TG2, which each have an identical activation period.

FIG. 3 shows a diagram belonging to the part-time interval pattern from FIG. 2 for identifying a 50 Hz flickering as a function of the brightness H and the input signal level L. The course of the characteristic curve F, which characterizes the 50 Hz flickering, shows L in particular at input signal levels <30 an intensely occurring 50 Hz flickering: a maximum can be determined on the basis of this simulation result with an input signal amplitude of 44 as flicker value Fm.

FIG. 4 shows the course of the average brightness Hm for a special input signal amplitude level of 44 as a function of time t. The 50 Hz flicker disturbance can be clearly seen from the brightness curve Hv.

Fig. 5 shows a accordance with the teachings of the present invention optimized part-time interval pattern. The reference symbols already introduced in connection with FIG. 2 are used here. In contrast to the pattern shown in FIG. 2, the part-time interval pattern shown in FIG. 5 has a changed order of the part-time intervals t1 to t8: Thus, in the embodiment shown in FIG. 5, the order of the weights 12, 4, 8, 1, 2, 12, 4, 8, while the order of the weights in the partial time interval pattern shown in FIG. 2 is 12, 8, 4, 2, 1, 4, 8, 12.

FIG. 6 shows the simulation result for the partial time interval pattern shown in FIG. 5. The reference symbols already introduced in connection with FIG. 3 are used here. The simulation shows that the partial time interval pattern shown in FIG. 5 has a significantly reduced flicker course compared to the flicker course shown in FIG. 3, in particular also at higher input signal levels.

In summary, the invention thus relates to a method and a Device for reducing, for example, particularly disruptive 50 Hz flicker interference in pulse width controlled image display device. Such an image display device is, for example, a Color plasma display for displaying television pictures. The Color plasma display is controlled by a pulse width modulator, where the duration of a television picture in a series of Sub-images are broken down, which are displayed one after the other. For Flicker reduction, especially a 50 Hz flicker reduction proposed that to reduce flicker in the images to be displayed Order of the part-time intervals and / or the activation sequences in such a way be specified that the flickering of the images to be displayed is minimal. It is particularly advantageous to activate the activation sequences of the part-time intervals to pretend to be essentially uniform Distribution results.

Claims (10)

1. Pulse-width-controlled image display device ( 2 ), in particular a plasma display with control means ( 10 , 11 , 12 ) for controlling a display device ( 14 ), such that the time interval (TG) available for an image display consists of overlapping time intervals (TG1, TG2) exists, which are divided into several temporally successive part-time intervals (t1 to t8) and the brightness signal ( 4 ) assigned to a pixel is generated by conversion into a predetermined number of activation sequences which are present during one or more of the part-time intervals (t1 to t8), thereby characterized in that the image display device ( 2 ) has flicker reducing means ( 10 ) which specify the sequence of the part-time intervals (TG) and / or the activation sequences of the part-time intervals (t1 to t8) such that the flickering of images to be displayed on the display device ( 14 ) is minimal is. 2. Image display device according to claim 1, characterized, that the activation sequences of the part-time intervals (t1 to t8) in such a way be specified that there is a substantially uniform distribution results. 3. Image display device according to one of claims 1 or 2, characterized, that the predetermined number of activation times in each of the Part-time intervals (t1 to t8) are essentially an integral multiple of Activation duration in the shortest of the part-time intervals (t1 to t8).   4. Image display device according to one of claims 1 to 3, characterized, that the number of generated in the part-time intervals (t1 to t8) Activation sequences is 12 and that the number of part-time intervals (t1 to t8) is eight, with the part-time intervals (t1 to t8) being in two overlapping part-time groups (TG1, TG2) are divided, each have identical activation sequences. 5. Image display device according to one of claims 1 to 4 characterized, that a time interval of 20 msec is provided and that the part-time interval frequency is 400 Hz. 6. Image display device according to one of claims 1 to 5, characterized in that the image display device ( 2 ) has a digital matrix ( 8 ) which is provided for processing a digital image signal ( 21 , 27 ) and an output signal to the pulse width modulator ( 10 ) supplied RGB image signal provides. 7. Image display device according to one of claims 1 to 6, characterized in that the control means ( 10 , 11 , 12 , 13 ) for controlling the display device ( 14 ) have a timing control device ( 13 ) which vertical and horizontal synchronization signals ( 23 , 24 ) processed and controls the timing of the pulse width modulator ( 10 ) and a horizontal driver device ( 12 ) of the display device ( 14 ). 8. Image display device according to one of claims 1 to 7 characterized, the activation time of the part-time intervals (t1 to t8) in the ratio 4, 8.1, 2, 12, 4, 8 to each other. 9. Display method for reducing flicker in pulse-width-controlled image, at which the time interval available for an image display (TG) is divided into overlapping time intervals (TG1, TG2), which in split up several successive part-time intervals (t1 to t8) and in which the brightness signal assigned to a pixel by a number of. which can be specified within a part-time interval (t1 to t8) Activation sequences is generated, characterized, that to reduce the flicker of the images to be displayed, the order of the Part time intervals (t1 to t8) and / or the activation sequences of the Part-time intervals (t1 to t8) are specified such that the flickering of the images to be displayed is minimized. 10. The method according to claim 9, characterized, that the activation sequences of the part-time intervals (t1 to t8) in such a way be specified that there is a substantially uniform distribution results.