EP1484738A2 - Method and apparatus for improving the display of grey levels in a pulse width modulated display device - Google Patents

Abstract

Analyses full frame from RGB signal (22), horizontal synchronization signal (23) or vertical synchronization signal (24), to detect white areas above predetermined surface area, and if image integral brightness and/or maximum brightness value agrees with predetermined value. Image analyzer (34) outputs to sustain pulse limiter (32) to reduce number of sustain pulse per time interval or subfield of full image. Frame is input to pulse width modulator (10) and shown on display with sustain pulse correction. INDEPENDENT CLAIM included for a device to improve gray value in converted pulse width controlled image display.

Description

The invention relates to a method and a device for improving the Gray value display of a pulse width controlled image display device.

Such a method and device come for example for plasma displays, which will be used in future for higher-quality televisions Complement or replace color picture tubes still in use become. In connection with color picture tubes, the user is of higher quality TV sets since the late 80s due to the 100 Hz technology used to a 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-like arrangement There are electrodes between which there is a noble gas mixture. The image information is not displayed line by line in plasma displays like with cathode steel tubes, but full frame. As with a plasma display do not switch the individual pixels on and on individually at any time can be switched off, the activation of the pixels for the entire display in one activation pass

A plasma display is controlled in several phases: one Addressing or initialization phase, a hold or activation phase and a deletion phase.

In the addressing or initialization phase, all cells of the plasma display electrically pre-charged, which in the subsequent holding or Activation phase should be activated. In the last step, the deletion phase, the preloaded cells are discharged again, the image information is deleted.

The time interval available for displaying a television picture is in part-time intervals of different duration or different weighting disassembled during which depending on the brightness value of a particular A predetermined activation sequence is selected. This corresponds to one or more flashes of the respective pixel during the time interval available for image display, whereby a predetermined period of time is assigned to each lighting up.

Known plasma displays of this type are used, for example, by companies Fujitsu and NEC manufactured and distributed.

DE A1 198 33 597 describes a method and a device for reducing flicker known in pulse-width-controlled image display devices, especially with a color plasma display. Such a color plasma display is used, for example, to display television pictures. The color plasma display is controlled by means of a pulse width modulator, whereby for control the duration of a television picture in a series of partial pictures or Part-time intervals are broken down, which are displayed one after the other. to Flicker reduction, especially a 50 Hz flicker reduction, is the Order of the part-time intervals and / or the activation sequences of the Part-time intervals specified such that the flickering of the to be displayed Images is minimal.

Furthermore, DE-A1 198 37 307 describes a motion detector-dependent one Change in the order of the part-time intervals known. In the presence of Movements, the order of the part-time intervals is chosen such that Movement artifacts can be avoided. Otherwise the order is chosen the part-time intervals in such a way that 50Hz flicker interference is reduced become.

Furthermore, it is already known in connection with plasma displays that Detect the brightness of an image to be displayed from the detected brightness value a maximum for each of the part-time intervals of the image to be displayed derive permissible light duration and in the event of a change in the detected Brightness value the maximum permissible lighting duration for each of the part-time intervals to change. This change takes place in such a way that when detected dark picture content or low brightness value the maximum permissible lighting duration is increased by the same amount of time in each of the part-time intervals. results on the other hand, the brightness detection of the image to be displayed, that an overall If there is light image content, then the maximum permissible light duration for each of the part-time intervals decreased by a period of time for all part-time intervals is equal to.

A disadvantage of this procedure is that the contrast of what is to be displayed Image is reduced, since when the brightness of the object to be displayed is detected, Reduced the time for the display of bright image components is dark gray when the low brightness of an image to be displayed is detected Image components are shown in light gray, as these are described by the Applying a constant offset pulled upwards become, i.e. shine longer

Finally, DE 101 12 622 describes a method and a device for Improvement of the gray value resolution in a pulse width controlled image display device known. This will be available for an image display standing time interval in consecutive weighted part-time intervals split, with low-weight part-time intervals and part-time intervals with higher weighting are provided by evaluating the Brightness of an image to be displayed, that a dark image is present, then use of part-time intervals with higher weighting waived and instead the number of part-time intervals with low weightings by using additional part-time intervals with low Weightings increased, with the weightings of the additional part-time intervals from the weightings of the first part-time intervals with low Differentiate weights. This will improve the gray value resolution reached when dark images are present. A disadvantage of this method is that with commercially available plasma displays with integrated control Usually the assignment of those for the display of a certain gray value part-time intervals to be addressed in the inaccessible control circuit fixed, d. H. cannot be changed.

Color plasma displays also have a regulation to control the Power consumption on. The purpose of this regulation is to prevent the display from being destroyed protect by overheating. It is related to this Plasma displays are known to measure power consumption either by measurement of the sustainer current or by evaluating the brightness of a display Capture image. In the latter case, the captured Brightness value for each of the part-time intervals of the image to be displayed maximum permissible lighting time derived and when the detected Brightness value the maximum permissible lighting duration for each of the part-time intervals changed. This change takes place in such a way that when detected dark picture content or low brightness value the maximum permissible lighting duration is selected in each of the part-time intervals. On the other hand, results in the brightness detection of the image to be displayed that an overall bright image content is present, the maximum permissible lighting duration for each of the part-time intervals decreased by a period of time. The reduction in lighting time follows - in Dependence on the integral brightness of the image to be displayed - one Function that limits the output to the upper permissible value.

Regardless of whether the measure of performance is the sustainer current or is the integral brightness of the image to be displayed, the control is carried out by that the number of sustainer pulses per part-time interval is reduced to realize the power limitation at the upper limit. The reduction the number of sustainer pulses per part-time interval is proportional for the duration of a part-time interval

The big disadvantage of this approach is that at high brightness of the image to be displayed, the length of time for the display of bright image components is reduced, white then turns gray. At low brightness one In return, the image to be displayed becomes dark gray image components shown in light gray. This is particularly unpleasant in the image impression off if the brightness is low over the entire image area because then the brightness transitions between the individual gray levels are very large. For the image impression, this means that the step size between two brightness levels is very large. Images with low brightness over the entire image area appear too bright.

Based on this prior art, the object of the invention based on showing a way, as in a pulse width controlled image display device the gray value display while avoiding the from the Disadvantages known in the art can be improved.

This object is achieved by a method, the features of which are set out in the claim 1 are specified or by a device with the specified in claim 15 features

Advantageous refinements and developments of the invention result from the dependent claims.

By the method of claim 1 can be achieved that at relative dark pictures, without striking bright areas, the step size between the Brightness levels of two successive grayscale is reduced, which there is an optimized display for such image content without thus impairing the display of dark images with light areas goes hand in hand.

By means of the analysis options of the specified in claims 2 to 5 The image to be displayed becomes the equipment required for the image analysis kept within reasonable limits Further advantageous refinements and further developments result from the features of claims 6 to 10

By analyzing over several successive images according to Claim 11 can be achieved that when sudden changes occur The image content is adjusted in stages, which makes it more pleasant Picture impression arises. Particularly advantageous further developments are given by the features according to claims 12 and 13.

With the circuit arrangement according to claim 15 can be easily an improvement in the display of dark images without clear bright areas achieve further advantageous refinements of the circuit arrangement are characterized in claims 16 and 17.

Further advantageous properties of the invention result from the explanation an embodiment with reference to the figures.

Figur 1

ein Blockschaltbild eines Fernsehempfängers mit einer pulsbreitengesteuerten Plasmadisplayanzeige;

Figur 2 und 2a

beispielhafte Diagramme zur Erläuterung der Erfindung und

Figur 3 bis 4c

weitere beispielhafte Diagramme zur Erläuterung der Erfindung

It shows:

Figure 1

a block diagram of a television receiver with a pulse width controlled plasma display;

Figure 2 and 2a

exemplary diagrams for explaining the invention and

Figure 3 to 4c

further exemplary diagrams for explaining the invention

The method according to the invention and the arrangement are described below in Connection described with a television receiver, but not limited to this to be. Rather, they can be used in any application uses a pulse width controlled plasma display and image signals displays such. B Data monitors or video monitors with corresponding plasma displays.

Figure 1 shows a block diagram of a television receiver with a pulse width controlled Plasma display. The television receiver 1, 2 points a television signal processing part 1 and an image processing part 2. The TV signal processing part 1 has a first input 17, which the Signals of an antenna device 19 are supplied. The signals of the input 17 are connected to a high frequency and intermediate frequency processing unit 4 and an audio signal processing unit 3. At the Output of the high frequency and intermediate frequency processing unit 4 is an FBAS signal, which is fed to an analog / digital converter 5. An external CVBS signal is fed in via a second signal input 20 possible, other signals, e.g. B. RGB, Y / C, YUV etc. (not shown) can of course at appropriate points via additional circuits be fed into the circuit. The output signal of the Analog / digital converter 5 then becomes a so-called feature box 6 headed. The feature box 6 performs certain functions such as demodulation of the CVBS signals, still image, zoom, format adjustment, image sharpness optimization, Picture-in-picture, etc. The resulting digital components Y, U, V of an image signal 21 are sent to a digital matrix unit 8 of the image processing part 2 forwarded. The Feature Box 6 is also used for conversion the interlaced signal into an interlaced signal and the necessary Adaptation of the signals to the screen 14 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 feeding a VGA signal supplied via an external signal input 18, which is converted into a digital signal by means of an analog / digital converter 25 becomes. An RGB signal 22 is present at the output of the digital matrix unit 8 with which a pulse width modulator 10 is controlled. The between the digital matrix unit 8 and the pulse width modulator arranged image analyzer 34 and its operation is described in detail below.

The pulse width modulator 10 generates the control signals from the RGB signal 22 26 for an address driver 11. For this signal generation is with the Pulse width modulator 10 coupled to a memory 9. The pulse width modulator 10 has a part-time interval weighting unit which is used to weight the Serves part-time intervals, d. H. to determine their order and duration The address driver device 11 controls the individual columns of the Plasma screen 14 on. The associated time control is carried out using the Time control device 13, the start of the part-time intervals and the times for the addressing and activation phase. This is used in the time control included part-time interval line controller. The timing device 13 is connected to a horizontal driver 12. This horizontal driver 12 is active during the activation phases. The power supply takes place with the help of a power supply 7.

During the operation and construction of the television signal processing section 1 essentially that of a conventional television receiver with picture tube corresponds, the structure of the image processing part 2 is fundamentally different. The main reason for this is that the plasma display device 14 shows a digital relationship between the input variable and the Luminance has only two states: switched on or switched off. To still have a wide range of different To be able to achieve intermediate gray levels is shown in FIG. 1 Image processing part 2 for image display a digital time division multiplex method used. In this, the RGB signals 22 are in several part-time intervals of different duration, d. h in part-time intervals of different weightings.

This is done with the aid of the pulse width modulator 10 and the pulse width modulator controlling further units, such as the time control device 13 and a memory 9. Appear through the sluggishness of the human eye on the plasma display device 14 no longer individual image changes, but a gray scale value that depends on the average activation time. Is this duration weighted in the part-time intervals, then with a few part-time intervals many shades of gray are displayed. With a binary weighting (1,2,4,8, ...) can be grayscale two exponentiated with the number of part-time intervals become. In order to be able to display as many gray levels as possible, it is desirable to use as many part-time intervals as possible, which is is not possible due to technological constraints. The pulse width modulator 10 determined by an assignment based on its input signal level depends on the order for each pixel of the image to be displayed and activation of the individual part-time intervals. In the case of a binary Weighting this assignment looks such that the digitally highest weighted Bit the longest part-time interval, the second highest weighted bit that second longest part-time interval, etc. is assigned.

In Figure 2 is an exemplary sequence of such part-time intervals, such as during a full screen takes place. The time to display one Full screen is 20 milliseconds and is in eight part-time intervals, which is also called Subfields (SF1 to SF 8) are divided. The subfields or part-time intervals are weighted in binary, as already explained above. With such a weighting of "black" (minimum brightness) to "white" (maximum brightness) display a total of 256 gray levels.

The individual part-time intervals are broken down, as exemplified by the subfield SF 6 shown in an addressing phase 28 and a sustain phase 29. While The addressing phase 28 becomes all pixels of the plasma display device 14 addressed, which should light up in the subfield SF 6 The addressing the individual pixels are based on those already described above Wise. During the following the addressing phase 28 Actual activation of the display in the sustain phase 29 are by means of a sustain pulse generator 31, which is shown in FIG Horizontal driver 12 is included, one for the subfield - in the present Example of subfield SF 6 - specific number of sustain pulses generated. These sustain pulses then cause a corresponding light emission of the pixels that are addressed during this subfield SF 6 were.

In order to protect the plasma display device 14 from overheating, is in the Horizontal drivers 12 include a video level integrator 30 that is derived from the RGB signal 22 generates the integral of the full image and with an integral of the Signal corresponding to the full frame to a sustain pulse limiter 32, such that it is then limited to the sustain pulse generator 31 acts when that from the video level integrator 30 to the sustain pulse limiter 32 delivered signal exceeds a predetermined value. The The sustain pulses are limited in such a way that, as in FIG. 2a shown by way of example, the number of sustain pulses 29 in each subfield the maximum number of sustain pulses by a given one Percentage is reduced. This measure changes the weighting of part-time intervals or subfields among themselves, so the The number of gray values that can be displayed remains the same, but it becomes one in total Reduces the luminance of the plasma display device 14, and evenly across all representable gray values

The consequences of the procedure described above for the gray value display are shown below in connection with Figures 3 and 3a explained in more detail

Assuming a relatively dark picture on the plasma display device 14, a gray scale 33 is shown in FIG Range from minimum luminance to maximum luminance includes for simplification in the following it is assumed that the area has minimal luminance up to maximum luminance represented by 12 discrete gray values G1 to G12 can be. If there is now a comparatively darker picture, leads this means that the gray area 35 actually shown in the image is only the Grayscale G 1 to G 9 includes. The consequence of this is that the step size proportionate between the individual discrete brightness values G 1, G 2 etc. is large, which in turn causes the gray transitions to be very large are staged. If, on the other hand, there is a very bright image, as shown in FIG. 3a, the power limitation for the plasma display device described above 14 active. This makes the luminance that occurs uniform reduced, so that the white areas appear gray, the number of representable However, grayscale remains unchanged, i.e. H. there are still 12 discrete gray levels G1 to G12 can be displayed, however the brightness values are in Moved towards "black". This effect is consciously accepted around small white areas in an overall rather darker picture brilliant white to appear

In order to improve the overall gray value display, especially at such images that are relatively dark and beyond that not brilliant bright areas to be displayed is shown in Fig. 1, an image analyzer 34 is used, which consists of the RGB signal 22 and Horizontal synchronization signal 23 or the vertical synchronization signal 24 a full image to be displayed is analyzed as to whether white areas in the image emerge that are above a specified surface area and whether the image to be displayed in its integral brightness and / or in its maximum brightness value corresponds to certain predetermined values. In Dependence on the image analysis in the image analyzer described above 34 this generates an output signal with which it the sustain pulse limiter 32 applied to the effect that this via the sustain pulse generator 31st the number of sustain pulses per part-time interval or subfield of a frame reduced. The reduction of the sustain pulses per subfield happens z. B as a percentage of the maximum number of occurrences within a subfield Sustain pulses. The RGB signal of a full image analyzed in the image analyzer 34 is then given to the input of the pulse width modulator 10 for display and with the sustain pulse correction described above on the Plasma display device 14 brought to the display.

With this procedure, as shown in FIG. 4, it can be achieved that all representable gray values G1 to G12 in the direction of black, so that the gray area 35 actually shown in the image, that is, the Shift gray values G1 to G9 towards black. As a result, the Increment between two successive gray values e.g. B. G1 and G2 lower and the picture overall darker.

As shown in Fig. 4a, the effect described increases when the im Gray area 35 actually shown only up to gray value G6 is enough, so it shifts even further towards dark, the step size between two gray values z. B. G 1 and G2 then becomes even smaller.

Now, as shown by way of example in FIG. 4b, step in a dark image, that includes a gray area 35 that extends up to gray value G6, small bright ones Surfaces 36 on, so the image analyzer 34 detects and increased over the Sustain pulse limiter 32 and the sustain pulse generator 31 the number of Sustain pulses per part-time interval or subfield e.g. B. for all subfields within percentage of this full image, so that for the representation of the bright areas 36 a lighter gray value G 12 is available

As shown in FIG. 4c, the bright, in particular white areas 37 relative to the screen area larger, there is a need to the maximum representable gray value G 12 to the maximum luminance in order to to achieve a more brilliant representation of the light areas 37 Here enlarges of course again the step size between two successive gray values z. B. G 1 and G 2, but this, as already stated, in favor accepted a better representation of the bright areas.

If the proportion of light or white areas continues to increase, the higher-level area takes over Power limitation in effect already in connection with above 1 and 2 have been described

The image analyzer 34 described in connection with FIG. 1 offers the possibility of to analyze the image to be displayed according to all possible criteria and the sustain pulse limiter 32 as a function of the analysis result act that this in turn via the sustain pulse generator 31 Number of sustain pulses per part-time interval or subfield for within the to limit the part-time intervals or subfields that are analyzed that an improvement in the gray value display of dark images is achieved without affecting the display of light areas.

As already indicated, there is the possibility with the image analyzer 34 that image to be displayed with regard to the presence of bright image areas, the Brightness values of such bright picture areas, the area extension of such lighter image areas, the maximum brightness value outside of these bright picture areas and the integral brightness value of the picture investigate. Further investigation options are a matter of course possible. No matter whether all or only a part of the above is addressed Evaluation options are used in the image analyzer 34 or, in operative connection with the image analyzer 34, provide a memory, in which reference values relating to the image analysis are stored, the are compared with the values obtained by the image analyzer 34 from the image analysis wins, with the reference values then again being assigned control values with which the image analyzer 34 the sustain pulse limiter 32nd applied to the desired via this and the sustain pulse generator 31 Number of sustain pulses within the part-time intervals or Generate subfields of a full screen.

The exemplary described above in connection with FIGS. 1 to 4c Design of the method according to the invention or of the invention Arrangement can of course be made accessible to the person skilled in the art Measures are supplemented and expanded. For example, in Connection with the arrangement from FIG. 1 is easily conceivable, because an image analyzer 34 to be integrated into the feature box 6, since it is not for image analysis it is imperative to use the RGB signal 22.

Of course, this has been combined in order to simplify it with a gray value representation to the three methods described in to present the primary colors red, green, blue applied to a video image, this does not change the principle of operation.

An advantageous development of the invention consists in the analysis of several successive images in the sense of a temporal filtering perform. This allows z. B. achieve that brightness jumps in consecutive images do not cause an abrupt change in the number of the sustain pulses generated, but a gradual adjustment in the sense of a transition function

Claims (17)

Method for improving the gray value display in the case of pulse-width-controlled image display device, in which the time interval available for an image display is divided into successive differently weighted part-time intervals and the brightness signals associated with the pixels of the image to be displayed are generated by conversion in the part-time intervals, the activation sequences being generated in each case predetermined numbers of sustain pulses exist and the number of sustain pulses can be changed for all activation sequences which lie within a time interval for displaying an image,
characterized in that
the image brightness ratios of the image to be displayed are recorded in an analysis of the image to be displayed, the image analysis recognizing when images with predominantly dark image parts without larger bright image areas are to be displayed and then depending on the image brightness ratios determined a signal is generated which represents the number the sustain pulses for activation sequences which lie within the time interval for the display of the image, changed by a degree assigned to the determined image brightness conditions. Method according to claim 1
characterized in that
the maximum brightness occurring is determined in an analysis of the image to be displayed and, depending on the brightness found in each case, the number of sustain pulses for activation sequences which lie within a time interval for the display of an image is changed by a degree assigned to the brightness Method according to claim 1
characterized in that
In an analysis of the image to be displayed, it is determined whether there are areas in the image to be displayed, whose brightness and their surface area lie within predetermined value ranges and that, depending on the value range pairs found in each case, the number of sustain pulses for activation sequences occurs within a time interval for the display of an image are changed by a degree assigned to the value pairs Method according to claim 1
characterized in that
the maximum brightness that occurs is determined in an analysis of the image to be displayed, and that if the brightness falls below a predetermined maximum value, depending on the brightness found, the number of sustain pulses for activation sequences that lie within a time interval for the display of an image by one of the brightness assigned degree is changed and that if the predetermined maximum brightness value is exceeded, an analysis of the image to be displayed determines whether there are contiguous areas in the image to be displayed, whose brightness and their surface area lie within predetermined value ranges and that the number of values depends on the value range pairs found in each case Sustain pulses for activation sequences that lie within a time interval for the display of an image by a degree that is assigned to the value range pairs. Method according to one of claims 2 or 3 or 4,
characterized in that
in addition, the integral brightness of the image to be displayed is determined and compared with the largest individual brightness value appearing in the image to be displayed or the brightness value of the brightest surface appearing in the image to be displayed and the brightness difference is assigned to value ranges, which in turn are assigned degrees of change and that depending on the value range in the the difference in brightness lies, the number of sustain pulses already determined is changed by a degree assigned to this value range Method according to one of the preceding claims,
characterized in that
the change in the number of sustain pulses is reduced from a maximum number. Method according to one of the preceding claims,
characterized in that
the change in the number of sustain pulses for all activation sequences which lie within the time interval for the display of the image follows a predetermined function such that the function indicates the degree of change for each partial time interval Method according to claim 7,
characterized in that
the function is a linear function. Method according to claim 7,
characterized in that
the function is a logarithmic function Method according to claim 7,
characterized in that
the function is an empirically determined function Method according to one of the preceding claims,
characterized in that
the analysis of several successive images is carried out in the sense of a temporal filtering and that if there are sudden changes in successive images, the number of sustain pulses generated is changed in stages A method according to claim 11,
characterized in that
the gradual change in the number of sustain pulses generated follows a predetermined transition function Method according to claim 12,
characterized in that
the course of the transition function depends on the type of sudden change. Method according to one of the preceding claims,
characterized in that
the pulse-width-controlled image display device is a ready-made image display device that already contains the control circuits. Device for improving the gray value display in a made-up pulse-width-controlled image display device, with Control means (9-13) for dividing the time interval available for an image display into successive weighted partial time intervals and for generating brightness signals which are associated with the pixels of the image to be displayed, the control means (9-13) convert the activation sequences assigned to the time intervals , wherein the activation sequences consist of predetermined numbers of sustain pulses which are generated by a sustain pulse generator (31) which has an externally actuated input and via this input the number of sustain pulses for activation sequences which occur within a time interval for the display of an image, is changeable, with an image analyzer (34) for detecting the image brightness ratios of the image to be displayed, the image analyzer (34) recognizing whether images with predominantly dark image areas without larger bright image areas are to be displayed and then generating an output signal depending on the image parameters determined, with a sustain pulse limiter (32) which can be acted upon by signals from the image analyzer (34) via its input, such that the sustain pulse limiter emits a signal to the sustain pulse generator (31) so that the latter the number of sustain pulses for activation sequences which lie within the time interval for the display of the image to be displayed, changed by a degree predetermined by the signal. Device according to claim 15,
characterized in that
the image analyzer is acted upon by its inputs with the image signal (22) and image synchronization signals (23, 24) of an image to be displayed. Device according to claim 16,
characterized in that
the image signal is the RGB signal (22) and the image synchronization signal is the horizontal synchronization signal (23) and the vertical synchronization signal (24)

Images