The present invention relates to a method for processing data of a picture to be displayed on a display panel with persistent luminous elements in order to reduce load effect in said display means.
High contrast is an essential factor for evaluating the picture quality of every display technologies. From this perspective, a high peak-white luminance is always required to achieve a good contrast ratio and, as a result, a good picture performance even with ambient light conditions. Otherwise, the success of a new display technology requires also a well-balanced power consumption. For every kind of active display, more peak luminance corresponds also to a higher power that flows in the electronic of the display. Therefore, if no specific management is done, the enhancement of the peak luminance for a given electronic efficacy will lead to an increase of the power consumption. So, it is common to use a power management concept to stabilize the power consumption of the display. The main idea behind every kind of power management concept associated with peak white enhancement is based on the variation of the peak luminance depending on the picture content in order to stabilize the power consumption to a specified value as illustrated on
The concept described on
In the case of analog displays like Cathode Ray Tubes (CRTs), the power management is based on a so called ABM function (Average Beam-current Limiter), which is implemented by analog means, and which decreases video gain as a function of average luminance, usually measured over a RC stage. In the case of a plasma display, the luminance as well as the power consumption is directly linked to the number of sustain pulses (light pulses) per frame. As shown on
The computation of the Average Power Level (APL) of a picture P is for example made through the following function:
where I(x,y) represents the luminance of a pixel with coordinates (x,y) in the picture P, C is the number of columns and L is the number of lines of the picture P.
Then, for every possible APL values, a maximal number of sustain pulses is fixed for the peak white pixels for keeping constant the power consumption of the PDP. Since, only an integer number of sustain pulses can be used, there is only a limited number of available APL values. In theory, the number of sustain pulses that can be displayed for the peak white pixels can be very high. Indeed, if the picture load tends to zero, the power consumption tends also to zero, and the maximal number of sustain pulses for a constant power consumption tends to infinite. However, the maximal number of sustain pulses defining the maximal peak white (peak white for a picture load of 0%) is limited by the available time in a frame for the sustaining and by the minimum duration of a sustain pulse.
In addition, in order to achieve a high maximal peak white, the number of subfield is kept to a minimum ensuring an acceptable grayscale portrayal (with few false contour effects), the addressing speed is increased to a maximum keeping an acceptable panel behavior (response fidelity) and the sustain pulse duration is kept to a minimum but having an acceptable efficacy.
But, at this stage, PDP makers are faced with another problem called load effect explained below. As previously mentioned, a high peak white requires to be able to shorten the duration of a sustain pulse. However, this increase of the sustain frequency has a strong drawback: it increases load effect, especially, when the xenon percentage in the gas of the PDP cells is high. This effect is illustrated by
The line load effect itself represents a dependence of subfield luminance towards its horizontal distribution. In that case, it does not matter to know the load of the subfield but rather to know the differences of load between two consecutive lines for the same subfield.
When the subfield distribution is “geometrical”, e.g. for displaying artificial geometrical patterns, the line load effect is much more critical than for video pictures which suffer mainly from a global load effect.
Generally the load effect is not only limited to the line load but also to a global load of the subfield in a frame. Indeed, if a subfield is globally more used than another one on the whole screen, it will have less luminance per sustain pulse due to this load effect (the losses occur in the screen and in the electronic circuitry).
Therefore, on the one hand, a high number of sustain pulses and a high sustain frequency are required for peak white modes and, on the other hand, the panel will lose its homogeneity in case of peak white modes. This can have dramatic effects on natural scene as shown in
The load effect has an impact on the grayscale portrayal under the form of a kind of solarization effect which looks like a lack of gray levels. In that case, the right picture seems to be coded with fewer bits than the left one. This is due to the fact that some subfields are suddenly less luminous than they should be. In that case, if we consider two video levels that should have similar luminance, and if one of them is using such a subfield, its global luminance will be too low compared to the other video level introducing a disturbing effect.
An object of the method of the invention is to reduce the line load effect that is directly linked to the capacity of a line and not the global load effect that can be compensated by other methods. The method of the invention can be used independently to those methods when a PC mode is selected or in addition to one of them since they are compatible.
Globally, the invention is based on a profile analysis of the line load for each subfield to determine if this subfield is more or less critical to line load effect. If such a subfield is detected, its sustain frequency is reduced to minimize the load effect.
The invention relates to a method and a device for reducing such a load effect in a display panel with persistent luminous elements.
The invention concerns a method for processing data of a picture to be displayed on a display panel with persistent luminous elements during a frame comprising a plurality of subfields, each subfield comprising an addressing phase during which the luminous elements of the panel are activated or not in accordance with the picture data and a sustain phase during which the activated luminous elements are illuminated by sustain pulses. It comprises the following steps:
Preferably, the calculation of the maximal load difference is only carried out only for lines whose load is greater than a minimal load. This minimal load is for example equal to 10% of the amount of luminous elements in a line of the display panel.
In a particular embodiment, the maximal load difference between two consecutive lines of the display panel is calculated, for each subfield, on the current frame and a plurality of frames preceding said current frame in order to avoid changes in picture luminance when some minor modifications are happening. The maximal load difference used for selecting the sustain frequency is then the mean value of the maximal load differences calculated for said plurality of frames.
Preferably, the number of sustain pulses of each subfield is adjusted in accordance with the number of luminous elements to be activated for displaying the current picture and with the selected sustain frequency for said subfield.
According to the invention, the load effect can also be compensated by adjusting the number of sustain pulses of each subfield.
In that case, the method further comprises the following steps:
For adjusting the number of sustain pulses of a subfield, the method comprises the following steps:
In a preferred embodiment, the correction values of the subfields are defined by a look up table with the load and the number of sustain pulses of the subfields as input signals. The correction values stored in the look up table can be achieved in at least two different ways.
In a first embodiment, the corrections values are computed by:
In a second embodiment, since the attenuation does not much vary with the number of sustain pulses, it is also possible to compute the correction values for a specific number of sustain pulses. In this case, the correction values included in the look up table are achieved by the following steps:
In order to avoid measurement errors, the specific first number of sustain pulses is preferably greater than 20.
In an improved embodiment, the inventive method comprises further a step for rescaling the second numbers of sustain pulses of the plurality of subfields in order to redistribute in each subfield an amount of the subtracted sustain pulses proportionally to its second number of sustain pulses.
In another improved embodiment, before the step of adjusting the number of sustain pulses of each subfield on the basis of its load, said number of sustain pulses is rescaled in order that the average power level needed by the display means for displaying the picture be approximately equal to a fixed target value.
The invention concerns also a device for processing data of a picture to be displayed on a display panel with persistent luminous elements during a frame comprising a plurality of subfields, each subfield comprising an addressing phase during which the luminous elements of the panel are activated or not in accordance with the picture data and a sustain phase during which the activated luminous elements are illuminated by sustain pulses. It comprises:
The invention concerns also a plasma display panel comprising a plurality of persistent luminous elements organized in rows and columns and said device for reducing load effect.
Exemplary embodiments of the invention are illustrated in the drawings and are explained in more detail in the following description, the drawings showing in:
The method of the invention is based on an analysis of the line load of each subfield in order to determine if this subfield is more or less critical to the so-called “line load effect”. If such an effect is detected for a subfield, its sustain frequency is reduced to minimize the load effect.
In the presented embodiments, the frame comprises 11 subfields with the following weights:
1-2-3-5-8-12-18-27-41-58-80 (Σ=255)
In order to better understand the type of picture sequence sensitive to line load effect, two picture sequences are analyzed below. The first one is a video sequence not critical for line load effect and the second one is a computer sequence comprising geometrical patterns that is more critical for line-load effect.
Analysis of a Video Sequence
The video sequence shown on the left side of
There is a big difference in the global load of the subfields: the subfield SF7 is less loaded than its neighbors (SF1, SF2, SF3, SF4, SF5, SF6, SF8). This introduces a so-called solarization or quantization effect since the subfield SF7 will be proportionally more luminous than the other ones.
The distribution line by line of the global load of each subfield is represented by the
From this figure, it can be seen that the line loads for the subfields SF0, SF1, SF2, SF3, SF4, SF5 and SF7 are quite stable whereas there are more variations for the other ones. In any case, the maximal difference between two consecutive lines is 105. In that case, the load difference of luminance of one subfield between two consecutive lines is not very high and not a big problem. Therefore, in case of such pictures, the line load effect is not annoying.
Analysis of a Computer Picture (Mode PC) for Monitors
The computer picture shown at the left side of
In that sequence, the load of the various subfields is more homogeneous than in the case of the video sequence. The distribution line by line of the global load of each subfield is represented by the
In that sequence, the load effect manifests itself by an enhancement of the luminance of the background behind the dark area of the title as shown on
Sustain Frequency Adjustment
The main idea of the invention is to adjust the sustain frequency of each subfield in accordance with its load. More particularly, the line load difference between two consecutive lines is analyzed for each subfield and the sustain frequency of the subfield is selected in accordance with its maximal line load difference.
Preferably, the lines with a low load for the current subfield are not analyzed. Indeed, it makes no sense to evaluate the influence of the load of a subfield if this subfield is not enough used. Therefore, in the analysis of the difference between two consecutive lines, we limit the analysis to lines that have at least 10% of illuminated cells. This limit is referenced MinLoad.
Then, for each subfield, the line load difference Diff(L,n) between two consecutive lines L and L+1 for a subfield n is computed as following:
where Load(L,n) is the load of the line L for the subfield n.
The maximal line load difference for a subfield n, referenced MaxDiff(n), is then calculated: MaxDiff(n)=MAXfor all L (Diff(L;n)).
The maximal line load difference of each subfield n for the computer picture of
The sustain frequence of each subfield n is then adjusted depending on the value MaxDiff(n) as indicated by the curve of
Depending on these values, the sustain frequency of the displayed picture is then selected according to a predetermined table. When the maximal load difference is low, the line load effect is low and the sustain frequency can be high (e.g. 250 kHz). At the opposite, when the maximal load difference is high, the line load effect is high and the sustain frequency should be low (e.g. 200 kHz) to minimize it. It has to be noted that the load effect is also higher when the percentage of xenon is important in the gas of the cell.
In the invention, with a judicious choice of the sustain frequency, it is possible to reduce by a factor of two the load effect.
Such an adjustment of the sustain frequency should be made cautiously to avoid any brutal change of the picture luminance when minor changes of the picture are happening. Therefore, it is preferable to reduce the load effect slowly for example by means of a temporal filter.
Consequently, the maximal load difference MaxDiff(n;t) for a subfield n and a frame t is preferably filtered on T preceding frames to deliver a value MaxDiff′(n;t)as following:
When a new scene is detected, for example by a scene cut detection means, the value MaxDiff(n;t) on T preceding frames and MaxDiff′(n;t) is directly be taken as equal to MaxDiff(n;t).
The method of the invention can be implemented in parallel to a power management method as described previously, by the computation of an average power level for each picture, and used for modifying the total amount of sustain pulses in the frame and consequently for modifying the amount of sustain pulses of each subfield.
The act of optimizing the sustain frequency of each subfield modifies the available time to generate sustain pulses. Indeed, if the sustain frequency of a high weight subfield is reduced, the time to generate all its sustain pulses is longer and it can limit the peak-white value if there is not enough time to generate them. For instance, if the sustain frequency of the most significant subfield (subfield with the highest weight) is reduced from 250 kHz to 200 kHz, then the time required for the sustain pulses of this subfield is increased by 20%.
Therefore, it is necessary to modify the number of sustain pulses of each subfield in accordance with the selected sustain frequencies in order to have enough time to perform all the sustain pulses.
To this end, the operations illustrated by
Circuit Implementation
The input data comprise 10 bits in our example whereas the output data comprise 16 bits. The data are then processed by a block 12 for delivering an average power level APL(t) for each frame t with
as described previously.
In parallel, the data outputted by the degamma block 10 are processed by a dithering block 11 in order to obtain 8 bits data (24 bits for the 3 colors). The data delivered by the dithering block 13 are then processed by an encoding block 13 that converts them by means of a LUT into subfield data (11 bits data in the present case). The subfield data are then stored in a frame memory 14 and converted into serial data before being displayed by the display panel.
For implementing the method of the invention, the circuit comprises a computation block 15 that processes the data outputted by the dithering block 11. The block 15 computes, for each frame t and for each subfield n, the maximal load difference MaxDiff(n;t) between two consecutive lines of the panel. The value MaxDiff(n;t) is then time filtered by a filter 16 in order to obtain MaxDiff′(n;t). If no scene cut is detected, there is no filtering.
The value MaxDiff′(n;t) is used by a first LUT 17 to deliver a sustain frequency SustainFreq(n) for each subfield n in accordance with said MaxDiff′(n;t) value and as illustrated by
The value MaxDiff′(n;t) is also used by a LUT 18 for determining an adjustment coefficient Adj(n) for each subfield n as explained before. A multiplier 19 is then used for multiplying this coefficient by the maximal number of sustain pulses MaxSustainNb(n;t) in a frame and the result is the value MaxSustainNb′(n;t).
The maximal numbers of sustain pulses MaxSustainNb′(n;t) of all subfields are summed up in a block 20 as following:
Based on this new total amount of sustain pulses Sum(t), an inverse APL table 21 delivers the average power level APL′(t) as explained before. The maximal value between APL(t) and APL′(t) is then selected by a block 22. This value, APL″(t), is then used by an APL table 23 for delivering for each sub-field n the total amount of sustains SustainNb(n) that should be employed by the panel to display the picture t.
According to the invention, the load effect can also be compensated by adjusting the number of sustain pulses of each subfield. A correction value is calculated for each subfield. This value, depending on the load and the number of sustain pulses of the subfield, is subtracted to the number of sustain pulses of the subfield. These method can be combined with the adjustment of the sustain frequency of each subfield in accordance with its maximal load difference. This method can also be used independently.
Preferably, the subtracted sustain pulses are redistributed to the subfields proportionally to their new amount of sustain pulses in order to avoid a loss of luminance (a reduced peak luminance).
Preferably, the adjusting step is implemented after the computation of the picture load, for example by calculating the Average Power Level (APL), and after the rescaling of the number of sustain pulses of each subfield in order to keep constant the power consumption of the display panel.
In a facultative preliminary step, the numbers of sustain pulses of the subfields are rescaled, for example by APL as shown in
This method comprises three main steps:
This step consists in counting the luminous elements that are to be illuminated during each subfield for the picture to be displayed.
This step can be easily implemented by using, for each subfield, a counter counting the subfield data corresponding to luminous elements “ON”.
Adjusting Step of Sustain Pulses
This step leads in the definition of a number of sustain pulses for each subfield minimizing the load effect.
For a peak white value with 1080 sustain pulses, the number of sustain pulses of the highest weight subfield is 80/255*1080=339. So, in order to determine the attenuation of all subfields due to load effect, it is necessary to measure the panel luminance behavior from a minimum of 1 sustain pulse up to a maximum of 340 sustain pulses. Obviously, not all values have to be measured but rather a subset of values. The other values are calculated by interpolation since load effect is more or less a proportional effect.
The measurement is for example carried out on a square area of the screen. The picture load is made evolving from, for example, 8.5% up to 100%. The gray levels in this area are coded with only one subfield having successively all sustain pulses numbers of the subset. An example of measurement results is presented on the table below for only some measuring points (from 1 sustain pulse to 130 sustain pulses with load varying from 8.5% to 100%). The luminance behavior results are expressed in candela per square meter (cd/m2). The load is given vertically in the left column of the table and the number of sustain pulses is given horizontally in the top row of the table. This table comprises a reduced amount of values to simplify the exposition of the invention.
Based on this measurement step, the luminance efficacy can be computed for each number of sustain pulses and load to provide the efficacy of each subfield compared with the luminance for the lowest non-zero load (8,5% in the present case). The efficacy results are given in the table below the values of load and sustain pulses number of the previous table. In this table, the efficacy of 100% is allocated to the values obtained for a load of 8.5%.
A luminance attenuation representative of the load effect can be deduced from these efficacy values for each subfield:
Attenuation=100%−efficacy
The previous table shows that, in fact, the load effect is quite independent from the number of sustain pulses. Indeed, if we except the values obtained for the very low sustain pulses number where a lot of measuring failures could be done (because luminance is too low), it can be seen that globally the attenuation for a given picture load is quite stable. The efficacy can be approximated to the mean value (without taking into account the first values) for each. The left column of the table gives this mean value for each load.
The minimal efficacy (66.29%) is obtained for a load of 100%. It corresponds to a luminance attenuation of 33.71%.
In order to have an homogeneous luminance behavior of the subfield independently of the load, the invention proposes to adjust the number of sustain pulses per subfield to get an efficacy of 66.29% for each subfield. For example, for a subfield that should have 107 sustain pulses after rescaling by APL:
This adjustment step for a subfield SFn can be illustrated by the following equation:
NB2[SFn]=NB1(SFn)−Corr[SFn,Load(SFn)]
where
In the preceding step, the subfields are corrected to deliver a maximum of 66.29% of luminance. Consequently, the maximal peak luminance of the display is reduced.
According the invention, it is proposed to rescale the number of sustain pulses of each subfield by redistributing in each subfield an amount of the sustain pulses that have been removed during the preceding step proportionally to its new number of sustain pulses.
To this end, the correction values of all subfields are summed up by a counter. This sum is called CorrSum:
The redistribution of the subtracted sustain pulses can be illustrated by the following equation:
where NB3(SFn) is the number of sustain pulses of the subfield SFn after redistribution of the subtracted sustain pulses.
Circuit Implementation
where DIN are the input data,
DOUT are the output data, and
γ=2.2.
The input data comprise 10 bits in our example whereas the output data have 16 bits. The output data are summed up by an Average Power Measure Block 12 to deliver an Average Power Level (APL) as described previously. A first number of sustain pulses NB1(SFn) is determining for each subfield SFn by a Power management LUT 20 receiving the APL value in order that the average power needed by the PDP for displaying the picture be approximately equal to a predetermined target value.
The output data from the degamma block 10 are in parallel processed by a dithering block 11 to come back to a 8 bits resolution The data outputted by the dithering block 11 are coded in subfield data by an encoding block 13. The subfield data are then stored in a frame memory 14. The amount of active pixel Load(SFn) for each subfield SFn is computed by a load subfield block 21.
Based on Load(SFn) and NB1(SFn), a correction LUT 22 defines the correction value Corr(SFn,Load(SFn)) to be subtracted to the number of sustain pulses NB1(SFn). Another block 23 is used to achieve the following operation NB1(SFn)-Corr(SFn,Load(SFn)). The new number of sustain pulses of the subfield SFn is referenced NB2(SFn).
A block 24 is then used for redistributing the subtracted sustain pulses in all the subfields proportionally to their number of sustain pulses NB2(SFn) and achieves the following operation:
The numbers of sustain pulses are computed and used to control the PDP to display the subfield data stored in the frame memory 14 and converted in series.
The load effect compensation concept of the present invention is based on a LUT 22 having two inputs: the number of sustain pulses and the subfield load. It delivers the amount of sustain pulses that should be subtracted to the number of sustain pulses to obtain the same luminance than a full loaded subfield. Such a LUT is illustrated by
In the previously described example, the number of sustain pulses is going from 1 to 339. The table comprises 339 horizontal inputs. For achieving a precision of 6 bits for the load effect, the subfield load should be expressed with 6 bits. The table comprises 64 vertical inputs. The maximal correction that should be applied is linked to the value 339 that should be adjusted to an attenuation of 33,71% (in this case, 114 sustain pulses should be subtracted). This means that a precision of 7 bits is needed for the correction. In that case, the overall memory requirements will be around 339×64×7bits=148 kbits.
For each number of sustain pulses contained by the current subfield (1 to 339) and for each load of this subfield (measured with a step of 1.5%), the LUT 22 provides the exact amount of sustain pulses that should be subtracted from the original amount of sustain pulses.
The utilization of this table requires to compute, for each subfield, its global load (the number of activated luminous elements divided by the total amount of luminous elements). To this end, the load subfield block 21 comprises 11 counters (preferably, 16 counters are planned to cover up to 16 subfield modes), one for each bit of the subfield data and each of them being reset at each frame on the V sync pulse. Then, for each pixel, the appropriate subfield counter is incremented by the corresponding bit of the subfield data. Each counter is incremented by the value of the bit of the subfield data (0 if the subfield is not activated for the current video value and 1 if activated). If the three colors are handled serially (one color at a time with the same encoder), 11 counters are sufficient. Otherwise, if the three colors are encoded in parallel with three LUTs, we will have 33 counters. The size of the counters depends on the maximal amount of analyzed luminous elements: a WXGA panel comprises 1365×768×3=3144960 luminous elements which means a 22 bits counter (222=4194304). The outputs of the counters are limited to 7 bits since a precision of 7 bits for the subfield load computation is sufficient.
In order to improve the working of the circuit, it is possible to add a hysteresis function on the output value of the load subfield block 21 in order to avoid any jitter or oscillation. This corresponds to a kind of filtering of the value of the subfield load.
As this solution is based on a LUT and is fully independent to the subfield structure used, the hardware implementation is very reduced.
Number | Date | Country | Kind |
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03293194.1 | Dec 2003 | EP | regional |
03293195.8 | Dec 2003 | EP | regional |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP04/53440 | 12/14/2004 | WO | 5/7/2007 |