JP2003015589A - Display device and method for displaying gradation - Google Patents

Abstract

PROBLEM TO BE SOLVED: To improve image quality by improving image deterioration which is called 'moving image false contour, when making gradation display of each pixel of a display panel, such as a PDP(plasma display panel). SOLUTION: When the data of adjacently disposed pixels P11 and P12 are inputted as '01110' and '10001', as shown in Figure 2 (a), for example, onto a horizontal line of a PDP, a data converting part 20 converts the data of the pixels P11 and P12 into '01111' and '10000' respectively, as shown in Figure 2 (b) for odd-numbered fields, and meanwhile, converts the data of the pixel P11 and P12 into '10000' and '01111' respectively, as shown in Figure 2 (c) for even-numbered fields. Thus, a moving image false contour that occurs between the pixels P11 and P12 is dispersed and offset visually, so as to be able to reduce the moving image false contour.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a display device and a gradation display method for displaying a display panel such as a plasma display panel.

[0002]

2. Description of the Related Art A PDP display device for displaying gray scales of a plasma display panel (hereinafter referred to as PDP) in which pixels are formed in a matrix form a level adjustment for adjusting a level of an input video signal as shown in FIG. The section 11 and the A / D conversion section 12 for A / D converting the output of the level adjustment section 11 into 8-bit display data and the display data output from the A / D conversion section 13 for γ inverse correction described later. Γ inverse correction unit 13 for performing the above, a frame memory 14 for accumulating display data from γ inverse correction unit 13 for one frame, and a frame memory 14
An output processing unit 15 for outputting the display data of PDP1 to PDP1,
A sync separator 16 that separates a sync signal (vertical sync signal) from the input video signal, and timing of A / D conversion of the A / D converter 12 based on the vertical sync signal from the sync signal separator 16. Of the PDP 1 based on the timing pulse, a timing pulse generation unit 17 that generates a timing pulse that defines the timing pulse, a memory control unit 18 that inputs the timing pulse and controls reading of display data from the frame memory 14. Drive timing generator 1 that generates a timing signal that defines the display timing of each pixel
9 and 9.

When displaying a display panel using such a PDP 1 or a ferroelectric liquid crystal element, one frame display period corresponding to 1/60 second (a period for displaying one screen of the display panel: one field period) Is composed of a plurality of sub-fields having different relative ratios of the sustain emission period (proportional to the emission luminance), which is the lighting period of the pixel.

The example of FIG. 6 is an example in which one frame display period is composed of eight subfields SF1 to SF8, and 256 grayscales are displayed by eight grayscale bits. That is, the highest grayscale bit (8th bit) corresponds to the subfield SF8, the 7th grayscale bit to the subfield SF7, and the 6th grayscale bit to the subfield SF6. The 5th bit grayscale bit is the subfield SF5, the 4th bit grayscale bit is the subfield SF4, the 3rd bit grayscale bit is the subfield SF3, and the 2nd bit grayscale bit is the subfield. The lowest grayscale bit (first bit) corresponds to SF2, and corresponds to the subfield SF1.

As described above, the subfields SF1 to SF
8, the sustain emission period is 1 (= 2 ⁰ ) and 2 (= the number of gradations (relative ratio of emission luminance: proportional to the number of sustain emission pulses)).
2 ¹ ), 4 (= 2 ² ), 8 (= 2 ³ ), 16 (= 2
⁴ ), 32 (= 2 ⁵ ), 64 (= 2 ⁶ ), 128 (= 2
⁷ ) is weighted as

Here, each of the sub-fields SF1 to SF8
Has a scanning period in addition to the sustain emission period. In the scanning period of the subfield SF1, the display data is written to each pixel of the PDP 1 corresponding to the display data of the least significant bit (first bit). When the writing of the display data on the entire screen of the PDP 1 is completed, the sustaining light emission pulse is applied to the entire screen of the PDP once, for example, in the sustaining light emission period to cause only the written pixel to emit light.

Next, in the scanning period of the subfield SF2, the display data is written to each pixel corresponding to the display data of the second bit. When the writing of the entire screen of the PDP 1 is completed, the sustaining light emission pulse is applied to the entire screen of the PDP 1 twice, for example, in the sustaining light emission period, and only the written pixel is made to emit light. Hereinafter, for the sub-fields SF3, SF4, SF5, SF6, SF7, SF8, display data is written to each pixel according to the display data of the corresponding bit during the scanning period, and when this is completed, the next sustain emission is performed. During the period, the sustain emission pulse is 4, 8, 16, 32, 64 times, respectively.
The pixel is written 128 times, and only the pixels for which writing has been performed emit light.

[0008]

In such a PDP, when the subfields are simply arranged and displayed in the order of the emission luminance ratio, the binary values of the respective display data of the first and second adjacent pixels are respectively changed. For example, "01111111"
One more than this, the emission brightness increased and a carry occurred.
Therefore, when the first pixel emits light in the sub-fields SF1 to SF7 and the second pixel emits light only in the sub-field SF8, a moving image false is generated between the first pixel and the second pixel. Image quality deterioration called a contour occurs. Therefore, attempts are made to improve such image quality deterioration by changing the arrangement of subfields or changing the light emission luminance ratio of each subfield.
There is a problem that such methods cannot be expected to improve image quality.

Therefore, it is an object of the present invention to improve the image quality by improving the image quality deterioration called a moving image false contour when displaying the gradation of each pixel of a display panel such as a PDP.

[0010]

In order to solve such a problem, the present invention is provided with a display panel in which a plurality of pixels are arranged in a matrix, and one of the display panels is provided.
The field display period is divided into a plurality of subfields each having a weighted luminance ratio, and when a video signal is input, A / D conversion is performed and γ inverse correction is performed to obtain n-bit display data, and the value of the display data is set. In a display device which performs gradation display of the pixel by selecting a subfield according to, when each display data of an adjacent pixel is input, at least 3 bits consecutive from the upper bit to the lower bit side of the input display data are input. Of the display data of the same bit position in one and the other of the adjacent pixels is detected by detecting whether or not the data value of one of the adjacent pixels includes bits which become “011” and “100” in order from the upper bit. The values of the above are “011” and “10”, respectively.
When the brightness change is determined by the brightness change determining unit that determines the brightness change between the adjacent pixels when it becomes “0”, and the brightness change determining unit determines the value of the display data of the adjacent pixels in odd and even fields. And a data conversion unit for converting with different patterns according to the above.

In this case, in the data conversion unit, the value of the display data of one pixel of the one and the other pixels adjacent in the horizontal direction is the first value including the value "011", and the value "100". Including a second value that includes, a third value that includes the value “011” that is greater than the first value and less than the second value, and includes the value “100” that is greater than the third value and less than the second value. A fourth value and any one of a fifth value which is an average value of the third value and the fourth value, including any one of the values “011” and “100”, and When the value of the display data of the other pixel is one of the first to fifth values that is different from the display data value of the one pixel, in the odd-numbered field, The display data is converted so as to have the above values “011” and “100”, respectively, and The field is to convert as display data of the one and the other pixel is the value respectively "100" and "011".

Further, the data conversion unit has a first value in which the value of the display data of one pixel of the one pixel and the other pixel adjacent in the vertical direction includes the value "011", and the value "10".
A second value including "0", a third value including the value "011" greater than the first value and less than the second value, and a value "100" greater than the third value and less than the second value And a fourth value including, and any one of a fifth value which is an average value of the third value and the fourth value including any of the values “011” and “100”, And when the value of the display data of the other pixel is one of the first to fifth values that is different from the display data value of the one pixel,
In the odd line, the display data of the one pixel is converted into one of the values “011” and “100”, and in the even line, the display data of the other pixel is converted into the value “10”.
It is converted into the other one of "0" and "011".

Further, the data conversion unit includes a first value in which the display data values of the first and second pixels adjacent in the horizontal direction each include the value "011" and a second value in which the value "100" is included. The display data of the first and second pixels when the value is 0, and the third value which is a value between the first value and the second value in the odd field and the value between the third value and the second value. Is converted to any one of the fourth values, and in the even field, the other is converted to the other of the third and fourth values.

Further, the data conversion unit includes a first value in which the display data values of the first and second pixels adjacent in the vertical direction include the value "011" and a second value in which the value "100" is included. Of the display data of the first and second pixels, the odd-numbered line displays a third value which is a value between the first value and the second value and a value between the third value and the second value. Of the fourth value, which is the value of
And the other of the fourth values.

Further, the data conversion section includes a first value in which the display data values of the first and second pixels adjacent in the vertical direction include the value "100" and a second value in which the value "011" is included. Of the same bit position as the display data of the first and second pixels as the display data of the third and fourth pixels horizontally adjacent to the first and second pixels. When the display data having the third value each including the value “100” and the display data having the fourth value including the value “011” are input, or the first and second vertically adjacent values are input. The value of the display data of the second pixel is the first value including the value “011” and the second value including the value “100”, respectively, and
And a third pixel horizontally adjacent to the second pixel.
And as the display data of the fourth pixel, the first and second
When the display data having the third value including the value “011” and the fourth value including the value “100” are input to the display data of the pixel of FIG. , In the odd field, the display data of the first pixel is converted into the display data including the value “011”, and the display data of the third pixel is converted into the value “100”.
Is converted into display data including the value “100” and the display data of the third pixel is converted into display data including the value “01”.
It is converted into display data including "1".

Further, in the data conversion section, the values of the display data of the first and second pixels adjacent to each other are each the value "01".
In the case of the first value including 1 ”and the second value including the value“ 100 ”, the display data of the first and second pixels belonging to either one of the odd line and the even line in the odd field is displayed. Data conversion is performed so that the values “011” and “100” are exchanged, and in the even field, the display data of the first and second pixels belonging to the other of the odd line and the even line is changed to the values “011” and “0”. The data is converted so that "100" is replaced.

[0017]

DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described below with reference to the drawings. Generally, in a display device that displays a plasma display panel (hereinafter, PDP) or a display panel using a ferroelectric liquid crystal element, one frame display period (1
(1 field period which is a display period of the screen) is divided into a plurality of sub-fields each weighted by the sustain emission period, and the input analog video signal is A / D
The converted data is converted into digital data having the number of bits corresponding to the number of subfields, and the corresponding subfield of the PDP is caused to emit light by the subfield corresponding to the converted bit data to obtain an image of a predetermined gradation.

FIG. 1 is a block diagram showing the structure of a PDP display device to which the present invention is applied. In FIG. 1, this P
The DP display device includes a PDP 1, a level adjusting unit 11, and A
/ D conversion unit 12, γ inverse conversion unit 13, frame memory 14, output processing unit 15, synchronization separation unit 16, timing pulse generation unit 17, memory control unit 18, drive timing generation unit 19 , And a data conversion unit 20.

The level adjusting section 11 adjusts the level of the input video signal. The A / D conversion unit 12 A / D converts the level of the level-adjusted video signal and outputs it as 8-bit display data. The γ inverse correction unit 13 has eight components to maintain compatibility with the emission characteristics of the CRT.
The bit data is inversely corrected by γ. When the data of a plurality of adjacent pixels that have been subjected to γ inverse correction are input, the data conversion unit 20 detects a brightness change portion based on the input data and converts the brightness change portion so that the brightness change portion is averaged. The frame memory 14 stores the 8-bit data converted by the data converter 20.
The output processing unit 15 sets each data in the frame memory 14 to P
It is output to the data electrode as display data of each pixel of DP1.

The sync separator 16 separates the sync signal from the input video signal. Timing pulse generator 1
Reference numeral 7 is for generating various timing signals such as timings at the time of data conversion by the A / D conversion unit 12 and the data conversion unit 20 based on the vertical synchronization signal extracted by the synchronization separation unit 16. The memory control unit 18 outputs the display data in the frame memory 14 to the output processing unit 15 side based on the timing signal of the timing pulse generation unit 17. The drive timing generation unit 19 uses the timing signals from the timing pulse generation unit 17 and the memory control unit 18 to determine the above-mentioned subfield timing and P
A pulse signal for driving each scan electrode and sustain electrode of DP1 is generated.

In general, in this type of PDP display device, as is well known, an input video signal is A / D converted by an A / D converter 12.
After D conversion into 8-bit display data, γ inverse correction is performed to maintain compatibility with the emission characteristics of the CRT. In the present embodiment, the data conversion unit 20 detects, from each piece of data of the adjacent pixel after the γ inverse correction, a luminance change portion called a moving image false contour that causes a deterioration in image quality, and performs data conversion so that the luminance change is reduced. By doing so, the false contour of the moving image is reduced.

Further, in this embodiment, the A / D conversion unit 1
The 8-bit data of 256 gradations A / D converted by 2 is subjected to γ-inverse correction by the γ-inverse correction unit 13A, and the γ-inverse-corrected data has the number of gradations for each light emission period as shown in FIG. 1 (= 2 ⁰ ), 2 (= 2 ¹ ), 4 (= 2
² ), 8 (= 2 ³ ), 16 (= 2 ⁴ ), 32 (= 2
⁵ ), 64 (= 2 ⁶ ), and 128 (= 2 ⁷ ), P by 8 subfields SF1 to SF8
The gradation display of each pixel in DP1 is realized.

(First Embodiment) FIG. 2 is a diagram showing a first embodiment of a PDP display device, and is a diagram for explaining the data conversion operation of the above-mentioned data conversion unit 20. Figure 2
As shown in (f), the pixels P11 and P12 are sequentially arranged in the odd line n + 1 of the PDP 1, and the pixel P11, P12 is arranged in the even line n + 2 which is the line next to the line n + 1.
When the pixels P21 and P22 are sequentially arranged corresponding to P12, the binary value of each 8-bit display data of the adjacent pixels P11 and P12 is, for example, “01111111” in order from the higher bit, and the first floor from this. When the number of keys increases and a carry occurs, the pixel P11 emits light in the subfields SF1 to SF7, and the pixel P12 emits light only in the subfield SF8 having the largest number of gradations. , A vertical moving image false contour is generated between the pixels P11 and P12. The combination of such display data is the pixel P21 shown in FIG.
And P22 between them, a moving image false contour in the vertical direction similarly occurs between these pixels. Further, such a combination of display data is obtained by setting the pixels P11 and P shown in FIG.
Also between 21 and between pixels P12 and P22, a horizontal moving image false contour is generated between these adjacent pixels.

Further, the combination of display data of adjacent pixels in which such a false contour of a moving image is generated is not limited to the above-mentioned example of 8-bit data, but "0" for lower 7-bit data.
111111 "and" 1000000 ", and" 011111 "and" 100000 "for the lower 6-bit data,
"01111" and "10" for the lower 5 bit data
000 ”,“ 0111 ”for the lower 4 bits of data
And “1000”, and for the lower 3 bits of data, there are combinations of “011” and “100”. Further, for example, the lower 5 bit data “01” shown in FIG.
For example, 110 "and" 10001 "have consecutive upper three-bit data of 8-bit data, the data of one pixel is" 011 ", and the data of the other pixel is" 100 ".
Also in the case of the combination, the moving image false contour is generated between these adjacent pixels. When the display data of such a combination is input, the data conversion unit 20 determines that the luminance change between adjacent pixels is large.

Here, the pixels P11 and P12 of the odd line
When the low-order 5 bit data for use becomes “01110” and “10001” as shown in FIG. 2A including high-order 3 bit data “011” and “100”, respectively, the data conversion unit 20 determines that the odd field In Fig. 2
As in (b), data conversion is performed such that the data of the pixel P11 is increased by 1 gradation to be “01111” and the data of the pixel P12 is decreased by 1 gradation to be “10000”. In the even field, as shown in FIG. 2C, the data of the pixel P11 is increased by 2 gradations to “10”.
000 ”and the data of the pixel P12 is reduced by 2 gradations to obtain“ 01111 ”. As a result, the false contour of the moving image generated between the corresponding pixels P11 and P12 of the PDP 1 is visually diffused and canceled, and as a result, the false contour of the moving image can be reduced.

In the odd field, the data conversion section 20 increases the data of the pixel P11 by 2 gradations to "10000" as shown in FIG.
Data conversion is performed so that the data of 2 is reduced by one gradation to be “10000”. In the even field, as shown in FIG. 2E, the data of the pixel P11 is increased by 1 gradation to be “01111”, and the data of the pixel P12 is decreased by 2 gradations to be “01111”. Data conversion. As a result, the corresponding pixel P11 of PDP1,
The false contour of the moving image generated between P12 is visually diffused and canceled out similarly, and as a result, the false contour of the moving image can be reduced.

The lower 5 bit data for the pixels P21 and P22 on the even line n + 2 of the PDP 1 are shown in FIG.
When input as “01110” and “10001” as shown in (a), the data conversion unit 20 performs data conversion different from the data conversion in the case of the odd line n + 1.
That is, in this case, in the odd field, as shown in FIG.
Data conversion is performed in a pattern as shown in FIG. 2C or FIG.
Data conversion is performed in a pattern as shown in (b) or FIG. 2 (d). As a result, moving image false contours generated between the adjacent pixels P11 and P12 and between the adjacent pixels P21 and P22, as well as between the adjacent pixels P11 and P21 and between the adjacent pixels P12 and P22.
Similarly, the false contours of the moving image generated between 22 are visually diffused and canceled out, and as a result, the false contours of the moving image can be reduced. In this way, three or four conversion patterns including the conversion patterns shown in FIGS. 2 (b) and 2 (c) and the conversion patterns shown in FIGS. 2 (d) and 2 (e) are provided. By combining them, the false contour of the moving image can be similarly reduced.

FIG. 3A is a block diagram showing the configuration of the data conversion unit 20. The data conversion unit 20 is shown in FIG.
As shown in (a), a line memory 21 that stores data for each pixel on one line, a detection unit 22 that simultaneously detects data of adjacent pixels, and a data selector 23.
The data switches 24 and 25 and the delay units 26 to 28 are included.

Here, as shown in FIG. 3B, the PDP
Each pixel is arranged in the order of P11 and P12 on one horizontal line n + 1, and each pixel is P21 and P on the next horizontal line n + 2.
22 are arranged in this order, the data for each pixel that has been γ-inversely corrected by the γ-inverse correction unit 13 has pixels P11 and P1.
When the input data IN is input to the data conversion unit 20 in the order of 2, the input data IN is directly input to the detection unit 22 that detects the brightness change between adjacent pixels, and the delay unit 27 outputs 1 The input is delayed by the number of pixels.
As a result, the detection unit 22 has the pixel P via the delay unit 27.
The data for 11 and the data for the pixel P12 that is directly input without passing through the delay unit 27 are input at the same time. As a result, the detection unit 22 can simultaneously detect the data of the adjacent pixels P11 and P12 on the horizontal line n + 1 shown in FIG. Similarly, the horizontal line n +
The data of the two pixels P21 and P22 can be detected at the same time. That is, the detection unit 22 can simultaneously detect data of adjacent pixels in the horizontal direction and output the data to the data selector 23.

The data IN which has been subjected to the γ inverse correction by the γ inverse correction unit 13 is stored in the line memory 21. The data of each pixel of one line in the line memory 21 is directly input to the detection unit 22 when the data of the next line is output from the γ inverse correction unit 13, and also the delay unit 2
It is delayed by one pixel by 6 and input to the detection unit. At this time, the data of the next line is directly detected by the detection unit 22.
Is input to the detection unit 22 after being delayed by one pixel by the delay unit 27.

Therefore, after the data for each pixel on the line n + 1 is input to the data converter 20 in the order of the pixels P11 and P12, the data for each pixel on the next line n + 2 is sequentially transferred to the data converters in the order of pixels P21 and P22. 20 is input to the line memory 21.
Data of the pixel P11 after being stored in
The data of the pixel P12 is directly input after being delayed by the number of pixels and input to the detection unit 22. At this time, the data of the pixel P21 is input to the detection unit 22 via the delay unit 27, and the data of the pixel P22 is directly input without passing through the delay unit 27. Thereby, each pixel P11, P12, P2
The data of P1 and P22 are input to the detection unit 22 at the same time, and as a result, in the detection unit 22, the data of the pixels P11 and P21 and the data of the pixels P12 and P22 shown in FIG. That is, the data of adjacent pixels in the vertical direction can be simultaneously detected and output to the data selector 23.

In the data selector 23, for example, consecutive 3-bit data values of the adjacent pixels detected by the detecting section 22 are
When the values are “011” and “100” as described above, it is determined that the luminance change between the adjacent pixels is large, and the data switches 24 and 25 are controlled according to the dot clock signal, the horizontal synchronizing signal, and the vertical synchronizing signal. , The data from the line memory 21 is converted by the data switches 24 and 25 according to the patterns shown in FIGS. 2B and 2C described above, thereby performing data conversion of the horizontal adjacent pixel and the vertical adjacent pixel. . When the data selector 23 determines that the data values of the adjacent pixels detected by the detection unit 22 are values such as “011” and “100” described above, and the luminance change between the adjacent pixels is large, the data selector 23 The data from the line memory 21 is controlled by the data switches 24 and 25 by controlling the switches 24 and 25, as shown in FIG.
Data conversion of the horizontal adjacent pixel and the vertical adjacent pixel is performed by performing conversion in the pattern shown in FIG.

(Second Embodiment) FIG. 4 is a diagram showing a second embodiment of the PDP display device, and is a diagram for explaining the data conversion operation of the data conversion unit 20 described above. PDP
Each pixel of 1 is arranged in 6 rows and 6 columns as shown in FIG.
The value (luminance level value) of the lower 5-bit data of each pixel input to the data conversion unit 20 is the pixel P of the horizontal line n + 1.
11 to P16, pixels P21 to P2 on the horizontal line n + 2
6, “01111” in the pixels P51 to P56 of the horizontal line n + 5 and the pixels P61 to P66 of the horizontal line n + 6, and each pixel P31 of the continuous horizontal lines n + 3 and n + 4
Up to P36 and P41 to P46, the number of gradations is increased by one from the above "01111" and a carry occurs "10000".
In this case, since a horizontal moving image false contour is generated between each pixel of the horizontal lines n + 3 and n + 4 and each pixel of each adjacent horizontal line, the data conversion unit 20 causes the odd-numbered field and the even-numbered field. The above-mentioned moving image false contour is reduced by performing the following data conversion with and.

That is, in the odd field, the data value "1"
Pixels P31 to P36 on the horizontal line n + 3 of "0000"
Centered on the horizontal line n + as shown in FIG.
Pixels P21 and P2 on the horizontal line n + 2 adjacent to 3
3, the data value of P25 is "01111", horizontal line n
The data value of each pixel P22, P24, P26 of +2 is set to "1.
Each of the pixels P41, P43, P4 of the horizontal line n + 3 adjacent to the horizontal line n + 3.
The data value of 5 is "01111" and the data value of each pixel P42, P44, P46 of the horizontal line n + 4 is "1000".
Convert to 0 ". In the even field, the pixels P31 to P31 of the horizontal line n + 3 having the data value "10000"
As shown in FIG. 4C, each pixel P21, P of the horizontal line n + 2 adjacent to the horizontal line n + 3 with 36 as the center.
The data value of 23 and P25 is converted to "10000", the data value of each pixel P22, P24 and P26 of the horizontal line n + 2 is converted to "01111", and the horizontal line n + 3 is converted.
The pixels P41, P43, of the horizontal line n + 4 adjacent to
Data value of P45 is "10000", horizontal line n + 4
The data value of each pixel P42, P44, P46 of
11 ".

As described above, in each pixel of the data value "01111", the pixel of the data value "10000" in which the number of gradations is increased by one and the carry is generated from this data value is continuous in two horizontal lines. And then distributed (that is, the data value "1
Even if the “0000” pixels are continuously distributed in the vertical direction by two pixels), the above-described data conversion processing of the data conversion unit 20 causes the false contours of moving images between adjacent vertical pixels having different data values to be visually diffused similarly. These are offset, and as a result, false contours in the moving image can be reduced. It should be noted that, in each pixel of a certain data value, the pixels of the data value in which the number of gradations is increased or decreased from this data value to cause a carry or a carry are continuously distributed in two horizontal lines. Can be similarly applied to. In addition, the number of pixels having such a data value is 2
The same applies to the case of distribution on one vertical line.

(Third Embodiment) FIG. 5 is a diagram showing a third embodiment of the PDP display device, and is a diagram for explaining the data conversion operation of the above-mentioned data conversion unit 20. PDP
Each pixel of 1 is arranged in 6 rows and 6 columns as shown in FIG.
The values of the lower 5 bit data of each pixel input to the data conversion unit 20 are P11 to P14, P21 to P24, P31 to
P34, P41 to P43, P51 to P53, P61 to P
In the case of 62, the data value is “10000”, and in other pixels, when the data value is “01111” in which the number of gradations is decreased by one from the data value “10000” and a carry-down has occurred, the data values “10000” and “01111” are Vertical moving image false contours occur between adjacent pixels. Therefore, the data conversion unit 20 reduces the above-described false contour of the moving image by performing the following data conversion on the odd field and the even field.

That is, in the data converting section 20, in the odd field, the odd lines n + 1 and n + as shown in FIG.
Data conversion is performed so that the data values are exchanged with each other only for the two adjacent pixels in the luminance change portion of 3, n + 5, and in the even field, the luminance change portion of the even line n + 2, n + 4, n + 6 as shown in FIG. Data conversion is performed so that the data values of only two adjacent pixels are exchanged. In the odd field, the above data conversion is performed only on the even lines n + 2, n + 4, n + 6, and in the even field, the odd lines n + 1, n +.
Data conversion may be performed only for 3 and n + 5. By such data conversion processing, since the average value of the data values “10000” and “01111” is displayed on the two adjacent pixels in the brightness change portion of the PDP 1 as shown in FIG. The change in luminance between pixels is relaxed, and as a result, the false contour of the moving image can be reduced.

In the second and third embodiments described above, the data value of one of the adjacent pixels input to the data conversion unit 20 is "01111", and the data value of the other pixel is "10000". However, the combination of data of one side and the other side of the adjacent pixels is not limited to the above, and “01111111” and “100” for 8-bit data as described in the above-described first embodiment.
"00001", lower 7-bit data "0111111" and "1000000", lower 6-bit data "011111"
And “100000”, the combination of “0111” and “1000” for the lower 4-bit data,
And "011" and "10" for the lower 3 bits of data.
The data conversion unit 20 can perform the same data conversion even in the combination of "0".

Further, in the present display device, when the data of one and the other of the adjacent pixels are “01111111” (the number of gradations 127) and “10000000” (the number of the gradations of 128), the data of the one and the other of the adjacent pixels are shown. Is set to “01111111” in the odd field and “10000000” in the even field (the number of gradations is 12).
7.5) can be displayed, and in this case, "01101010" (the number of gradations is 106) in the odd field.
In the even field, the average value (the number of gradations 127.5) can be similarly displayed as “10010101” (the number of gradations 149). With this configuration, the moving image false contour generated between the adjacent pixels P11 and P12 is visually diffused and canceled in the same manner, and the moving image false contour is reduced.

Further, in this display device, the adjacent pixel P1
The data of 1 and P12 are, for example, "0111100".
In the case of 1 ”(the number of gradations 121) and“ 10000101 ”(the number of gradations 133), the data conversion unit 20 sets the data of the adjacent pixels P11 and P12 to“ 10000000 ”(the number of gradations 128) in the odd field. , "01111
010 ”(the number of gradations 122), and in the even field, the data of the adjacent pixels P11 and P12 are respectively changed to“ 011 ”.
10010 "(114 gradations)," 10010000 "
It can also be converted to (the number of gradations 144), and even by such data conversion, the moving image false contour generated between the adjacent pixels P11 and P12 is visually diffused and canceled in the same manner, and the moving image false contour is reduced.

In the present embodiment, as shown in FIG. 6, the light emitting periods are gradation numbers 1 (= 2 ⁰ ) and 2 (= 2), respectively.
¹ ), 4 (= 2 ² ), 8 (= 2 ³ ), 16 (= 2 ⁴ ),
Eight subfields SF1 to SF weighted as 32 (= 2 ⁵ ), 64 (= 2 ⁶ ), and 128 (= 2 ⁷ ).
Although the example in which the gradation display of each pixel in the PDP 1 is performed by 8 is described, the present invention is not limited to this example, and even when the number of subfields is changed and the emission luminance ratio of each subfield is changed. The same effect can be obtained by detecting the carry or the carry of the gradation based on the display data of the adjacent pixels and setting the converted data value to the corresponding value.

[0042]

As described above, according to the present invention, a display panel in which a plurality of pixels are arranged in a matrix is provided, and one field display period of the display panel is divided into a plurality of sub-pixels each weighted by a luminance ratio. When the video signal is divided into fields, A / D conversion and γ inverse correction are performed to obtain n-bit display data, and a subfield corresponding to the value of the display data is selected to select the sub-field of the pixel. In a display device that performs gray scale display, a brightness change determination unit that determines a brightness change between adjacent pixels based on display data of the adjacent pixels and a data conversion unit are provided, and the brightness change determination unit displays each display data of the adjacent pixels. When input, a data value of at least 3 bits consecutive from the upper bit to the lower bit of the input display data is output to one and the other of the adjacent pixels. Position in order respectively from the bit-side "01
Detects whether or not the bits that become "1" and "100" are included,
When the values of the display data at the same bit position in one and the other of the adjacent pixels become the values “011” and “100”, respectively, the change in brightness between the adjacent pixels is determined, and the data converter determines the change in brightness. When the change in brightness is determined by the determination unit, the values of the display data of the adjacent pixels are converted in different patterns according to the odd and even fields, so that each pixel of the display panel such as PDP is converted into a floor. In the case of the gray scale display, the false contour of the moving image is reduced, and the image quality of the display panel can be improved.

[Brief description of drawings]

FIG. 1 is a block diagram showing a configuration of a display device according to the present invention.

FIG. 2 is a diagram showing a first data conversion example by a display device.

FIG. 3 is a block diagram of a data conversion unit that performs data conversion.

FIG. 4 is a diagram showing a second data conversion example by the display device.

FIG. 5 is a diagram showing a third data conversion example by the display device.

FIG. 6 is a diagram showing an arrangement configuration of subfields in a display device.

FIG. 7 is a block diagram of a conventional PDP display device.

[Explanation of symbols]

1 ... PDP, 12 ... A / D conversion unit, 13 ... γ inverse correction unit,
14 ... Frame memory, 15 ... Output processing unit, 16 ... Sync separation unit, 17 ... Timing pulse generation unit, 18 ... Memory control unit, 19 ... Drive timing generation unit, 20 ... Data conversion unit, 21 ... Line memory, 22 ... Detection unit, 23 ... Data selector, 24, 25 ... Data switch, 26-28
... Delay unit, P11 to P16, P21 to P26, P31 to
P36, P41 to P46, P51 to P56, P61 to P
66 ... Pixels.

─────────────────────────────────────────────────── ─── Continuation of front page (51) Int.Cl. ⁷ Identification code FI theme code (reference) H04N 5/66 101 G09G 3/28 K

Claims (14)

[Claims] 1. A display panel having a plurality of pixels arranged in a matrix, wherein one field display period of the display panel is divided into a plurality of subfields each weighted by a luminance ratio, and a video signal is input. A /
In a display device that performs D conversion and γ inverse correction to obtain n-bit display data, and also performs gradation display of the pixel by selecting a subfield according to the value of the display data, When display data is input, a data value of at least 3 bits consecutive from the upper bit to the lower bit of the input display data is “011” and “10” in order from the upper bit in one and the other of the adjacent pixels, respectively.
It is detected whether or not a bit that becomes "0" is included, and when the values of the display data at the same bit position in one and the other of the adjacent pixels become the values "011" and "100", respectively, between the adjacent pixels. A brightness change determination unit that determines a brightness change, and when the brightness change determination unit determines a brightness change, data that converts the display data value of the adjacent pixel into a different pattern according to each of odd and even fields. A display device comprising: a conversion unit. 2. The data conversion unit according to claim 1, wherein the value of the display data of one of the one and the other of the pixels adjacent in the horizontal direction is the first value including the value “011”, A second value including the value “100”, a third value including more than the first value and less than the second value “011”, and more than the third value and less than the second value "10
A fourth value including "0" and the values "011" and "10"
0 ”, which is any one of the fifth value which is the average value of the third value and the fourth value, and the value of the display data of the other pixel is the first value. If the display data value of the one pixel is different from the display data value of the one pixel among the fifth values, the display data of the one and the other pixels in the odd field are the values “011” and “100”, respectively. The display device is characterized in that the display data of the one and the other pixels are converted to the values “100” and “011”, respectively, in an even field. 3. The data conversion unit according to claim 1, wherein the value of the display data of one of the one and the other of the pixels adjacent in the vertical direction is the first value including the value “011”, A second value including the value “100”, a third value including more than the first value and less than the second value “011”, and more than the third value and less than the second value "10
A fourth value including "0" and the values "011" and "10"
0 ”, which is any one of the fifth value which is the average value of the third value and the fourth value, and the value of the display data of the other pixel is the first value. Through the fifth value, the display data of the one pixel is set to one of the values “011” and “100” in the odd line when the display data value of the one pixel is different from the display data value of the one pixel. A display device, wherein the display data is converted into one and the display data of the other pixel is converted into the other one of the values “100” and “011” in an even line. 4. The data conversion unit according to claim 1, wherein the values of the display data of the first and second pixels adjacent in the horizontal direction each include the value “011” and the value “ The display data of the first and second pixels is set to the second value including 100 ", and the third value and the third value which are values between the first value and the second value in the odd field. And a fourth value which is a value between the second value and the second value, and in the even field, the third value and the fourth value are converted into the other. 5. The data conversion unit according to claim 1, wherein the display data values of the first and second pixels that are vertically adjacent to each other include the first value and the value “011”, respectively. The display data of the first and second pixels is set to the second value including 100 ", and the third and third values which are values between the first value and the second value on the odd line. And a second value, which is one of the fourth values, and an even line is converted to the other of the third and fourth values. 6. The data conversion unit according to claim 1, wherein the display data values of the first and second pixels adjacent in the vertical direction each include the first value and the value “100”. 011 ”as the second value and is the display data of the first and second pixels as the display data of the third and fourth pixels that are horizontally adjacent to the first and second pixels, respectively. When the display data having the third value including the value “100” and the display data having the fourth value including the value “011” are input, respectively, or the vertical direction. First and second adjacent to
The values of the display data of the pixels are the first value including the value “011” and the second value including the value “100”, respectively, and are horizontal to the first and second pixels, respectively. As display data of the adjacent third and fourth pixels,
Display data in which the values of the same bit positions as the display data of the first and second pixels each have a third value including the value "011" and a fourth data including the value "100". Is input, the display data of the first pixel is converted into the display data including the value “011” and the display data of the third pixel is converted into the display data including the value “100” in the odd field. However, in the even field, the display data of the first pixel is set to the value “100”.
And a display data of the third pixel is converted into display data including the value “011”. 7. The data conversion unit according to claim 1, wherein the values of the display data of the first and second pixels adjacent to each other include the value “011” and the value “10”.
In the case of the second value including “0”, the display data of the first and second pixels belonging to either the odd line or the even line in the odd field is set to the values “011” and “100”.
And data are converted so that the display data of the first and second pixels belonging to the other of the odd line and the even line in the even field are switched so that the values “011” and “100” are switched. A display device characterized by conversion. 8. A display panel in which a plurality of pixels are arranged in a matrix is provided, and one field display period of the display panel is divided into a plurality of subfields each weighted with a luminance ratio, and a video signal is input. A /
A gradation display method in a display device which performs D conversion and γ inverse correction to obtain n-bit display data, and also performs gradation display of the pixel by selecting a subfield according to the value of the display data. Then, when each display data of the adjacent pixel is input, a data value of at least 3 bits continuous from the upper bit to the lower bit side of the input display data is sequentially read from the upper bit side in one and the other of the adjacent pixels. 011 ”and“ 10
It is detected whether or not a bit that becomes "0" is included, and when the values of the display data at the same bit position at one and the other of the adjacent pixels become "011" and "100", respectively, the brightness between the adjacent pixels. When a luminance change is determined based on the first step of determining a change and the process of the first step, the value of the display data of the adjacent pixel is converted into a different pattern according to each of odd and even fields. And a second step of performing the gradation display method. 9. The processing according to claim 8, wherein in the process in the second step, the value of the display data of one pixel of the one and the other of the pixels adjacent in the horizontal direction includes the value “011”. Value, a second value including the value "100", a third value including more than the first value and less than the second value "011", more than the third value than the second value The less the above value "10
A fourth value including "0" and the values "011" and "10"
0 ”, which is any one of the fifth value which is the average value of the third value and the fourth value, and the value of the display data of the other pixel is the first value. If the display data value of the one pixel is different from the display data value of the one pixel among the fifth values, the display data of the one and the other pixels in the odd field are the values “011” and “100”, respectively. Gradation display characterized by including a third step of converting the display data of the one and the other pixels into the values “100” and “011”, respectively, in an even field. Method. 10. The process according to claim 8, wherein in the process in the second step, the value of the display data of one pixel of the one pixel and the other pixel adjacent in the vertical direction includes the value “011”. Value, a second value including the value "100", a third value including more than the first value and less than the second value "011", more than the third value than the second value The less the above value "10
A fourth value including "0" and the values "011" and "10"
0 ”, which is any one of the fifth value which is the average value of the third value and the fourth value, and the value of the display data of the other pixel is the first value. Through the fifth value, the display data of the one pixel is set to one of the values “011” and “100” in the odd line when the display data value of the one pixel is different from the display data value of the one pixel. A gradation display method comprising a fourth step of converting the display data of one pixel into the other one of the values “100” and “011” on an even line. 11. The processing according to claim 8, wherein in the processing in the second step, the display data values of the first and second pixels adjacent in the horizontal direction each include the first value including the value “011”, and When the second value includes the value “100”, the display data of the first and second pixels is displayed, and in the odd field, the third value and the third value which are values between the first value and the second value. A fifth step of converting into one of a fourth value which is a value between the third value and the second value and converting into the other of the third and fourth values in the even field. A gradation display method characterized by. 12. The process according to claim 8, wherein the processing in the second step includes: a first value in which display data values of first and second pixels adjacent in the vertical direction include the value “011”; When the second value includes the value “100”, the display data of the first and second pixels is displayed, and on the odd line, the third value and the third value which are values between the first value and the second value. A sixth step of converting to one of a fourth value which is a value between the third value and the second value and converting to the other of the third and fourth values on the even line. A gradation display method characterized by. 13. The processing according to claim 8, wherein in the processing in the second step, display data values of first and second pixels vertically adjacent to each other include a first value including the value “100” and The display data of the third and fourth pixels, which is a second value including the value “011” and adjacent to the first and second pixels in the horizontal direction, is used as the display data of the first and second pixels. When the display data having the third value including the value “100” and the fourth value including the value “011” are input to the pixel at the same bit position as the display data of the pixel, or , Vertically adjacent first and second
The values of the display data of the pixels are the first value including the value “011” and the second value including the value “100”, respectively, and are horizontal to the first and second pixels, respectively. As display data of the adjacent third and fourth pixels,
Display data in which the values of the same bit positions as the display data of the first and second pixels each have a third value including the value "011" and a fourth data including the value "100". Is input, the display data of the first pixel is converted into the display data including the value “011” and the display data of the third pixel is converted into the display data including the value “100” in the odd field. However, in the even field, the display data of the first pixel is set to the value “100”.
And a display data of the third pixel is converted into display data including the value “011”.
A gradation display method comprising the step of. 14. The processing according to claim 8, wherein in the processing in the second step, the first value and the value “1” in which the values of the display data of the first and second pixels adjacent to each other include the value “011”, respectively. 10
In the case of the second value including “0”, the display data of the first and second pixels belonging to either the odd line or the even line in the odd field is set to the values “011” and “100”.
And data are converted so that the display data of the first and second pixels belonging to the other of the odd line and the even line in the even field are switched so that the values “011” and “100” are switched. A gradation display method comprising an eighth step of converting.