KR100471972B1 - Gray Scale Display Apparatus for Plasma Display Panel and Method thereof - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a gradation display device of a plasma display panel and a method thereof, and more particularly to a gradation display device of a plasma display panel, wherein a gradation display device of a plasma display panel includes a plurality of subfields having luminance specific gravity arranged in chronological order. A gray level display device of a plasma display panel which determines a number of the subfields according to an average signal level of image data, comprising: an automatic power controller configured to detect an average signal level of each field of image data; First and second frame memories capable of storing the image data for even and odd frames; The image data output from the automatic power controller is mapped according to the number of subfields determined by the average signal level detected by the automatic power controller to generate corresponding grayscale data and selectively store the gray scale data in the first and second frame memories. A subfield generator; An address data generator for generating address data corresponding to the subfield data output from the subfield generator and applying the address data to the plasma display panel; The number of subfields determined by the average signal level of the current field output from the automatic power controller is compared with the number of subfields determined by the average signal level of the previous field, and when the number of the compared subfields is different, the current field. An average signal level adjusting unit for selecting and outputting one of the average signal level of the current field and the average signal level of the previous field according to a difference between the average signal level of the average field and the average signal level of the previous field; And a sustain scan pulse generator configured to generate sustain pulses and scan pulses corresponding to the average signal levels adjusted and output by the average signal level adjuster, and apply the sustain pulses and scan pulses to the plasma display panel. According to the present invention, by adjusting the number of subfields using a high correlation between video signal frames, automatic power control inconsistencies generated at the subfield boundary when applying a variable subfield algorithm without using a field memory can be prevented. have. In addition, since no field memory is used, the cost is reduced, and the complexity of the structure is also reduced.

Description

Gray scale display device for plasma display panel and method thereof {Gray Scale Display Apparatus for Plasma Display Panel and Method}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a plasma display panel, and more particularly, to automatic power control (APC) generated when a variable subfield (VSF) algorithm is applied without using field memory in a plasma display panel. The present invention relates to a gray scale display device of a plasma display panel that eliminates mismatches, and a method thereof.

A plasma display panel is a type of display element that recovers image data input as an electric signal by arranging a plurality of discharge cells in a matrix shape and selectively emitting them.

In order to show performance as a color display element in such a plasma display panel, gray scale display should be possible. As a method of implementing the gray scale display, a gray scale display method of dividing one field into a plurality of subfields and controlling the time division is used.

In the general gray scale display method, the number of subfields is fixed regardless of the image data. However, in the gray scale display method using the variable subfield method, the average signal level of an image signal of one field is referred to as ASL. The number of subfields is determined, and the input image data is mapped and stored in the field memory according to the determined number of subfields. Since the ASL is determined only when all of the image data of one field is input, a field memory to store this data is necessary while determining the ASL of the image data which is continuously input.

1 is a block diagram of a gray scale display device using a variable subfield method in a conventional plasma display panel.

As shown in FIG. 1, the gradation display device using the variable surf field method includes an image signal processor 10, a gamma correction and error diffusion unit 20, an automatic power controller 30, and first and second field memories. 40 and 50, a subfield generator 60, first and second frame memories 70 and 80, an address data generator 90, and a sustain scan pulse generator 100.

The image signal processor 10 digitizes an image signal input from the outside to generate digital image data.

The gamma correction and error diffusion unit 20 receives digital image data output from the image signal processing unit 10, corrects a gamma value according to the characteristics of the plasma display panel 110, and simultaneously diffuses a display error with respect to surrounding pixels. Outputs the output.

The automatic power controller 30 selectively stores the image data output from the gamma correction and error diffusion unit 20 in the first and second field memories 40 and 50 according to the even field or the odd field. Detect ASL. The ASL may be determined after image data is stored in each of the field memories 40 and 50.

The subfield generator 60 selectively stores the image data output from the automatic power controller 30 in the first and second frame memories 70 and 80 and then generates the subfield data corresponding to each image data. do.

The address data generator 90 generates address data corresponding to the subfield data output from the subfield generator 60 and applies the address data to the address electrodes A1, A2,... Am of the plasma display panel 110. .

The sustain scan pulse generator 100 receives the ASL output from the automatic power controller 30 and generates corresponding sustain pulses and scan pulses to scan electrodes X1, X2, .. Xn of the plasma display panel 110. And sustain electrodes Y1, Y2, ..., Yn.

In order to detect the ASL of the currently input field when the variable subfield is implemented, it may be known by examining image data values of the entire field.

Therefore, in order to know the ASL of one field, the image data value input through the image signal processing unit 10 should be examined. The image data input during the one field may be input to the first field memory 40 or the second field memory 50. ), The automatic power control unit 30 detects the ASL of the corresponding field.

When the ASL of one field is determined as described above, the subfield generator 60 reads image data stored in the first field memory 40 or the second field memory 50 to generate subfield data corresponding to the ASL. And store it in the first frame memory 70 or the second frame memory 80 again, and then, at the next field time, the address data generator 90 is stored in the first frame memory 70 or the second frame memory 80. The stored subfield data is read, the corresponding address data is generated, applied to the address electrodes A1, A2, ..Am of the plasma display panel 110, and the sustain scan pulse generator 100 is automatically controlled by the automatic power controller. In response to the ASL output from 30, corresponding sustain pulses and scan pulses are generated to generate scan electrodes X1, X2,... Xn and sustain electrodes Y1, Y2, .., Yn of the plasma display panel 110. Plasma display The image corresponding to the panel 110 is implemented.

However, in the related art, the first field memory 40 and the second field memory 50 which store corresponding image data while examining the image data of the entire field to detect the ASL of the field currently input when the variable subfield is implemented. Has to be necessary, there is a problem in that the cost for implementing the variable sub-field is expensive, and the structure is complicated.

To solve this problem, the first field memory 40 and the second field memory 50 are removed, and the image data output from the image signal processor 10 and the gamma correction and error diffusion unit 20 is automatically controlled. A method for detecting the ASL of the current field while 30 directly stores in the first frame memory 70 and the second frame memory 80 has been proposed.

At this time, the image data stored in the first frame memory 70 and the second frame memory 80 is stored according to the number of subfields determined using the ASL of the previous field since the ASL of the current field has not yet been detected.

In this method, the following problems arise and will be described in detail with reference to the drawings.

FIG. 2 is a diagram schematically illustrating a method of displaying grayscale using a variable subfield method in a conventional plasma display panel.

As shown in FIG. 2. In the n-1 th field, the n-1 th field data D _n-1 is input to the first frame memory 70 through the automatic power control unit 30, and the n-1 th field data D _n-1. ) ASL of the n-1 th field data D _n-1 at the time when the input is completed, that is, when the n-1 th field data D _n-1 is stored in the first frame memory 70, That is, ASL _n-1 is determined by the automatic power control unit 30. In the nth field and the n + 1th field, as in the n-1th field described above, ASL _n which is the ASL of the _nth field data D _n and ASL which is the ASL of the n + 1st field data D _{n + 1} . _{n + 1} is determined.

On the other hand, each field data (D _n-1 , D _n , D _{n + 1} ) are divided into even and odd fields and are alternately stored in the first frame memory 70 and the second frame memory 80, respectively. At this time, each field data D _n-1 , D _n , D _{n + 1} is subfield-mapped according to the ASL determined in the previous field and stored in the corresponding frame memories 70 and 80.

For example, the n-th field data D _n is subfield-mapped according to the number of subfields determined by ASL _n-1 determined in the n-1th field and stored in the second frame memory 70, and n The +1 th field data D _{n + 1} is subfield mapped according to the number of subfields determined by ASL _n determined in the n th field and stored in the first frame memory 80.

Meanwhile, in each field, the sustain operation on the plasma display panel 110 is performed according to the number of subfields determined by ASL determined in the previous field by reading data stored in the previous field.

For example, in the nth field, the n-1th field data D _n-1 stored in the first frame memory 70 is read in the n-1th field, and ASL _n-1 is determined in the n-1th field. The sustain operation is performed according to the determined number of subfields, and in the n + 1th field, ASL _n determined in the nth field by reading the nth field data D _n stored in the second frame memory 80 in the nth field. The sustain operation is performed according to the number of subfields determined by.

Here, referring to the n-th field data D _n stored in the second frame memory 80 in the n-th field, the subfield mapping for the second frame memory 80 is the n-1 th field, which is the previous field. While the ASL is determined according to the number of subfields determined by ASL _n-1 , the storage is performed and stored, whereas the sustain operation is performed in the n + 1th field, so that the ASL determined by the previous field is called ASL _n It can be seen that it is performed according to the number of determined subfields.

Meanwhile, in the variable subfield method, subfield mapping is different according to ASL of image data. For example, when ASL is 33, 10 subfields are mapped, and when ASL is 34, 11 subfields are mapped.

In this variable subfield method, if the ASL of the adjacent pixels corresponds to the boundary at which the subfield mapping is different, that is, when the ASL of the adjacent pixels is 33 and 34, respectively, referring to the example above, There is a problem that the screen flicker occurs due to the difference between the ASL applied when storing the memory and the ASL applied when performing the sustain.

More specifically, as shown in the accompanying FIG. 3, the ASL of the _n- th field data D _n-1 is 33, the ASL of the n-th field data D _n is 34, and the ASL is 33. In this case, 10 subfields are mapped, and when ASL is 34, 11 subfields are mapped.

In this case, n-th field of data (D _n) are of 10 by the n-1-th field of data (D _n-1) generates sub-field due to the number 10 of the sub-field unit 60, which is determined by the ASL of 33 After being mapped and stored in the second frame memory 80 as a subfield, the subfield is output to the address data generator 90 in the n + 1th field and provided to the plasma display panel 110 as 10 subfields. The operation is determined by the automatic power control unit 30 in the nth field and the sub scan field is applied to the plasma display panel 110 by 11 subfields applied by 34, which is ASL transmitted to the sustain scan pulse generator 100. Is output. As a result, only 10 subfields are provided by the second frame memory 50 while the address data applied to the plasma display panel 110 becomes 11 sustains by the sustain scan pulse generator 100. After all, only the 11th invalid sustain is achieved.

On the contrary, as shown in FIG. 4, when the ASL of the _n- th field data D _n-1 is 34 and the ASL of the n-th field data D _n is 33, the second frame memory 80 11 sub-fields are mapped, whereas sustain is performed only for 10 sub-fields, so the 11th is addressed to the second frame memory 80, but no sustain is performed.

As described above, in the variable subfield method applied in the conventional plasma display panel, when the ASLs of adjacent pixels are located at the boundary where the number of subfields is different, subfield mapping for the frame memory and subfield mapping for performing the sustain operation are performed. Due to this difference, screen configuration problems such as screen flashing and pseudo contours occur.

In particular, when switching from a black screen to a full white (F / W: full white) screen, not only the area of each subfield number is different, but also the maximum sustain is applied to the full white at this moment because the previous sustain is maintained. At this time, a large amount of current flows for one field at a moment, and a transient current flows in the SMPS, so that over current protection may be applied or broken, and noise may be generated due to a transient current during pattern switching.

Accordingly, an object of the present invention is to solve the above-described problem, and by using a variable correlation between video signals between frames, gray scale display is possible using a variable subfield method in a plasma display panel without employing field memory. There is provided a gradation display device of a plasma display panel and a method thereof.

In order to achieve the above object, a gradation display device of a plasma display panel according to a feature of the present invention is provided.

A gradation display device of a plasma display panel in which a plurality of subfields having luminance specific gravity are arranged in chronological order to display gradations, and the number of the subfields is determined according to an average signal level of image data.

An automatic power control unit detecting an average signal level of each field of the image data; First and second frame memories capable of storing the image data for even and odd frames; The image data output from the automatic power controller is mapped according to the number of subfields determined by the average signal level detected by the automatic power controller to generate corresponding grayscale data and selectively store the gray scale data in the first and second frame memories. A subfield generator; An address data generator for generating address data corresponding to the subfield data output from the subfield generator and applying the address data to the plasma display panel; The number of subfields determined by the average signal level of the current field output from the automatic power controller is compared with the number of subfields determined by the average signal level of the previous field, and when the number of the compared subfields is different, the current field. An average signal level adjusting unit for selecting and outputting one of the average signal level of the current field and the average signal level of the previous field according to a difference between the average signal level of the average field and the average signal level of the previous field; And a sustain scan pulse generator configured to generate sustain pulses and scan pulses corresponding to the average signal levels adjusted and output by the average signal level adjuster, and apply the sustain pulses and scan pulses to the plasma display panel.

Here, the subfield generation unit maps and stores the image data of the current field in one of the first and second frame memories according to the number of subfields determined by the average signal level of previous field image data. It features.

In addition, the average signal level adjusting unit receives the current field output from the automatic power controller to determine the number of corresponding subfields, compares the number of subfields determined by the average signal level of the previous field, and If the number of subfields determined by the average signal level of the field is the same as the number of subfields determined by the average signal level of the current field, the average signal level of the current field is output to the sustain scan pulse generator. It is done.

Further, when the number of subfields determined by the average signal level of the previous field and the number of subfields determined by the average signal level of the current field are not the same, the average signal level of the current field and the average of the previous field are the same. It is determined whether the difference between the signal levels is smaller than a specific reference value, and when the difference between the average signal level of the current field and the average signal level of the previous field is smaller than the specific reference value, the average signal level of the previous field is output to the sustain scan pulse generator. Characterized in that.

The average signal level of the current field may be output to the sustain scan pulse generator when the difference between the average signal level of the current field and the average signal level of the previous field is greater than or equal to the specific reference value.

According to another aspect of the invention, the gray scale display method of the plasma display panel,

A gradation display method of a plasma display panel in which a plurality of subfields having luminance specific gravity are arranged in chronological order to display gradations, and the number of the subfields is determined according to an average signal level of image data.

a) detecting an average signal level of the image data of the current field; b) mapping and storing the image data of the current field according to the number of subfields determined by the average signal level of the image data of the previous field already detected; c) comparing the number of subfields determined by the average signal level of the image data of the current field with the number of subfields determined by the average signal level of the image data of the previous field; d) in step c), if the number of subfields determined by the average signal level of the current field and the number of subfields determined by the average signal level of the image data of the previous field are the same, Outputting an average signal level; e) in step c), if the number of subfields determined by the average signal level of the current field is different from the number of subfields determined by the average signal level of the image data of the previous field, Selecting and outputting one of the average signal level of the current field and the average signal level of the previous field according to the difference between the average signal level and the average signal level of the previous field; And f) applying image data of the current field stored in step b) to the plasma display panel, and generating sustain scan pulses according to the average signal level output in step d) or e). Applying to.

The gray scale display method of the plasma display panel according to another aspect of the present invention,

A gradation display method of a plasma display panel in which a plurality of subfields having luminance specific gravity are arranged in chronological order to display gradations, and the number of the subfields is determined according to an average signal level of image data.

Determining whether or not the consecutive specific field data pairs of the image data are data pairs located at a boundary at which the number of subfields determined by each corresponding average signal level is different; When it is determined that the consecutive specific field data pairs are data pairs located at boundaries where the number of subfields determined by the corresponding average signal levels is different, the difference between the respective average signal levels corresponding to the specific field data pairs is a specific reference value. Determining whether it is smaller; When it is determined that the difference between the respective average signal levels corresponding to the specific field data pair is smaller than a specific reference value, the sustain scan pulse applied to the plasma display panel is applied to the average signal level of the field data processed first among the specific field data pairs. Generating correspondingly; And when it is determined that the difference between the respective average signal levels corresponding to the specific field data pair is equal to or greater than a specific reference value, the sustain scan pulse applied to the plasma display panel is applied to the average signal level of the field data processed later in the specific field data pair. And correspondingly occurring.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

5 is a block diagram of a gray scale display device using a variable subfield method in a plasma display panel according to an exemplary embodiment of the present invention.

In FIG. 5, the same reference numerals are used to describe the image signal processor 10, the gamma correction unit, and the error diffusion unit 20, which are the same components as those of FIG. 1.

As shown in FIG. 5, the gradation display device according to the exemplary embodiment of the present invention includes an image signal processor 10, a gamma correction and error diffusion unit 20, an automatic power control unit 120, and a subfield generation unit 60. And an ASL adjuster 120, first and second frame memories 70 and 80, an address data generator 90, and a sustain scan pulse generator 100.

The image signal processor 10 digitizes an image signal input from the outside to generate digital image data, and the gamma correction and error diffusion unit 20 receives the digital image data output from the image signal processor 10 to display a plasma. The gamma value is corrected according to the characteristics of the panel 110, and the display error is diffused to the surrounding pixels and output.

The automatic power control unit 120 detects the ASL of the image data while directly transmitting the image data output from the gamma correction and error diffusion unit 20 to the subfield generation unit 60 unlike the conventional two field memories. do. That is, the conventional field memory is not used.

The subfield generator 60 selectively stores the image data output from the automatic power controller 120 in the first and second frame memories 70 and 80 and then generates the subfield data corresponding to each image data. do.

The address data generator 90 generates address data corresponding to the subfield data output from the subfield generator 60 and applies the address data to the address electrodes A1, A2,... Am of the plasma display panel 110. .

The ASL controller 130 compares the number of subfields determined by the ASL output from the automatic power controller 120 with the number of subfields determined by the ASL of the previous field, and determines the subfields determined by the ASL of the previous field. If the number of fields and the number of subfields determined by the ASL of the current field are not the same, one of the ASL of the previous field and the ASL of the current field is selected and output according to the difference between the two ASLs. If the difference between the two ASL is smaller than the reference value, the ASL of the previous field is output. If the difference is greater than the reference value, the ASL of the current field is output. Here, the reference value may be predetermined or set externally.

The sustain scan pulse generator 100 receives the ASL adjusted and output from the ASL adjuster 130 and generates corresponding sustain pulses and scan pulses to scan electrodes X1, X2, .. Xn of the plasma display panel 110. ) And sustain electrodes Y1, Y2, ..., Yn.

FIG. 6 is a flowchart illustrating a method of displaying grayscales using a variable subfield method in a plasma display panel according to an exemplary embodiment of the present invention, and FIG. 7 is a diagram schematically illustrating an operation according to the method of FIG. 6.

6 and 7, in the n-1 th field, the n-1 th field data D _n-1 is n-2 th through the automatic power control unit 120 and the subfield generation unit 60. Subfield-mapped by ASL (not shown) of the field data and input to the first frame memory 70, and the n-1th field at the time when the input of the _n- 1th field data D _n-1 is completed. The ASL of the data D _n-1 , that is, ASL _n-1 is determined by the automatic power control unit 30 (S10). In the nth field and the n + 1th field, as in the n-1th field described above, ASL _n which is the ASL of the _nth field data D _n and ASL which is the ASL of the n + 1st field data D _{n + 1} . _{n + 1} is determined (S10).

Meanwhile, the ASL adjustment unit 130 compares (S20) the number of subfields VSF_ID (previous) determined by the ASL of the previous field with the number of subfields VSF_ID (current) determined by the ASL of the current field (S20). If not, a function of selecting and outputting one of the ASL of the previous field and the ASL of the current field according to the difference between the ASL of the previous field and the ASL of the current field (S30, S40, S50), n-1 in FIG. Assuming that the number of subfields determined by ASLn-1, which is the ASL of the first field, and the number of subfields determined by ASLn, which is the ASL of the nth field, are the same (S20), the ASL adjustment unit 130 performs the nth field. In step S50, ASLn, which is the ASL of the nth field, is outputted to the sustain scan pulse generator 100 so that automatic power control (APC (current)) by the ASL of the current field is performed.

This is similar to the conventional view from the sustain scan pulse generator 100, that is, when the number of subfields determined by the ASL of the previous field is equal to the number of subfields determined by the ASL of the current field, the sustain scan pulse generator ( The number of subfields input to 100 has the same value as in the prior art.

However, as shown in FIG. 8, the number of subfields determined by ASLn-1, the ASL of the n-1th field, and the number of subfields determined by ASLn, the ASL of the nth field, have different values. In a case (S20), the ASL adjusting unit 130 does not output ASLn, which is the ASL of the nth field in the n + 1th field, to the sustain scan pulse generator 100, but is the ASL of the previous field, that is, the n-1th field. Determines whether the difference between ASLn-1 (ASL (previous)) and the current field, that is, ASLn (ASL (current)), which is the ASL of the nth field, that is, | ASL (current) -ASL (previous) | (S30).

8 illustrates a case where a difference between ASLn-1, which is the ASL of the previous field, that is, the n-1th field, and ASLn, which is the ASL of the current field, that is, the nth field, is smaller than the reference value. Therefore, in this case, the ASL adjuster 130 outputs ASLn-1, which is the ASL of the previous field, that is, the n-1 th field, to the sustain scan pulse generator 100 so that the screen flicker does not occur. (APC (previous)) is performed (S40).

Accordingly, in the case of the n-th field data D _n in which the sustain operation is performed in the n + 1 th field, data subfield-mapped by the number of subfields determined by ASL n-1, which is ASL of the n-1 th field, is conventionally used. In this embodiment, a flicker and pseudo contour are generated according to the number of subfields determined by ASLn, which is ASL of the nth field. The subfield mapped data according to the number of fields is adjusted by the ASL control unit 130 and the sustain operation is performed according to the number of subfields determined by ASLn-1, which is the ASL of the n-1th field. The subfields are mapped by the number of fields and the sustain operation is performed so that flicker and pseudo contours are not generated.

On the other hand, if the change in ASL is large, such as when switching from a black screen to a full white screen, the difference between ASLn-1, which is the ASL of the n-1th field, and ASLn, which is the ASL of the nth field, is different. It becomes equal to or more than the reference value, and in this case, the same operation as in the case of FIG.

Therefore, in this case, the ASL adjuster 130 outputs ASLn, which is the ASL of the current field, that is, the n-th field, to the sustain scan pulse generator 100 to switch from the black screen to the full white screen, so that the ASL difference is greater than or equal to the reference value. Automatic power control (APC (present)) is performed to prevent an automatic power control mismatch, which occurs at a large boundary, from occurring (S50).

Meanwhile, FIGS. 9 and 10 attach an example in which 10 subfields are mapped when ASL is 33, 11 subfields are mapped when ASL is 34, and 12 subfields are mapped when ASL is 43. If described with reference to:

As shown in FIG. 9, the ASL of the _n- th field data D _n-1 is 33, the ASL of the n-th field data D _n is 34, and when the ASL is 33, 10 subfields are represented. If it is mapped and ASL is 34, it is assumed that 11 subfields are mapped.

In this case, the n-th field data D _n is divided into ten sub-fields by the subfield generation unit 60 due to 33 being ASL of the _n- th field data D _n-1 . ) Is stored in the n + 1th field, and is output to the address data generator 90 and provided to the plasma display panel 110 as 10 subfields.

On the other hand, the ASL adjuster 130 is the number 11 of the subfields determined by the ASL 34 of the n-th field data (D _n ) output from the automatic power control unit 120 and the data of the previous field, that is, the n-1 field Since the number 10 of subfields determined by 33, which is the ASL of (D _n-1 ), is different from each other, 34 of the nth field data (D _n ) and the data (D _n-1 ) of the _n- 1th field Compare the reference value of 1 with the difference of 33, which is ASL. The reference value may vary depending on the characteristics of the plasma display panel and may also vary according to a user input. Here, for example, when the reference value is set to 5, since the difference between the two obtained ASL is 1, this value is smaller than the reference value, so 34, which is the ASL of the n th field data D _n , is ignored and 33, which is an ASL of D _n-1 , is output to the sustain scan pulse generator 100 and used for automatic power control.

The maintenance scan pulse generating unit 100 maintains the number of subfields, that is, the 10 subfields according to 33, which is the ASL of the data D _{n-1 of the n-} 1th field output from the ASL adjustment unit 130. The scan pulse is output to the plasma display panel 110.

Therefore, the address data applied to the plasma display panel 110 is provided to the ten subfields by the second frame memory 80, and the number of sustains by the sustain scan pulse generating unit 100 is also ten, so that the number is increased. By coinciding with each other, flicker and pseudo contours which have conventionally been generated are not generated.

Meanwhile, referring to FIG. 10, when the n-th field data D _n-1 has an ASL of 33, the n-th field data D _n has an ASL of 43, and when the ASL is 33, 10 subfields. Are mapped, and when the ASL is 43, 12 subfields are mapped.

In this case, the n-th field data D _n is divided into ten sub-fields by the subfield generation unit 60 due to 33 being ASL of the _n- th field data D _n-1 . ) Is stored in the n + 1th field, and is output to the address data generator 90 and provided to the plasma display panel 110 as 10 subfields.

On the other hand, ASL adjuster 130 is earlier as the number 12 of the subfield is determined by the 43 ASL of the n-th field of data (D _n) which is output from the automatic power controller 120, a field, that is, n-1 of the second field data Since the number 10 of subfields determined by 33, which is the ASL of (D _n-1 ), is different from each other, the ASL of the _nth field data (D _n ) 43 and the data (D _n-1 ) of the _n- 1th field are different. Compare the reference value with 10, which is the difference of 33, which is ASL. Here, the reference value is set to 5 as in the above example.

Since the calculated difference between the two ASLs is 10, this value is larger than the reference value. Thus, 43, which is the ASL of the n-th field data D _n , is output to the sustain scan pulse generator 100 and used for automatic power control.

In this case, when the nth field data D _n is mapped and stored into 10 subfields and sustain is performed for 12 subfields, but there is a large change in ASL such as switching from a black screen to a full white screen, In order to prevent the occurrence of automatic power control mismatch, it is desirable to allow automatic power control according to the ASL of the current field to be performed.

Although the present invention has been described with reference to the most practical and preferred embodiments, the present invention is not limited to the above disclosed embodiments, but also includes various modifications and equivalents within the scope of the following claims.

According to the present invention, by adjusting the number of subfields using a high correlation between video signal frames, automatic power control inconsistencies generated at the subfield boundary when applying a variable subfield algorithm without using a field memory can be prevented. have.

In addition, since no field memory is used, the cost is reduced, and the complexity of the structure is also reduced.

1 is a block diagram of a gray scale display device using a variable subfield method in a conventional plasma display panel.

FIG. 2 is a diagram schematically illustrating a method of displaying grayscale using a variable subfield method in a conventional plasma display panel.

3 is a diagram schematically illustrating an example of a method of displaying grayscale using a variable subfield method in a conventional plasma display panel.

4 is a diagram schematically illustrating another example of a method of displaying gray scales using a variable subfield method in a conventional plasma display panel.

5 is a block diagram of a gray scale display device using a variable subfield method in a plasma display panel according to an exemplary embodiment of the present invention.

FIG. 6 is a flowchart illustrating a method of displaying grayscale using a variable subfield method in a plasma display panel according to an exemplary embodiment of the present invention.

FIG. 7 is a diagram schematically illustrating an operation according to the method of FIG. 6 and illustrates a case where the number of subfields of a previous field and a current field is the same.

FIG. 8 is a diagram schematically illustrating an operation according to the method of FIG. 6, in which a number of subfields of a previous field and a current field is different, and a difference between an average signal level of each field is smaller than a reference value.

FIG. 9 is a diagram illustrating an example of an operation according to the method of FIG. 6, in which a number of subfields of a previous field and a current field is different, and a difference between an average signal level of each field is smaller than a reference value.

FIG. 10 is a diagram illustrating an example of an operation according to the method of FIG. 6, in which the number of subfields of a previous field and a current field is different, and a difference between an average signal level of each field is greater than or equal to a reference value.

Explanation of symbols on the main parts of the drawings

10: image signal processor 20: gamma correction and error diffusion unit

30, 120: automatic power control unit 40: first field memory

50: second field memory 60: subfield generating unit

70: first frame memory 80: second frame memory

90: address data generator 100: sustain scan pulse generator

110: plasma display panel 130: ASL control unit

Claims (8)

In a gradation display device of a plasma display panel in which a plurality of subfields having luminance specific gravity are arranged in chronological order to display gradations, and the number of the subfields is determined according to an average signal level of image data. An automatic power control unit detecting an average signal level of each field of the image data; First and second frame memories capable of storing the image data for even and odd frames; The image data output from the automatic power controller is mapped according to the number of subfields determined by the average signal level detected by the automatic power controller to generate corresponding grayscale data and selectively store the gray scale data in the first and second frame memories. A subfield generator; An address data generator for generating address data corresponding to the subfield data output from the subfield generator and applying the address data to the plasma display panel; The number of subfields determined by the average signal level of the current field output from the automatic power controller is compared with the number of subfields determined by the average signal level of the previous field, and when the number of the compared subfields is different, the current field. An average signal level adjusting unit for selecting and outputting one of the average signal level of the current field and the average signal level of the previous field according to a difference between the average signal level of the average field and the average signal level of the previous field; And A sustain scan pulse generator for generating a sustain pulse and a scan pulse corresponding to the average signal level adjusted and output by the average signal level adjuster and applying the same to the plasma display panel. Gray display device of the plasma display panel comprising a. The method of claim 1, The subfield generator maps and stores the image data of the current field in one of the first and second frame memories according to the number of subfields determined by the average signal level of previous field image data. The gradation display device of the plasma display panel. The method of claim 2, The average signal level adjusting unit The number of subfields is determined by receiving the current field output from the automatic power controller, and compared with the number of subfields determined by the average signal level of the previous field. When the number of subfields determined by the average signal level of the previous field is equal to the number of subfields determined by the average signal level of the current field, the average signal level of the current field is output to the sustain scan pulse generator. A gradation display device of a plasma display panel. The method of claim 3, If the number of subfields determined by the average signal level of the previous field and the number of subfields determined by the average signal level of the current field are not the same, the average signal level of the current field and the average signal level of the previous field are not the same. To determine if the difference is less than a certain threshold, Outputting the average signal level of the previous field to the sustained scan pulse generator when the difference between the average signal level of the current field and the average signal level of the previous field is smaller than the specific reference value. A gradation display device of a plasma display panel. The method of claim 4, wherein Outputting the average signal level of the current field to the sustained scan pulse generator when the difference between the average signal level of the current field and the average signal level of the previous field is equal to or greater than the specific reference value. A gradation display device of a plasma display panel. In a gradation display method of a plasma display panel, a gray scale is displayed by arranging a plurality of subfields having luminance specific gravity in chronological order, and determining the number of the subfields according to an average signal level of image data. a) detecting an average signal level of the image data of the current field; b) mapping and storing the image data of the current field according to the number of subfields determined by the average signal level of the image data of the previous field already detected; c) comparing the number of subfields determined by the average signal level of the image data of the current field with the number of subfields determined by the average signal level of the image data of the previous field; d) in step c), if the number of subfields determined by the average signal level of the current field and the number of subfields determined by the average signal level of the image data of the previous field are the same, Outputting an average signal level; e) in step c), if the number of subfields determined by the average signal level of the current field is different from the number of subfields determined by the average signal level of the image data of the previous field, Selecting and outputting one of the average signal level of the current field and the average signal level of the previous field according to the difference between the average signal level and the average signal level of the previous field; And f) applying the image data of the current field stored in step b) to the plasma display panel, and generating sustain scan pulses according to the average signal level output in step d) or e), Authorizing step Gray scale display method of the plasma display panel comprising a. The method of claim 6, Step e), Determining whether a difference between an average signal level of the current field and an average signal level of a previous field is smaller than a specific reference value; Outputting an average signal level of the previous field if it is determined that a difference between the average signal level of the current field and the average signal level of the previous field is smaller than the specific reference value; And Outputting an average signal level of the current field if it is determined that a difference between the average signal level of the current field and the average signal level of the previous field is greater than or equal to the specific reference value. A gradation display method of a plasma display panel. In a gradation display method of a plasma display panel, a gray scale is displayed by arranging a plurality of subfields having luminance specific gravity in chronological order, and determining the number of the subfields according to an average signal level of image data. Determining whether or not the consecutive specific field data pairs of the image data are data pairs located at a boundary at which the number of subfields determined by each corresponding average signal level is different; When it is determined that the consecutive specific field data pairs are data pairs located at boundaries where the number of subfields determined by the corresponding average signal levels is different, the difference between the respective average signal levels corresponding to the specific field data pairs is a specific reference value. Determining whether it is smaller; When it is determined that the difference between the respective average signal levels corresponding to the specific field data pair is smaller than a specific reference value, the sustain scan pulse applied to the plasma display panel is applied to the average signal level of the field data processed first among the specific field data pairs. Generating correspondingly; And When it is determined that the difference between the respective average signal levels corresponding to the specific field data pair is equal to or greater than a specific reference value, the sustain scan pulse applied to the plasma display panel corresponds to the average signal level of field data processed later in the specific field data pair. Steps that occur Gray scale display method of the plasma display panel comprising a.