KR20070005163A - Plasma display panel device - Google Patents

Abstract

A plasma display device is provided to reduce a half-tone noise on a low brightness image by discarding decimal fraction data during a sub-field mapping, when the APL of an image is low. A plasma display device includes a sub-field mapper(60) and a bit adjuster(30). The sub-field mapper performs a sub-field mapping according to the APL(Average Picture Level) of an image. The bit adjuster adjusts the bit number of the data, which is inputted to the sub-field mapper. The bit adjuster reduces the bit number of the data as the APL decreases. The bit number of output data from the bit adjuster is one of 14, 15, and 16 bits. The bit adjuster varies the data bit number, when the data is decimal fraction data.

Description

 Plasma display panel device

1 is a diagram showing a configuration of a plasma display apparatus according to the prior art;

2 is a diagram showing the configuration of a plasma display device according to the present invention.

<Explanation of symbols on main parts of the drawings>

10: reverse gamma correction unit 30: bit adjustment unit

60: subfield mapping unit

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a plasma display device, and more particularly, to a plasma display device capable of improving gray scale linearity by reducing the number of data bits when the average image level, i.e., APL is small, to prevent halftone noise.

The plasma display panel drives the corresponding pixel according to gray level data of the image. The plasma display panel is driven by dividing one frame into several subfields having different number of emission times in order to express gray scales. The subfield is divided into a reset period for uniformly generating a discharge, an address period for selecting a cell to be discharged, and a sustain period for implementing gray levels according to the number of discharges.

For example, assuming that the plasma display panel uses eight subfields to represent 256 levels of gray scale, the reset period and the address period of each subfield are the same, but the sustain period is 2 ⁿ (for each subfield). n = 0, 1, 2, 3, 4, 5, 6, 7). At this time, since the intensity (applied voltage) of each sustain signal is the same and the amount of light emitted per hour is the same, when the sustain period (the number of sustain pulses) is increased, the integral amount is increased so that the screen becomes bright and gray scales are expressed.

The apparatus for driving the plasma display panel according to the related art is an inverse gamma correction unit 1, an error diffusion unit 5, and a sub for gradation representation, into which an image signal is input, as shown in FIG. The field mapping unit 6 is configured.

The inverse gamma correction unit 1 inversely gamma corrects the input image signal and linearly converts the luminance value according to the gray value of the image signal to match the characteristics of the plasma display panel. The error diffusion unit 5 finely adjusts the luminance value between adjacent cells in the unit pixel region for more accurate gray level expression, and the subfield mapping unit 6 separates data output from the error diffusion unit according to the luminance relative ratio. Perform subfield mapping.

The plasma display apparatus includes a mapping switch unit 4 for dividing an average image level (hereinafter referred to as APL) into several sections and calculating a subfield mapping value according to data output from the inverse gamma correction unit 1. It is composed.

The subfield mapping value output from the mapping conversion unit 4 has a value less than or equal to the decimal point, and the data stored in the subfield mapping unit 6 is an integer value, so the subfield mapping output from the mapping conversion unit 4 is performed. The value is converted into an integer value while passing through the error diffusion unit 5.

Since the data having a value below the decimal point is converted to an integer value while passing through the error diffusion unit 5, the data applied to the mapping switch 4 and the data output from the mapping switch 4 are different from each other. Even if it is through the error diffusion unit 5 is output to the same value occurs.

Despite the need to express different gradations, the same gradation is expressed, resulting in a decrease in gradation linearity when displaying still images, and when a video is displayed, there is a problem in that halftone noise is generated such as being displayed on the screen.

This is because the data of the integer part is the same, and if the data of the fractional part is different, different gray levels must be expressed, but the data is changed so that the same gray level is expressed through the error diffusion part 5.

In particular, in the case of low gradation, the gradation required to be expressed is different from each other, but the gradation linearity deterioration is more serious because the gradation represented substantially becomes the same.

The present invention has been made to solve the above-mentioned problems of the prior art, and when the APL is small, the number of data bits is reduced, and when the APL is large, the data bit number is increased, thereby reducing the generation of halftone noise at low gradation, thereby improving gray linearity. The present invention provides a plasma display device.

According to an aspect of the present invention, there is provided a plasma display device including: a mapping switch for performing subfield mapping according to an average picture level (APL), and the number of bits of data input to the mapping switch. Characterized in that it comprises a bit adjustment unit for adjusting the.

Hereinafter, a plasma display device of the present invention will be described with reference to the accompanying drawings.

The plasma display device of the present invention is a device for performing subfield mapping by reducing the number of data bits when the APL is low. As shown in FIG. 2, the inverse gamma corrector 10, the gain adjuster 20, The error diffusion unit 50 and the subfield mapping unit 60 are basically included.

The inverse gamma correction unit 10 performs inverse gamma correction on the R / G / B image signal converted into a digital value to linearly convert the luminance value according to the gray value of the image signal. The gain adjusting unit 20 adjusts the gain of the data corrected by the inverse gamma adjusting unit by the effective gain.

In addition, the plasma display apparatus includes an APL detector 70 that detects an APL on a frame basis with respect to the R / G / B image signal converted into the digital value. The APL detected by the APL detector includes an input image signal. Assuming a 10-bit value, it is divided into 1024 steps from 0 to 1023.

The lower the APL, the darker the gradation, and the higher the APL, the brighter the gradation. Each APL has a different number of sustain pulses applied during one frame. That is, the lower the APL, the darker the gradation, the greater the number of sustain pulses applied during one frame, and conversely, the higher the APL, the smaller the number of sustain pulses.

The mapping switching unit 40 divides the APL into a plurality of sections, and a subfield mapping value corresponding to the input image data value is output in a section corresponding to the APL detected by the APL detector 70. It consists of.

In this case, the mapping switch 40 typically outputs a subfield mapping value by dividing the APL into 32 sections, and the data output from the mapping switch includes a value below the decimal point.

The subfield mapping unit 60 performs subfield mapping corresponding to the subfield mapping value output from the mapping switching unit 40, and the plasma display panel is driven according to the determined subfield mapping to display a screen. .

In other words, the data output from the mapping switching unit 40 may be referred to as an address value of the subfield mapping previously stored in the subfield mapping unit 60. That is, assuming that data output from the mapping switch is 10, the plasma display panel is driven using the 10th subfield mapping of the subfield mapping unit 60.

The subfield mapping unit 60 needs to receive data consisting of only integer units and perform subfield mapping. Since the data output from the mapping switch unit 40 has a fractional part, the subfield mapping unit 60 converts the data into integers through the error diffusion unit 50. Must be converted to a value.

The error diffusion unit 50 spreads the quantization error generated while converting the data output from the mapping conversion unit 40 into an integer value to adjacent cells. In general, the error diffusion unit 50 divides the data output from the mapping conversion unit 40 into an integer part and a decimal part, multiplies the decimal part by a specific value, and converts the data into an integer value.

As a result, although the data output from the mapping switching unit 40 is different from each other, the data applied to the subfield mapping unit 60 through the error diffusion unit 50 may be the same.

In other words, assume that the data output from the mapping switch 40 are 27.5 and 28.4 for the two cells, respectively. One cell should display the screen according to the 27.5th stored subfield mapping of the subfield mapping unit 60, and the other cell displays the screen according to the 28.4th stored subfield mapping of the subfield mapping unit 60. Should be displayed.

However, when the data output from the mapping switch unit 40 passes through the error diffusion unit 50, the same outputs 28. Accordingly, the two cells display the screen according to the same subfield mapping. Although the two cells should display different gray scales, the two cells represent the same gray scales due to error diffusion.

Particularly, in the case of adjacent cells, although the adjacent cells must express different gray scales, if the same gray scales are expressed due to error diffusion or gray level inversion occurs, gray scale linearity of the plasma display panel is degraded, and halftone noise occurs when the screen is displayed. Will occur.

The halftone noise and grayscale linearity degradation are more severely generated in low grayscale, which is sensitive to low grayscale, and the mapping conversion unit 40 subdivides the grayscale gradually to low grayscale to increase gray scale expressiveness. Because express.

In the case of low gradation, the mapping switching unit 40 determines the subfield mapping value such that the input data and the output data are 1: 1, and the subfield mapping value that is output even if the input data is different toward the higher gradation level is different. Make it the same. In the case of a high gradation, although different gradations must be expressed, even when the same gradation is expressed using the same subfield mapping, the human eye is insensitive to the difference, so the mapping switching unit 40 becomes one sub as the gradation increases. Subfield mapping is performed to increase the gradation level represented by the field mapping.

Therefore, in the case of low gradation, since the difference in the value output from the mapping switching unit 40 is smaller than the high gradation, when the error diffusion is performed, gradation inversion or halftone noise is more increased when the screen is displayed on the actual plasma display panel. Will occur.

For example, assuming that data input to the mapping switch unit 40 includes an integer part of 10 bits and a fractional part of 6 bits, the data input to the mapping switch unit has a difference of at least 1/128.

The mapping switching unit 40 allows all data to have different subfield mapping values in the case of low gradation, and different input data has the same subfield mapping value in the case of high gradation.

That is, in the case of low gradation, the input data of A outputs a subfield mapping value of A ', and the input data of B which is 1/128 larger than A outputs subfield mapping value of B' for each input data. The subfield mapping value is output at 1: 1.

On the contrary, in the case of high gradation, all the data of D, which is 64/128 larger than C, from the input data of C, also output the same subfield mapping value of C ', and the data of E which is 1/128 larger than C, All data named F as large as 128 output subfield mapping values of E '.

When the data output from the mapping conversion unit 40 passes through the error diffusion unit 50, all of the data is converted into an integer value. In the case of low gradation, the difference between the A 'and B' is not so short that the mapping is performed after the diffusion. Even though the output of the switching unit is different between A 'and B', the screen is displayed through a subfield mapping of A ''. On the other hand, in the case of high gradation, since the difference between C 'and E' is large, C 'displays a screen through subfield mapping of C' 'and E' of E ''.

In the case of low gradation, the difference between the subfield mapping values output from the mapping switching unit 40 is close, and in the case of high gradation, the difference between the subfield mapping values output from the mapping switching unit is small. Therefore, in the case of the low gradation, even if it has different subfield mapping values, it is easy to express the same gradation due to error diffusion, and thus gradation linearity is deteriorated.

In order to prevent this, the plasma display apparatus of the present invention includes a bit adjuster 30 that varies the number of bits of data input to the mapping switch 40.

The bit adjuster 30 reduces the number of bits of data input to the mapping switching unit 40 as the APL detected by the APL detector 70 is lower, and conversely, the higher the APL detected by the APL detector 70 as the APL is detected. Increase the number of bits of data input to the switching unit.

In general, if the data output from the gain adjusting unit 20 is 16 bits, 10 bits represent an integer value and 6 bits represent a decimal value. In this case, the bit adjuster 30 keeps the data of the integer part and changes only the data of the fractional part.

The bit adjuster 30 divides the APL into at least two sections, and adjusts the number of bits of data applied to the mapping switcher 40 according to the section corresponding to the APL detected by the APL detector 70. It can be implemented with a selector.

When the data output from the gain adjuster 20 is 16 bits and the APL is divided into three sections, the bit adjuster 30 sets the number of bits of the data applied to the mapping switch 40 to 14 bits and 15 bits. Or 16 bits.

That is, in the case of low gradation with small APL, the data applied to the mapping switching unit 40 is 14 bits, and the bit is converted into 15 bits in the middle gradation and 16 bits in the case of high gradation with a large APL. The number of bits of data varied by the bit adjuster 30 may not exceed the number of bits of data input to the bit adjuster 30.

As described above, in the case of low gradation with low APL by the bit adjuster 30, the step of data output from the mapping converter 40 is increased. Accordingly, when the subfield mapping value has different subfield mapping values, the data values applied to the subfield mapping unit 60 are different even after passing through the error diffusion unit 50, and thus different subfield mapping is performed.

Even in the case of low gradation, since 14 bits of data are output from the bit adjusting unit 30, each gradation step of data applied to the mapping converter 40 has a 1/16 difference. Since the difference between the data applied to the mapping converter is increased, the interval of the subfield mapping values output from the mapping converter is also increased. If the output data of the mapping converter is different, different subfield mapping is performed.

On the other hand, if the output of the bit adjuster 30 is 16 bits, each gradation step is 1/128, so that the interval of data input to the mapping converter 40 becomes dense, but in the case of high gradation, the subfield mapping is fine. Since the spacing is performed, even if the interval of data input to the mapping converter is tight, the interval of the output subfield mapping value is small. Therefore, even after the error diffusion, if the output data of the mapping converter 40 is different, different subfield mapping is performed to maintain gray linearity in both low and high gray levels.

As such, by adjusting the number of bits of the data input to the mapping switching unit 40 and performing subfield mapping by reducing data below the decimal point toward lower gray levels, the screen may be displayed without gray level inversion and halftone noise. .

As described above, the plasma display device according to the present invention has been described with reference to the illustrated drawings. However, the present invention is not limited by the embodiments and drawings disclosed herein, and is provided to those skilled in the art within the scope of the technical idea of the present invention. Application is possible.

The plasma display apparatus according to the present invention configured as described above reduces the generation of halftone noise at low grayscales by reducing data below the decimal point when the average image level, that is, APL is low, and reduces grayscale linearity. It is effective to express natural image.

Claims (4)

A subfield mapping unit for performing subfield mapping according to an average picture level (hereinafter referred to as APL); And a bit adjusting unit for adjusting the number of bits of data input to the subfield mapping unit. The method according to claim 1, And the bit adjusting unit adjusts the bits so that the number of bits of data decreases as the average picture level (APL) decreases. The method according to claim 1, And the bit adjuster is one of 14 bits, 15 bits, or 16 bits of output data. The method according to claim 1, And the bit adjuster varies the number of data bits below the decimal point.

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