KR100309996B1 - Apparatus for Driving Plasma Display Panel Using Encode Scan Addressing Technique - Google Patents

Abstract

According to the present invention, a scan number block and an order of blocks to be output are determined according to a result of analyzing the arrangement of pixel data, and the data is rearranged according to the scan number block. The scan scan addressing drive controls the scan driver and the address driver so that the scan pulse generated from the scan driver is applied to the plasma display panel, and the output of the address driver is applied to the plasma display panel according to the generated scan pulse. The present invention relates to a plasma display panel driving apparatus using the method.

According to the present invention, it is possible to obtain sufficient luminance by increasing the display discharge time as the addressing time is reduced by minimizing the number of scans by simultaneously performing scans sequentially rather than sequentially according to the image data.

Description

Apparatus for Driving Plasma Display Panel Using Encode Scan Addressing Technique}

The present invention relates to an apparatus for driving a plasma display panel using an encode scan addressing drive method. More particularly, the present invention relates to a plasma display panel driving apparatus. The present invention relates to a plasma display panel driving apparatus using an encode scan addressing drive system capable of obtaining luminance.

Plasma refers to an ionized gas, which is called a fourth state of matter because the gas begins to be produced at temperatures of tens of thousands or more, and has a very different nature than ordinary gases. Plasma has many atoms and molecules excited inside, so it can emit a lot of light, making it a very effective light source. The sun is a kind of plasma light source that exists naturally. The most typical plasma discharge tube lamp is a low-pressure mercury lamp, which fills the tube with mercury vapor at about 100,000 atmospheres and discharges 253.7nm UV light into visible light through a fluorescent material applied to the inner wall. Instead, if you enclose a gas such as neon, you can get the visible light unique to the gas. Increasing the gas pressure inside the discharge tube can increase the current to improve the luminous efficiency, and high-pressure arc lamps can be used as high-efficiency lighting sources because they can obtain high luminance and compactness. Currently, CRTs are widely used as display devices for images and information. However, CRTs are bulky and have high power consumption. Therefore, a portable computer or screen requiring 40 to 50 inches is required. Indicators needed in next-generation high-definition TVs need to be flat panel displays. Liquid crystal displays are the best in terms of display performance and functionality for screen sizes below 20 inches, and plasma display panels (PDPs) that use light emitted by plasma are the most likely candidates for display performance and functions. It is considered to be. PDP can be divided into AC and DC type according to the driving method, and it can give high viewing angle and brightness, and it is easy to realize color gradation by using the high nonlinear nature of plasma. Due to its characteristics, it is easy to manufacture with a large screen, and in the late 2000s, it is expected that the plasma display panel (PDP) will have an absolute advantage in the large part of the flat display market which is expected to grow to the size of the current semiconductor market.

In short, Plasma Display Panel (PDP) is emerging as a next-generation flat panel display with a wall-mounted TV display. Its thin and light feature makes it possible to achieve large screens of 40 inches or more compared to LCDs that are difficult to enlarge. Another advantage is that the fields of application are very diverse, such as wall-mounted TVs, stock trading boards, video conferencing, and displays for various presentations.

FIG. 1 is a block diagram illustrating a driving apparatus of a general plasma display panel, and FIG. 2 is a timing diagram illustrating scan pulses and address data of FIG. 1.

As shown in FIG. 1, a general apparatus for driving a plasma display panel includes a digital image input unit 10 and a plasma display panel 50 for inputting digital image data to be displayed on a plasma display panel (P) 50. There is an address driver (30) for recording data on the upper side of the plasma display panel 50 to drive the < RTI ID = 0.0 >), < / RTI > There is a scan driver 40, and is composed of an address / scan pulse controller 20 for controlling an address and a scan.

In the conventional plasma display panel configured as described above, when performing addressing, as shown in FIG. 2, the address / scan pulse controller 20 causes the scan driver 40 to sequentially generate scan pulses. Then, the address driver 30 performs the addressing process by sending data in response to the sequentially generated scan pulses.

Accordingly, when performing addressing, since the scan pulse and the address data are sequentially exported, the address time always consumes a certain time regardless of the arrangement of the data.

However, in the case of adopting a driving method that performs addressing and display in a digital flat panel display such as a PDP, the shorter the addressing time, the longer the display time is. Therefore, the brightness of the display can be increased and the sub like the PDP. In the case of a driving method using a subfield, the number of subfields can be increased to help solve problems such as pseudo contours. In other words, the addressing time that does not directly contribute to the display can be shortened according to the arrangement of the digital values of the signal in the same way as the present invention. Can be.

Accordingly, the present invention has been devised to meet such a demand. When driving the PDP, the scan and addressing time is long, and thus the display discharge time is short, so that the luminance is not sufficient. As a result, the Encode Scan Addressing Drive method which minimizes the number of scans by performing the scans sequentially and simultaneously, using the Encode Scan Addressing Drive method, which achieves sufficient brightness by increasing the display discharge time by reducing the addressing time. It is an object of the present invention to provide a plasma display panel driving apparatus.

1 is a block diagram illustrating a driving apparatus of a general plasma display panel;

2 is a timing diagram illustrating scan pulses and address data of FIG. 1;

3 is a block diagram showing a preferred embodiment of a plasma display panel driving apparatus using an encode scan addressing drive method;

4 is a waveform diagram illustrating scan pulses and addressing data of FIG. 3;

5 is an exemplary diagram for describing the number of scans generated when the present invention is applied.

<Explanation of symbols for the main parts of the drawings>

100: plasma display panel 110: digital image input unit

120: encode scan designation unit 130: address driver

140: scan driver 150: address / scan pulse controller

In order to achieve the above object, a plasma display panel driving apparatus using an encode scan addressing drive method according to the present invention includes a scan number block and a sequence of blocks to be output according to a result of analyzing an arrangement of pixel data. After reconstructing the data according to the scan number block, and controlling the scan driver and the address driver according to the scan number block and the order of the blocks, the scan pulse generated from the scan driver is applied to the plasma display panel. By controlling the output of the address driver to be applied to the plasma display panel in accordance with the scan pulse, the scan is sequentially and simultaneously performed according to the image data, thereby minimizing the number of scans and increasing the display discharge time as the addressing time is reduced. Enough whee Characterized be obtained.

Hereinafter, a preferred embodiment of a plasma display panel driving apparatus using an encode scan addressing drive method according to the present invention will be described with reference to the accompanying drawings.

FIG. 3 is a block diagram showing a preferred embodiment of a plasma display panel driving apparatus using an encode scan addressing drive method. FIG. 4 is a waveform diagram showing scan pulses and addressing data of FIG.

A plasma display panel 100 using light emitted from plasma;

A digital image input unit (110) for outputting digital image data to be displayed on the plasma display panel (100);

The scan number block to be output and the order of the blocks are determined according to the result of analyzing the arrangement of the pixel data by receiving the output of the digital image input unit 100 and rearranging the data according to the scan number block. Encode scan designation unit 120;

An address driver 130 for addressing pixel data to be displayed when the plasma display panel 100 is driven;

A scan driver 140 for addressing scan and display discharge; And

By receiving the output of the digital image input unit 110 and the output of the encode scan designator 120 to control the scan driver 140 and the address driver 130 in accordance with the scan number block and the order of the blocks An address that causes a scan pulse generated by the scan driver to be applied to the plasma display panel 100 and controls the output of the address driver 130 to be applied to the plasma display panel 100 in accordance with the generated scan pulse. / Scan pulse control unit 150 is configured.

An operation of the preferred embodiment of the plasma display panel driving apparatus using the encode scan addressing drive method according to the present invention configured as described above will be described in detail with reference to the accompanying drawings.

First, when digital image data to be displayed on the plasma display panel 100 is output from the digital image input unit 110, the encode scan designation unit 120 receives an output of the digital image input unit 100 to receive respective pixel data. The scan number block to be output and the order of the blocks are determined according to the result of analyzing the array of and the data is rearranged according to the scan number block.

Accordingly, as illustrated in FIG. 4, the address / scan pulse controller 150 receives the output of the digital image input unit 110 and the output of the encode scan designation unit 120 to receive the scan number block and the block. The scan driver 140 and the address driver 130 are controlled in order so that the scan pulse generated by the scan driver is applied to the plasma display panel 100, and the address driver is adapted to the generated scan pulse. The output of 130 is controlled to be applied to the plasma display panel 100.

In this way, the addressing time can be simultaneously and sequentially scanned according to the digital image data to reduce the addressing time as much as possible, and to increase the display time to show the display's inherent performance. As the driving time of the display is relatively increased, a better image quality can be realized by giving time to solve the driving problem.

In this case, the address driver 130 performs an addressing function for specifying pixel data to be displayed on the plasma display panel 100 under the control of the address / scan pulse controller 150, and the scan driver 140 performs a scan pulse. By generating the addressing scan and the display discharge is performed.

5 is an exemplary diagram for describing the number of scans generated when the present invention is applied.

In order to address digital image data having a pixel arrangement as shown in FIG. 5, six scans are conventionally required. Since this gives address data sequentially, the addressing time is always due to the constant time spent regardless of the arrangement of the data. In contrast, in the encoded scan addressing drive method disclosed in the present invention, the number of scans can be completed at maximum four times by analyzing the arrangement of data. The reason why the number of scans can be reduced can be attributed to the absence of pixel data in the first and last lines when referring to the pixel data array of FIG. 5.

Terminologies used herein are terms defined in consideration of functions in the present invention, which may vary according to the intention or customs of those skilled in the art, and the definitions should be made based on the contents throughout the present application. will be.

Although specific embodiments of the invention have been described and illustrated, it will be apparent that the invention may be embodied in various modifications by those skilled in the art.

In addition, since the present invention has been described through the preferred embodiment of the present invention, in view of the technical difficulty aspects of the present invention, those having ordinary skill in the art can easily be different from another embodiment of the present invention. As modifications may be made, it is obvious that both the embodiments and modifications cited in the above description belong to the appended claims.

As described in detail above, the scan number block to be output and the order of the blocks are determined according to the result of analyzing the arrangement of the pixel data, and the data is rearranged according to the scan number block, and then the scan number block Controlling the scan driver and the address driver according to the order of and blocks so that the scan pulse generated from the scan driver is applied to the plasma display panel, and the output of the address driver is applied to the plasma display panel according to the generated scan pulse. According to the present invention, it is possible to obtain sufficient luminance by increasing the display discharge time as the addressing time is reduced by minimizing the number of scans by simultaneously performing scans sequentially rather than sequentially according to the image data.

In short, according to the present invention, when driving a display device such as a plasma display panel, the addressing time required to designate the pixel data to be displayed can be significantly reduced, and thus the addressing time can be reduced, so that the display can be performed. Over time, the brightness of the display can be dramatically increased. In addition, as the addressing time is reduced, the driving time of the display is freed, which may effectively improve driving problems such as pseudo contours.

Claims (1)

A plasma display panel using light emitted from plasma; A digital image input unit for outputting digital image data to be displayed on the plasma display panel; An encoder for determining a scan number block and an order of blocks according to a result of analyzing the arrangement of the pixel data by receiving the output of the digital image input unit and rearranging the data according to the scan number block. A scan designation unit; An address driver for addressing pixel data to be displayed when the plasma display panel is driven; A scan driver for addressing scan and display discharge; And In response to the output of the digital image input unit and the output of the encode scan designator, the scan number block and the address driver are controlled according to the order of the scan number block and the block so that the scan pulse generated by the scan driver is displayed in the plasma display. And an address / scan pulse control unit configured to be applied to the panel and controlling the output of the address driver to be applied to the plasma display panel according to the generated scan pulse. Panel drive.