KR20070056858A - Electron emission display for reducing data distortion - Google Patents

Abstract

An electron emission display for reducing signal distortion is provided to represent accurate gray level of a data signal by compensating for distortion phenomenon in each line of the data signal. An electron emission display for reducing signal distortion includes a pixel unit(100), a clock generating unit(200) for generating and outputting a count clock signal as a compensation value for a first gradation pulse of an inputted image data signal, a data driving unit, a look-up table and a scan driving unit. The data driving unit(300) applies an image data signal to the pixel unit corresponding to the count clock signal. Scan blank signals obtained by compensating the image data signal every scan line are stored in the look-up table(400). The scan driving unit(500) applies scan signals to the pixel unit corresponding to the scan blank signals stored in the look-up table.

Description

Electronic emission display for reducing signal distortion {Electron Emission Display for Reducing Data Distortion}

1 is a view schematically showing a configuration of a conventional electron emission display device.

2 is a diagram illustrating a distortion of a signal output from a data driver according to the related art.

3 is a view schematically showing an example of the structure of an electron emission display device for reducing signal distortion according to the present invention.

FIG. 4 shows an example of a part of a pixel portion that can be employed in the electron emission display device shown in FIG.

5 illustrates the pulse width of a compensated data signal in accordance with the present invention.

<Description of main parts of drawing>

100 --- Pixel part 200 --- Clock generator

300 --- scan driver 400 --- lookup table

500 --- data driver

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an electron emission display device for reducing signal distortion, and more particularly, to an electron emission display device for reducing signal distortion that can express accurate gradation of a data signal by compensating for distortion of each line of a data signal. .

In general, a flat panel display (FPD) is a device for manufacturing a sealed container by standing a side wall between two substrates, and placing a suitable material inside the container to display a desired screen. Together, its importance is increasing. In response to this, various flat panel displays such as a liquid crystal display (LCD), a plasma panel (PDP), an electron emission display, and the like have been developed and put into practical use.

In particular, the electron-emitting display device can be implemented as a low-power flat-panel display without distorting the image while maintaining excellent characteristics of the cathode ray tube (CRT) by using phosphor emission by electron beams in the same way as the cathode ray tube (CRT). It is attracting attention as a next-generation display that is satisfactory in terms of high, viewing angle, high-speed response, high brightness, high definition, and thinness.

The electron emission display device has a structure of a triode having a cathode, an anode, and a gate electrode. Specifically, a cathode electrode generally used as a scan electrode is formed on a substrate, and an insulating layer having holes on the cathode electrode and a gate electrode generally used as a data electrode are stacked. An emitter, which is an electron emission source, is formed in the hole and contacts the cathode electrode.

The electron emission display device configured as described above concentrates a high electric field on an emitter and emits electrons by a quantum mechanical tunnel effect, and electrons emitted from the emitter are caused by a voltage applied between the cathode electrode and the anode electrode. By accelerating and colliding with the RGB fluorescent layer formed on the anode, the phosphor is emitted to represent an image.

As the emitted electrons collide with the fluorescent layer and the phosphor emits light, the luminance of the displayed image is changed according to the value of the input digital image signal. Specifically, the value of the digital video signal is composed of 8 bits of RGB data, respectively. That is, the value of the digital video signal may be 0 (00000000 ₍₂₎ ) to 255 (11111111 ₍₂₎ ), and thus 256 gray levels may be represented by 256 values. Luminance is expressed.

In order to adjust the luminance represented according to the value of the digital image signal, a pulse width modulation (PWM) method or a pulse modulation (PAM) method is generally used.

The PWM method modulates the pulse width of the driving waveform applied to the data electrode in accordance with the digital image signal input from the data electrode driver, and 255 is input as the value of the digital image signal within the maximum available on-time. In this case, the pulse width is maximized to display the maximum luminance, and when 127 is input as the value of the digital video signal, the pulse width is 1/2 to decrease the luminance. On the other hand, in the PAM method, the pulse width is constant regardless of the input digital video signal, but the luminance is controlled by varying the pulse voltage level of the driving waveform applied to the data electrode, that is, the pulse size, according to the input digital video signal.

1 is a view schematically showing a configuration of a conventional electron emission display device. As illustrated, the electron emission display device includes a pixel unit 10, a data driver 20, a scan driver 30, a power supply 40, and a controller 50.

The pixel portion 10 includes n scan lines S1, S2,... Sn, m data lines D1, D2, ... Dm, and an anode electrode ANODE. Scan lines S1, S2, ... Sn and data lines D1, D2, ... Dm cross each other. The anode ANODE may be formed over the entire area of the pixel portion as shown in the figure, and although not shown in the figure, may be formed in a plurality of stripe shapes formed in the row direction similar to the scan lines. Similar to the data lines, a plurality of stripes may be formed in a column direction or may be formed in a mesh form.

Even when the anode electrode is formed in the form of a plurality of stripes or in the form of a mesh, generally the same voltage (Vanode) is applied to the entire anode electrode. The electron emission device including the cathode electrode, the gate electrode, and the anode electrode is formed in an area where the scan line and the data line intersect, one of the scan line and the data line acts as a cathode, and the other of the scan line and the data line is a gate. It acts as an electrode.

The data driver 20 performs a function of applying a data signal corresponding to the input image data DATA to the data lines D1, D2,..., Dm. In the present invention, a pulse width modulation (also referred to as PWM) data driving unit will be described. However, any data driving unit for adjusting the electron emission time of the electron emitting device in response to the input image data is the scope of the present invention. Included in

The scan driver 30 sequentially applies a scan signal to the scan lines S1, S2,... Sn.

The power supply 40 includes a microcomputer 41 and a D / A converter 42. The first power supply VS1 is applied to the data driver 20, and the second power supply VS2 is applied to the scan driver 30. And the third power source VS3 is applied to the anode electrode.

The controller 50 includes a frame memory 51, a LUT 52, and an operation unit 53, and after obtaining an image level of the image data DATA, a voltage applied to the anode electrode corresponding to the obtained image level. And at least one of a voltage applied to the cathode electrode and a voltage applied to the gate electrode. Here, the image level is a concept corresponding to the brightness of the entire pixel portion 10. A high image level means that the pixel portion 10 is bright, and a low image level means that the pixel portion 10 is dark. Means that. The image level can be obtained by, for example, summing up image data DATA of one frame.

The controller 50 controls the power supply 40 to increase the anode voltage at the time of electron emission when the image level is low and to decrease the anode voltage at the time of electron emission when the image level is high. When the brightness is realized by controlling the anode voltage, not only the number of gray levels is reduced, but also the driving conditions such as the pulse width modulation method (PWM) or the amplitude modulation method (PAM) can be easily realized without changing the driving conditions.

In addition, the power supply 40 is controlled to increase the difference between the cathode voltage and the gate voltage. The controller 50 reduces the difference between the cathode voltage and the gate voltage at the time of electron emission when the image level is increased, and increases the difference between the cathode voltage and the gate voltage at the time of electron emission when the image level is decreased. ).

However, in the conventional electron emission display device, the luminance difference between the beginning and the end of the data line is generated even when the gray level is the same due to the signal distortion of the data line, thereby preventing accurate gray scale representation.

2 is a diagram illustrating a distortion of a signal output from a data driver according to the related art. As shown in the drawing, the signal output from the data driver is severely distorted as the signal goes downward, thereby causing a problem of lowering luminance and low gray scale expression.

SUMMARY OF THE INVENTION An object of the present invention is to provide an electron emission display device for reducing signal distortion that can compensate for distortion of each line of a data signal to express accurate gray scale of the data signal.

In order to achieve the above object, an electron emission display device for reducing signal distortion according to the present invention includes: a pixel unit; A clock generator for generating and outputting a count clock signal of a compensation value for the first gray pulse of the input image data signal; A data driver for applying an image data signal in response to a count clock signal of a compensation value for the first gray pulse output from the clock generator; A lookup table configured to compensate for a scan blank signal for each scan line of the data signal output from the data driver; It is characterized in that it comprises a scan driver for applying a scan signal corresponding to the scan blank signal stored in the lookup table.

In particular, the scan driver may output the image data signal having an increased compensation value for the first gray pulse output from the data driver by controlling the scan blank signal according to the scan line.

In particular, the clock generator is characterized in that the main clock is generated as a count clock of the compensation value for the first gray pulse according to the image data signal.

Here, in particular, the compensation value of the scan blank signal stored according to the scan line of the lookup table is divided into a predetermined number of steps, and a compensation value according to a predetermined number of frames is stored, and the predetermined number of frames is a number of steps using a random function. * This feature is characterized by the fact that the compensation value for N frame values is stored.

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

3 is a view schematically showing an example of the structure of an electron emission display device according to the present invention. As shown in the drawing, an electron emission display device for reducing signal distortion according to the present invention includes: a pixel unit 100; A clock generator 200 generating and outputting a count clock signal of a compensation value for the first gray pulse of the input image data signal; A data driver 300 for applying an image data signal corresponding to the count clock signal of the compensation value for the first gray pulse output from the clock generator 200; A lookup table (400) storing the data signal output from the data driver (300) by compensating a scan blank signal for each scan line; And a scan driver 500 for applying a scan signal corresponding to the scan blank signal stored in the lookup table 400.

The pixel unit 100 includes n scan lines S1, S2,... Sn, m data lines D1, D2, ... Dm, and an anode electrode ANODE, and scan lines S1, S2. , ... Sn and the plurality of pixels 50 are formed in a region where the data lines D1, D2, ... Dm cross each other. In this case, the anode electrode ANODE may be formed over the entire area of the pixel portion 100, and any one of the scan lines S1, S2,... Sn and the data lines D1, D2,... It may be used as a cathode electrode and the other one may be used as a gate electrode.

The clock generator 200 generates a count clock corresponding to an image data signal of a main clock input from an external source.

More specifically, the clock signal is generated as a count clock in consideration of the compensation value for the first gray pulse of the input image data signal. That is, as the input image data signal descends to the scan line, the first gray pulse becomes severely distorted. The count clock is generated by calculating a maximum value for one gray that can compensate for the distortion along the scan line.

In the look up table 400, a compensation value of a scan blank signal according to a scan line is stored. In this case, the compensation value of the scan blank signal is divided into a predetermined number of steps, and a compensation value according to a predetermined number of frames is stored, and the predetermined number of frames have a compensation value for the number of steps * N frames using a random function. Stored. For example, since the compensation value of the scan blank signal is difficult to divide by the resolution (for example, 768 or more), the desired value can be expressed in the number of possible steps (step 10). In addition, the scan blank signal can be expressed over N frames, and the scan blank signal is output only once during N frames to be the lowest compensation value. Here, the degradation of the image quality that cannot be represented every frame can be solved by applying a random function.

In addition, the data conversion index for each step is stored by dividing the average value of the reference luminance level of the image data signals into detailed steps of light and dark of the screen according to the average value.

The scan driver 500 sequentially applies a scan signal to the plurality of scan lines S1, S2,... Sn. At this time, the scan signal scanned in each line is applied to include the pulse width of the maximum value of the compensation of the image data signal.

The data driver 300 applies an image data DATA signal previously compensated for the first gray pulse to the plurality of data lines D1, D2,...

4 is a diagram illustrating an example of a part of a pixel unit that may be employed in the electron emission display device illustrated in FIG. 3. As shown therein, the pixel unit 100 includes an electron emission substrate 120 and an image forming substrate 130. In addition, the electronic device may further include a spacer 140 that maintains a constant gap between the electron emission substrate 120 and the image forming substrate 130.

The electron emission substrate 120 is a substrate that emits electrons in response to the voltage between the cathode electrode 122 and the gate electrode 124. The back substrate 121, the cathode electrode 122, the insulating layer 123, and the gate are provided. The electrode 124 and the electron emission part 125 are provided.

The back substrate 121 may be, for example, a glass or silicon substrate. When the back substrate 121 is formed by back exposure using a carbon nanotube (CNT) paste as the electron emission unit 125, a transparent substrate such as a glass substrate is preferable. .

The cathode electrode 122 may be formed in a stripe shape on the rear substrate. The cathode electrode 122 is supplied with a data signal or a scan signal applied from the data driver or the scan driver. The cathode electrode 122 may be a conductor and may be a transparent conductor such as indium tin oxide (ITO), for the same reason as the back substrate 121.

The insulating layer 123 is formed on the back substrate 121 and the cathode electrode 122, and electrically insulates the cathode electrode 122 from the gate electrode 124. The insulating layer 123 may be made of an insulating material, for example, PbO and SiO ₂ mixed glass.

The gate electrode 124 is disposed on the insulating layer 123 in a predetermined shape, for example, in a direction crossing the cathode electrode 122 on a stripe, and each data signal or scan signal applied from the data driver or the scan driver. Is supplied. The gate electrode 124 is made of a metal having good conductivity, such as at least one conductive metal material selected from gold (Au), silver (Ag), platinum (Pt), aluminum (Al), chromium (Cr), and alloys thereof. Can be. The insulating layer 123 and the gate electrode 124 have at least one first opening 126 at the intersection of the cathode electrode 122 and the gate electrode 124 so that the cathode electrode 122 is exposed.

The electron emission unit 125 is electrically connected to and positioned on the cathode electrode 122 exposed by the first opening 126, and includes a carbon nanotube; Nanotubes by graphite, diamond, diamond-like carbon or a combination thereof; Or a nanowire of Si or SiC.

The image forming substrate 130 is a substrate for forming an image by collision of electrons emitted from the electron emission substrate 120 to emit light. The image forming substrate 130 includes a front substrate 131, an anode electrode 132, a phosphor 133, and a light shielding film. 134 and a metal reflective film 135.

The front substrate 131 is preferably made of a transparent material such as glass so that light emitted from the phosphor 133 is transmitted to the outside.

The anode electrode 132 is preferably made of a transparent material such as an ITO electrode so that light emitted from the phosphor 133 is transmitted to the outside. The anode electrode 132 accelerates the electrons emitted from the electron emitting device even better. To this end, a high voltage positive voltage is applied to the anode electrode 132 to accelerate the electrons toward the phosphor 133.

The phosphor 133 emits light due to the collision of electrons emitted from the electron emission substrate 120, and is selectively disposed on the anode electrode 132 at random intervals. Examples of the G phosphor, that is, the phosphor that develops green color include, for example, ZnS: Cu, Zn ₂ SiO ₄ : Mn, ZnS: Cu + Zn ₂ SiO ₄ : Mn, Gd ₂ O ₂ S: Tb, Y ₃ Al ₅ O ₁₂ : Ce, ZnS: Cu, Al, Y ₂ O ₂ S: Tb, ZnO: Zn, ZnS: Cu, Al + In ₂ O ₃ , LaPO ₄ : Ce, Tb, BaO · 6Al ₂ O ₃ : Mn, (Zn, Cd) S: Ag, (Zn, Cd) S: Cu, Al, ZnS: Cu, Au, Al, Y ₃ (Al, Ga) ₂ O ₁₂ : Tb, Y ₂ SiO ₅ : Tb, or LaOCl: Tb Can be used. In addition, the B phosphor, i.e., a phosphor that develops blue color, may be, for example, ZnS: Ag, ZnS: Ag, Al, ZnS: Ag, Ga, Al, ZnS: Ag, Cu, Ga, Cl, ZnS: Ag + In ₂ O. ₃ , Ca ₂ B ₅ O ₉ Cl: Eu ²⁺ , (Sr, Ca, Ba, Mg) ₁₀ (PO ₄ ) ₆ Cl ₂ : Eu ²⁺ , Sr ₁₀ (PO ₄ ) ₆ C ₂ : Eu ²⁺ , BaMgAl ₁₆ O ₂₆ : Eu ²⁺ , CoO, Al ₂ O ₃ Added ZnS: Ag, ZnS: Ag or Ga may be used. Further, the R phosphor, i.e., the phosphor emitting red color, may be, for example, Y ₂ O ₂ S: Eu, Zn ₃ (PO ₄ ) ₂ : Mn, Y ₂ O ₃ : Eu, YVO ₄ : Eu, (Y, Gd) BO ₃ : Eu, γ-Zn ₃ (PO ₄ ) ₂ : Mn, (ZnCd) S: Ag, (ZnCd) S: Ag + In ₂ O ₃ , or Fe ₂ O ₃ added Y ₂ O ₂ S: Eu Can be used.

The light shielding film 134 is disposed at random intervals between the phosphors 133 to absorb and block external light and prevent optical crosstalk, thereby improving contrast ratio.

The metal reflective film is formed on the phosphor 133 to better focus electrons emitted from the electron emission substrate 120, and reflects light emitted from the phosphor 133 to the front substrate 131 by collision of electrons. To improve reflection efficiency. On the other hand, if the metal reflecting film serves as an anode electrode, the formation of the anode electrode 132 is optional and may be an unnecessary component.

5 is a diagram illustrating a pulse width of a scan blank signal according to a data signal according to the present invention. As shown in the drawing, an image data signal having an increased compensation value for the first gray pulse output from the data driver 300 is controlled by the scan driver to output a scan blank signal according to a scan line.

That is, the data signal is one of 0 to 255 gray, and includes a pulse width for the first gray value in advance, and in a low step the scan blank signal according to the scan line output from the scan driver 500 is lowered. The output will be compensated to a higher level.

The scan blank signal outputs a value compensated for the first gray pulse as an uncompensated value, and outputs the compensated value stored in the lookup table 400 from the second scan line.

Although the present invention has been described with reference to the embodiments illustrated in the drawings, this is merely exemplary, and it will be understood by those skilled in the art that various modifications and equivalent other embodiments are possible. Therefore, the true technical protection scope of the present invention will be defined by the technical spirit of the appended claims.

As described above, the electron emission display device for reducing the signal distortion of the present invention can express the accurate gradation of the data signal by compensating for the distortion of each line of the data signal.

Claims (5)

A pixel portion; A clock generator for generating and outputting a count clock signal of a compensation value for the first gray pulse of the input image data signal; A data driver for applying an image data signal in response to a count clock signal of a compensation value for the first gray pulse output from the clock generator; A lookup table configured to compensate for a scan blank signal for each scan line of the data signal output from the data driver; And a scan driver configured to apply a scan signal in response to the scan blank signal stored in the lookup table. The method of claim 1, And controlling the scan blank signal according to the scan line to the image data signal having the increased compensation value for the first gray pulse output from the data driver. The method of claim 1, And the clock generation unit generates the input main clock as a count clock of a compensation value for the first gray pulse according to the image data signal. The method of claim 1, The compensation value of the scan blank signal stored according to the scan line of the lookup table is divided into a predetermined number of steps, and the compensation value according to the predetermined number of frames is stored. The method of claim 4, wherein And a compensation value for the number of steps * N frame values is stored in the predetermined number of frames using a random function.

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