KR20060022205A - Plasma display panel - Google Patents

Abstract

The present invention is to change the structure of the transparent electrode in each of the R, G, B discharge cells according to the light emission characteristics of the fluorescent material coated in the discharge cell to achieve a pure white within the error range without color temperature correction In this regard, the driving margin is increased by preventing the degradation of the gray level generated in the color temperature correction process.

The present invention includes a front substrate having a scan electrode and a sustain electrode formed thereon, a rear substrate having an address electrode arranged to intersect the scan electrode and the sustain electrode, and a red (R), green (G), and blue ( B) A plasma display panel including partition walls formed to partition discharge cells, respectively, wherein the scan electrode and the sustain electrode each comprise a transparent electrode and a bus electrode, and the red (R), green (G), and blue (B) layers. The length of at least one of the discharge cells in the transparent electrode toward the center of the discharge cell is different from the length of the transparent electrode in the discharge cell toward the center of the discharge cell.

Plasma Display Panel, Discharge Cell, R, G, B, Light Emitting Characteristics, Fluorescent Material, White Balance, Color Temperature Correction, Electrode Structure, Transparent Electrode

Description

Plasma Display Panel

1 is a diagram showing the structure of a typical plasma display panel.

2 is a view showing an electrode structure of a conventional plasma display panel.

3 is a diagram illustrating a method of implementing image gradation of a conventional plasma display panel.

4 is a diagram showing electrode structures in R, G, and B discharge cells of a conventional plasma display panel.

5 is a view for explaining light emission characteristics of R, G, and B discharge cells of a conventional plasma display panel.

6 is a view showing an electrode structure in the R, G, B discharge cells according to an embodiment of the plasma display panel of the present invention.

7A to 7B illustrate an example in which a length of a transparent electrode and a distance between transparent electrodes are determined in consideration of light emission characteristics of R, G, and B fluorescent materials in the embodiment of the plasma display panel of FIG. 6.

8 is a view showing an electrode structure in R, G, B discharge cells according to another embodiment of the plasma display panel of the present invention.

9 is a view showing an electrode structure in R, G, B discharge cells according to another embodiment of the plasma display panel of the present invention.

10 is a view for explaining the light emission characteristics of the R, G, B discharge cells of the plasma display panel of the present invention.

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

60: R discharge cell 61: G discharge cell

62: B discharge cell 112: address electrode

a: transparent electrode b: bus electrode

The present invention relates to a plasma display panel, and more particularly, to a plasma display panel for improving pure electrode white by improving an electrode structure in a discharge cell and increasing driving margin.

In general, a plasma display panel is a partition wall formed between an upper substrate and a lower substrate to form one unit cell, and each cell includes neon (Ne), helium (He), or a mixture of neon and helium (Ne + He) and An inert gas containing the same main discharge gas and a small amount of xenon is filled. When discharged by a high frequency voltage, the inert gas generates vacuum ultraviolet rays and emits phosphors formed between the partition walls to realize an image. Such a plasma display panel has a spotlight as a next generation display device because of its thin and light configuration.                         

1 illustrates a structure of a general plasma display panel. As shown, the plasma display panel is coupled in parallel with the upper substrate 100, which is the display surface on which the image is displayed, and the lower substrate 110 forming the rear surface with a predetermined distance therebetween.

On the upper substrate 100, a scan electrode 101 and a sustain electrode 102, that is, a transparent electrode (a) formed of a transparent ITO material and mutually discharged in one discharge cell and maintaining light emission of the cell, are made of a metallic material. The scan electrode 101 and the sustain electrode 102 provided as the bus electrode b are formed in pairs. The scan electrode 101 and the sustain electrode 102 are covered by one or more dielectric layers 103 which limit the discharge current and insulate the electrode pairs, and the magnesium oxide top surface of the dielectric layer 103 to facilitate the discharge conditions. A protective layer 104 on which (MgO) is deposited is formed.

On the lower substrate 110, a plurality of discharge spaces, that is, barrier ribs 111 of stripe type (or well type) for forming discharge cells are arranged in parallel. In addition, a plurality of address electrodes 112 which perform address discharge to generate vacuum ultraviolet rays are arranged in parallel with the partition wall 111. On the upper side of the lower substrate 110, R, G, and B phosphors 113 which emit visible light for image display during address discharge are coated. A white dielectric 114 is formed between the address electrode 112 and the phosphor 113 to protect the address electrode 112 and reflect visible light emitted from the phosphor 113 to the upper substrate 100.

2 is a diagram illustrating an electrode structure of a conventional plasma display panel. As shown, the electrode structure of the plasma display panel is formed by the transparent electrode (a) and the bus electrode (b) is arranged in a stripe on the front substrate, the address electrode 112 is a transparent electrode (a) and the bus electrode ( It is formed on the rear substrate (not shown) in the direction intersecting with b).

A method of implementing image gradation of the plasma display panel having such a structure is as shown in FIG. 3.

3 is a diagram illustrating a method of implementing image grayscale of a conventional plasma display panel. As shown in the drawing, the gray level display method of a conventional plasma display panel is driven by dividing one frame into several subfields having different number of emission times, and each subfield is reset period for discharging uniformly and discharge. It is divided into a sustain period for implementing gradation according to an address period and a discharge number for selecting a cell. For example, when displaying an image with 256 gray levels, a frame period (16.7 ms) corresponding to 1/60 second is divided into eight subfields SF1 through SF8, and eight subfields SF1 through. SF8) Each is subdivided into a reset period, an address period and a sustain period. The reset period and the address period of each subfield are the same for each subfield. The address discharge for selecting the discharge cell is caused by the voltage difference between the address electrode and the transparent electrode which is the scan electrode. The sustain period is increased at a rate of 2 ⁿ ( ^where n = 0, 1, 2, 3, 4, 5, 6, 7) in each subfield. In this way, since the sustain period is different in each subfield, the gray scale of the image is expressed by adjusting the sustain period of each subfield, that is, the number of sustain discharges.

The electrode structure in the discharge cell of the plasma display panel that implements the grayscale of the image in this manner is as follows.

4 is a view showing electrode structures in R, G, and B discharge cells of a conventional plasma display panel. As shown, the electrode structure in the R, G, B discharge cells of the conventional plasma display panel has a bus electrode b formed at both points in each of the R, G, B discharge cells 40, 41, 42. The polygonal transparent electrodes a are positioned at both points at which the bus electrodes b are formed to face each other with the center of the discharge cell interposed therebetween. In addition, the address electrode 112 corresponding to the bus electrode b and the transparent electrode (a) in a state in which the discharge space between the bus electrode (b) and the transparent electrode (a) in each discharge cell with a discharge distance therebetween. ) To intersect. Although not shown, a fluorescent material emitting light of each of R, G, and B is discharged between the transparent electrodes a in the R, G, and B discharge cells 40, 41, and 42. Therefore, the electrode structure of the R, G, B discharge cells 40, 41, 42, that is, the length of the transparent electrode a in each of the R, G, B discharge cells 40, 41, 42 in the discharge cell center direction ( The distance d between the L and the transparent electrodes a is the same, but the fluorescent material applied between the transparent electrodes a of the R, G, and B discharge cells 40, 41, and 42 is R, G, Because of the different B, each of the R, G, and B discharge cells 40, 41, and 42 may be R, G according to the light emission characteristics of the fluorescent material by the leveled and proportionally adjusted driving signals applied during the discharge of the plasma display panel. , Light of B is emitted at a predetermined gray level.

In the conventional plasma display panel having such an electrode structure, the electrode structures in the R, G, and B discharge cells 40, 41, and 42 are all the same, and light emitting fluorescent materials emitting light of R, G, and B are discharged. Since the characteristics are all different, when the same driving signal is input, the gray levels of the light emitted by the R, G, and B discharge cells 40, 41, and 42 are also different. Looking at the light emission characteristics of the R, G, B discharge cells 40, 41, 42 as shown in FIG.

5 is a diagram for describing light emission characteristics of R, G, and B discharge cells. As shown, the light emission characteristics of the R, G, B discharge cells 40, 41, 42 have the same driving signal, for example, the number of discharges n, of the R, G, B discharge cells 40, 41, 42, respectively. When the same signal is applied, the R, G, and B discharge cells 40, 41, and 42 each emit light of different gradations. This is caused by the light emission characteristics of the R, G, and B fluorescent materials applied to the R, G, and B discharge cells 40, 41, and 42. Accordingly, in order to realize pure white, white balance, that is, color temperature correction is required.

In order to correct such a color temperature, the conventional plasma display panel attempts to realize pure white by applying different driving waveforms to the electrodes of the R, G, and B discharge cells 40, 41, and 42 according to the light emission characteristics of the fluorescent material. For example, in the NTSC (National Television System Committee) method, the color temperature is corrected by processing an image signal at a ratio of Y = 0.3R + 0.6G + 0.1B. That is, the G discharge cell 41 coated with the G fluorescent material is applied to a driving signal having the same size, for example, a signal of the same magnitude as the order of G-R-B in the order of the R, G, and B fluorescent materials. The R discharge cell 40 which emits the light of the highest gradation, and then the R discharge cell 40 coated with the R fluorescent material emits the light of the second highest gradation, and finally the B discharge cell 42 which is coated with the B fluorescent material Since this light emits light having the lowest gray level, the driving signal having the largest magnitude is applied to the B discharge cell 42 to realize pure white, and the B discharge cell 42 is applied to the R discharge cell 40. The drive signal smaller than the applied drive signal by a predetermined ratio is applied, and the drive signal smaller by the predetermined ratio than the drive signal applied to the R discharge cell 40 is applied to the G discharge cell 41. Accordingly, each of the R, G, and B discharge cells 40, 41, and 42 emits R, G, and B light having the same gradation to realize pure white within an error range.

However, such a color temperature correction method has a problem in that the gray level is degraded in the process of leveling and processing the input image signal in order to adjust the ratio according to the light emission characteristics of the R, G, and B fluorescent materials.

Accordingly, an object of the present invention is to provide a plasma display panel capable of realizing pure white without adjusting a ratio by leveling an input image signal according to light emission characteristics of R, G, and B fluorescent materials.

Another object of the present invention is to reduce the deterioration of the driving margin.

In order to achieve the above object, the present invention provides a front substrate having a scan electrode and a sustain electrode formed thereon, a rear substrate having an address electrode arranged to intersect the scan electrode and the sustain electrode formed thereon, and a red (R) and green (G) layer formed on the rear substrate. And a partition wall formed to partition the blue (B) discharge cells, wherein the scan electrode and the sustain electrode each comprise a transparent electrode and a bus electrode, and the red (R) and green (G) electrodes. The length of the transparent electrode of the at least one discharge cell in the blue (B) discharge cell toward the center of the discharge cell is different from that of the other discharge cell in the center of the discharge cell.

The red (R), green (G), and blue (B) discharge cells may have different lengths in the center direction of the transparent electrode in each discharge cell.

The length of the red (R) discharge cell in the direction of the center of the discharge cell of the transparent electrode is smaller than the length of the blue (B) discharge cell in the direction of the center of the discharge cell of the transparent electrode, and discharge of the transparent electrode of the green (G) discharge cell. The length in the cell center direction is smaller than the length in the center of the discharge cell of the transparent electrode of the red (R) discharge cell.

Among the red (R), green (G), and blue (B) discharge cells, the lengths of the transparent electrodes in the center of the discharge cell are equal to each other, and the lengths of the transparent electrodes in the other discharge cells are the same. It is characterized by another.

The length of the transparent electrode of the red (R) discharge cell in the direction of the center of the discharge cell and the length of the green (G) discharge cell of the transparent electrode in the center of the discharge cell are the same, and the length of the transparent electrode of the blue (B) discharge cell is the same. The length of the discharge cells in the center direction is greater than the length of the red (R) discharge cells or the green (G) discharge cells in the discharge cell center direction.

Hereinafter, a plasma display panel of the present invention will be described in detail with reference to the accompanying drawings. 6 is a view showing an electrode structure in a discharge cell according to an embodiment of the plasma display panel of the present invention. As shown, the electrode structure in the red (R), green (G), blue (B) discharge cells according to an embodiment of the plasma display panel of the present invention is each of the R, G, B discharge cells (60, Bus electrodes b are formed at both points in the 61 and 62, and rectangular transparent electrodes a are positioned at both points at which the bus electrodes b are formed, thereby interposing the centers of the R, G, and B discharge cells. It is made to face each other. In addition, the address electrode 112 corresponds to the bus electrode b in the R, G, and B discharge cells, and the bus electrode b is spaced apart by a predetermined distance with the discharge electrode interposed therebetween. And the transparent electrode a. Although not shown, a fluorescent material that emits light of each of R, G, and B is discharged between the transparent electrodes a in each of the R, G, and B discharge cells 60, 61, and 62. In addition, the transparent electrodes a in each of the R, G, and B discharge cells 60, 61, and 62 have different structures for each discharge cell. For example, the length LB of the transparent electrode a in the B discharge cell 62 toward the center of the discharge cell is relatively long, and the transparent electrode a in the R discharge cell 60 is relatively long. The length L _R in the discharge cell center direction is smaller than the length L _B in the discharge cell center direction in the B discharge cell 62, and the length of the transparent electrode a in the G discharge cell 61. The length L _G in the discharge cell center direction is smaller than the length L _R in the discharge cell center direction in the R discharge cell 61.

The reason for adjusting the length of the transparent electrode a in the R, G, B discharge cells 60, 61, and 62 toward the center of the discharge cell is the area of the transparent electrode a or the transparent electrodes a. This is because the amount of light emitted can be adjusted by adjusting the interval between them. For example, when the length of the transverse direction (the traveling direction of the bus electrode b) of the transparent electrode a is fixed, the length of the longitudinal direction (the discharge cell center direction) of the transparent electrode a is increased to make the whole transparent. As the area of the electrode a is increased, more wall charges participating in the discharge voltage during discharge are generated, thereby increasing the amount of light emitted by the same driving signal, for example, the signal having the same number of discharges, and conversely, the transparent electrode a When the length of the transverse direction (the traveling direction of the bus electrode b) is fixed, the length of the transverse direction (the discharge cell center direction) of the transparent electrode a is reduced and the area of the entire transparent electrode a is reduced. Accordingly, relatively little wall charges participating in the discharge voltage during discharge are generated, thereby reducing the amount of light emitted by the same driving signal. Further, as the distance between the transparent electrodes a facing each other increases, the amount of light emitted by the same driving signal decreases, and as the distance between the transparent electrodes a facing each other decreases, the amount of light emitted by the same driving signal increases. . As a result, when the length of the transparent electrode a in the R, G, B discharge cells 60, 61, 62 is fixed in the horizontal direction of the discharge cell center, the R, G, B discharges are controlled. Since the distance between the transparent electrodes a in the cells 60, 61, and 62 is also adjusted, the center of the discharge cells of the transparent electrodes a in the R, G, and B discharge cells 60, 61, and 62 is adjusted accordingly. The amount of light emitted from each of the discharge cells can be controlled by controlling the length and the interval between the transparent electrodes a in the R, G, and B discharge cells 60, 61, and 62.

The length of each transparent electrode (a) in each of the R, G, B discharge cells (60, 61, 62) to achieve pure white in this electrode structure is within the R, G, B discharge cells (60, 61, 62) It is determined by the light emission characteristics of R, G, and B fluorescent materials applied. As a result, the interval between the transparent electrodes a in each of the R, G, and B discharge cells 60, 61, and 62 for realizing pure white is also applied in the R, G, and B discharge cells 60, 61, and 62. It is determined by the light emission characteristics of R, G, and B fluorescent materials. An example in which electrode structures in each of the R, G, and B discharge cells 60, 61, and 62 are determined by the light emission characteristics of the R, G, and B fluorescent materials is shown in FIGS. 7A through 7B.                     

7A to 7B illustrate an example in which a length of a transparent electrode and a distance between transparent electrodes are determined in consideration of light emitting characteristics of R, G, and B fluorescent materials in the embodiment of the plasma display panel of FIG. 6. First, referring to FIG. 7A, the length of the transparent electrode a in each of the R, G, and B discharge cells 60, 61, and 62 of the plasma display panel according to the present invention toward the center of the discharge cell is 100 nm, and each R, G is 100 nm. Assuming that the distance between the transparent electrodes a is 100 nm in the B discharge cells 60, 61, and 62, and the same driving signal, for example, a voltage of 100 V is applied, the R discharge cell 60 has a gray level of 32. It is assumed that the G discharge cell 61 realizes 40 gray levels and the B discharge cell 62 realizes 28 gray levels. That is, when the potential difference between both transparent electrodes a is 100 V, the R discharge cells 60 emit light at 32 gradations, the G discharge cells 61 emit light at 40 gradations, and the B discharge cells 62 emit 28 Light emission with gradation, that is, light emission with gradation ratio of R: G: B = 32: 40: 28, and each time the applied driving signal decreases or increases by 1V, the gradation realized decreases or increases by 1, and each R, G When the sum of the lengths of both transparent electrodes a in the discharge cell center direction in the B discharge cells 60, 61, 62 decreases or increases by 1 nm, the potential difference between the two transparent electrodes a decreases or increases by 1V. When the distance between the transparent electrodes a in each of the R, G, and B discharge cells 60, 61, and 62 decreases or increases by 1 nm, the potential difference between the two transparent electrodes a decreases or increases by 1V. Assume

The structure of the transparent electrode a of each of the R, G, and B discharge cells 60, 61, and 62 is changed in FIG. 7B so that the plasma display panel of FIG. 7A having such a condition realizes pure white.

Referring to FIG. 7B, the lengths of the R discharge cells 70 in the direction of the center of the discharge cells of the transparent electrodes a are 101 nm, and the gaps between the transparent electrodes a are 98 nm. The length of the G discharge cells 71 in the direction of the center of the discharge cells of the transparent electrodes a is 99 nm, and the distance between the transparent electrodes a is 102 nm. The length of the B discharge cells 72 in the direction of the center of the discharge cells of the transparent electrodes a is 102 nm, and the interval between the transparent electrodes a is 96 nm.

The driving signal applied to each of the R, G, and B discharge cells 70, 71, and 72 is the length of the transparent electrode a in the R discharge cell 70 toward the center of the discharge cell in the state of being kept constant at 100V. Is increased by 1 nm, the spacing between the transparent electrodes a in the R discharge cell 70 decreases by 2 nm, increasing the voltage of 2 V by the increase of 2 nm of the total length of both transparent electrodes a toward the center of the discharge cell. The voltage difference of 2V due to the decrease of 2 nm of the gap between the transparent electrodes a and the transparent electrodes a causes the potential difference of the voltage across the transparent electrodes a of the R discharge cells 70 to be 104V, resulting in R discharge cells ( 70) emits light of 36 gradations.

In addition, when the length of the transparent electrode a in the G discharge cell 71 toward the center of the discharge cell is decreased by 1 nm, the interval between the transparent electrodes a in the G discharge cell 71 increases by 2 nm, thereby making it totally transparent. The voltage of 2V due to the decrease of 2V of the total length toward the center of the discharge cell of the electrode a and the decrease of the voltage of 2V by the increase of 2nm of the gap between the transparent electrodes a result in the The potential difference between the voltages applied to both transparent electrodes a becomes 96V, and as a result, the G discharge cells 71 emit 36 gray levels of light.

In addition, if the length of the transparent electrode a in the B discharge cell 72 is increased by 2 nm in the center direction of the discharge cell, the distance between the transparent electrodes a in the B discharge cell 72 decreases by 4 nm, thereby making it totally transparent. B discharge cell 72 is eventually caused by an increase in voltage of 4V due to a 4 nm increase in the total length of the discharge cell of the electrode a toward the center and a voltage increase of 4 V due to a 4 nm decrease in the gap between the transparent electrodes a. The potential difference between the voltages across both the transparent electrodes a is 108V, and as a result, the B discharge cells 72 emit 36 gray levels of light.

Accordingly, the transparent electrodes in each of the R, G, B discharge cells 70, 71, 72 are not applied to the R, G, B discharge cells 70, 71, 72 by applying leveling control signals by leveling. Only the structure of (a) can be changed to achieve pure white. Herein, the numerical values such as the length of the transparent electrodes a in the centers of the discharge cells in the R, G, and B discharge cells 70, 71, and 72 described above with reference to FIGS. The figures are arbitrarily designated for convenience of description, and these values are not features of the plasma display panel of the present invention.

In the above-described electrode structure of the plasma display panel of the present invention, the transparent electrodes a in each of the R, G, and B discharge cells have different structures for each of the discharge cells, and thus are the same for each of the R, G, and B discharge cells. Pure white, even when the driving signal is applied, differently, the transparent electrodes (a) in the two discharge cells of the R, G, B discharge cells have the same structure, the transparent electrode (a) in the other discharge cell Only one has a different structure, and the two discharge cells having the same transparent electrode (a) structure are applied with the leveled and scaled driving signal, and the other one is not applied with the unscaled driving signal. Pure white can be achieved. Alternatively, the same driving signal may be applied to each of the R, G, and B discharge cells to implement white of red tone or white of blue tone.

An electrode structure of the plasma display panel is illustrated in FIG. 8.                     

8 is a view showing an electrode structure in a discharge cell according to another embodiment of a plasma display panel of the present invention. As shown, the electrode structure in the discharge cell according to another embodiment of the plasma display panel of the present invention toward the center of the discharge cell of the transparent electrode (a) of the R discharge cell 80 and B discharge cell 82 The length of and the interval between each transparent electrode (a) is the same, except that the structure of the transparent electrode (a) in the G discharge cell 81 is a transparent electrode (a) of the R discharge cell 80 and B discharge cell 82 Is different from the structure. In the plasma display panel having such an electrode structure, the length of the transparent electrode a in the R discharge cell 80 in the direction of the center of the discharge cell is 101 nm, respectively, as compared with the case of FIG. 7B. Assuming that the interval is 98 nm, the length of the transparent electrode a in the G discharge cell 81 toward the center of the discharge cell is 99 nm, the interval between the transparent electrodes a is 102 nm, and the transparent in the B discharge cell 82 The length of the electrode a toward the center of the discharge cell is 101 nm, which is the same as that of the R discharge cell 80, and the gap between the transparent electrodes a is 98 nm, which is the same as the R discharge cell 80. At this time, assuming that 100 V driving signals are applied to each of the R, G, and B discharge cells 80, 81, and 82 as described above with reference to FIGS. 7A to 7B, the R discharge cells 80 and the G discharge cells 81 are used. Implements the same gradation of 36. In contrast, the B discharge cell 82 implements 32 gradations. Therefore, when the driving signal leveled to have a potential difference of 104 V is applied to the B discharge cell 82, the R discharge cell 80, the G discharge cell 81, and the B discharge cell 82 all realize the same gray level of 36. Thus, pure white is realized. Alternatively, the same driving signal may be applied to each of the R, G, and B discharge cells 80, 81, and 82 to implement white of red tone.

In contrast, the R discharge cell and the G discharge cell have the same electrode structure based on the R discharge cell, thereby applying a leveled driving signal to the G discharge cell, and the B discharge cell having the same gray level within the error range as the R and G discharge cells. There is also a method of implementing pure white by having a different electrode structure to implement. This method is illustrated in FIG. 9.

9 is a view showing an electrode structure in a discharge cell according to another embodiment of the plasma display panel of the present invention. As shown, the electrode structure in the discharge cell according to another embodiment of the plasma display panel of the present invention is the discharge cell center direction of the transparent electrode (a) of the R discharge cell 90 and G discharge cell 91 The length of the electrode and the distance between each transparent electrode a are the same, except that the structure of the transparent electrode a in the B discharge cell 92 is the transparent electrode a of the R discharge cell 90 and the G discharge cell 91. ) Is different from the structure. In the plasma display panel having such an electrode structure, the length of the transparent electrode a in the R discharge cell 90 in the center direction of the discharge cell is 101 nm, respectively, as compared with the case of FIG. 7B. Assuming that the interval is 98 nm, the transparent electrode a in the G discharge cell 91 also has the same structure as the R discharge cell 90, and the length of the transparent electrode a toward the center of the discharge cell is 101 nm. The interval between a) is 98 nm, the length of the transparent electrode a in the discharge cell 92 in the direction of the center of the discharge cell is 102 nm, and the interval between the transparent electrodes a is 96 nm. At this time, assuming that a driving signal of 100 V is applied to each of the R, G, and B discharge cells 90, 91, and 92 as described above with reference to FIGS. 7A to 7B, the R discharge cells 90 and the B discharge cells 92 are used. Implements the same gradation of 36. In contrast, the G discharge cell 91 realizes 44 gray levels. Therefore, when the driving signal leveled to have a potential difference of 92 V is applied to the G discharge cell 91, the R discharge cell 90, the G discharge cell 91, and the B discharge cell 92 all realize gray levels of 36. Thus, pure white is realized. Alternatively, the same driving signal may be applied to each of the R, G, and B discharge cells 90, 91, and 92 to implement white of blue tone.

The emission characteristics of the R, G, and B discharge cells of the plasma display panel according to the present invention are as follows.

10 is a view for explaining the light emission characteristics of the R, G, B discharge cells of the plasma display panel of the present invention. As shown, the light emission characteristics of the R, G, and B discharge cells of the plasma display panel according to the present invention are R, G, B discharge cells when the same drive signal, for example, the drive signal of the same number of discharges n is applied. Emits light of the same gradation within the margin of error. This is because the structure of the transparent electrode in the R, G, B discharge cells is changed according to the light emission characteristics of the R, G, B fluorescent material. Accordingly, pure white can be realized without white balance, that is, color temperature correction.

As described above, those skilled in the art will appreciate that the present invention can be implemented in other specific forms without changing the technical spirit or essential features.

Therefore, the above-described embodiments are to be understood as illustrative and not restrictive in all respects, and the scope of the present invention is indicated by the appended claims rather than the detailed description, and the meaning and scope of the claims and All changes or modifications derived from the equivalent concept should be interpreted as being included in the scope of the present invention.

 As described in detail above, the present invention changes the structure of the transparent electrode in each of the R, G, and B discharge cells according to the light emission characteristics of the fluorescent material coated in the discharge cell, thereby eliminating pure white color within the error range without color temperature correction. In addition, the driving margin may be improved by preventing a decrease in the gray level generated in the color temperature correction process.

Claims (5)

A front substrate having a scan electrode and a sustain electrode formed thereon, a back substrate having an address electrode arranged to intersect the scan electrode and the sustain electrode, and red (R), green (G), and blue (B) discharges on the back substrate A plasma display panel comprising partition walls formed to partition cells, respectively, The scan electrode and the sustain electrode are each made of a transparent electrode and a bus electrode, The length of at least one of the red (R), green (G), and blue (B) discharge cells in the direction of the center of the discharge cell of the transparent electrode of the discharge cell is equal to the length of the direction of the discharge cell of the transparent electrode of the other discharge cell. Another plasma display panel. The method of claim 1, And a length of each of the red (R), green (G), and blue (B) discharge cells in the discharge cell center direction is different from each other. The method of claim 2, The length of the transparent electrode of the red (R) discharge cell toward the center of the discharge cell is smaller than the length of the transparent electrode of the blue (B) discharge cell toward the center of the discharge cell and the transparent electrode of the green (G) discharge cell. And the length of the red (R) discharge cell in the center direction of the discharge cell is smaller than the length of the transparent electrode in the discharge cell center direction. The method of claim 1, Among the red (R), green (G), and blue (B) discharge cells, the lengths of the transparent electrodes in the center of the discharge cells are equal to each other, and the discharge cells of the transparent electrodes are disposed within the other discharge cells. And a plasma display panel different from the length in the center direction. The method of claim 4, wherein The length of the transparent electrode of the red (R) discharge cell toward the center of the discharge cell and the length of the green (G) discharge cell of the transparent electrode toward the center of the discharge cell are the same, and the transparent of the blue (B) discharge cell is the same. And a length of the electrode toward the center of the discharge cell is greater than a length of the red (R) discharge cell or the green (G) discharge cell toward the center of the discharge cell.

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