KR100581891B1 - Plasma display panel - Google Patents

Abstract

An object of the present invention is to provide a plasma display panel in which the overall brightness is remarkably improved and streaks are not generated during full white driving.

The present invention, in order to achieve the above object, the back substrate; A plurality of address electrodes disposed in parallel with each other on an upper side of the rear substrate; A first dielectric layer covering the address electrodes; Red light emitting cells, green light emitting cells, blue light emitting cells, and white light emitting cells defined by a barrier rib formed on an upper side of the first dielectric layer; A red light emitting phosphor, a green light emitting phosphor, a blue light emitting phosphor, and a white light emitting phosphor coated in the red light emitting cells, the green light emitting cells, the blue light emitting cells, and the white light emitting cells, respectively; A front substrate disposed to face the rear substrate; A plurality of sustain electrode pairs disposed below the front substrate to intersect the address electrodes; And a second dielectric layer covering the sustain electrode pairs.

The sustain electrode pair includes an X electrode and a Y electrode, and each of the X electrode and the Y electrode has sub electrodes continuously extending over a row of light emitting cells, and the sub part of the X electrode disposed in the white light emitting cell. Electrodes are electrically connected by a short bar, and sub-electrodes of the Y electrode disposed in the white light emitting cell are electrically connected by a short bar.

Description

Plasma display panel {Plasma display panel}

1 is a plan view showing a part of a plasma display panel having four color light emitting cells;

2 is a partial cutaway perspective view showing a part of a plasma display panel according to a first embodiment of the present invention;

3 is a plan view seen from the direction A of FIG.

4A is a cross-sectional view showing a state before the sub-electrodes of the X electrode and the Y electrode of the plasma display panel according to the present invention are patterned;

4B is a cross-sectional view showing a state after the sub electrodes of the X electrode and the Y electrode of the plasma display panel according to the present invention are patterned;

5 is a plan view showing a modification of the first embodiment,

FIG. 6 is a graph showing light emission luminances varying from a center of the light emitting cell shown in FIG.

FIG. 7 is a plan view of a portion of a plasma display panel according to a second exemplary embodiment of the present invention seen in the direction A of FIG. 2;

8 is a plan view showing a first modification of the second embodiment,

9 is a plan view showing a second modification of the second embodiment,

FIG. 10 is a plan view of a portion of a plasma display panel according to a third exemplary embodiment of the present invention as viewed in direction A of FIG. 2;

11 is a plan view showing a first modification of the third embodiment,

12 is a plan view showing a second modification of the third embodiment,

FIG. 13 is a plan view of a portion of a plasma display panel according to a fourth embodiment of the present invention as viewed in the direction A of FIG. 2;

14 is a plan view showing a first modification of the fourth embodiment,

Fig. 15 is a plan view showing a second modification of the fourth embodiment.

Explanation of symbols on the main parts of the drawings

10: back substrate 20: address electrode

30: first dielectric layer 40: partition wall

50r: red light emitting cell 50g: green light emitting cell

50b: blue light emitting cell 50w: white light emitting cell

60: front substrate 80: second dielectric layer

81: electrode sheet 81a: white layer

81b: dark layer 81c: resist layer

X: X electrode Xsb: Short bar of X electrode

X1, X2, X3, X4: first sub electrode, second sub electrode, third sub electrode, fourth sub electrode

Y: Y electrode Ysb: Short bar of Y electrode

Y1, Y2, Y3, Y4: first sub electrode, second sub electrode, third sub electrode, fourth sub electrode

W1: width of first subelectrode W2: width of second subelectrode

W3: width of third sub-electrode W4: width of fourth sub-electrode

G0: distance from the center of the light emitting cell to the first sub-electrode

G1: gap between the first sub-electrode and the second sub-electrode

G2: gap between the second sub electrode and the third sub electrode

G3: spacing between the third sub-electrode and the fourth sub-electrode

R: red phosphor G: green phosphor

B: blue light emitting phosphor W: white light emitting phosphor

The present invention relates to a plasma display panel having four light emitting cells including a red light emitting cell, a green light emitting cell, a blue light emitting cell, and a white light emitting cell, and more particularly, to a plasma display having improved luminance of a white light emitting cell. It is about the panel.

The conventional plasma display panel having three color light emitting cells including a red light emitting cell, a green light emitting cell, and a blue light emitting cell has a problem in that luminance, which is a major factor in image quality, is weak compared to other display devices.

SUMMARY OF THE INVENTION An object of the present invention is to solve the above problems and to provide a plasma display panel with significantly improved overall brightness.                         

Another object of the present invention is to provide a plasma display panel in which streaks are not generated during full white driving.

The present invention to achieve the above object,

Back substrate;

A plurality of address electrodes disposed in parallel with each other on an upper side of the rear substrate;

A first dielectric layer covering the address electrodes;

Red light emitting cells, green light emitting cells, blue light emitting cells, and white light emitting cells defined by a barrier rib formed on an upper side of the first dielectric layer;

A red light emitting phosphor, a green light emitting phosphor, a blue light emitting phosphor, and a white light emitting phosphor coated in the red light emitting cells, the green light emitting cells, the blue light emitting cells, and the white light emitting cells, respectively;

A front substrate disposed to face the rear substrate;

A plurality of sustain electrode pairs disposed below the front substrate to intersect the address electrodes; And

A second dielectric layer covering the sustain electrode pairs;

The sustain electrode pair includes an X electrode and a Y electrode, and each of the X electrode and the Y electrode has sub electrodes continuously extending over a row of light emitting cells, and the sub part of the X electrode disposed in the white light emitting cell. Electrodes are electrically connected by a short bar, and sub-electrodes of the Y electrode disposed in the white light emitting cell are electrically connected by a short bar.

The spacing between the first and second sub-electrodes disposed from the centers of the light emitting cells of each of the X and Y electrodes disposed in all of the light emitting cells is between the second and third sub-electrodes arranged from the center of the light emitting cells. It is preferred to be wider than the interval.

In addition, the present invention to achieve the above object,

Back substrate;

A plurality of address electrodes disposed in parallel with each other on an upper side of the rear substrate;

A first dielectric layer covering the address electrodes;

Red light emitting cells, green light emitting cells, blue light emitting cells, and white light emitting cells defined by a barrier rib formed on an upper side of the first dielectric layer;

A red light emitting phosphor, a green light emitting phosphor, a blue light emitting phosphor, and a white light emitting phosphor coated in the red light emitting cells, the green light emitting cells, the blue light emitting cells, and the white light emitting cells, respectively;

A front substrate disposed to face the rear substrate;

A plurality of sustain electrode pairs disposed below the front substrate to intersect the address electrodes; And

A second dielectric layer covering the sustain electrode pairs;

The sustain electrode pair includes an X electrode and a Y electrode, and each of the X electrode and the Y electrode includes sub-electrodes, and the first and second electrodes from the center of the light emitting cell of each of the X and Y electrodes disposed in the white light emitting cell. The interval between the sub-electrodes arranged in the second is provided from the center of the white light emitting cell is wider than the interval between the sub-electrodes disposed in the second and third.

The sub-electrodes of the X electrode disposed in the white light emitting cell are electrically connected by a short bar, and the sub-electrodes of the Y electrode arranged in the white light emitting cell are electrically connected by a short bar.

It is preferable that the sub-electrodes of the X electrodes arranged in all the light emitting cells are electrically connected by a short bar, and the sub-electrodes of the Y electrodes arranged in all the light emitting cells are electrically connected by a short bar.

Some of the sub-electrodes of the X electrode and some of the sub-electrodes of the Y electrode are intermittently intermittent for each light emitting cell.

Furthermore, the present invention to achieve the above object,

Back substrate;

A plurality of address electrodes disposed in parallel with each other on an upper side of the rear substrate;

A first dielectric layer covering the address electrodes;

Red light emitting cells, green light emitting cells, blue light emitting cells, and white light emitting cells defined by a barrier rib formed on an upper side of the first dielectric layer;

A red light emitting phosphor, a green light emitting phosphor, a blue light emitting phosphor, and a white light emitting phosphor coated in the red light emitting cells, the green light emitting cells, the blue light emitting cells, and the white light emitting cells, respectively;

A front substrate disposed to face the rear substrate;

A plurality of sustain electrode pairs disposed below the front substrate to intersect the address electrodes; And

A second dielectric layer covering the sustain electrode pairs;

The sustain electrode pair includes an X electrode and a Y electrode, and each of the X electrode and the Y electrode includes sub-electrodes, and the first and second electrodes from the center of the light emitting cell of each of the X and Y electrodes disposed in the white light emitting cell. The distance between the sub-electrodes arranged in the second is wider than the distance between the sub-electrodes arranged in the first and second from the center of the light emitting cell of each of the X electrode and the Y electrode disposed in the other light emitting cell to provide.

The distance between the second and third sub-electrodes disposed from the centers of the light emitting cells of the X and Y electrodes disposed in the white light emitting cells is two from the center of the light emitting cells of each of the X and Y electrodes arranged in the other light emitting cells. It is preferable that the gap between the secondary electrodes arranged in the second and third is wider than the interval.

The sub-electrodes of the X electrode disposed in the white light emitting cell are electrically connected by a short bar, and the sub-electrodes of the Y electrode arranged in the white light emitting cell are electrically connected by a short bar.

It is preferable that the sub-electrodes of the X electrodes arranged in all the light emitting cells are electrically connected by a short bar, and the sub-electrodes of the Y electrodes arranged in all the light emitting cells are electrically connected by a short bar.

Some of the sub-electrodes of the X electrode and some of the sub-electrodes of the Y electrode are preferably connected to each light emitting cell.

Furthermore, the present invention to achieve the above object,

Back substrate;

A plurality of address electrodes disposed in parallel with each other on an upper side of the rear substrate;

A first dielectric layer covering the address electrodes;

Red light emitting cells, green light emitting cells, blue light emitting cells, and white light emitting cells defined by a barrier rib formed on an upper side of the first dielectric layer;

A red light emitting phosphor, a green light emitting phosphor, a blue light emitting phosphor, and a white light emitting phosphor coated in the red light emitting cells, the green light emitting cells, the blue light emitting cells, and the white light emitting cells, respectively;

A front substrate disposed to face the rear substrate;

A plurality of sustain electrode pairs disposed below the front substrate to intersect the address electrodes; And

A second dielectric layer covering the sustain electrode pairs;

The sustain electrode pair includes an X electrode and a Y electrode, each of the X electrode and the Y electrode includes sub electrodes, and the number of sub electrodes disposed on each of the X electrode and the Y electrode disposed in the white light emitting cell is different. The present invention provides a plasma display panel, wherein the number of sub electrodes disposed on each of the X electrode and the Y electrode disposed in the light emitting cell is smaller than the number of sub electrodes.

The distance between the first and second sub-electrodes disposed in the white light emitting cells and the centers of the light emitting cells of each of the Y electrodes is from the center of the light emitting cells of each of the X and Y electrodes arranged in the other light emitting cells. It is preferable that the gap between the first and second secondary electrodes is wider than the gap.

The distance between the second and third sub-electrodes disposed from the centers of the light emitting cells of the X and Y electrodes disposed in the white light emitting cells is two from the center of the light emitting cells of each of the X and Y electrodes arranged in the other light emitting cells. It is preferable that the gap between the secondary electrodes arranged in the second and third is wider than the interval.

The sub-electrodes of the X electrode disposed in the white light emitting cell are electrically connected by a short bar, and the sub-electrodes of the Y electrode arranged in the white light emitting cell are electrically connected by a short bar.

It is preferable that the sub-electrodes of the X electrodes arranged in all the light emitting cells are electrically connected by a short bar, and the sub-electrodes of the Y electrodes arranged in all the light emitting cells are electrically connected by a short bar.

Some of the sub-electrodes of the X electrode and some of the sub-electrodes of the Y electrode are intermittently intermittent for each light emitting cell.

In all the above-described plasma display panels, all the sub-electrodes of the X electrode and the Y electrode may extend continuously over one row of light emitting cells.

In all the above-described plasma display panels, the red light emitting cells, the green light emitting cells, the blue light emitting cells, and the white light emitting cells are preferably arranged to form a rectangle.

1 is a plan view of a plasma display panel having four color light emitting cells. The sustain discharge electrodes X and Y of the plasma display panel do not have an ITO layer formed of ITO, which is a transparent conductive material, and have sub electrodes X1, X2, X3, X4, which are formed of only an opaque conductive material. Y1, Y2, Y3, Y4) only.

One pixel of the plasma display panel includes four light emitting cells 50r, 50g, 50b, and 50w that emit red, green, blue, and white light, respectively, and the light emitting cells are divided by the partition 40. It is. The X electrode X and the Y electrode Y extend from the upper side of the light emitting cells, and the X electrode has four sub electrodes X1, X2, X3, and X4, and the Y electrode has four Sub electrodes Y1, Y2, Y3, and Y4 are provided.

The white light emitting cells are added to improve the luminance of the plasma display panel. The white light emitting phosphor disposed in the white light emitting cell is a mixture of a red light emitting phosphor, a green light emitting phosphor, and a blue light emitting phosphor. When the luminance of the white light emitting cell is lower than the average luminance of light emitted from the red light emitting cell, the green light emitting cell, and the blue light emitting cell, the brightness of the entire plasma display panel is not improved much, and the full white of the plasma display ( Full white) Since gray stripes occur along the white light emitting cells during driving, the brightness of the white light emitting cells needs to be high.

Meanwhile, as shown in FIG. 1, when the red light emitting cells 50r, the green light emitting cells 50g, the blue light emitting cells 50b, and the white light emitting cells are arranged in a row, gray stripes as described above may be further highlighted. Not preferred.

Next, the plasma display panel according to the first embodiment of the present invention will be described in detail with reference to FIGS. 2 to 4B.

The plasma display panel according to the present exemplary embodiment includes a rear substrate 10, a plurality of address electrodes 20 disposed in parallel with each other on the rear substrate, a first dielectric layer 30 covering the address electrodes, and the first substrate. The red light emitting cells 50r, the green light emitting cells 50g, the blue light emitting cells 50b, and the white light emitting cells 50w, and the red light emitting cells are defined by the partition wall 40 formed on the upper side of the dielectric layer. The green light emitting cells, and the red light emitting phosphor (R), the green light emitting phosphor (G), the blue light emitting phosphor (B), and the white light emitting phosphor (W), respectively, which are coated in the blue light emitting cells, A front substrate 60 disposed to face each other, a plurality of storage electrode pairs 82 disposed to intersect the address electrodes at a lower side of the front substrate, and a second dielectric layer 80 covering the storage electrode pairs; do. It is preferable that the protective layer 90 formed of MgO is formed under the second dielectric layer.

The back substrate 10 functions to support the address electrodes 20, the first dielectric layer 30, and the like, and is typically formed of glass as a main material.

The address electrodes 20 are used to generate an address discharge for facilitating a discharge of the sustain electrode pair, and more specifically, serve to lower a voltage for generating a discharge. The address discharge is a discharge occurring between the Y electrode Y and the address electrode 20. When the address discharge is completed, cations are accumulated on the Y electrode side and electrons are accumulated on the X electrode side. It is easier than the transition.

The first dielectric layer 30 is formed as a dielectric that prevents cations or electrons from colliding with the address electrode 20 and damages the address electrode upon discharge, and induces charge on the surface thereof. PbO, B ₂ O ₃ , SiO ₂ and the like.

The partition wall 40 partitions a region to which respective phosphors R, G, B, and W are applied, and prevents misdischarge between light emitting cells 50r, 50g, 50b, and 50w. In FIG. 2, the partition wall 40 is illustrated as being formed in a matrix shape, but is not limited thereto. The partition wall 40 may be formed in a stripe, a honeycomb shape, or another polygonal shape.

The light emitting cell refers to one light emitting cell among four light emitting cells 50r, 50g, 50b, and 50w constituting one pixel which is a minimum driving unit for realizing an image, wherein the partition wall has a matrix shape or In the case of being formed in a closed shape such as a honeycomb shape, it means a space defined by the partition wall. When the partition is formed in a stripe shape, the space defined by two adjacent partitions and the X electrode and the Y electrode in which the electric discharge occurs is defined. it means. Phosphors capable of emitting red, green, blue, and white visible light on the inner surface of the light emitting cells 50r, 50g, 50b, and 50w, more specifically, on the inner surface of the partition and the upper surface of the first dielectric layer 30, respectively. (R, G, B, W) is applied. The light emitting cell is filled with a discharge gas (mainly Ne-Xe mixed gas).

The front substrate 60 is generally formed of a transparent material mainly made of glass. The sustain electrode pair refers to a pair of X electrodes (X) and Y electrodes (Y) formed on the front substrate 60 in order to cause a discharging, and the sustain electrode pair is a light emitting cell 50 on the front substrate. It is arranged in parallel at the same interval as the interval of.

The second dielectric layer 80 prevents the adjacent X electrode and the Y electrode from being directly energized at the time of discharging, and prevents cations or electrons in the light emitting cell from directly colliding with the X electrode (X) and the Y electrode (Y) to damage them. It is possible to prevent charges, induce charges on the surface thereof, to accumulate wall charges, and to form a light-transmitting dielectric. Examples of such dielectrics include PbO, B ₂ O ₃ , and SiO ₂ .

The protective layer 90 is formed as a material which prevents damage of the second dielectric layer due to cations and electrons colliding with the second dielectric layer 80 during discharge, has good light transmittance, and emits a large amount of secondary electrons during discharge. As is preferable, MgO is usually used. However, the protective layer may not be present. For example, the second dielectric layer 80 itself may be formed of MgO.

The X electrode X and the Y electrode Y will be described in more detail with reference to FIG. 3. As shown in FIG. 3, the X electrodes include sub-electrodes X1, X2, X3, and X4 that extend continuously over a row of light emitting cells (light emitting cells arranged in the horizontal direction shown in FIG. 3). A short bar Xsb is disposed on the white light emitting cell 50w and electrically connects the negative electrodes. Preferably, the sub electrodes X1, X2, X3, and X4 and the short bar Xsb are integrally formed. In addition, the Y electrode includes the sub-electrodes Y1, Y2, Y3, Y4 and the white light-emitting cell 50w which extend continuously over one row of light emitting cells (light emitting cells arranged in the horizontal direction shown in FIG. 3). And a short bar (Ysb) disposed at and electrically connected to the negative electrodes. Preferably, the sub electrodes Y1, Y2, Y3, and Y4 and the short bar Ysb are integrally formed.

The short bars Xsb and Ysb facilitate the first discharging between the two sub-electrodes X1 and Y1 disposed at the center of the white light emitting cell 50w to extend around the light emitting cell and thus the same. Compared to the case where there is no short bar under the condition, the electric discharge occurs more strongly, and the luminous intensity of the white light emitting cell in which the short bar is disposed becomes higher than that of the other light emitting cell without the short bar under the same conditions.

6, the distance G0 from the center of the light emitting cell to the first sub-electrodes X1 and Y1 and the distance G1 between the first sub-electrodes X1 and Y1 and the second sub-electrodes X2 and Y2. And the ratio of the distance G3 between the second sub-electrodes X2 and Y2 and the third sub-electrodes X3 and Y3 is 1: 2: 2: 2, and the width of the first sub-electrodes X1 and Y1 ( W1), the width W2 of the second sub-electrodes X2 and Y2, the width W3 of the third sub-electrodes X3 and Y3, and the width W4 of the fourth sub-electrodes X4 and Y4 are all A graph showing the light emission luminance distribution of the light emitting cells in the same case is shown. As shown, the light emission luminance of the portion where the negative electrode is disposed (hatched) is significantly low because light is shielded by the negative electrode itself.

In the graph of FIG. 6, the luminance of light emitted from the region where the light is not shielded gradually decreases toward the periphery of the light emitting cell along the L line. In consideration of the above matters, it is concluded that the total amount of luminance (M) of the luminance is widened toward the periphery of the emission cell, where the region where the luminance is reduced by the sub-electrodes (hatched). However, when the gaps G1 and G2 of the sub-electrodes disposed near the center of the light emitting cell become too wide, it becomes difficult to discharge at the center of the light emitting cell or the discharge generated at the center of the light emitting cell does not extend well around the light emitting cell. Therefore, the curve L itself may be deformed. Therefore, the gaps G1 and G2 of the sub-electrodes should be determined so as to maximize the total amount of the luminance of the light emitting cells in consideration of the above matters.

Preferably, the spacing (2 × G0) between two sub-electrodes X1 and Y1 closest to the center of the light emitting cell has an optimized value so that initial discharge can easily occur. In addition, the interval G1 between the first and second sub-electrodes X1 and X2 disposed from the center of the light emitting cell among the sub-electrodes of the X electrode X is second and third from the center of the light emitting cell. It is preferable that the gap G2 is wider than the gap G2 between the arranged sub electrodes X2 and X3.

If the widths W1, W2, W3, and W4 of the sub-electrodes X1, X2, X3, X4, Y1, Y2, Y3, and Y4 are too narrow, the discharge does not occur sufficiently. On the other hand, the light emitting cells are too wide. Shields a lot of light emitted from Therefore, the widths W1, W2, W3, and W4 of the sub-electrodes should be determined to maximize the light emission luminance of the light emitting cells.

3 illustrates four sub-electrodes of the X electrode and four sub-electrodes of the Y electrode, but each of the sub-electrodes of the X electrode and the sub-electrodes of the Y electrode may be three.

The X electrode (X) and the Y electrode (Y) may be formed in the pattern shown in Figure 3 through the steps of front printing, exposure, development, drying, and firing of the electrode layer, or may be formed in the following manner have. First, a JSR electrode sheet 81 having a dark layer 81a, a white layer 81b, and a resist layer 81c is laminated on the lower side of the front substrate 80 (FIG. 4A). Thereafter, an X electrode and a Y electrode having a predetermined pattern are formed through a process such as exposure, development, and baking. The X electrode and the Y electrode thus formed have a cross section as shown in FIG. 4B. The dark layer 81a is for reducing the contrast decrease of the plasma display panel due to external light reflection, and the white layer 81b is for reducing the decrease in luminance by absorbing the light emitted from the light emitting cell by the electrode. will be. The white layer is preferably formed of silver having good conductivity and light reflectivity.

In the plasma display panel having the above structure, an address discharge occurs by applying an address voltage Va between the address electrode 20 and the Y electrode Y, and as a result of the address discharge, the first dielectric layer 20 is formed. The wall charge is accumulated on the upper side and the lower side of the second dielectric layer 80, so that the light emitting cell in which the discharging will occur is selected. After that, when the sustain discharge voltage Vs is applied between the Y electrode Y and the X electrode X of the selected light emitting cell, cations accumulated on the Y electrode and electrons accumulated on the X electrode collide with each other. When the electricity is generated, the energy level of the discharged gas excited during this discharging is lowered and ultraviolet rays are emitted. The ultraviolet rays excite the phosphors R, G, B, and W applied in the light emitting cells. The energy level of the excited phosphors is lowered to emit visible light, and the emitted visible light forms an image.

5 shows a modification of the first embodiment. In this modification, the red light emitting cell 50r, the green light emitting cell 50g, the blue light emitting cell 50b, and the white light emitting cell 50w are arranged to form a rectangle. When the luminance of the white light emitting cells 50w is lower than the average brightness of the other light emitting cells 50r, 50g, and 50b, and the white light emitting cells are arranged in a row according to the arrangement shown in FIG. When the panel's full white operation, gray streaks may appear on the screen. However, when the light emitting cells are arranged in the shape of a quadrangle as in the present modified example, the white light emitting cells 50w are not arranged in a row, but between the other light emitting cells (the light emitting cells illustrated as the green light emitting cells 50g in FIG. 5). Since the plasma display panel is operated in full white, the gray streaks do not occur as described above.

A plasma display panel according to a second embodiment of the present invention will be described with reference to FIG. 7 but focusing on matters different from those of the first embodiment. The present embodiment differs from the first embodiment in that the distance G1a between the X electrodes disposed in the white light emitting cells 50w and the sub electrodes disposed first and second from the centers of the light emitting cells of each of the Y electrodes is It is larger than the gap G2a between the second and third sub electrodes disposed from the center of the white light emitting cell.

If the white light emitting body W has lower light emitting luminance than other phosphors R, G, and B, the light emitting luminance of the white light emitting cell 50w may be improved even if the configuration of other components other than the white light emitting phosphor is slightly changed. It is preferable. In the present exemplary embodiment, the white light is emitted from the center G1a between the first and second sub-electrodes X1 and X2 (Y1 and Y2) from the center of the white light emitting cell 50w in which the phosphor having low light emission is disposed. The luminance of the white light emitting cell 50w is improved by making it wider than the interval G2a between the second and third sub electrodes X2 and X3 (Y2 and Y3) disposed from the center of the cell 50w. As such, the luminance of the white light emitting cell is improved, thereby improving the luminance of the entire plasma display panel, and preventing or at least reducing streaks on the screen during the full white operation of the plasma display panel.

From the graph shown in FIG. 6, it can be seen that when the distance G1a between the first and second sub electrodes disposed from the center of the light emitting cell is widened, the light emission luminance of the light emitting cell is improved.

In FIG. 7, a case in which four sub-electrodes of the X electrode and four sub-electrodes of the Y electrode are described as an example is described, but each of the sub-electrodes of the X electrode and the sub-electrodes of the Y electrode may be three. In FIG. 7, each of the sub-electrodes extends continuously over a row of light emitting cells (light emitting cells arranged in a horizontal direction in FIG. 7).

In order to further improve the luminance of the white light emitting cell, each of the negative electrodes of the X electrode and the negative electrodes of the Y electrode disposed in the white light emitting cell is energized by the short bars Xsb and Ysb as shown in FIG. 3. Can connect

With reference to FIG. 8, the first modified example of the second embodiment will be described, focusing on the matters different from the second embodiment. This modification is different from the second embodiment in that the sub-electrodes of the X electrode and the Y electrode are connected to the light emitting cells 50r, 50g, 50b, and 50w by the short bars Xsb and Ysb. That is, the sub-electrodes X1, X2, X3, and X4 of the X electrodes arranged in all the light emitting cells are electrically connected by the short bar Xsb, and the sub-electrodes Y1 of the Y electrodes arranged in all the light emitting cells. Y2, Y3 and Y4 are electrically connected by the short bar Ysb. The short bar increases the light emission luminance of the corresponding light emitting cell by increasing the discharge of the light emitting cell. When the short bars are arranged in all the light emitting cells as in the present modification, the brightness is improved over the entire screen of the plasma display panel. Of course, the gap G1a between the first and second sub-electrodes disposed from the center of the white light-emitting cell is equal to the distance G1 or the white emission between the sub-electrodes disposed first and second from the center of the other light emitting cell. Since the gap G2a is wider than the gaps G2a disposed between the second and third cells of the cell, the luminance of the white light emitting cell may be further improved.

With reference to FIG. 9, the 2nd modified example of a 2nd Example is demonstrated centering on a different thing from the 1st modified example of 2nd Example. Some of the sub-electrodes (X1, X2, X3) of the X electrode and some of the sub-electrodes (Y1, Y2, Y3) of the Y electrode are interrupted for each light emitting cell. As such, when some of the sub-electrodes are interrupted for each light emitting cell, the power consumed by the part of the sub-electrode disposed on the partition 40 during discharge is reduced. In addition, the fluorescent material coated adjacent to the partition wall 40 emits light of high luminance. As illustrated in FIG. 9, when the intermittent sub-electrodes are separated from the partition 40, the light shielded by the sub-electrode decreases. Therefore, there is an advantage that the brightness of the light emitting cell is improved.

9 illustrates four sub-electrodes of the X electrode and four sub-electrodes of the Y electrode, but each of the sub-electrodes of the X electrode and the sub-electrodes of the Y electrode may be three. 9, the first, second, and third electrodes X1, X2, X3, Y1, Y2, and Y3 are interrupted from the center of the light emitting cell, but at least one of the sub-electrodes of the X electrode is intermittent. If only at least one of the negative electrodes of the and Y electrodes is not interrupted, the other negative electrode may be interrupted.

Also in the case of the second embodiment, the same modifications as in the modification of the first embodiment are possible. That is, the red light emitting cell 50r, the green light emitting cell 50g, the blue light emitting cell 50b, and the white light emitting cell 50w may be arranged to form a rectangle. When the light emitting cells are arranged in the shape of a rectangle as in the present modified example, the white light emitting cells 50w are not arranged in a row but disposed with other light emitting cells interposed therebetween, even though the plasma display panel is operated in full white. Streaks do not occur.

A plasma display panel according to a third embodiment of the present invention will be described with reference to FIG. 10 and focusing on differences from the first embodiment. The present embodiment differs from the first embodiment in that the distance G1b between the X electrodes disposed in the white light emitting cells 50w and the sub electrodes disposed first and second from the centers of the light emitting cells of each of the Y electrodes is It is larger than the gap G1 between the first and second sub-electrodes arranged from the center of the light-emitting cell of each of the X and Y electrodes disposed in the other light emitting cells 50r, 50g, and 50b.

If the white light emitting body W has lower light emitting luminance than other phosphors R, G, and B, the light emitting luminance of the white light emitting cell 50w may be improved even if the configuration of other components other than the white light emitting phosphor is slightly changed. It is preferable. In the present exemplary embodiment, the light emission G1b is different from the center G1b between the first and second sub electrodes X1 and X2 (Y1 and Y2) from the center of the white light emitting cell 50w in which the phosphor having the low luminance is disposed. The luminance of the white light-emitting cell 50w is increased by making it wider than the gap G1 between the first and second sub-electrodes disposed from the centers of the light emitting cells of the X and Y electrodes disposed in the cells 50r, 50g, and 50b. Improve. As such, the luminance of the white light emitting cell is improved, thereby improving the luminance of the entire plasma display panel, and preventing or at least reducing streaks on the screen during the full white operation of the plasma display panel.

From the graph shown in FIG. 6, it can be seen that when the distance between the first and second sub-electrodes disposed from the center of the light emitting cell is widened, the light emission luminance of the light emitting cell is improved.

In FIG. 10, the case of four negative electrodes of the X electrode and four negative electrodes of the Y electrode is described as an example. However, each of the negative electrodes of the X electrode and the negative electrodes of the Y electrode may be three. In FIG. 10, each of the sub-electrodes extends continuously over a row of light emitting cells (light emitting cells arranged in a horizontal direction in FIG. 10).

In order to further improve the luminance of the white light emitting cell, each of the negative electrodes of the X electrode and the negative electrodes of the Y electrode disposed in the white light emitting cell is energized by the short bars Xsb and Ysb as shown in FIG. 3. Can connect

The present embodiment differs from the second embodiment in that the second embodiment includes the sub electrodes X1 and Y1 adjacent to the center of the white light emitting cell 50w and the sub electrodes X4 and Y4 disposed on the outermost side of the light emitting cell. ) G1a + W2 + G2a + W3 + G3 between the sub-electrodes X1, Y1 adjacent to the center of the other light-emitting cells 50r, 50g, 50b and the sub-electrodes X4 disposed on the outermost side of the light-emitting cells , Y4) is the same as the interval (G1 + W2 + G2 + W3 + G3), but in this embodiment, the sub-electrodes X1 and Y1 adjacent to the center of the white light emitting cell 50w and the outermost side of the light emitting cell are disposed. The gaps (G1b + W2 + G2b + W3 + G3b) between the negative electrodes X4 and Y4 adjacent to the centers of the other light emitting cells 50r, 50g and 50b and the outermost sides of the light emitting cells It is larger than the interval (G1 + W2 + G2 + W3 + G3) between the sub-electrodes X4 and Y4 disposed on the substrate. That is, in the present embodiment, the ratios G1b: G2b: G3b of the intervals G1b, G2b, and G3b between the sub-electrodes of the white light emitting cell 50w are different from those of the other light emitting cells 50r, 50g, and 50b. May be equal to the ratio G1: G2: G3 of the intervals G1, G2, G3, but the interval G1b is larger than the interval G1, and the interval G2b is greater than the interval G2, The interval G3b is larger than the interval G3. Thus, it can be seen from the graph shown in FIG. 6 that the luminance of the white light emitting cell 50w is improved because the intervals G1b, G2b, and G3b are larger than the intervals G1, G2, and G3, respectively.

With reference to FIG. 11, the 1st modification of 3rd Embodiment is demonstrated centering on a different matter from 3rd Embodiment. This modification is different from the third embodiment in that the sub-electrodes of the X electrode and the Y electrode are connected by the short bars Xsb and Ysb arranged for each of the light emitting cells 50r, 50g, 50b, and 50w. . That is, the sub-electrodes X1, X2, X3, and X4 of the X electrodes arranged in all the light emitting cells are electrically connected by the short bar Xsb, and the sub-electrodes Y1 of the Y electrodes arranged in all the light emitting cells. Y2, Y3 and Y4 are electrically connected by the short bar Ysb. The short bar increases the light emission luminance of the corresponding light emitting cell by increasing the discharge of the light emitting cell. When the short bars are arranged in all the light emitting cells as in the present modification, the brightness is improved over the entire screen of the plasma display panel. Of course, the distance G1b between the first and second sub-electrodes disposed from the center of the white light emitting cell is wider than the distance G1 between the first and second sub-electrodes disposed from the center of the other light emitting cells. Therefore, the luminance of the white light emitting cells can be further improved.

With reference to FIG. 12, the 2nd modified example of a 3rd Example is demonstrated centering on the matter different from the 1st modified example of 3rd Example. Some of the sub-electrodes (X1, X2, X3) of the X electrode and some of the sub-electrodes (Y1, Y2, Y3) of the Y electrode are interrupted for each light emitting cell. As such, when some of the sub-electrodes are interrupted for each light emitting cell, the power consumed by the part of the sub-electrode disposed on the partition 40 during discharge is reduced. In addition, the fluorescent material coated adjacent to the partition wall 40 emits light of high luminance. As illustrated in FIG. 9, when the intermittent sub-electrodes are separated from the partition 40, the light shielded by the sub-electrode decreases. Therefore, there is an advantage that the brightness of the light emitting cell is improved.

12 illustrates four sub-electrodes of the X electrode and four sub-electrodes of the Y electrode, but each of the sub-electrodes of the X electrode and the sub-electrodes of the Y electrode may be three. In addition, although the first, second, and third electrodes X1, X2, X3, Y1, Y2, and Y3 are intermittently interposed from the center of the light emitting cell in FIG. 12, at least one of the negative electrodes of the X electrode is illustrated. If only at least one of the negative electrodes of the and Y electrodes is not interrupted, the other negative electrode may be interrupted.

Also in the case of the third embodiment, the same modifications as in the modification of the first embodiment are possible. That is, the red light emitting cell 50r, the green light emitting cell 50g, the blue light emitting cell 50b, and the white light emitting cell 50w may be arranged to form a rectangle. When the light emitting cells are arranged in the shape of a rectangle as in the present modified example, the white light emitting cells 50w are not arranged in a row but disposed with other light emitting cells interposed therebetween, even though the plasma display panel is operated in full white. Streaks do not occur.

A plasma display panel according to a fourth embodiment of the present invention will be described with reference to FIG. 13 and focusing on matters different from those of the first embodiment. The present embodiment differs from the first embodiment in that the number of sub-electrodes disposed in each of the X and Y electrodes disposed in the white light-emitting cell 50w in which the white light-emitting phosphors having relatively low luminance are arranged is different. It is less than the number of sub-electrodes disposed on each of the X electrodes and the Y electrodes disposed at (50r, 50g, 50b).

In order to increase the light emission luminance of the white light emitting cell 50w coated with the white light emitting phosphor W having relatively low light emission luminance under the same conditions, as can be seen from the above-described second and third embodiments, It is preferable to arrange the secondary electrode disposed second from the center of the light emitting cell to the outside of the light emitting cell. In the second embodiment, the innermost secondary electrodes X1 and Y1 and the outermost secondary electrodes X4 and Y4 of the white light emitting cell are left unchanged, and the secondary electrodes X2 and Y2 positioned second from the innermost side are disposed. By slightly moving around the light emitting cell, the aperture ratio of the center region of the white light emitting cell 50w is increased to improve luminance. In the third embodiment, the gap between all the sub-electrodes is increased to increase the aperture ratio of the center region of the light emitting cell, thereby improving luminance. In this embodiment, the third sub-electrodes X3 and Y3 of the four sub-electrodes of the white light-emitting cell 50w to which the white light-emitting phosphor having low emission luminance is applied are removed, and the second sub-electrodes X2 'and Y2' are removed. By moving outward from the light emitting cell to widen the interval between the sub-electrodes, the aperture ratio of the central region of the white light emitting cell is increased to improve luminance.

Specifically, the sub-electrodes X1 disposed first and second from the centers of the light emitting cells of the X electrode and the Y electrode disposed on the white light emitting cell 50w coated with the white light emitting phosphor W having low light emission luminance. The distance Gm1 between ', X2') (Y1 ', Y2') is the X electrode disposed in the other light emitting cells 50r, 50g, and 50b coated with the phosphors R, G, and B having a relatively high luminance. It is wider than the distance G1 between the first and second sub electrodes X1 and X2 (Y1 and Y2) disposed from the center of the light emitting cell of each of the and Y electrodes. As such, the opening ratio of the central portion of the light emitting cell 50w to which the white light emitting phosphor W is applied is increased, thereby improving the brightness of the light emitting cell, thereby improving the overall brightness of the plasma display panel.

In addition, the distance Gm2 between the second and third sub-electrodes disposed from the centers of the light emitting cells of the X and Y electrodes disposed in the white light emitting cells is determined by the light emitting cells of the X and Y electrodes arranged in the other light emitting cells. The gap G2 is wider than the gap G2 between the second and third sub-electrodes disposed from the center, which contributes to the improvement of the luminance of the white light-emitting cell.

In FIG. 13, the negative electrodes of the light emitting cells 50r, 50g, and 50b each having three sub-electrodes disposed on the white light-emitting cell 50w coated with the white light-emitting phosphor having low light emission luminance and having relatively high light-emitting luminance are applied. Although illustrated as four, there may be two sub-electrodes disposed in the white light-emitting cell 50w and three sub-electrodes of the other light-emitting cells 50r, 50g, and 50b. In addition, in FIG. 13, each of the sub electrodes extends continuously over a row of light emitting cells (light emitting cells arranged in a horizontal direction in FIG. 13). In particular, the second sub electrode X1 ′ of the X electrode disposed in the white light emitting cell 50w is connected to the second and third sub electrodes X2 and X3 arranged in the other light emitting cells 50r, 50g, and 50b. The same holds true for the Y electrode.

A first modified example of the fourth embodiment will be described with reference to FIG. 14, focusing on matters different from the fourth embodiment. This modification is different from the fourth embodiment in that the sub-electrodes of the X electrode and the Y electrode are connected to the light emitting cells 50r, 50g, 50b, and 50w by the short bars Xsb and Ysb. That is, the sub-electrodes X1, X1 ', X2, X2', X3, and X4 of the X electrodes arranged in all the light emitting cells are electrically connected by a short bar Xsb arranged in the longitudinal direction of the light emitting cells. The sub-electrodes Y1, Y1 ', Y2, Y2', Y3, and Y4 of the Y electrode arranged in the light emitting cell are also electrically connected by the short bar Ysb arranged in the longitudinal direction of the light emitting cell. The short bar increases the light emission luminance of the corresponding light emitting cell by increasing the discharge of the light emitting cell. When the short bars are arranged in all the light emitting cells as in the present modification, the brightness is improved over the entire screen of the plasma display panel. Of course, the distance Gm2 between the first and second sub-electrodes disposed from the center of the white light emitting cell is wider than the distance G1 between the first and second sub-electrodes disposed from the center of the other light emitting cell. Therefore, the luminance of the white light emitting cells can be further improved.

With reference to FIG. 15, the 2nd modification of 4th Example is demonstrated centering on the matter different from the 1st modification of 4th Example. Some of the sub-electrodes (X1, X1 ', X2, X2', X3) of the X electrode and some of the sub-electrodes (Y1, Y1 ', Y2, Y2', Y3) of the Y electrode in this modified example are each light emitting cell. It is cracked down. As such, when some of the sub-electrodes are interrupted for each light emitting cell, the power consumed by the part of the sub-electrode disposed on the partition 40 during discharge is reduced. In addition, the fluorescent material coated adjacent to the partition wall 40 emits light of high luminance. As illustrated in FIG. 15, when the intermittent negative electrodes are spaced apart from the partition wall 40, the light shielded by the negative electrode is reduced. Therefore, there is an advantage that the brightness of the light emitting cell is improved.

FIG. 15 shows that the first, second, and third electrodes X1, X1 ', X2, X2', X3, Y1, Y1 ', Y2, Y2', and Y3 are interrupted from the center of the light emitting cell. However, if only at least one of the sub-electrodes of the X electrode of each light emitting cell and at least one of the sub-electrodes of the Y electrode are not intermitted, another sub-electrode may be intermitted.

Also in the case of the fourth embodiment, the same modifications as in the modification of the first embodiment are possible. That is, the red light emitting cell 50r, the green light emitting cell 50g, the blue light emitting cell 50b, and the white light emitting cell 50w may be arranged to form a rectangle. When the light emitting cells are arranged in the shape of a rectangle as in the present modified example, the white light emitting cells 50w are not arranged in a row but disposed with other light emitting cells interposed therebetween, even though the plasma display panel is operated in full white. Streaks do not occur.

According to the present invention, there is provided a plasma display panel having a four-color light emitting cell having improved light emission luminance of the white light emitting cell.

In addition, according to the present invention, a plasma display panel having improved light emission luminance of all light emitting cells is provided.

Furthermore, according to the present invention, there is provided a plasma display panel in which streaks are not generated during full white driving.

Although the present invention has been described with reference to the embodiments shown 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.

Claims (25)

Back substrate; A plurality of address electrodes disposed in parallel with each other on an upper side of the rear substrate; A first dielectric layer covering the address electrodes; Red light emitting cells, green light emitting cells, blue light emitting cells, and white light emitting cells defined by a barrier rib formed on an upper side of the first dielectric layer; A red light emitting phosphor, a green light emitting phosphor, a blue light emitting phosphor, and a white light emitting phosphor coated in the red light emitting cells, the green light emitting cells, the blue light emitting cells, and the white light emitting cells, respectively; A front substrate disposed to face the rear substrate; A plurality of sustain electrode pairs disposed below the front substrate to intersect the address electrodes; And A plasma display panel comprising: a second dielectric layer covering the sustain electrode pairs; The sustain electrode pair includes an X electrode and a Y electrode, and each of the X electrode and the Y electrode has sub electrodes continuously extending over a row of light emitting cells, and the sub part of the X electrode disposed in the white light emitting cell. Electrodes are electrically connected by a short bar, and the sub-electrodes of the Y electrode disposed in the white light emitting cell are electrically connected by a short bar. The method of claim 1, The spacing between the first and second sub-electrodes disposed from the centers of the light emitting cells of each of the X and Y electrodes disposed in all of the light emitting cells is between the second and third sub-electrodes arranged from the center of the light emitting cells. Plasma display panel, characterized in that wider than the interval. The method of claim 1, And all the sub-electrodes of the X electrode and the Y electrode extend continuously over one row of light emitting cells. The method of claim 1, The red light emitting cell, the green light emitting cell, the blue light emitting cell, and the white light emitting cell are arranged to form a rectangle. Back substrate; A plurality of address electrodes disposed in parallel with each other on an upper side of the rear substrate; A first dielectric layer covering the address electrodes; Red light emitting cells, green light emitting cells, blue light emitting cells, and white light emitting cells defined by a barrier rib formed on an upper side of the first dielectric layer; A red light emitting phosphor, a green light emitting phosphor, a blue light emitting phosphor, and a white light emitting phosphor coated in the red light emitting cells, the green light emitting cells, the blue light emitting cells, and the white light emitting cells, respectively; A front substrate disposed to face the rear substrate; A plurality of sustain electrode pairs disposed below the front substrate to intersect the address electrodes; And A plasma display panel comprising: a second dielectric layer covering the sustain electrode pairs; The sustain electrode pair includes an X electrode and a Y electrode, and each of the X electrode and the Y electrode includes sub-electrodes, and the first and second electrodes from the center of the light emitting cell of each of the X and Y electrodes disposed in the white light emitting cell. And a gap between the sub-electrodes disposed in the second is wider than a distance between the sub-electrodes disposed in the second and third from the center of the white light emitting cell. The method of claim 5, wherein And all the sub-electrodes of the X electrode and the Y electrode extend continuously over one row of light emitting cells. The method of claim 5, wherein And the sub-electrodes of the X electrode arranged in the white light emitting cell are electrically connected by a short bar, and the sub-electrodes of the Y electrode arranged in the white light emitting cell are electrically connected by a short bar. The method of claim 5, wherein And the sub-electrodes of the X electrodes arranged in all the light emitting cells are electrically connected by a short bar, and the sub-electrodes of the Y electrodes arranged in all the light emitting cells are electrically connected by a short bar. The method of claim 8, And a portion of the sub-electrodes of the X electrode and some of the sub-electrodes of the Y electrode are interrupted for each light emitting cell. The method of claim 5, wherein The red light emitting cell, the green light emitting cell, the blue light emitting cell, and the white light emitting cell are arranged to form a rectangle. Back substrate; A plurality of address electrodes disposed in parallel with each other on an upper side of the rear substrate; A first dielectric layer covering the address electrodes; Red light emitting cells, green light emitting cells, blue light emitting cells, and white light emitting cells defined by a barrier rib formed on an upper side of the first dielectric layer; A red light emitting phosphor, a green light emitting phosphor, a blue light emitting phosphor, and a white light emitting phosphor coated in the red light emitting cells, the green light emitting cells, the blue light emitting cells, and the white light emitting cells, respectively; A front substrate disposed to face the rear substrate; A plurality of sustain electrode pairs disposed below the front substrate to intersect the address electrodes; And A plasma display panel comprising: a second dielectric layer covering the sustain electrode pairs; The sustain electrode pair includes an X electrode and a Y electrode, and each of the X electrode and the Y electrode includes sub-electrodes, and the first and second electrodes from the center of the light emitting cell of each of the X and Y electrodes disposed in the white light emitting cell. The interval between the sub-electrodes disposed in the second is wider than the interval between the sub-electrodes disposed in the first and second from the center of the light emitting cell of each of the X electrode and the Y electrode disposed in the other light emitting cell. The method of claim 11, The distance between the second and third sub-electrodes disposed from the centers of the light emitting cells of the X and Y electrodes disposed in the white light emitting cells is two from the center of the light emitting cells of each of the X and Y electrodes arranged in the other light emitting cells. A plasma display panel, characterized in that it is wider than a gap between the second and third sub electrodes. The method of claim 11, And all the sub-electrodes of the X electrode and the Y electrode extend continuously over one row of light emitting cells. The method of claim 11, And the sub-electrodes of the X electrode arranged in the white light emitting cell are electrically connected by a short bar, and the sub-electrodes of the Y electrode arranged in the white light emitting cell are electrically connected by a short bar. The method of claim 11, And the sub-electrodes of the X electrodes arranged in all the light emitting cells are electrically connected by a short bar, and the sub-electrodes of the Y electrodes arranged in all the light emitting cells are electrically connected by a short bar. The method of claim 15, And a portion of the sub-electrodes of the X electrode and some of the sub-electrodes of the Y electrode are interrupted for each light emitting cell. The method of claim 11, The red light emitting cell, the green light emitting cell, the blue light emitting cell, and the white light emitting cell are arranged to form a rectangle. Back substrate; A plurality of address electrodes disposed in parallel with each other on an upper side of the rear substrate; A first dielectric layer covering the address electrodes; Red light emitting cells, green light emitting cells, blue light emitting cells, and white light emitting cells defined by a barrier rib formed on an upper side of the first dielectric layer; A red light emitting phosphor, a green light emitting phosphor, a blue light emitting phosphor, and a white light emitting phosphor coated in the red light emitting cells, the green light emitting cells, the blue light emitting cells, and the white light emitting cells, respectively; A front substrate disposed to face the rear substrate; A plurality of sustain electrode pairs disposed below the front substrate to intersect the address electrodes; And A plasma display panel comprising: a second dielectric layer covering the sustain electrode pairs; The sustain electrode pair includes an X electrode and a Y electrode, each of the X electrode and the Y electrode includes sub electrodes, and the number of sub electrodes disposed on each of the X electrode and the Y electrode disposed in the white light emitting cell is different. A plasma display panel comprising fewer than the number of sub-electrodes disposed on each of the X and Y electrodes disposed in the light emitting cell. The method of claim 18, The distance between the first and second sub-electrodes disposed in the white light emitting cells and the centers of the first and second electrodes is from the center of the light emitting cells in each of the X and Y electrodes arranged in the other light emitting cells. A plasma display panel, characterized in that it is wider than the gap between the first and second secondary electrodes. The method of claim 18, The distance between the second and third sub-electrodes disposed from the centers of the light emitting cells of the X and Y electrodes disposed in the white light emitting cells is two from the center of the light emitting cells of each of the X and Y electrodes arranged in the other light emitting cells. A plasma display panel, characterized in that it is wider than a gap between the second and third sub electrodes. The method of claim 18, And all the sub-electrodes of the X electrode and the Y electrode extend continuously over one row of light emitting cells. The method of claim 18, And the sub-electrodes of the X electrode arranged in the white light emitting cell are electrically connected by a short bar, and the sub-electrodes of the Y electrode arranged in the white light emitting cell are electrically connected by a short bar. The method of claim 18, And the sub-electrodes of the X electrodes arranged in all the light emitting cells are electrically connected by a short bar, and the sub-electrodes of the Y electrodes arranged in all the light emitting cells are electrically connected by a short bar. The method of claim 23, And a portion of the sub-electrodes of the X electrode and some of the sub-electrodes of the Y electrode are interrupted for each light emitting cell. The method of claim 18, The red light emitting cell, the green light emitting cell, the blue light emitting cell, and the white light emitting cell are arranged to form a square.

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