KR100667942B1 - Plasma display panel and driving method of the same - Google Patents

Abstract

In the plasma display panel of the present invention, the luminous efficiency is improved and the manufacturing cost is reduced, and the first substrate and the second substrate disposed to face each other, and the partition wall and the discharge space partitioning a plurality of discharge spaces adjacent to the second substrate are provided. In the phosphor layer formed inside the discharge cell formed by the first substrate, a first electrode for partitioning the closed discharge space corresponding to each discharge cell and connecting in one direction, and the first substrate, And a second electrode that extends across the connecting direction of the electrode.

Plasma, display, discharge cell, address electrode, scan electrode, sustain discharge, reset discharge

Description

Plasma Display Panel and Driving Method {PLASMA DISPLAY PANEL AND DRIVING METHOD OF THE SAME}

1 is a partially exploded perspective view of a plasma display panel according to an embodiment of the present invention.

2 is a partial plan view schematically illustrating a relationship between a discharge cell and an electrode in a plasma display panel according to an exemplary embodiment.

3 is a partial cross-sectional view taken along the line A-A of FIG.

4 is a partial perspective view schematically showing the shape and arrangement of the electrodes in the plasma display panel according to an embodiment of the present invention.

5 is a driving waveform diagram of a plasma display panel driving method according to an embodiment of the present invention.

6-12 are partial cross-sectional views of other embodiments compared to FIG. 3.

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a plasma display panel and a driving method thereof, and more particularly, to a plasma display panel and a driving method thereof for improving luminous efficiency and reducing manufacturing cost.

In general, a plasma display panel (hereinafter referred to as a 'PDP') includes a three-electrode surface discharge type PDP. The three-electrode surface discharge type PDP is composed of a substrate including sustain electrodes and scan electrodes located on the same surface and another substrate including address electrodes extending in a vertical direction spaced apart therefrom by a discharge gas (for example, And a mixed gas of neon (Ne) and xenon (Xe).

In this PDP, the presence or absence of discharge is determined by the discharge of the scan electrode and the address electrode independently connected to each line, and the sustain discharge displaying the screen is made by the sustain electrode and the scan electrode located on the same plane.

In this PDP, the luminous efficiency η is expressed as η = L / (Ic x Vs). Where L is luminance, Ic is discharge current, and Vs is sustain voltage.

Therefore, the increase in the luminous efficiency η in the PDP reduces the discharge current Ic and the sustain voltage Vs while maintaining the luminance L, or maintains the discharge current Ic and the sustain voltage Vs. This is possible by increasing the luminance L in the state.

In general, since the increase in the luminance L is accompanied by an increase in the discharge current Ic, the sustain voltage Vs is decreased while maintaining the luminance L and the discharge current Ic in order to improve the luminous efficiency η. It is preferable to make it.

In addition, about half of the price of the PDP depends on the driving circuit portion, and the price of the driving circuit depends on the current flowing through the PDP and the magnitude of the voltage applied thereto. In other words, the price of each element constituting the driving circuit increases as the discharge current Ic increases and the sustain voltage Vs increases.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and an object thereof is to provide a plasma display panel and a driving method for improving the luminous efficiency and reducing the manufacturing cost.

According to an embodiment of the present invention, a plasma display panel includes a first substrate and a second substrate disposed to face each other, a partition wall partitioning a plurality of discharge spaces adjacent to the second substrate, and a discharge cell formed by the discharge spaces. In the phosphor layer formed therein, a first electrode for partitioning the closed discharge space corresponding to each discharge cell and connecting in one direction, and a second electrode extending in a connection direction of the first substrate in the first substrate. Include.

The first electrode extends in one direction of the discharge cell and extends in one direction, and forms an enclosed discharge space corresponding to the discharge cell in the extension and extends in a direction perpendicular to the substrate surface at the extension. Contains wealth. At this time, the second electrode is preferably disposed in the center of the discharge cell to cross the stretched portion. The second electrode may further include an elongate portion extending in a direction crossing the first electrode, and a protrusion protruding in the vertical direction of the substrate surface with respect to the closed discharge space formed by the first electrode at the elongated portion. It is preferable.

In addition, the second electrode extends in a direction crossing the first electrode on one side of the discharge cell, and a branch extending from the stretched portion toward the center of the discharge cell in the horizontal direction of the substrate surface. And a projection protruding in the vertical direction of the substrate surface with respect to the closed discharge space formed by the first electrode in this branch. The protrusions may be variously formed in a quadrangular, polygonal, circular, or oval shape with respect to the plane direction of the substrate.

In the above, the first electrode and the second electrode are formed of a metal electrode and have excellent electrical conductivity, and have a dielectric layer on its outer surface to form wall charges. This dielectric layer may be formed of an opaque dielectric and may have a protective film on its outer surface. This protective film may have visible light impermeability.

In the above, a dielectric layer may be provided between the second substrate and the partition wall.

In the above, the partition wall may include a first partition member extending in one direction, and a second partition member intersecting the first partition member to form a discharge cell in a closed type, and may be stripped by the first partition member. It is also possible to form a discharge cell in the mold.

In the above, the discharge space of the second substrate may be formed by etching the second substrate at a position corresponding to the discharge cell and applying a phosphor layer thereto.

In the above, one or two first electrodes may be formed along the vertical direction of the substrate.

The first electrode may be formed in one, and may have a cross-sectional shape in which the width of the second electrode side is wide in the vertical direction of the substrate and the width thereof is narrowed toward the second substrate side. In this case, the second electrode is preferably formed to have a wide width corresponding to the wide width of the first electrode, and is formed to have a width narrowing to correspond to the narrow width of the first electrode.

In addition, two first electrodes may be formed, and an electrode cross-sectional area of the second electrode side may be wider than an electrode cross-sectional area of the front substrate side in the vertical direction of the substrate.

In addition, the plasma display panel driving method according to an embodiment of the present invention, the partition wall formed adjacent to the second substrate, and corresponding to each discharge cell in the first substrate, partitioning the closed discharge space by one 1. A plasma display panel driving method comprising: a first electrode connected in a direction; and a second electrode extended in a direction crossing the first electrode and opposed to the first electrode, wherein one side is a discharge cell in a sustaining period. A sustain pulse having a positive sustain voltage (+ Vs) at a first electrode which maintains a second electrode provided at the center of the reference voltage (0V) and forms a closed discharge space corresponding to the discharge cell is negative. A sustain pulse having a sustain voltage (-Vs) is repeatedly applied.

In the sustain section, wall charges formed by sustain discharge are applied to the first electrode by applying an eraser pulse gradually decreasing from the reference voltage (0V) to a negative sustain voltage (-Vs). Clears.

In the above, the reset period is gradually increased from the positive sustain voltage (+ Vs) to the voltage (Vset) that can be discharged in the discharge cells of all conditions, and then applying a pulse falling to the reference voltage to the first electrode Then, the wall charges formed by the reset discharge are erased to initialize the discharge cells.

In the addressing period, a scan pulse Vsc is applied to the first electrode and an address pulse Va is applied to the second electrode to select a discharge cell to be turned on.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention. As those skilled in the art would realize, the described embodiments may be modified in various different ways, all without departing from the spirit or scope of the present invention. In the drawings, parts irrelevant to the description are omitted in order to clearly describe the present invention, and like reference numerals designate like elements throughout the specification.

1 is a partially exploded perspective view of a plasma display panel according to an embodiment of the present invention, FIG. 2 is a partial plan view schematically illustrating a relationship between a discharge cell and an electrode in the plasma display panel according to an embodiment. 1 is a partial cross-sectional view taken along line AA of FIG. 1, and FIG. 4 is a partial perspective view schematically illustrating the shape and arrangement of the electrodes in the plasma display panel according to an exemplary embodiment of the present invention.

Referring to the PDP with reference to the drawings, the PDP of the present invention is basically a first substrate (10, hereinafter referred to as a "back substrate") and a second substrate (20, hereinafter referred to as a "front substrate") arranged at a predetermined interval And a partition wall 26 provided between the front substrate 20 and the rear substrate 10. The partition wall 26 is formed adjacent to the front substrate 20 and forms a discharge cell 28 partitioned into a plurality of discharge spaces 28. In the discharge cell 28, a phosphor layer 29 that absorbs vacuum ultraviolet rays and emits visible light is formed, and discharge gases (for example, neon and xenon) are generated to generate vacuum ultraviolet rays by plasma discharge. Mixed gas), and the like.

The partition wall 26 is formed to protrude toward the rear substrate 10 adjacent to the front substrate 20, the discharge cell 28 can be formed in various shapes such as a square or hexagon, this embodiment is formed in a square The discharge cell 28 to be illustrated is illustrated. The partition wall 26 is formed in the direction in which the first partition member 26a extends from the front substrate 20 in one direction (y axis direction) and intersects with the first partition member 26a (x axis direction). A second barrier member 26b is formed to extend and form a discharge cell 28 on the front substrate 20 side together with the first barrier member 26a. In addition, the partition wall 26 may be formed of the first partition wall members 26a to form the discharge cells 28 in a stripe shape (not shown).

The phosphor layer 29 is coated on each inner surface of the first partition member 26a and the second partition member 26b and the inner surface of the front substrate 20 forming the discharge cells 28. The phosphor layer 29 may be formed by forming a dielectric layer 27 on the front substrate 20, forming a partition 26 on the dielectric layer 27, and then applying a phosphor on the dielectric layer 27 (FIG. 1) may also be formed by selectively forming a partition 26 on the front substrate 20 and applying a phosphor, without forming a dielectric layer on the front substrate 20 (see FIG. 3). For convenience, the dielectric layer 27 is shown in FIG. 1, and the dielectric layer 27 is omitted in FIG. 3.

Further, the phosphor layer 29 may be formed by etching the front substrate 20 to correspond to the shape of the discharge cell 28 and then applying a phosphor thereon (see FIG. 6). At this time, the partition wall 26 is made of the same material as the front substrate 20. This visual processing method has an advantage of reducing the processing cost compared to the method of separately providing the partition wall 26 on the front substrate 20.

In the above, after the sustain discharge, the phosphor layer 29 absorbs vacuum ultraviolet rays inside the discharge cell 28 to generate visible light directed toward the front substrate 20. In order to produce an image by generating vacuum ultraviolet rays that will collide with the phosphor layer 29 by plasma discharge, the back substrate 10 includes a first electrode 32 corresponding to each discharge cell 28 (hereinafter referred to as a 'scan electrode'). And a second electrode 11 (hereinafter referred to as an address electrode).

The scan electrode 32 is arranged adjacent to the rear substrate 10 to partition the closed discharge space 18 corresponding to each discharge cell 28, and the closed discharge space 18 in one direction (x-axis direction). It is formed into a structure that connects. The discharge space 18 formed on the rear substrate 10 side by the scan electrode 32 is one discharge cell 18, 28 together with the discharge space 28 formed on the front substrate 20 side. To form.

The address electrode 11 extends in the direction (y-axis direction) adjacent to the back substrate 10 in the direction intersecting the connection direction (x-axis direction) of the scan electrode 32. As the address electrode 11 crosses the scan electrode 32 to one side thereof, the address electrode 11 interacts with the scan electrode 32 to cause an address discharge, and the scan electrode 32 faces the scan electrode 32 to the other side thereof. ) To form a sustain discharge.

In more detail, the scan electrode 32 may be formed to extend along one direction (x-axis direction) on one side of the discharge cell 28, and the discharge cell may be formed on the stretched portion 32a. An extension part 32b is formed to form a closed discharge space 18 corresponding to 28 and extend in a direction perpendicular to the surfaces of the substrates 10 and 20 from the extension part 32a (z-axis direction).

In addition, the address electrode 11 is adjacent to the extending portion 11a which is formed to extend in the direction (y axis direction) that intersects the extending portion 32a of the scan electrode 32 on the other side of the discharge cell 28. From the extension part 11a toward the center of one side discharge cell 28 in the horizontal direction (xy plane) of the board | substrate 10, 20 surface to select one discharge cell 28 of the discharge cells 28 to The vertical direction z of the surface of the substrates 10 and 20 with respect to the branch 11b extending in the x-axis direction and the closed discharge space 18 formed by the scan electrode 32 in the branch 11b. And projections 11c protruding in the axial direction). The protrusions 11c may be variously formed in a quadrangular, polygonal, circular, or oval shape with respect to the planar direction (x-y plane) of the substrates 10 and 20.

Each of the elongated portions 11a and 32a of the two electrodes 11 and 32 is formed by the intersection of the first partition member 26a and the second partition member 26b between the rear substrate 10 and the partition wall 26. Despite being provided to cross each other to correspond to the lattice structure, the insulating structure is formed so as not to interfere with each other, and the extension portion 32b of the scan electrode 32 and the protrusion 11c of the address electrode 11 are discharge space 18. Alternatively, opposing discharge structures are formed in the two discharge spaces 18 and 28.

In the scan electrode 32, the extension part 32a is formed to extend along the direction (x-axis direction) parallel to and corresponding to the second partition member 26b of the front substrate 20. The expansion part 32b is provided in the position corresponding to both sides of each discharge cell 28 in the. The scan electrodes 32 are arranged in plural in parallel with each other while maintaining an interval corresponding to each discharge cell 28 in the y-axis direction. In other words, the elongate portions 32a are provided in pairs on both sides with respect to one discharge cell 18 and 28 and extend in the y-axis direction on the other side extended portion 32b forming the closed discharge space 28. Are formed).

In the address electrode 11, the extension part 11a is formed to correspond to the first partition member 26a of the front substrate 20 and extend along a parallel direction (y-axis direction), and the branch 11b is discharged. The extension part 32b (extending in the x-axis direction) of the scan electrode 32 forming the space 18 extends into the discharge space 18 in a direction parallel to the scan electrode 32, and the protrusion 11c is formed in the discharge space 18. Protruding toward the discharge space 28 at the tip of the branch (11b) of. The extension portions 11a of the address electrodes 11 are arranged in plurality in parallel with each other while maintaining an interval corresponding to each discharge cell 28 in the x-axis direction.

Since the scan electrode 32 and the address electrode 11 are provided on the back substrate 10 reflecting the visible light without the phosphor layer 29, there is no fear of blocking the visible light generated in the discharge cell 28. The scanning electrode 32 is provided to correspond to the partition wall 26 which is the non-discharge area, and the extension part 11a of the address electrode 11 is provided to correspond to the first partition member 26a to be the non-discharge area. Reference numerals 32 and 11 may be formed of an opaque material because they do not block visible light generated from the discharge cells 28, and may be formed of a metal positive electrode having excellent electrical conductivity.

On the other hand, the scan electrode 32 protrudes toward the front substrate 20 on the back substrate 10 to form a closed discharge space 18 corresponding to the partition wall 26, and the extension portion 32a is the address electrode. Electrically insulated from (11) and is formed in a structure connected along the direction (x-axis direction) intersecting with it. Therefore, the stretched portion 32a of the scan electrode 32 is preferably surrounded by the dielectric layer 34 on the outer surface thereof. As shown in FIG. 1, the outer surface of the extended portion 32b of the scan electrode 32 is preferably surrounded by the dielectric layer 35 in response to the closed discharge space 18 formed by the scan electrode 32. . Therefore, the dielectric layer 34 and the dielectric layer 35 surrounding the scan electrode 32 may be formed in a lattice shape corresponding to the partition wall 26. In addition, the address electrode 11 may be formed on the inner surface of the back substrate 10 to be covered or surrounded by the dielectric layer 17.

It is preferable that the dielectric layers 34, 25, and 17 have a protective film 36 on the outer surface thereof. The protective film 36 may be formed only at a portion exposed to the plasma discharge occurring in the discharge space inside the discharge cell 28. This protective film 36 protects the dielectric layers 34, 35, and 17 and requires a high secondary electron emission coefficient, but it does not need to have visible light transmission. That is, the scan electrode 32 and the address electrode 11 are not formed on the front substrate 20, but are formed on the rear substrate 10 side between the substrates 10 and 20, so that the dielectric layers 34, 35, The protective film 36 coated on the substrate 17 may be formed of a material having visible light impermeability. As an example of this protective film 26, the visible light-transmissive MgO has a much higher secondary electron emission coefficient value than the visible light-transmissive MgO, and thus the discharge start voltage can be further lowered.

Since the address electrode 11 is covered with a dielectric layer 17 having the same dielectric constant, the address electrode 11 has the same discharge start voltage between red (R), green (G), and blue (B) of the phosphor layer 29, thereby providing a high voltage. No margin is required.

Referring to FIG. 5, the scan electrode 32 applies a reset pulse Vr to a reset period, a scan pulse Vsc to an addressing period, and a sustain pulse (+ Vs, -Vs) to a sustain period. The discharge cell 28 is reset together with the address electrode 11, the discharge cell 28 to be turned on is selected, and an image is displayed by the selected discharge cell 28. Also, the address electrode 11 maintains the reference voltage (0V) in the reset period, applies the address pulse (Va) in the addressing period, and maintains the reference voltage (0V) in the sustaining period to control the above sections. Let's do it. However, each electrode may perform its role differently according to the signal voltage applied thereto, so the present invention does not need to be limited to the above.

The scan electrode 32 is provided on the rear substrate 10 side together with the address electrode 11 to form an opposite discharge structure, so that the discharge start voltage for sustain discharge can be lowered compared to the surface discharge structure.

In addition, the scan electrode 32 and the address electrode 11 have a back substrate 10 and a front substrate 20 in a discharge space 18 corresponding to each discharge cell 28 in order to induce opposite discharge of a larger area. Expansion portions 32b and projections 11c extending in a direction perpendicular to the direction (z-axis direction). The expansion part 32b places the projection 11c at the center of the discharge space 18 and surrounds it.

Therefore, when discharging between the projection 11c and the expansion portion 32b, the discharge starts at the shortest distance between the projection 11c and the expansion portion 32b, and this discharge is performed between the projection 11c and the expansion portion 32b. It spreads to the far side of and spreads all over the extension part 32b. In other words, the protrusion 11c and the expansion part 32b form a short gap during initial discharge to enable discharge to be initiated by a low voltage, and thereafter, a long gap is formed to improve discharge efficiency. To increase.

In addition, the extension part 32b provided at both sides of the y-axis direction has a cross-sectional structure in which the rear substrate 10 and the front substrate 20 are cut in the vertical direction, and the length h _v of the vertical direction thereof is horizontal in the horizontal direction. It has a cross-sectional structure longer than the length h _h . The counter discharge, which is widely formed in the extension part 32b, generates strong vacuum ultraviolet rays, and the strong vacuum ultraviolet rays collide with the phosphor layer 29 over the large area inside the discharge cell 28 to generate the amount of visible light. Increase

The scan electrode 32 can be fabricated by TFCS (Thick Film Ceramic Sheet) method. That is, the electrode unit including the scan electrode 32 may be separately manufactured and then coupled to the front substrate 20 having the partition wall 26 formed thereon.

Hereinafter, a method of driving the plasma display panel described above will be described.

5 is a driving waveform diagram of a plasma display panel driving method according to an embodiment of the present invention.

Hereinafter, for convenience, the driving waveforms applied to the scan electrodes 32 (hereinafter referred to as 'Y electrodes') and the address electrodes 11 (hereinafter referred to as 'A electrodes') forming one discharge cell 18 and 28 are described. Explain.

One subfield includes a reset period, an addressing period, and a sustain period, and the reset period includes a rising period.

In the rising section of the reset section, while maintaining the A electrode at the reference voltage (0 V in FIG. 5), the voltage of the Y electrode is gradually increased from the negative holding voltage (Vs) to the Vset voltage, and then to the reference voltage (0V). Apply a falling pulse. In FIG. 5, the voltage of the Y electrode is shown to increase in the form of a lamp. While the voltage of the Y electrode increases, a weak discharge (hereinafter referred to as "weak discharge") occurs between the Y electrode and the A electrode, thereby initializing the discharge cells 18 and 28. Since the reset section has a rising section instead of a section that gradually falls after the Vset voltage applied to the Y electrode, the reset time can be shortened.

Next, a scan pulse Vsc is applied to the Y electrode and an address pulse Va is applied to the A electrode to select the discharge cells 18 and 28 to be turned on in the addressing period.

In the sustain period, a reference voltage (0V) is applied to the A electrode provided on one side of the discharge cells 18 and 28, and a positive sustain pulse (+ Vs) and a negative sustain pulse (-Vs) are repeatedly applied to the Y electrode. Is applied to implement an image.

A falling section is formed at the end of the holding section, which gradually decreases the voltage of the Y electrode from 0 V to the negative holding voltage (-Vs) while maintaining the A electrode at the reference voltage (0 V). Apply a laser pulse. Then, while the voltage of the Y electrode decreases, a weak discharge occurs between the Y electrode and the A electrode, and the wall charge formed by the sustain discharge is erased.

As described above, in the exemplary embodiment of the present invention, the reset operation, the address operation, and the sustain discharge operation may be performed only by the driving waveform applied to the Y electrode while the A electrode is biased with the reference voltage (0 V). Therefore, since the conventional sustain electrode (X electrode) and the driving board for driving the same can be removed, the circuit cost is reduced.

7-12 are partial cross-sectional views of other embodiments compared to FIG. 3.

Various embodiments of the present invention will be described with reference to the drawings. In the following description, the description of the same parts as the configuration of the above embodiment will be omitted and other parts will be described.

FIG. 7 shows an example in which the address electrode 11 intersects the extension portion 32a of the scan electrode 32 and is disposed at the center of the discharge cell 28. In this case, the address electrode 11 is disposed at the center of the discharge cell 28 to select the discharge cell 28 in the addressing period, and the address electrode 11 and the scan electrode (above the address electrode 11). 32) will cause a discharge.

8 and 9 show an example in which the address electrode 11 is formed of the extending portion 11a and the projection 11c, and the address electrode 11 is disposed in the center of the discharge cell 28. As shown in FIG. In addition, one or two scan electrodes 32 may be formed along the vertical direction (z-axis direction) of the substrates 10 and 20. 8 and 9 show an example in which the scan electrodes 32 are arranged side by side in the z-axis direction.

FIG. 10 shows the cross-sectional area of the electrode 32 _c on the address electrode 11 side in the vertical direction (z-axis direction) of the substrates 10 and 20 in addition to the structures of FIGS. 8 and 9. The electrode 32 _d is formed wider than the cross-sectional area. In this case, the protrusion (11c) and a front substrate of the address electrode 11, the projection (11c) and the electrode (32 _c) short initial discharge taking place in the gap states and then the address electrode 11 is formed between the adjacent thereto of The discharge is caused in the long gap state formed between the (20) side electrodes 32 _d .

FIG. 11 shows that one scanning electrode 32 is formed, and the width of the address electrode 11 is wide along the vertical direction (z-axis direction) of the substrates 10 and 20, and is narrow toward the front substrate 20. Losing cross-sectional shape. In this case, an initial discharge occurs in a short gap state, and then gradually causes a discharge in a long gap state.

12 is a cross-sectional shape in which, in addition to the structure of FIG. 11, the address electrode 11 is formed to have a wide width corresponding to the wide width of the scan electrode 32, and the width thereof is narrowed to correspond to the narrow width of the scan electrode 32. Has In this case, the discharge gap may be further improved by forming a long gap which is further increased as compared with FIG. 11.

Although the preferred embodiments of the present invention have been described above, the present invention is not limited thereto, and various modifications and changes can be made within the scope of the claims and the detailed description of the invention and the accompanying drawings. Naturally, it belongs to

As described above, according to the present invention, a closed discharge space is formed as a scan electrode on the rear substrate, and an address electrode for forming a counter discharge with the scan electrode is disposed at the center of the discharge cell and a phosphor layer is formed on the discharge cell on the front substrate. By controlling the reset period, the addressing period, and the sustain period with two electrodes, the discharge cell is selected and the image is realized through the selected discharge cell, thereby lowering the discharge start voltage by opposing discharge to improve the luminous efficiency, and driving circuit Reduction of the number reduces the manufacturing cost of the driving circuit.

Claims (21)

A first substrate and a second substrate disposed to face each other; Barrier ribs defining a plurality of discharge spaces adjacent to the second substrate; A phosphor layer formed inside a discharge cell formed by the discharge space; A first electrode on the first substrate, the first electrode configured to partition a closed discharge space corresponding to each of the discharge cells and to connect in one direction; And And a second electrode extending from the first substrate to cross the connecting direction of the first electrode. The method of claim 1, The first electrode extends along one direction at one side of the discharge cell; And an extension part forming a closed discharge space corresponding to the discharge cells in the extension part and extending in a direction perpendicular to the surface of the substrate in the extension part. The method of claim 2, And the second electrode intersects the stretcher and is disposed at the center of the discharge cell. The method of claim 3, wherein The second electrode may include an elongate portion extending in a direction crossing the connection direction of the first electrode; And a projection protruding in the vertical direction of the surface of the substrate with respect to the closed discharge space formed by the first electrode in the extension part. The method of claim 1, The second electrode extends in a direction extending in a direction crossing the connection direction of the first electrode on one side of the discharge cell; A branch extending from the stretcher toward the center of the discharge cell in the horizontal direction of the substrate surface, And a projection protruding in the vertical direction of the substrate surface with respect to the closed discharge space formed by the first electrode in the branch. The method of claim 5, And the protrusions are formed in any one of a rectangle, a polygon, a circle, and an oval with respect to a plane direction of the substrate. The method of claim 1, The first electrode and the second electrode is a plasma display panel formed of a metal electrode. The method of claim 1, The first electrode and the second electrode is a plasma display panel having a dielectric layer on the outer surface. The method of claim 8, And the dielectric layer is formed of an opaque dielectric. The method of claim 8, The dielectric layer has a protective film on its outer surface. The method of claim 1, And a dielectric layer disposed between the second substrate and the partition wall. The method of claim 1, The partition wall includes a first partition wall member extending in one direction, and the second partition wall member intersecting the first partition wall member. The method of claim 1, And a discharge space of the second substrate is formed by etching the second substrate at a position corresponding to the discharge cell and applying a phosphor layer thereto. The method of claim 1, And one or two first electrodes formed along a vertical direction of the substrate. The method of claim 14, And one first electrode, and having a cross-sectional shape in which the width of the second electrode is wide in the vertical direction of the substrate and the width of the first electrode is narrowed toward the second substrate. The method of claim 14, And the second electrode is formed to have a wide width corresponding to the wide width of the first electrode, and has a width narrowing to correspond to the narrow width of the first electrode. The method of claim 14, And the first electrode is formed in two, and an electrode cross-sectional area of the second electrode side is wider than an electrode cross-sectional area of the front substrate side in the vertical direction of the substrate. A partition wall formed adjacent to the second substrate, a first electrode corresponding to the first substrate and partitioning the closed discharge space corresponding to each discharge cell in one direction, and a direction crossing the first electrode; A plasma display panel driving method comprising: a second electrode extended to a second electrode and opposed to the first electrode; In the sustaining period, one side thereof maintains the second electrode provided at the center of the discharge cell at the reference voltage (0V), A plasma display panel repeatedly applying a sustain pulse having a positive sustain voltage (+ Vs) and a sustain pulse having a negative sustain voltage (-Vs) to a first electrode forming a closed discharge space corresponding to the discharge cell. Driving method. The method of claim 18, The sustain period is a plasma display panel driving method for applying a laser pulse gradually decreases from the reference voltage (0V) to a negative sustain voltage (-Vs) to the first electrode at the end portion. The method of claim 18, The reset period gradually increases from a positive sustain voltage (+ Vs) to a voltage (Vset) at which discharge can occur in discharge cells under all conditions, and then applies a pulse falling to a reference voltage to the first electrode. Driving method. The method of claim 18, In the addressing period, a scan pulse Vsc is applied to the first electrode, and an address pulse Va is applied to the second electrode corresponding thereto.

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