JP2001084906A - Plasma display device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To improve high definition, while securing emission luminance. SOLUTION: This plasma display device is provided with a front surface substrate and a back surface substrate which are arranged facing each other, plural pairs (electrode pairs) of scanning electrodes and common electrodes which extend on the inner surface of the front surface substrate in approximately the same direction at a distance (a surface discharge distance), and a plurality of data electrodes extending on the inner surface of the back surface substrate at a distance, so as to be approximately perpendicular to the scanning electrodes and the common electrodes, and discharge gas is filled between the substrates. The product of the surface discharge distance by discharge gas pressure is set so as to be lower than the Paschen minimum, less likely the discharge is not generated, the smaller the distance is between the electrodes, and the electrode pairs are arranged thickly to realize high definition. Since the distance between a scanning electrode 12 and a common electrode 13 of different electrode pairs, namely, the sum of the non-discharge distance NDG and the width W of either the scanning electrode 12 or the common electrode 13 is smaller than a surface discharge distance DG, errors in discharging in paths B between mutually adjacent electrode pairs can be prevented.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

[0001] 1. Field of the Invention [0002] The present invention relates to a plasma display device.

[0002]

2. Description of the Related Art Plasma display panels (PDs)
P), in particular, an AC discharge type plasma display panel (AC-PDP) is used as a flat display which can be easily enlarged in a display device of a personal computer or a workstation, and is used in a wall-mounted television or the like.

[0003] PDPs are classified into DC type and AC type according to their structural classification.
Divided into types. In the DC type, the electrodes are directly exposed to the discharge gas, whereas in the AC type, the electrodes are not directly exposed to the discharge gas because the electrodes are covered with a dielectric. The AC type is further classified into a memory operation type using a memory function by the charge storage action of the dielectric and a refresh operation type not using this memory function. FIG. 6 is a sectional view showing an example of a configuration of a general memory operation type AC-PDP, and FIG. 7 is a schematic plan view of the AC-PDP shown in FIG. The PDP 2 shown in FIGS. 6 and 7 has a front substrate 10 (FIG. 6) made of glass and a rear substrate 1 also made of glass.
The following structure is formed in a space sandwiched between the two. On the front substrate 10, a plurality of scanning electrodes 12 (first row electrodes) extending at a predetermined interval in FIG.
And a plurality of common electrodes 13 (second row electrodes). Each scanning electrode 12 and each common electrode 13 are adjacent to each other and form a pair, and the interval between each pair of the scanning electrode 12 and the common electrode 13 is also referred to as a surface discharge interval here.
The interval between each pair of the scanning electrode 12 and the common electrode 13 is referred to as a non-discharge interval here.

FIG. 8 is an enlarged plan view showing a scanning electrode and a common electrode in detail. As shown in FIG. 8, in order to increase the independence of driving for each cell CL, that is, in order to prevent discharge from occurring between a pair of the adjacent scan electrode 12 and common electrode 13, normally, a non-discharge is performed. The discharge interval NDG is set to be larger than the surface discharge interval DG. In FIG. 8, Pc represents the width of the cell CL, and W represents the width of the scanning electrode 12 and the common electrode 13.

The scanning electrode 12 and the common electrode 13 formed on the inner surface of the front substrate 10 are covered with a dielectric layer 15a,
Further, a protective layer 16 made of MgO (magnesium oxide) or the like for protecting the dielectric layer 15a from discharge is formed on the dielectric layer 15a. In FIG. 6, a plurality of data electrodes 19 are formed on the inner surface of the rear substrate 11 so as to extend in the left-right direction of the drawing so as to be orthogonal to the scanning electrodes 12 and the common electrodes 13. The data electrode 19 is a dielectric layer 1
The phosphor 18 is coated on the dielectric layer 15b so as to cover the dielectric layer 15b so as to convert ultraviolet light generated by the discharge into visible light. If the phosphor 18 is separately applied to each cell, for example, red, green and blue (RGB), which are three primary colors of light, a color display PDP 2 is obtained.

A discharge space 20 is secured between the dielectric layer 15a on the front substrate 10 and the dielectric layer 15b on the rear substrate 11, and a pair of the scanning electrode 12 and the common electrode 1 is formed.
A partition wall 17 is formed at each intersection of the data electrode 3 and the data electrode 19 to divide the cell. In the discharge space 20, He (helium), Ne (neon), Ar (argon), Kr (krypton), Xe (xenon), N
A gas containing a mixture of ₂ (nitrogen), O ₂ (oxygen), CO ₂ (carbon dioxide) and the like is sealed as a discharge gas.

As shown in FIG. 7, in the PDP 2, m (m is a positive integer) scan electrodes Si (i = 1, 2,...)
, M) and the common electrode Ci (i = 1, 2,...,
m) are formed in the row direction, and n (n is a positive integer) data electrodes Dj (j = 1, 2,..., n) are formed in the column direction, and the scanning electrode, the common electrode, and the data electrode are formed. Cell CL is formed at each intersection with. As described above, each common electrode Ci forms a pair with each scanning electrode Si (C1 and S1, C2 and S2,...), And both extend substantially in parallel.

Next, the operation of the PDP 2 configured as described above will be described. FIG. 9 is a timing chart showing a driving voltage waveform applied to each electrode of the conventional PDP 2. First, an erasing pulse 21 is applied to all the scanning electrodes 12, and the discharge state of the cells that have been emitting light by the sustain discharge before the time shown in FIG. 9 is stopped, and all the cells are brought into the erased state.
The discharge operation by this pulse is called sustain discharge erase. Here, erasing means an operation of reducing or eliminating wall charges, which will be described later.

Next, a pre-discharge pulse 22 is applied to the common electrode 13 to forcibly discharge and emit light in all the cells, and a pre-discharge erase pulse 23 is applied to the scan electrode 12 to erase the discharge in all the cells. . The discharge operation by the pre-discharge pulse is called pre-discharge, and the discharge operation by the pre-discharge erase pulse is called pre-discharge erase. Pre-discharge and pre-discharge erasure facilitate subsequent write discharge.

After the preliminary discharge erasure, a scan pulse 24 is applied to the scan electrodes S1 to Sm at different timings,
The data pulse 2 is applied to the data electrodes D1 to Dn in accordance with the display data in accordance with the timing at which the scan pulse 24 is applied.
7 is applied. The hatching of the data pulse 27 shown in FIG. 9 indicates that the presence or absence of the data pulse 27 is determined according to the presence or absence of the display data. In the cell to which the data pulse 27 is applied when the scan pulse 24 is applied, a discharge occurs in the discharge space 20 between the scan electrode 12 and the data electrode 19, but the data pulse 27 is not applied when the scan pulse 24 is applied. And no discharge occurs. Since display information is written into each cell based on the presence or absence of this discharge, this is called a write discharge.

In the cell in which the write discharge has occurred, positive charges called wall charges are accumulated in the dielectric layer 15a on the scan electrode 12. At this time, negative wall charges are accumulated in the dielectric layer 15b on the data electrode 19. The superposition of the positive potential due to the positive wall charges formed on the dielectric layer 15 a on the scan electrode 12 and the first sustain pulse 25 which is negative and is applied to the common electrode 13 causes the scan electrode 12 to A first surface discharge occurs between the pair of common electrodes 13.

When the first discharge occurs, positive wall charges are accumulated on the dielectric layer 15a on the common electrode 13, and negative wall charges are accumulated on the dielectric layer 15a on the scan electrode 12. The second sustain pulse 26 applied to the scanning electrode 12 is superimposed on the potential difference due to the wall charges, and a second discharge occurs. As described above, the potential difference due to the wall charges formed by the n-th discharge and the (n + 1) -th sustain pulse are superimposed to maintain the discharge. For this reason, this discharge operation is called a sustain discharge. Brightness is controlled by the number of sustain discharges.

If the voltages of the sustain pulse 25 and the sustain pulse 26 are adjusted in advance to such an extent that a discharge does not occur only by applying these pulses, the first sustain voltage is applied to a cell in which no write discharge has occurred. Since there is no potential due to wall charges before the pulse 25 is applied, the first sustain pulse 25
Is applied, no first sustain discharge is generated, and therefore no subsequent sustain discharge is generated.

In the driving voltage waveform of FIG. 9 described above, the period in which the erase pulse 21, the preliminary discharge pulse 22, and the preliminary discharge erase pulse 23 are applied is defined as a preliminary discharge period 100,
The period during which the scanning pulse 24 and the data pulse 27 are applied is referred to as a scanning period 102, and the period during which the sustain pulses 25 and 26 are applied is referred to as a sustain period 104. Preliminary discharge period, scan period,
The sustain period is also referred to as a subfield SF.

Next, a gradation display method in the conventional PDP 2 will be described. FIG. 10 is a timing chart for explaining a gradation display method in the plasma display panel. A period for displaying one screen (for example, 1/6
One field (0 seconds) is divided into a plurality of subfields (for example, four subfields). The subfields have the configuration shown in FIG. 9, and each subfield is ON / OFF of display independently of the other subfields.
Is possible. Further, each subfield has a different length of the sustaining period, in other words, the number of sustaining pulses, and therefore has a different luminance. In the four subfield division as shown in FIG. 10, if the luminance ratio when each subfield emits light alone is adjusted to 1: 2: 4: 8, the four subfields are adjusted. Display ON / O
By the combination of the FFs, a 16-level luminance display from a luminance ratio of 0 when all sub-fields are not selected to a luminance ratio of 15 when all sub-fields are selected is possible. In general, one field is divided into n subfields, and the luminance ratio of each subfield is set to 1 (= 2 ⁰ ): 2 (=
2 ¹ ):...: 2 ⁿ⁻² : 2 ⁿ⁻¹ enables 2n gradation display.

[0016]

However, in such a conventional color plasma display panel, as described with reference to FIG. 8, the non-discharge interval NDG is the surface discharge interval DG.
Had been set larger. Therefore, when the dimension Pc of the cell CL is reduced in order to increase the definition of the plasma display panel, in order to maintain the relationship of DG <NDG,
The width of the scanning electrode 12 and the common electrode 13 must be reduced, or the surface discharge interval DG must be reduced.
However, a reduction in the electrode width causes a decrease in the light emission luminance, while a reduction in the surface discharge interval DG causes a decrease in the light emission luminance and the light emission efficiency. Therefore, increasing the definition of the plasma display panel has conventionally resulted in a decrease in light emission luminance. The present invention has been made to solve such a problem, and an object of the present invention is to provide a plasma display device capable of achieving high definition while ensuring sufficient light emission luminance.

[0017]

In order to achieve the above object, the present invention includes two substrates, at least one of which is disposed opposite to each other, and at least one of which is transparent, and one of the substrates has substantially the same inner surface. And a plurality of pairs of first and second row electrodes extending at intervals from each other in the direction of, and on the inner surface of the other substrate, substantially orthogonal to the first and second row electrodes. And
A plurality of column electrodes extend at intervals from each other, a discharge gas is sealed between the two substrates, and each intersection between the pair of the first and second row electrodes and the column electrode is formed. A plasma display apparatus, wherein a sustain discharge is performed between a pair of the first and second row electrodes corresponding to each pixel, wherein a distance between a pair of the first and second row electrodes and a first and a second row electrode are set. The sum of the width of one of the second row electrodes and the width of one of the second row electrodes forms a pair.
And a distance smaller than the interval between the second row electrodes.

In the present invention, the surface discharge interval and the discharge gas pressure are set so that the product of the interval between the paired first and second row electrodes, ie, the surface discharge interval, and the discharge gas pressure is smaller than the Paschen minimum. Set. Therefore, assuming that the discharge gas pressure is constant, the shorter the distance between the electrodes is, the higher the discharge starting voltage is, and the more difficult the discharge is to occur. At this time, as described above, the sum of the interval between the pair of the first and second row electrodes (row electrode pair) and the width of any one of the first and second row electrodes forms the pair. When the distance between the first and second row electrodes is narrower, the distance between adjacent row electrode pairs is always narrower than the surface discharge interval, so that discharge can be prevented from occurring between adjacent row electrode pairs. In the first and second row electrodes belonging to different adjacent row electrode pairs and adjacent to each other, the distance between the sides on the same side in the row electrode arrangement direction is shorter than the surface discharge interval. Such discharge between the electrode portions can be prevented from occurring. Therefore, in the present invention, the row electrode pairs can be arranged close to each other without causing erroneous discharge between adjacent row electrode pairs, that is, between electrodes belonging to adjacent pixels, and a high definition display can be realized. The above conditions regarding the width and spacing of the electrodes can be achieved after securing the width of the electrodes and the spacing between the surface discharges, and it is possible to obtain sufficient light emission luminance.

The present invention also includes two substrates, at least one of which is disposed opposite to each other and is transparent, and extends on the inner surface of one of the substrates at a distance from each other in substantially the same direction. A plurality of pairs of first and second row electrodes are arranged on the other surface of the substrate, and a plurality of columns are provided on the inner surface of the other substrate, substantially orthogonal to the first and second row electrodes and spaced apart from each other. An electrode extends, a discharge gas is sealed between the two substrates, and each intersection of the first and second row electrode pairs and the column electrodes corresponds to each pixel and forms a pair. A plasma display device in which a sustain discharge is performed between the first and second row electrodes, wherein a distance between a pair of the first and second row electrodes, a width of the first row electrode, and a second Is smaller than the distance between the first and second row electrodes forming a pair.

In the present invention, the surface discharge interval and the discharge gas pressure are adjusted so that the product of the interval between the paired first and second row electrodes, ie, the surface discharge interval, and the discharge gas pressure is smaller than the Paschen minimum. Set. Therefore, assuming that the discharge gas pressure is constant, the shorter the distance between the electrodes is, the higher the discharge starting voltage is, and the more difficult the discharge is to occur. At this time, as described above, the sum of the distance between the pair of the first and second row electrodes (row electrode pair), the width of the first row electrode, and the width of the second row electrode forms a pair. When the distance between the first and second row electrodes is narrower,
First, since the interval between adjacent row electrode pairs is always narrower than the surface discharge interval, discharge can be prevented from occurring between adjacent row electrode pairs. Further, in the first and second row electrodes belonging to different adjacent row electrode pairs and adjacent to each other, the distance between opposite side portions which are further apart in the arrangement direction of the row electrodes is a surface discharge interval. Since the length is shorter, it is possible to prevent such discharge between the electrode portions. Therefore, in the present invention, the row electrode pairs can be arranged close to each other without causing erroneous discharge between adjacent row electrode pairs, that is, between electrodes belonging to adjacent pixels, and a high definition display can be realized. The above conditions regarding the width and spacing of the electrodes can be achieved after securing the width of the electrodes and the spacing between the surface discharges, and it is possible to obtain sufficient light emission luminance.

[0021]

Embodiments of the present invention will be described below with reference to the drawings. The plasma display device according to the embodiment of the present invention described here is the same as the PDP 2 shown in FIGS. 6 and 7 and described in detail in terms of the basic configuration. Therefore, description of the common parts with PDP 2 is omitted here. The plasma display device of the embodiment is particularly different from the conventional PDP 2 in the electrode arrangement and dimensions and the discharge gas, which will be described in detail below.

FIG. 1 is an enlarged plan view showing in detail a scanning electrode and a common electrode constituting the plasma display device of the embodiment. In the drawings, the same elements as those in FIGS. 6 to 8 are denoted by the same reference numerals. As shown in FIG.
In the plasma display device of the embodiment, the non-discharge interval NDG is set smaller than the surface discharge interval DG. The discharge generated between the scan electrode 12 and the common electrode 13 spreads on both electrodes and between the two electrodes. However, the discharge between the scan electrode 12 and the common electrode 13 belonging to another adjacent pixel, and therefore belonging to another cell. Does not spread. If the discharge utilization efficiency Eff is defined by the ratio of the discharge region to the cell area, Eff = (2W + DG) / (2W + DG + ND
G). Therefore, in the embodiment, since the non-discharge interval NDG is smaller than the surface discharge interval DG as described above, the discharge utilization efficiency is improved. Further, even if the electrode width W and the surface discharge interval DG are the same, the non-discharge interval NDG is made smaller than the surface discharge interval DG, so that the plasma display device of the embodiment can easily achieve high definition.

In this embodiment, as described below, by appropriately setting the interval between the electrodes and the sealing pressure of the discharge gas, a pair of a scanning electrode and a common electrode corresponding to an adjacent pixel is set. Discharge is prevented from occurring between the electrode pairs. FIG. 2 shows the discharge electrode interval d.
FIG. 4 is a characteristic diagram showing a relationship between a discharge starting voltage and a product of pressure and gas pressure P. In the figure, the horizontal axis represents the product of the electrode interval d and the gas pressure P, and the vertical axis represents the discharge starting voltage. The characteristic shown in FIG. 2 represents Paschen's law that the firing voltage is determined by the Pd product.

As can be seen from FIG. 2, the discharge starting voltage becomes minimum at a certain Pd value, and this point is called Paschen minimum. In the conventional PDP, the Pd value was on the right side of the Paschen minimum (arrow E). On the right side of the Paschen minimum, the larger the Pd value, the higher the firing voltage,
When P is constant, the larger the value of d, the higher the discharge starting voltage. Therefore, when applying a pulse to an electrode belonging to an adjacent pixel (cell), a surface discharge interval DG is set so that a discharge is not erroneously generated at a non-discharge interval instead of an intended surface discharge interval.
(D) and the non-discharge interval NDG (d) are expressed as DG <N
DG.

In the present embodiment, conditions are set so that this Pd value becomes the value on the left side (arrow D) of Paschen's minimum. As can be seen from FIG. 2, on the left side of the Paschen minimum, the smaller the Pd value, the higher the discharge starting voltage. Therefore, if P is constant, the smaller the d, the higher the discharge starting voltage. Therefore, as described above, DG> N
In the case of DG, it is possible to prevent a discharge from being erroneously generated between adjacent pairs of electrodes. For example, according to a measurement result using a mixed gas containing Xe, the discharge electrode interval d = 10
The operating point at 0 μm and gas pressure P = 200 torr is the Paschen minimum. If the gas pressure P is set to be smaller than 200 torr, the interval smaller than 100 μm corresponds to the left region of the Paschen minimum. Therefore, for example, non-discharge interval NDG = 50 μm, surface discharge interval DG = 100
In the case of μm, the discharge start voltage at the non-discharge interval is higher than the discharge start voltage at the surface discharge interval, and erroneous discharge does not occur between adjacent electrode pairs.

By the way, even if the NDG is reduced as described above in order to avoid an erroneous discharge between the electrode pairs, since the electrodes are on the same plane, a long discharge traversing the electrodes in the width direction is required. An erroneous discharge may occur by forming a path. When the non-discharge interval NDG is set as described above,
Erroneous discharge does not occur in the path A in FIG. However, in the “detour path” B, discharge can occur because the interval is longer than NDG. Therefore, in the present embodiment, the interval between the electrode pairs, that is, the non-discharge interval NDG, and the width W of one of the scan electrode 12 and the common electrode 13 (in the present embodiment, for example, the width of both electrodes is equal). Is smaller than the surface discharge interval DG. That is, in the present embodiment, the surface discharge interval,
Set the non-discharge interval and electrode width. As a result, erroneous discharge due to the path B shown in FIG. 1 does not occur.

Further, if the sum of the non-discharge interval, the width of the scan electrode, and the width of the common electrode is set to be smaller than the surface discharge interval, that is, DG> 2W + NDG, the path shown in FIG. Discharge due to C can be prevented, and occurrence of erroneous discharge can be more reliably prevented. FIG. 3 is a drawing corresponding to FIG. 1, and the same elements as those in FIG. 1 are denoted by the same reference numerals. The above conditions relating to the width and spacing of these electrodes can be mainly achieved by reducing the spacing between the electrode pairs, and the electrode width and the surface discharge spacing can be set large, so that sufficient light emission luminance can be secured.

Next, the discharge gas used in this embodiment will be described in detail. FIG. 4 is a characteristic diagram showing the result of actually measuring the relationship between the discharge gas pressure and the luminous efficiency, and FIG. 5 is a characteristic diagram showing the result of actually measuring the relationship between the mixing ratio of Xe in the discharge gas and the luminous efficiency. In FIG. 4, the horizontal axis represents gas pressure, and the vertical axis represents luminous efficiency. In FIG. 5, the horizontal axis represents the Xe mixture ratio, and the vertical axis represents the luminous efficiency. FIG.
As shown in (2), a decrease in gas pressure causes a decrease in luminous efficiency.
On the other hand, as shown in FIG. 5, the luminous efficiency increases as the Xe mixture ratio increases. Therefore, when the gas pressure is reduced to use the left region of the Paschen minimum as described above, it is effective to increase the Xe mixture ratio in order to compensate for the decrease in luminous efficiency.

According to the measurement results shown in FIG. 5, the luminous efficiency is remarkably increased up to the Xe mixing ratio of about 10%, and the luminous efficiency is gradually saturated at a higher ratio. Therefore, it is most effective to set the Xe mixture ratio to about 10%. Although the result shown in FIG. 5 is an example of the measurement result, the saturation of the light emission efficiency occurs even when the Xe mixture ratio becomes at least 10% or more according to the measurement result under another discharge gas condition. . Therefore, in order to compensate for a decrease in luminous efficiency due to the use of the left region of the Paschen minimum, it is desirable that the Xe mixture ratio be at least 10% or more.

[0030]

As described above, the present invention includes two substrates, at least one of which is transparent and disposed opposite to each other,
On the inner surface of one of the substrates, a plurality of pairs of first and second row electrodes extending at intervals from each other in substantially the same direction are provided, and on the inner surface of the other substrate, A plurality of column electrodes extend substantially orthogonal to the first and second row electrodes and spaced apart from each other, a discharge gas is sealed between the two substrates, and the first and the second Each intersection between the pair of row electrodes and the column electrodes corresponds to each pixel, and the first paired electrodes are paired with each other.
And a sustain discharge is performed between a second row electrode and a gap between the pair of the first and second row electrodes and a width of any one of the first and second row electrodes. Is smaller than the distance between the first and second row electrodes forming a pair.

According to the present invention, the surface discharge interval and the discharge gas pressure are set so that the product of the distance between the first and second row electrodes forming a pair, ie, the surface discharge interval, and the discharge gas pressure is smaller than the Paschen minimum. Set. Therefore, assuming that the discharge gas pressure is constant, the shorter the distance between the electrodes is, the higher the discharge starting voltage is, and the more difficult the discharge is to occur. At this time, as described above, the sum of the interval between the pair of the first and second row electrodes (row electrode pair) and the width of any one of the first and second row electrodes forms the pair. When the distance between the first and second row electrodes is narrower, the distance between adjacent row electrode pairs is always narrower than the surface discharge interval, so that discharge can be prevented from occurring between adjacent row electrode pairs. In the first and second row electrodes belonging to different adjacent row electrode pairs and adjacent to each other, the distance between the sides on the same side in the row electrode arrangement direction is shorter than the surface discharge interval. Such discharge between the electrode portions can be prevented from occurring. Therefore, in the present invention, the row electrode pairs can be arranged close to each other without causing erroneous discharge between adjacent row electrode pairs, that is, between electrodes belonging to adjacent pixels, and a high definition display can be realized. The above conditions regarding the width and spacing of the electrodes can be achieved after securing the width of the electrodes and the spacing between the surface discharges, and it is possible to obtain sufficient light emission luminance.

Also, the present invention includes two substrates, at least one of which is disposed opposite to each other and is transparent, and extends on the inner surface of one of the substrates at a distance from each other in substantially the same direction. A plurality of pairs of first and second row electrodes are arranged on the other surface of the substrate, and a plurality of columns are provided on the inner surface of the other substrate, substantially orthogonal to the first and second row electrodes and spaced apart from each other. An electrode extends, a discharge gas is sealed between the two substrates, and each intersection of the first and second row electrode pairs and the column electrodes corresponds to each pixel and forms a pair. A plasma display device in which a sustain discharge is performed between the first and second row electrodes, wherein a distance between a pair of the first and second row electrodes, a width of the first row electrode, and a second Is smaller than the distance between the first and second row electrodes forming a pair.

In the present invention, the surface discharge interval and the discharge gas pressure are set so that the product of the interval between the paired first and second row electrodes, ie, the surface discharge interval, and the discharge gas pressure is smaller than the Paschen minimum. Set. Therefore, assuming that the discharge gas pressure is constant, the shorter the distance between the electrodes is, the higher the discharge starting voltage is, and the more difficult the discharge is to occur. At this time, as described above, the sum of the distance between the pair of the first and second row electrodes (row electrode pair), the width of the first row electrode, and the width of the second row electrode forms a pair. When the distance between the first and second row electrodes is narrower,
First, since the interval between adjacent row electrode pairs is always narrower than the surface discharge interval, discharge can be prevented from occurring between adjacent row electrode pairs. Further, in the first and second row electrodes belonging to different adjacent row electrode pairs and adjacent to each other, the distance between opposite side portions which are further apart in the arrangement direction of the row electrodes is a surface discharge interval. Since the length is shorter, it is possible to prevent such discharge between the electrode portions. Therefore, in the present invention, the row electrode pairs can be arranged close to each other without causing erroneous discharge between adjacent row electrode pairs, that is, between electrodes belonging to adjacent pixels, and a high definition display can be realized. The above conditions regarding the width and spacing of the electrodes can be achieved after securing the width of the electrodes and the spacing between the surface discharges, and it is possible to obtain sufficient light emission luminance.

[Brief description of the drawings]

FIG. 1 is an enlarged plan view showing in detail a scanning electrode and a common electrode constituting a plasma display device according to an embodiment.

FIG. 2 is a characteristic diagram showing a relationship between a discharge starting voltage and a product of a discharge electrode interval d and a gas pressure P;

FIG. 3 is an enlarged plan view showing in detail a scanning electrode and a common electrode included in a plasma display device according to another embodiment.

FIG. 4 is a characteristic diagram showing a result of actually measuring a relationship between discharge gas pressure and luminous efficiency.

FIG. 5 is a characteristic diagram showing a measurement result of a relationship between a mixing ratio of Xe in a discharge gas and luminous efficiency.

FIG. 6 is a sectional view showing an example of a configuration of a general memory operation type AC-PDP.

FIG. 7 is a schematic plan view of the AC-PDP shown in FIG.

FIG. 8 is an enlarged plan view showing a scanning electrode and a common electrode in detail.

FIG. 9 is a timing chart showing a driving voltage waveform applied to each electrode of a conventional PDP.

FIG. 10 is a timing chart illustrating a gradation display method in a plasma display panel.

[Explanation of symbols]

2 ... PDP, 10 ... front substrate, 11 ... rear substrate,
12 ... scanning electrode, 13 ... common electrode, 15a ... dielectric layer, 16 ... protective layer, 18 ... phosphor, 19 ... data electrode, 20 ... discharge space.

Claims (6)

[Claims] At least one of the substrates disposed opposite to each other includes two transparent substrates, and an inner surface of one of the substrates includes:
A plurality of pairs of first and second row electrodes extending at intervals from each other in substantially the same direction are provided, and on the inner surface of the other substrate, the pair of first and second row electrodes is provided. A plurality of column electrodes extend at right angles to each other and are spaced apart from each other, a discharge gas is sealed between the two substrates, and a pair of the first and second row electrodes and the column electrodes A plasma display apparatus in which each intersection corresponds to each pixel and sustain discharge is performed between a pair of the first and second row electrodes, wherein a distance between the pair of the first and second row electrodes is provided. And a sum of a width of the first and second row electrodes and a width of one of the first and second row electrodes is smaller than an interval between the pair of the first and second row electrodes. 2. At least one of the substrates disposed opposite to each other includes two transparent substrates, and an inner surface of one of the substrates includes:
A plurality of pairs of first and second row electrodes extending at intervals from each other in substantially the same direction are provided, and on the inner surface of the other substrate, the pair of first and second row electrodes is provided. A plurality of column electrodes extend at right angles to each other and are spaced apart from each other, a discharge gas is sealed between the two substrates, and a pair of the first and second row electrodes and the column electrodes A plasma display apparatus in which each intersection corresponds to each pixel and sustain discharge is performed between a pair of the first and second row electrodes, wherein a distance between the pair of the first and second row electrodes is provided. And a sum of a width of the first row electrode and a width of the second row electrode is smaller than a distance between the paired first and second row electrodes. 3. The product according to claim 1, wherein the product of the interval between the first and second row electrodes forming a pair and the sealing pressure of the discharge gas is smaller than the value of Paschen minimum. Plasma display device. 4. The plasma display device according to claim 3, wherein Xe is mixed with the discharge gas at a mixing ratio of 10% or more. 5. The method according to claim 1, wherein the first and second substrates are provided on an inner surface of each substrate.
2. The plasma display device according to claim 1, wherein a dielectric layer covering each of said row electrode and said column electrode is formed. 6. The plasma display device according to claim 5, wherein a phosphor is applied on the dielectric layer covering the column electrodes.