Plasma display panel using Xe discharge gas

Information

  • Patent Grant
  • 6611099
  • Patent Number
    6,611,099
  • Date Filed
    Wednesday, March 31, 1999
    25 years ago
  • Date Issued
    Tuesday, August 26, 2003
    21 years ago
Abstract
In a flat display apparatus of this invention, which uses a discharge plasma, a UV discharge gas prepared by mixing Xe as a main discharge gas and Ne as a discharge control gas such that the partial pressure of Xe becomes, e.g., 15% is injected into a space between a display substrate and a counter substrate opposing the display substrate at a predetermined pressure. A plurality of first electrodes capable of specifying a position in the first direction on the substrate, a plurality of second electrodes capable of specifying a position in the second direction perpendicular to the first direction, and third electrodes (auxiliary electrodes) equal in number to the first or second electrodes are formed on at least one substrate at a predetermined interval. With this arrangement, the discharge start voltage required for initialization of the discharge generation portion (pixels between the substrates), a write in a memory, and discharge sustaining and memory erase operations can be set to be low.
Description




BACKGROUND OF THE INVENTION




The present invention relates to an arrangement capable of increasing the luminance and service life of a flat panel display apparatus, i.e., a plasma display panel for obtaining a visible image using a plasma discharge.




EL (Electro Luminescence) panels, LED (Light Emission Diode) array panels, PDPs (Plasma Display Panels), FL (Fluorescent Light) panels, LCD (Liquid Crystal Display) panels, and the like are popularly used for portable and compact equipment, business equipment, and computers because a portion necessary for display can be made thin.




Of these display panels, a PDP is used for a large-screen TV because its angle of field is large, and no light source is required.




In a PDP, a space between two opposing insulating substrates is filled with discharge gas. A voltage is applied between the substrates to generate a plasma discharge and generate UV rays. A phosphor is made to emit light using the UV rays, thereby obtaining a visible image.




Normally, as the discharge gas, a gas mixture of Ne (neon) and Xe (xenon) is used. The mixing ratio is Ne:Xe=9:1.




Although the PDP can achieve a wider angle of field than that of an LCD panel, the screen is darker (luminous efficiency is low) than that of a CRT (cathode-ray tube normally called a Braun tube and used as a picture tube of a commercial TV). In addition, the service life (period until the luminance becomes too low to disable use of the panel) is shorter than that of a CRT or an LCD panel.




BRIEF SUMMARY OF THE INVENTION




It is an object of the present invention to allow a flat panel display apparatus using a plasma discharge to maintain a high luminous efficiency and display images with high luminance for a long time period.




According to an aspect of the present invention, there is provided a flat type display apparatus using a discharge plasma, comprising:




a first substrate capable of passing visible light;




a second substrate arranged to oppose the first substrate at a predetermined gap;




a discharge gas sealed between the first substrate and the second substrate;




excitation means for exciting the discharge gas to generate UV rays; and




photoconversion means for emitting predetermined visible light on the basis of the UV rays,




wherein the discharge gas is caused by the excitation means to perform excimer light emission.




According to another aspect of the present invention, there is provided a flat type display apparatus using a discharge plasma, comprising:




a first substrate capable of passing visible light;




a second substrate arranged to oppose the first substrate at a predetermined gap;




a discharge gas sealed between the first substrate and the second substrate;




excitation means, including a front electrode formed on a side of the first substrate opposing the second substrate, for exciting the discharge gas to generate UV rays; and




photoconversion means for emitting predetermined visible light on the basis of the UV rays,




wherein letting W be a width of the front electrode, and D be the gap between the first and second substrates,






0.5


≦W/D


≦2.4






is satisfied.




According to still another aspect of the present invention, there is provided a flat type display apparatus using a discharge plasma, comprising:




a first substrate capable of passing visible light;




a second substrate arranged to oppose the first substrate at a predetermined gap;




a discharge gas sealed between the first substrate and the second substrate;




excitation means for exciting the discharge gas to generate UV rays; and




photoconversion means, arranged on the second substrate, for emitting predetermined visible light on the basis of the UV rays,




wherein a UV reflection film for reflecting the UV rays is inserted between the first substrate or second substrate and the photoconversion means.




According to still another aspect of the present invention, there is provided a flat type display apparatus using a discharge plasma, comprising:




a first substrate capable of passing visible light;




a second substrate arranged to oppose the first substrate at a predetermined gap;




a discharge gas sealed between the first substrate and the second substrate;




excitation means, including a first electrode arranged on a side of the first substrate opposing the second substrate and a second electrode arranged on a side of the second substrate opposing the first substrate, for exciting the discharge gas to generate UV rays; and




a phosphor layer formed on the second substrate to emit predetermined visible light on the basis of the UV rays,




wherein the phosphor layer is partially removed in a region corresponding to the second electrode or has a thickness smaller in the region than that in the remaining regions.




According to still another aspect of the present invention, there is provided a flat type display apparatus using a discharge plasma, comprising:




a first substrate capable of passing visible light;




a second substrate arranged to oppose the first substrate at a predetermined gap;




a discharge gas sealed between the first substrate and the second substrate;




excitation means, comprising a first electrode arranged on a side of the first substrate opposing the second substrate and a second electrode arranged on a side of the second substrate opposing the first substrate, for exciting the discharge gas to generate UV rays; and




photoconversion means, arranged on the second substrate, for emitting predetermined visible light on the basis of the UV rays,




wherein the first substrate comprises a protective film formed in a region corresponding to the first electrode, and a UV reflection layer formed on a region other than the region corresponding to the first electrode to reflect the UV rays.




Additional objects and advantages of the invention will be set forth in the description which follows, and in part will be obvious from the description, or may be learned by practice of the invention. The objects and advantages of the invention may be realized and obtained by means of the instrumentalities and combinations particularly pointed out hereinafter.











BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWING




The accompanying drawings, which are incorporated in and constitute a part of the specification, illustrate presently preferred embodiments of the invention, and together with the general description given above and the detailed description of the preferred embodiments given below, serve to explain the principles of the invention.





FIG. 1

is a schematic perspective view showing a plasma discharge flat display apparatus (PDP) to which the most preferred embodiment of the present invention is applied;





FIG. 2A

is a partial schematically sectional view of the PDP shown in

FIG. 1

;





FIG. 2B

is a schematic partial sectional view of the PDP shown in

FIG. 2A

;





FIG. 2C

is a schematic view showing the phosphor layer of a discharge space of the PDP shown in

FIGS. 1

,


2


A, and


2


B;





FIG. 3

is a schematic block diagram for explaining a driving circuit for causing the PDP shown in

FIGS. 1

,


2


A, and


2


B to display an image;





FIG. 4

is a graph showing the wavelength distribution of UV rays generated by a plasma discharge between a front substrate and a light-emitting substrate in the PDP shown in

FIGS. 1

,


2


A, and


2


B;





FIG. 5

is a graph showing the relationship between the luminous efficiency and the pulse rise time of an image display pulse applied, in a subfield, to each discharge space of the PDP shown in

FIGS. 1

,


2


A, and


2


B;





FIG. 6

is a graph showing the reflection characteristics of a multilayered dielectric film used as the UV reflection layer of the PDP shown in

FIGS. 1

,


2


A, and


2


B;





FIG. 7

is a graph showing improvement of the luminous efficiency of visible light radiating from the discharge space by using, in the PDP shown in

FIGS. 1

,


2


A, and


2


B, the UV reflection layer having the reflection characteristics explained with reference to

FIG. 6

;





FIG. 8

is a graph showing the relationship between the ratio of visible light extracted from each discharge space of the PDP shown in

FIGS. 1

,


2


A, and


2


B and a back reflection layer formed on the light-emitting substrate side of the discharge space;





FIG. 9

is a graph showing the relationship between the luminous efficiency and the partial pressure of Xe in the gas mixture supplied between the front substrate and light-emitting substrate of the PDP shown in

FIGS. 1

,


2


A, and


2


B;





FIG. 10

is a graph showing the relationship between the reflectance and the thickness of a reflection layer used for the visible light reflection layer of the PDP shown in

FIGS. 1

,


2


A, and


2


B;





FIG. 11

is a schematic sectional view showing the intensity distribution of visible light radiating from the phosphor layer upon discharge in the space between the front electrodes on the front substrate and the counter electrodes on the light-emitting substrate of the PDP having the structure shown in

FIGS. 1

,


2


A, and


2


B when viewed from the same direction as that in

FIG. 2B

;





FIG. 12

is a graph showing the relationship between the extraction efficiency and the light intensity, i.e., the luminance of visible light radiating from each discharge space of the PDP having the structure shown in

FIGS. 1

,


2


A, and


2


B;





FIG. 13

is a partial schematic perspective view for explaining the arrangement of a discharge space capable of lowering the discharge start voltage in the PDP having the structure shown in

FIGS. 1

,


2


A, and


2


B;





FIG. 14

is a partial schematic perspective view for explaining a modification of the discharge spaces shown in

FIG. 13

, which can lower the discharge start voltage;





FIG. 15

is a partial schematic plan view showing an arrangement different from the arrangements of the discharge spaces shown in

FIGS. 13 and 14

;





FIGS. 16A and 16B

are partial schematic views for explaining still another arrangement of the discharge spaces shown in

FIG. 15

, which can lower the discharge start voltage;





FIG. 17

is a graph for explaining the relationship between the partial pressure of Xe and an inter electrode voltage applied to the electrodes of the front substrate and light-emitting substrate of the PDP


1


shown in

FIGS. 1

,


2


A, and


2


B;





FIG. 18

is a graph showing the relationship between the luminous efficiency and the height of a barrier (rib) for defining the discharge spaces in the PDP


1


shown in

FIGS. 1

,


2


A, and


2


B;





FIG. 19

is a partial schematic sectional view for explaining another embodiment of the discharge space of the PDP


1


shown in

FIGS. 1

,


2


A, and


2


B;





FIG. 20

is a partial schematic sectional view for explaining still another embodiment of the discharge space of the PDP


1


shown in

FIGS. 1

,


2


A, and


2


B;





FIG. 21

is a partial schematic perspective view showing another PDP different from the matrix discharge type PDP shown in

FIGS. 1

,


2


A, and


2


B;





FIG. 22

is a partial schematic sectional view of the PDP shown in

FIG. 21

;





FIG. 23

is a schematic block diagram for explaining a driving circuit for causing the PDP shown in

FIGS. 21 and 22

to display an image;





FIG. 24

is a partial schematic sectional view showing another embodiment of the PDP shown in

FIGS. 21 and 22

;





FIG. 25

is a partial schematic view showing still another PDP different from the matrix discharge type PDP shown in

FIGS. 1

,


2


A, and


2


B;





FIG. 26

is a partial schematic sectional view showing still another PDP different from the matrix discharge type PDP shown in

FIGS. 1

,


2


A, and


2


B;





FIGS. 27A and 27B

are partial schematic sectional views showing still another PDP different from the matrix discharge type PDP shown in

FIGS. 1

,


2


A, and


2


B;





FIG. 28

is a partial schematic perspective view showing still another PDP different from the matrix discharge type PDP shown in

FIGS. 1

,


2


A, and


2


B;





FIGS. 29A and 29B

are partial schematic sectional views of the PDP shown in

FIG. 28

;





FIG. 30

is a partial schematic sectional view showing still another PDP different from the matrix discharge type PDP shown in

FIGS. 1

,


2


A, and


2


B;





FIGS. 31A and 31B

are partial schematic sectional views showing still another PDP different from the matrix discharge type PDP shown in

FIGS. 1

,


2


A, and


2


B;





FIGS. 32A and 32B

are partial schematic sectional views showing still another PDP different from the matrix discharge type PDP shown in

FIGS. 1

,


2


A, and


2


B;





FIG. 33

is a partial schematic sectional view showing still another PDP different from the matrix discharge type PDP shown in

FIGS. 1

,


2


A, and


2


B;





FIGS. 34A and 34B

are partial schematic sectional views showing still another PDP different from the matrix discharge type PDP shown in

FIGS. 1

,


2


A, and


2


B;





FIG. 35

is a timing chart showing a write sequence which can be applied to the PDPs of various forms shown in

FIGS. 28

,


29


A,


29


B,


30


,


31


A,


31


B,


32


A,


32


B,


33


,


34


A,


34


B;





FIG. 36

is a timing chart showing another write sequence different from the write sequence shown in

FIG. 35

;





FIG. 37

is a timing chart showing still another write sequence different from the write sequence shown in

FIG. 35

;





FIG. 38

is a timing chart showing still another write sequence different from the write sequence shown in

FIG. 35

;





FIG. 39

is a timing chart showing still another write sequence different from the write sequence shown in

FIG. 35

;





FIG. 40

is a schematic equivalent circuit diagram showing a driving circuit capable of providing the sequence shown in

FIG. 39

;





FIG. 41

is a timing chart showing still another write sequence different from the write sequence shown in

FIG. 35

;





FIG. 42

is a schematic equivalent circuit diagram showing a pulse generation circuit capable of providing the sequence shown in

FIG. 41

;





FIG. 43

is a timing chart showing a write sequence capable of further reducing power consumption by using the pulse generation circuit shown in

FIG. 42

;





FIG. 44

is a timing chart showing a write sequence capable of shortening the rise time by using the pulse generation circuit shown in

FIG. 41

;





FIG. 45

is a timing chart showing a write sequence which can be applied to the PDP of type shown in

FIG. 25

;





FIG. 46

is a partial schematic sectional view for explaining still another embodiment of the discharge space of the PDP


1


shown in

FIGS. 1

,


2


A, and


2


B; and





FIG. 47

is a partial schematic perspective view showing another PDP different from the matrix discharge type PDP shown in

FIGS. 1

,


2


A, and


2


B.











DETAILED DESCRIPTION OF THE INVENTION




A flat panel display apparatus of the present invention, which uses a plasma discharge, will be described below in detail with reference to the accompanying drawing.




As shown in

FIGS. 1

,


2


A, and


2


B, a flat panel display apparatus (to be referred to as a PDP=Plasma Display Panel hereinafter)


1


of the present invention using a plasma discharge has a front substrate


11


which is made of a transparent material and outputs display light (visible light) corresponding to an input image signal, and a light-emitting substrate


31


opposing the front substrate


11


at a predetermined interval to generate visible light corresponding to the display light displayed on the front substrate


11


.




For the front substrate


11


, a material stable in a high-temperature environment generated by a plasma discharge, e.g., glass is used.




The distance between the front substrate


11


and light-emitting substrate


31


is set to be, e.g., 200 μm.




A gas mixture


51


for generating UV rays, which is prepared by mixing Xe (xenon) as a main discharge gas and Ne (neon) as a discharge control gas at a predetermined ratio, is injected into the space between the front substrate


11


and light-emitting substrate


31


at a predetermined pressure P. He (Helium) can also be used as a discharge control gas. The pressure P of the gas mixture


51


is set to satisfy P·d≧7.5 (torr.cm);




when d denotes that the distance between the surface of the front substrate


11


opposing the light-emitting substrate


31


and the surface of the light-emitting substrate


31


opposing the front substrate


11


.




More specifically, the pressure P of the gas mixture


51


is set at a pressure lower than 760 torr and, more preferably, 500 torr.




The partial pressure of the Xe (xenon) gas is preferably set to be 30% larger than 15% or more, as will be described later with reference to FIG.


4


.




A plurality of display electrodes


13


made from metal materials, for example, chromium extending in the first direction (X-axis direction) are formed at a predetermined interval on the surface of the front substrate


11


opposing the light-emitting substrate


31


. The display electrode


13


defines an address in the vertical, i.e., “column” direction and is dominated by the size of the display region of the PDP


1


and required resolution. For example, when the PDP complies with the VGA (Video Graphic Array) standard of the NTSC (National Television System Committee) mode with a diagonal size of 42 inches and an aspect ratio of 16:9, the width and the number of display electrodes


13


are 1.08 mm and 480 (852 sets of corresponding electrodes in the “row” direction are formed on the light-emitting substrate


31


side, as will be described below).




A dielectric layer


15


is formed on the front substrate


11


on the display electrode


13


side to cover both the display electrodes


13


and portions where the front substrate


11


is exposed. That is, the surfaces of the display electrodes


13


, which oppose the front substrate


11


, are protected by the dielectric layer


15


from ions generated from a plasma discharge.




On the dielectric layer


15


, protective films


17


for preventing ions generated from a plasma discharge from reaching the display electrodes


13


are formed at and near portions behind the display electrodes


13


when the display electrodes


13


are viewed from the direction in which an image is output from the front substrate


11


, i.e., from a display surface


11




a.


For the protective films


17


, for example, MgO (magnesium oxide) having a high emission efficiency (secondary electron emission coefficient) of secondary electrons emitted by using ions generated by discharge as a source is used. The thickness of the protective film


17


is set within the range of, e.g., 100 to 1,000 nm and, more preferably, 500 to 1,000 nm and set to 500 nm in the present embodiment.




An ultraviolet light (UV) reflection layer


19


which has characteristics as will be described below with reference to FIG.


7


and reflects UV rays generated from a plasma discharge to the light-emitting substrate


31


side is formed in the entire region on the dielectric layer


15


except the region of the protective film


17


. The UV reflection layer


19


formed from a multilayered dielectric film reflects a predetermined wavelength component of UV rays generated from the plasma discharge and transmits visible light to be transmitted through the front substrate


11


. The UV reflection layer


19


contains YF


3


(yttrium fluoride) having a high reflectance (low absorbance) with respect to photons emitted by Xe* and Xe


2


* (* represents an excited state).




The protective film


17


may cover the entire region of the UV reflection layer


19


disposed on the dielectric layer


15


. In this case, the thickness of the protective film


17


sets to be 40 nm or less, more preferably 20 nm, for introducing the UV rays to the UV reflection layer


19


in high efficiency. The UV reflection layer


19


can be interposed between the protective film


17


and the dielectric layer


15


.




A plurality of display electrodes (counter electrodes)


33


made from metal materials, for example, chromium extend on the surface of the light-emitting substrate


31


opposing the front substrate


11


in the second direction (i.e., Y-axis direction) perpendicular to the direction in which the display electrodes


13


extend on the front substrate


11


, for generating UV rays from the gas mixture


51


injected into the space between the light-emitting substrate


31


and front substrate when a predetermined voltage is applied between the display electrodes


13


and the counter electrodes


33


.




Each counter electrode


33


selectively drives a discharge space


39


corresponding to one of R (red), G (green), and B (blue) at an intersection between one counter electrode


33


and one display electrode


13


on the front substrate


11


when the front substrate


11


is viewed from the display surface


11




a


side. To display a color image by the additive method, three counter electrodes


33


are arranged in correspondence with R (red), G (green), and B (blue) as additive primaries for each pixel, respectively, i.e., 852×3=2556 counter electrodes


33


are arranged in a panel having a display region having the above-described size. In this case, the pitch is ⅓ the pixel size (1.08 mm when the pixel is almost square), i.e., 0.36 mm. The distance between the counter electrodes


33


is set to be smaller than at least that between ribs (barriers) to be described below.




A dielectric layer


35


is formed on the surface of the light-emitting substrate


31


opposing the front substrate


11


to cover both the counter electrodes


33


and portions where the light-emitting substrate


31


is exposed (the entire surface of the light-emitting substrate). That is, the surface of the light-emitting substrate


31


opposing the front substrate


11


is protected from ions generated by a plasma discharge.




On the surface of the light-emitting substrate


31


opposing the front substrate


11


, a plurality of barriers (ribs)


37


are also formed at a predetermined interval to be parallel to the counter electrodes


33


. In this embodiment, ribs


37


are painted black at their top portion using black paint


37




a,


for instance, to improve display contrast of the observer side. In addition to this method, display constrast may also be improved by applying black paint


37




a


to those regions of front substrate


11


that are opposite to ribs


37


, which will be explained later (See FIG.


19


). The distance between the centers of the ribs


37


in the X-axis direction is 0.36 mm, and 852×3+1=2557 ribs are arranged in a panel having a display region having the above-described size.




Each rib


37


forms a discharge space


39


with the adjacent rib


37


. One counter electrode


33


is located in correspondence with each discharge space


39


. At an intersection between one counter electrode


33


and one display electrode


13


on the front substrate


11


, a plasma discharge is selectively generated in the discharge space


39


on the basis of image information of an image to be displayed, as has been described above.




A phosphor layer


41


which emits visible light in accordance with UV rays generated from exited Xe is formed on the inner wall of each discharge space


39


. The phosphor layer


41


is formed by stacking a plurality of phosphor balls formed in substantially spherical shapes with an average grain size of 3 μm or less and, preferably, 2 μm or less and, more preferably, 1 μm or less to a predetermined thickness. By stacking an arbitrary number of phosphor balls, the thickness is set to be, e.g., 5 μm. To display a color image, phosphors


41


R,


41


G, and


41


B having different light-emitting characteristics to display R (red), G (green), and B (blue) images, respectively, are used in units of discharge spaces


39


. The surface of each of the phosphor balls


41


R,


41


G, and


41


B is coated with a phosphor layer protective film


41




a


shown in

FIG. 2C

, which contains at least MgO, protects the phosphor ball


41


R,


41


G, or


41


B from a plasma discharge generated in the discharge space


39


, and passes visible light generated by each phosphor. The phosphor layer protective film


41




a


may contain MgF


2


. This phosphor structure can also be used in another embodiments of this invention.




A visible light reflection layer


43


for reflecting visible light (fluorescent light) generated by the phosphor layers


41


R,


41


G, or


41


B of the phosphor layer


41


toward the front substrate


11


is formed between the inner wall of the discharge space


39


and phosphor layer


41


. The visible light reflection layer


43


suppresses visible light generated in each discharge space


39


from passing through the light-emitting substrate


31


and radiating in a direction reverse to the display surface


11




a


of the front substrate


11


(to the rear surface of the light-emitting substrate


31


), thereby to be extract the light of display light (extraction efficiency η


ex1


) from the display surface


11




a


of the front substrate


11


to an observer side. For the visible light reflection layer


43


, fine reflection particles of Al


2


O


3


(alumina), TiO


2


(titania), MgO, MgF


2


(magnesium fluoride), or the like are used. The visible light reflection layer


43


mainly aims at reflecting visible light and can be painted in, e.g., white. The thickness of the visible light reflection layer


43


dominates the reflectance, as shown in FIG.


10


. When the thickness of the visible light reflection layer


43


is larger than 100 nm, the reflectance is 50% or more. Assume that the center wavelength of visible light is almost 550 nm. When the thickness of the visible light reflection layer


43


is λ/4, the thickness is set to be 130 nm. When the thickness is 2λ, the thickness is set to be 1.1 μm. The grain size (average diameter) of the reflection material of the visible light reflection layer


43


is set to be, e.g., 550 nm by a fine particle manufacturing method (a detailed description thereof will be omitted). It is effective to thin the visible light reflection layer


43


to increase the space of the discharge space


39


. The size of the discharge space depends on the pixel pitch, i.e., resolution and the screen size, and a specific value cannot be indicated. For example, when the pixel pitch is 0.66 mm, and the interval between the discharge spaces


39


is 0.22 mm, the luminous efficiency can be increased by roughly 20% as compared to a conventional arrangement using a phosphor layer with a coating thickness of 20 μm.




An MgO layer having a predetermined thickness may be formed between the visible light reflection layer


43


and dielectric layer


35


as needed. More specifically, since MgO has a function of lowering the discharge voltage, the luminous efficiency can be further increased by forming an MgO layer on the discharge space side of the light-emitting substrate


31


.




Instead of forming a phosphor layer protective film on each phosphor forming the phosphor layer


41


, a phosphor layer protective film may be independently formed on the discharge space


39


side of the visible light reflection layer


43


, as will be described later with reference to FIG.


19


.





FIG. 3

is a block diagram showing a driving circuit for causing the PDP


1


shown in

FIGS. 1

,


2


A, and


2


B to display an image.




As shown in

FIG. 3

, the PDP


1


is connected to a column driving circuit


101


for applying a predetermined voltage to the display electrodes


13


corresponding to an image signal in the X-axis direction under the control of a main control circuit


111


, a row driving circuit


103


for applying a predetermined voltage to counter electrode


33


at positions corresponding to an image signal in the Y-axis direction, and a frame memory


107


for storing an externally supplied image signal. An image signal is input to the frame memory


107


through a video interface


109


for receiving the external image signal.




The main control circuit


111


is connected to known image display circuits including a ROM (program memory)


113


storing drive conditions and control data unique to the PDP


1


, a fundamental clock generation circuit


115


for generating a fundamental clock, a vertical synchronizing signal generation circuit


117


for generating a vertical synchronizing signal V-sync for vertical synchronization with an image signal stored in the frame memory


107


, and a horizontal synchronizing signal generation circuit


119


for generating a horizontal synchronizing signal H-sync for horizontal synchronization with an image signal stored in the frame memory


107


.




Each of the column driving circuit


101


and row driving circuit


103


applies an image display voltage to the display electrodes


13


and counter electrodes


33


, which specify the discharge spaces


39


, in units of subfields divided into a predetermined number of subfields in accordance with a known subfield method, under the control of the main control circuit


111


. More specifically, when a predetermined voltage is applied to each of an arbitrary display electrode


13


on the front substrate


11


and arbitrary counter electrodes


33


(R, G, and B) on the light-emitting substrate


31


, discharge corresponding to image information occurs at the intersection between the electrodes when viewed from the display surface


11




a


side of the front substrate


11


. Due to UV rays generated by a plasma discharge, the phosphor layer


41


(R, G, and B) formed in the discharge space


39


emits visible light of a predetermined color. When driving voltages are applied to the column driving circuit


101


and row driving circuit


103


, sustaining discharge and write discharge are repeated in each discharge space


39


at a predetermined timing.




Each of the column driving circuit


101


and row driving circuit


103


can generate a driving pulse whose rise time is shorter than the duration of Xe


2


* (lifetime of metastable atoms in the excited state). The pulse rise time defined as a time required to change the magnitude of a pulse from 10% to 90% is set to be 10 to 200 nanoseconds (to be referred to as ns hereinafter), as will be described later with reference to FIG.


5


.





FIG. 4

is a graph showing the wavelength distribution of UV rays generated in each discharge space


39


of the PDP


1


shown in

FIGS. 1

,


2


A, and


2


B. The scale representing the intensity in

FIG. 4

is normalized by setting the peak value at


1


.




As shown in

FIG. 4

, in the PDP


1


shown in

FIGS. 1

,


2


A, and


2


B, the partial pressure of Xe, i.e., the ratio of the main discharge gas Xe to the discharge control gas Ne is increased within the range of 15% to 100%. With this arrangement, not only UV rays having a wavelength of 147 nm as Xe* resonant rays of the UV rays generated in a known PDP but also UV rays having a wavelength of 172 nm are obtained by Xe


2


* excimer light emission.




More specifically, conventionally, the partial pressure of Xe in a gas mixture G is increased. Since








e


+Xe→


e


+Xe*






Xe*→Xe+UV rays with wavelength of 147 nm UV rays having a wavelength of 147 nm are extracted. However, since






Xe*+2Xe→Xe*+Xe






Xe


2


*→2Xe+UV rays with wavelength of 172 nm UV rays having a wavelength of 172 nm can be obtained.




The energy for exciting the phosphors of the phosphor layer


41


is smaller for UV rays having a wavelength of 172 nm generated by Xe


2


* excimer light emission than for UV rays having a wavelength of 147 nm. For this reason, the luminous efficiency increases. As is apparent from

FIG. 4

, when the partial pressure of Xe is 10%, a large number of UV rays having a wavelength of 147 nm are contained although UV rays having a wavelength of 172 nm are also generated. Hence, the partial pressure of Xe is preferably 15% or more. In contrast, the partial pressure of Xe is preferably lower than 70%, preferably 60%, more preferably, 40%, since the discharge start voltage becomes high, when the partial pressure of Xe is too higher.





FIG. 5

is a graph showing the relationship between the luminous efficiency and the rise time of an image display pulse applied from each of the column driving circuit


101


and row driving circuit


103


shown in

FIG. 3

to each discharge space


39


, i.e., between one display electrode


13


on the front substrate


11


and one counter electrode


33


on the light-emitting substrate


31


in a subfield. In

FIG. 5

, the efficiency is represented by an arbitrary scale.




As shown in

FIG. 5

, the more quickly a pulse rises (the shorter the rise time is), the higher the luminous efficiency becomes. Hence, a driving pulse with a rise time of 2 μs (microseconds) or less is used.





FIG. 6

is a graph showing the reflection characteristics of the multilayered dielectric film used as the UV reflection layer


19


on the front substrate


11


of the PDP


1


shown in

FIGS. 1

,


2


A, and


2


B.




As shown in

FIG. 6

, the UV reflection layer


19


can provide the maximum reflectance against UV rays with a wavelength of about 172 nm when the UV rays are incident on the reflection layer


19


itself from the normal direction (θ=0°) or at 30° (θ=30°) from the normal. When the incident angle is 45 (θ=45°) from the normal, the peak reflection wavelength is not 172 nm, though it is effective to increase the reflectance of the total UV ray energy generated by discharge. When the UV reflection layer


19


is formed on the surface of the front substrate


11


opposing the light-emitting substrate


31


, the total UV ray energy directed toward the light-emitting substrate


31


is increased by 15% or more.





FIG. 7

is a graph showing improvement of the luminous efficiency of visible light radiating from the discharge space


39


by forming the UV reflection layer


19


having the reflection characteristics shown in

FIG. 6

in the PDP shown in

FIGS. 1

,


2


A, and


2


B.




As shown in

FIG. 7

, when the partial pressure of Xe in the gas mixture is 15%, the luminous efficiency is increased by about 25% by forming the UV reflection layer


19


. When the partial pressure of Xe is 40%, the luminous efficiency is increased by about 20%. As has already been described above, in the PDP


1


shown in

FIGS. 1

,


2


A, and


2


B, the protective film


17


having a thickness of 20 nm is formed on the surface of the UV reflection layer


19


opposing the light-emitting substrate


31


. For this reason, the luminous efficiency is further increased by about 20% for each partial pressure of Xe.





FIG. 8

is a graph showing the relationship between the ratio of visible light extracted from each discharge space


39


of the PDP


1


shown in

FIGS. 1

,


2


A, and


2


B and the reflectance of the visible light reflection layer


43


formed in the discharge space


39


on the light-emitting substrate


31


side.




As shown in

FIG. 8

, when the visible light reflection layer


43


is colored in white using, e.g., Al


2


O


3


(alumina), an almost twice larger (0.8 on the ordinate) visible light amount can be obtained than that (0.4 on the ordinate) in an unprocessed film.





FIG. 9

is a graph showing the relationship between the luminous efficiency and the partial pressure of Xe in the gas mixture


51


supplied in the space (gap) between the front substrate


11


and light-emitting substrate


31


at the pixel pitch of 0.36 mm and 0.22 mm.




As shown in

FIG. 9

, when the partial pressure of Xe is 15% or more, the luminous efficiency is almost doubled. When the partial pressure of Xe is increased, the discharge start voltage becomes higher. However, the discharge start voltage can be suppressed to, e.g., 350V or less by employing a matrix discharge type.





FIG. 11

is a schematic sectional view showing the intensity distribution of visible light radiating from the phosphor layer


41


upon discharge in the space between the front electrodes


13


on the front substrate


11


and the counter electrodes


33


on the light-emitting substrate


31


of the PDP


1


having the structure shown in

FIGS. 1

,


2


A, and


2


B when viewed from the same direction as that in FIG.


2


B.




As shown in

FIG. 11

, in the space between the front electrodes


13


and counter electrodes


33


, visible light radiating from the phosphor layer


41


due to discharge between the electrodes has an intensity distribution as indicated by a region a according to the cosine law for an arbitrary one of a plurality of light emission points on the phosphor layer


41


where the visible light radiates due to discharge. More specifically, of visible light components radiating from an arbitrary point due to discharge between the electrodes, visible light components from a portion indicated by a region β cannot be seen from the side of the display surface


11




a


because the region is covered with the front electrode


13


. Hence, an extraction region γ where visible light radiates toward the display surface


11




a


is indicated by an arc δ. Letting θ be the angle made by an arbitrary point and the discharge center, the extraction efficiency η


ex2


excluding the visible light components that cannot be seen from the display surface


11




a


side because the region is covered with the front electrode


13


is represented by






∫∫½π cos ω·


dωdθ


  (1)






At this time, a light emission intensity I is given by








I=f·D




disp


·η


ex1


·η


ex2


η


UV


·η


phos




·WD


  (2)






where




f is the pulse frequency (normally 100 kHz) in the display period




D


disp


is the duty ratio (normally 10%) in the display period




WD=Cg(V


2


−Ve


2


)




V is the applied voltage, and Ve is the end voltage




The duty ratio D


disp


is set to be 10% by setting an address period D


address


to be 90% in consideration of high accuracy. In addition, η


ex1


is the normal extraction efficiency, η


ex2


is the extraction efficiency excluding the visible light components that cannot be seen from the display surface


11




a


side because of shade of the front electrode


13


, η


phos


is the luminous efficiency of a single phosphor used in the phosphor layer


41


, and η


UV


is the UV luminous efficiency. When the electrostatic capacitance of glass is Cg=εS/d (S: area of front electrode


31


, d: thickness of glass (front substrate)


11


), and the applied voltage is V, the power consumption per pulse is represented by Cg(V


2


−Ve


2


).





FIG. 12

is a graph showing the relationship between the above-described extraction efficiency and the light intensity, i.e., luminance of visible light radiating from each discharge space. Letting W be the width (in the direction perpendicular to the ribs) of the front electrode


13


and D be the distance between the surface of the front substrate


11


on the opposite side of the display surface


11




a


and the surface of the light-emitting substrate


31


opposing the front substrate


11


, W/D is plotted along the horizontal axis in FIG.


12


. Within the range of 0.5≦W/D≦2.4, even when visible light emitted from the discharge space


39


is shielded by the front electrode


13


made from metal materials which is not transparent with visible light, a luminance of 200 cd/m


2


or more and an extraction efficiency of 50% or more can be ensured.




For outdoor use, a luminance higher than 1,000 cd/m


2


is often required.




In this case, the luminance can be increased by increasing WD of equation (2), i.e., S of the area of Cg(V


2


−Ve


2


), i.e., the area of the front electrode


13


.




However, when the area of the front electrode


13


increases, the extraction efficiency η


ex2


decreases.




When the front electrode


13


is formed from at least one of ITO and IZO (Indium Zinc Oxide) using metal materials which passes visible light wavelength radiating from the phosphor layer


41


due to discharge, the luminance can be ensured by increasing the area of the front electrode


13


while increasing the extraction efficiency.





FIGS. 13 and 14

are schematic perspective views for explaining alternative arrangements of the discharge space


39


capable of lowering the discharge start voltage in association with the electrode width W and the distance D between the front substrate


11


and light-emitting substrate


31


, which have been described with reference to

FIGS. 11 and 10

.





FIG. 13

is a view for explaining the first application example. The phosphor layer


41


in the discharge space


39


is removed, along the ribs


37


defining the discharge spaces


39


, in a rectangular shape with an arbitrary width and a predetermined depth by, e.g., a fiber (not shown) having a width smaller than the width of the inner space of the discharge space


39


, i.e., the interval between the ribs


37


(


41




p


), so the phosphor layer


41


becomes thin. In this case, the phosphor can be removed by laser ablation using a laser beam, or an electron beam or ion beam.

FIG. 14

is a view for explaining the second application example. The phosphor layer


41


in the discharge space


39


has an arcade thin portion with a predetermined depth along the extending direction of the ribs


37


(


41




q


).




In the example shown in

FIG. 13

, since the amount of remaining phosphor after removal is sometimes smaller than a predetermined amount, the luminance of visible light generated by discharge may undesirably decrease. Preferably, the phosphor layer


41


is thinned, as shown in

FIG. 14

, or the counter electrode


33


is partially exposed from the phosphor layer


41


, as will be described below.





FIG. 15

shows an example in which a window-shaped electrode exposure portion


41




r


is formed in the phosphor layer


41


to partially expose the counter electrode


33


from the phosphor layer


41


instead of changing the thickness of the phosphor layer


41


in the discharge space


39


as in

FIGS. 13 and 14

.




The length m of the exposure portion


41




r


in the widthwise direction of the ribs


37


is smaller than the width of the counter electrode


33


, and the width of the counter electrode


33


is smaller than the distance between the ribs


37


and the electrode exposure portion


41




r


can lower the discharge start voltage when at least one or all of the following conditions are satisfied:






½


<k




2


, and


k




1




>k




2


>½,






when, k


1


denotes the width of the rib


37


,


1


denotes the distance between the centers of the ribs


37


, k


2


denotes the length of the electrode exposure portion


41




r


in the longitudinal direction of the ribs


37


, and


m


be the length of the electrode exposure portion


41




r


in the widthwise direction of the ribs


37


.




In this embodiment, the electrode exposure portion


41




r


is located within the area of the counter electrode


33


for preventing changes of the discharge start voltage. In stead of the above structure, the m can be set larger than the width of the counter electrode


33


.




The counter electrode exposure portion


41




r


is preferably formed to overlap the display electrode


13


(behind the display electrode


13


) when viewed from the side of the display surface


11




a.






The length m of the counter electrode exposure portion


41




a


in the widthwise direction of the ribs


37


is set to be equal to or smaller than the distance




1




between the centers of the ribs


37


within the range of 50 μm or more (if the length m is smaller then 50 μm, the discharge start voltage cannot be lowered). The length k


2


of the electrode exposure portion


41




r


in the longitudinal direction of the ribs


37


is set to be equal to or smaller than the width W of the display electrode


13


within the range of 50 μm or more (if the length k


2


is smaller then 50 μm, the discharge start voltage cannot be lowered).




As shown in

FIGS. 16A and 16B

, the electrode exposure portion


41




r


of the phosphor layer


41


may have a tapered shape, i.e., the phosphor layer


41


may be removed larger on the inner surface side of the discharge space


39


than at the exposure portion of the counter electrode


33


.




To form the electrode exposure portion


41




r


as shown in

FIGS. 15

,


16


A, and


16


B, before the process of applying or depositing the phosphor layer


41


, a material with high water repellency, e.g., F (fluorine), may be applied in advance to the region where the counter electrode


33


is to be exposed to partially eliminate the phosphor layer


41


.




As described above, when the counter electrode


33


on the light-emitting substrate


31


is partially exposed into the discharge space


39


, or the phosphor layer


41


covering the counter electrode


33


is partially thinned, the discharge start voltage (voltage applied between the display electrode


13


and counter electrode


33


) in the discharge space


39


can be lowered.





FIG. 17

is a graph for explaining the relationship between the partial pressure of Xe and a voltage applied between the display electrode


13


on the front substrate


11


and the counter electrode


33


on the light-emitting substrate


31


in each discharge space


39


in the PDP


1


shown in

FIGS. 1

,


2


A, and


2


B and a surface discharge type PDP (a detailed description thereof will be omitted).




As shown in

FIG. 17

, when the counter discharge scheme is used, and the partial pressure of Xe in the gas mixture is 70% or less, the discharge start voltage can be set to be lower than 350V. Hence, from the viewpoint of lowering the discharge start voltage, the optimum value of the partial pressure of Xe is preferably 15% to 70%, more preferably 60% or less. The discharge start voltage of a known surface discharge type display apparatus exceeds 400V under the same conditions even when the partial pressure of Xe is about 15%, so this apparatus need use a driving element with a higher breakdown voltage than that for the counter discharge type display apparatus.





FIG. 18

is a graph showing the relationship between the luminous efficiency and the height of the barrier (rib)


37


for defining the discharge spaces in the PDP


1


shown in

FIGS. 1

,


2


A, and


2


B. The scale representing luminous efficiency is arbitrary.




As shown in

FIG. 18

, when the matrix discharge scheme is employed, the height of the barrier


37


and the luminous efficiency are substantially proportional to each other. Hence, from the viewpoint of improving the luminous efficiency, the high of the rib comparing to the above described effective distance between the light-emitting substrate


31


and front substrate is preferably 70% or more to reduce crosstalk. In this case, the effective distance between the light-emitting substrate


31


and front substrate


11


is preferably set to be equal to the distance (the rib


37


is in contact with the inner surface of the front substrate


11


) or form a very small gap within a range not to influence the mass producibility in the manufacturing process of the light-emitting substrate


31


in the present invention.





FIG. 19

is a schematic sectional view for explaining the characteristic feature of the discharge space


39


of the PDP


1


shown in

FIGS. 1

,


2


A, and


2


B.

FIG. 19

shows discharge spaces


39


R,


39


G, and


39


B in which the R phosphor (containing a phosphor for mainly emitting the wavelength of a red component)


41


R for displaying red, the G phosphor (containing a phosphor for mainly emitting the wavelength of a green component)


41


G for displaying G, and the B layer (containing a phosphor for mainly emitting the wavelength of a blue component)


41


B for displaying B are deposited to a thickness of about 5 μm, respectively, to display a color image by the additive method.




As has already been described with reference to

FIGS. 1

,


2


A, and


2


B, in each of the discharge spaces


39


R,


39


G, and


39


B, the visible light reflection layer


43


is formed between the phosphor layer


41


(phosphors


41


R,


41


G, or


41


B) and dielectric layer


35


. The visible light reflection layer


43


has a specific thickness defined on the basis of the light emission characteristics (especially light emission intensity) of the phosphor


41


R,


41


G, or


41


B in the corresponding discharge space.




More specifically, in the discharge space


39


R for emitting red light, the thickness of the visible light reflection layer


43


is set to be 200 nm. In the discharge space


39


G for emitting green light, the thickness of the visible light reflection layer


43


is set to be 300 nm. In the discharge space


39


B for emitting blue light, the thickness of the visible light reflection layer


43


is set to be 200 nm.




Since the luminous efficiencies of the phosphors


41


R,


41


G, and


41


B are different, and the visual sensitivity of a human eye changes in units of colors, the light intensity to be output from the discharge space


39


must be set in units of colors. When the thickness of the visible light reflection layer


43


is optimally set in accordance with the color of light to be emitted from each discharge space, the deviation of luminance of each color when viewed from the display surface


11




a


side can be set within a predetermined range. The visual sensitivity to green (G) is high, and even for a slight change in luminance, one feels green dark as compared to other colors. For this reason, as described above, the thickness of the back reflection layer formed for a phosphor with a low luminous efficiency, i.e., in the discharge space


39


G for emitting green light is set to be several times larger than that of the back reflection film formed in the discharge space


39


R or


39


B for emitting red (R) or blue (B) light. The counter electrode exposure portion (


41




p,




41




q


or


41




r


) shown in

FIGS. 13

,


14


,


15


,


16


A, and


16


B may be formed integrally with the visible light reflection layer


43


.





FIG. 20

is a schematic sectional view showing another characteristic feature of the discharge space


39


of the PDP


1


shown in FIG.


19


. The example to be described below with reference to

FIG. 20

includes elements inconsistent with the arrangement described above with reference to

FIGS. 1

,


2


A, and


2


B. However, it can be used as a new variation by optimally setting the luminous efficiencies of the phosphors


41


R,


41


G, and


41


B, the voltage to be applied between the display electrode


13


and counter electrode


33


, the thickness of the dielectric layer


15


, and the like.




As shown in

FIG. 20

, the phosphor layers


41


formed in the discharge spaces


39


R,


39


G, and


39


B have different thickness in accordance with the light emission characteristics of the phosphors


41


R,


41


G, and


41


B of different colors.




More specifically, in the discharge space


39


R for emitting red light, the thickness of the phosphor layer


41


is set to be 20 μm. In the discharge space


39


G for emitting green light, the thickness of the phosphor layer


41


is set to be 40 μm. In the discharge space


39


B for emitting blue light, the thickness of the phosphor layer


41


is set to be 30 μm.




Each of the phosphor layers


41


R,


41


G, and


41


B formed in the discharge spaces


39


(R, G, and B) is covered with a phosphor layer protective film


45


containing MgO. In the discharge spaces


39


, the thickness of the phosphor layer protective film


45


R corresponding to the red phosphor layer


41


R is set to be 50 nm on the phosphor layer


41


R, the thickness of the phosphor layer protective film


41


G corresponding to the green phosphor layer


41


G is set to be 30 nm on the phosphor layer


41


G, and the thickness of the phosphor layer protective film


41


B corresponding to the blue phosphor layer


41


B is set to be 40 nm on the phosphor layer


41


B. The electrode exposure portion


41




p,




41




q


or


41




r


shown in

FIGS. 13

,


14


,


15


,


16


A, and


16


B may be formed integrally with the phosphor layer


41


R,


41


G, or


41


B, and MgO layer


45


.




When different characteristics are imparted to the discharge spaces


39


in units of colors. of light to be emitted, the discharge start voltages for the discharge spaces (colors) can be uniformed.




More specifically, when the thickness is small, the voltage applied to the phosphor becomes low, and the discharge start voltage can be set to be low. Since MgO used for the protective layer has a large secondary electron emission coefficient, the discharge start voltage can be lowered by forming a protective layer.




Therefore, when the types and thickness of phosphors and the thickness of the protective layers are optimally set, the deviation of discharge start voltage when each discharge space emits light of a corresponding color can be set within a predetermined range. This facilitates drive control for displaying an image.





FIGS. 21 and 22

are schematic views showing another embodiment of the matrix discharge type PDP shown in

FIGS. 1

,


2


A, and


2


B.




A PDP


201


has a front substrate


211


using glass or the like as a support material, and a light-emitting substrate


231


which opposes the front substrate


211


at an interval of, e.g., 200 μm and emits visible light corresponding to display light to be displayed on the front substrate


211


.




A UV ray discharge gas mixture


51


containing Xe as a main discharge gas with a partial pressure of, e.g., 15% and Ne as a discharge control gas is injected into a space between the front substrate


211


and light-emitting substrate


231


at a predetermined pressure P. The partial pressure of Xe gas is preferably set to be 15% to 70% as has been described above with reference to FIG.


4


.




A plurality of display electrodes


213


formed from a transparent material such as ITO for passing visible light wavelength extend at a predetermined interval in the X-axis direction on the surface of the front substrate


211


opposing the light-emitting substrate


231


.




A dielectric layer


215


is formed on the surface of the front substrate


211


opposing the light-emitting substrate


231


to cover the display electrodes


213


and front substrate


211


. Auxiliary electrodes


221


are also formed on the surface of the front substrate


211


opposing the light-emitting substrate


231


in the Y-axis direction perpendicular to the display electrodes


213


. The dielectric layer


215


has the same structure as that of the dielectric layer


15


described above with reference to

FIGS. 1

,


2


A, and


2


B.




For the auxiliary electrodes


221


, a metal material having a lower reflectance than that of ITO used for the display electrodes


213


, or an electrode material prepared by stacking ITO on a metal is used.




A UV reflection layer


223


for reflecting UV rays generated from exited Xe to the light-emitting substrate


231


side is formed on the entire region on the dielectric layer


215


except the region of the auxiliary electrode


221


. The UV reflection layer


223


has substantially the same multilayered dielectric structure as that of the UV reflection layer


19


used in the PDP


1


shown in

FIGS. 1

,


2


A, and


2


B.




A protective film


225


formed from, e.g., MgO or MgO containing MgF


2


is formed on the UV reflection layer


223


. The protective film


225


has substantially the same structure as that of the protective film


17


used in the PDP


1


shown in

FIGS. 1

,


2


A, and


2


B, and the thickness is set to be, e.g., 40 nm or less and, preferably, 20 nm.




Counter electrodes


233


for causing discharge from the gas mixture


51


injected into the space between the light-emitting substrate


231


and front substrate


211


when a predetermined voltage is applied between the display electrodes


213


and auxiliary electrodes


221


on the front substrate


211


extend on the surface of the light-emitting substrate


231


opposing the front substrate


211


in a direction (Y-axis direction) parallel to the auxiliary electrodes


221


on the front substrate


211


. The counter electrode


233


has substantially the same structure as that of the counter electrode


33


used in the PDP


1


shown in

FIGS. 1

,


2


A, and


2


B.




Discharge spaces


239


are formed by a dielectric layer


235


and ribs


237


in the entire region on the counter electrodes


233


and exposed portions on the surface of the light-emitting substrate


231


opposing the front substrate


211


. A phosphor layer


241


and visible light reflection layer


243


as those in the PDP described above with reference to

FIGS. 1

,


2


A, and


2


B are formed on the inner surfaces of each discharge space


239


.




Phosphor balls


241


R,


241


G, and


241


B having different light emission characteristics are used for the phosphor layers


241


to allow emission of light of R (red), G (green), and B (blue).




The phosphor layer


241


is formed by stacking a plurality of phosphor balls formed in substantially spherical shapes with an average grain size of 3 μm or less and, preferably, 2 μm or less and, more preferably, 1 μm or less to a thickness of, e.g., 5 μm. To display a color image, the phosphor balls


241


R,


241


G, and


241


B having different light emission characteristics are used to allow emission of light of R (red), G (green), and B (blue) in units of phosphor layers


241


.




Each phosphor layer


241


is covered with a phosphor layer protective film


245


containing at least MgO. The phosphor layer protective films


245


protect the phosphor balls


241


R,


241


G, and


241


B forming the phosphor layers from a plasma discharge generated in the discharge spaces


239


and can pass visible light.




In this case, the types and thickness of phosphors and the thickness of the protective layers are optimally set, the deviation of discharge start voltage when each discharge space emits light of a corresponding color can be set within a predetermined range mentioned above.





FIG. 23

is a block diagram showing a driving circuit for causing the PDP


201


shown in

FIGS. 21 and 22

to display an image.




As shown in

FIG. 23

, the PDP


201


is connected to a column (X-axis direction) driving circuit


301


, a row (Y-axis direction) driving circuit


303


, an auxiliary electrode driving circuit


305


for applying a predetermined voltage to the auxiliary electrodes


221


, and a frame memory


307


. The column driving circuit


301


, row driving circuit


303


, and frame memory


307


substantially have the same arrangements as those of the circuits described above with reference to FIG.


3


.




Each of the column driving circuit


301


and row driving circuit


303


applies an image display discharge voltage to each discharge space


239


in units of subfields divided into a predetermined number of subfields in accordance with a known subfield method, under the control of a main control circuit


311


. More specifically, first discharge, i.e., initial discharge is induced between the display electrodes


213


and auxiliary electrodes


221


on the front substrate


211


, as schematically shown in FIG.


22


. The discharge gas in each discharge space


239


is ionized, and subsequent write discharge and sustaining discharge with the counter electrodes


233


can be started at a low interelectrode voltage. In addition, when the interiors of all the discharge spaces


239


are initialized by initial discharge before write discharge for image display, initial conditions in the discharge spaces


239


are uniformed, so controllability in the entire display region is improved.




The main control circuit


311


is connected to known image display circuits including a ROM


313


storing drive conditions and control data unique to the PDP


201


, a fundamental clock generation circuit


315


for generating a fundamental clock, a vertical synchronizing signal generation circuit


317


for generating a vertical synchronizing signal V-sync for vertical synchronization with an image signal stored in the frame memory


307


, and a horizontal synchronizing signal generation circuit


319


for generating a horizontal synchronizing signal H-sync for horizontal synchronization with an image signal stored in the frame memory


307


, as has been described above with reference to FIG.


3


.




Each of the column driving circuit


301


and row driving circuit


303


outputs an exciting pulse shorter than 2 μs, as has been described above with reference to FIG.


3


.





FIG. 24

is a schematic sectional view showing a modification of the PDP


201


shown in

FIGS. 21 and 22

. As a characteristic feature, on a display-surface-


211




a


-side surface of each auxiliary electrode


221


on the surface substrate


211


, a mask member


221




a


using black ink or the like is formed integrally with the auxiliary electrode


221


or stacked on the auxiliary electrode


221


.




According to this arrangement, diffused reflection which takes place when the front substrate


211


is viewed from the display surface


211




a


side, i.e., that light coming from the display surface


211




a


side of the front substrate


211


to the light-emitting substrate


231


side is diffused and reflected by the auxiliary electrodes


221


and returned to the display surface


211




a


side can be suppressed, so dark luminance in the undischarged state, i.e., on the black screen can be lowered. Hence, display (black) of a black image can be faithfully reproduced. In addition, since slight emission upon initial discharge caused by applying a voltage between the display electrode


213


and auxiliary electrode


221


can be shielded from the side of the display surface


211




a,


dark contrast can be improved.





FIG. 25

is a schematic sectional view showing an embodiment of one pixel of a coplanar discharge type (display electrodes are formed on the same surface) PDP different from the counter electrode type PDP shown in

FIGS. 1

,


2


A, and


2


B or

FIGS. 21 and 22

. In

FIG. 25

, the light-emitting substrate


431


is rotated with 90 degree against to the front substrate


411


for easy understanding.




As shown in

FIG. 25

, a PDP


401


has a front substrate


411


on which first electrodes (X display electrodes)


413




a


extending in the first direction (X-axis direction) and second electrodes (Y display electrodes)


413




b


extending almost parallel to the first electrodes


413




a


are formed on the same surface, and a light-emitting substrate


431


opposing the front substrate


411


at a predetermined interval.




On the surfaces of the first and second electrodes


413




a


and


413




b,


a dielectric layer


415


containing, e.g., MgO is formed to cover the electrodes


413




a


and


413




b


and portions where the front substrate


411


having none of the electrodes


413




a


and


413




b


are exposed.




Protective films


417




a


and


417




b


for protecting the electrodes


413




a


and


413




b


from ions generated from exited Xe are formed on the dielectric layer


415


at and near portions behind the electrodes


413




a


and


413




b


when viewed from a display surface


411




a


side of the front substrate


411


. The protective films


417




a


and


417




b


substantially have the same structure as that of the protective film


17


used for the PDP


1


shown in

FIGS. 1

,


2


A, and


2


B and are formed to a thickness of, e.g., of 100 nm or more, for instance, of 500 nm.




A UV reflection layer


419


for reflecting UV rays generated in the discharge space to the light-emitting substrate


431


side is formed at each portion where the dielectric layer


415


is exposed (region where none of the protective films


417




a


and


417




b


are formed). The UV reflection layer


419


is formed from a multilayered dielectric film substantially having the same structure as that of the UV reflection layer


19


used for the PDP


1


shown in

FIGS. 1

,


2


A, and


2


B.




Address electrodes


433


(R, G, and B) extending in a direction (Y-axis direction) perpendicular to the first and second electrodes


413




a


and


413




b


are formed on the surface of the light-emitting substrate


431


opposing the front substrate


411


at a pitch defined on the basis of the resolution required of the PDP


401


. The address electrode


433


has a structure similar to that of the counter electrode


33


used for the PDP


1


shown in

FIGS. 1

,


2


A, and


2


B.




Each address electrode


433


(R, G, or B) is used to cause predischarge in a corresponding discharge space


439


defined by a dielectric layer


435


and ribs


437


and specify the discharge space


439


where UV rays must be generated from a gas mixture


51


injected into a space between the light-emitting substrate


431


and front substrate


411


in accordance with discharge by the first and second electrodes


413




a


and


413




b


for image display before the plasma discharge is caused by applying a predetermined voltage to the first and second electrodes


413




a


and


413




b.


Three address electrodes


433


are prepared for each pixel in accordance with the display color (R, G, or B) to be displayed by the pixel.




A visible light reflection layer


443


and a phosphor layer


441


for emitting visible light in accordance with the UV rays generated from exited Xe by the plasma discharge are formed on the inner wall of each discharge space


439


. The phosphor layer


441


is covered with a phosphor layer protective film


445


containing, e.g., MgO and MgF


2


as in the above-described PDPs.




In the PDP


401


having display electrodes (first and second electrodes) formed on the same surface, an erase pulse, a write pulse, and a sustaining pulse for causing initial discharge, write discharge, and sustaining discharge, respectively, are applied to the first and second electrodes


413




a


and


413




b


and address electrodes


433


at a predetermined timing.





FIG. 26

is a schematic sectional view showing a barrier rib type PDP which is different from the above-described matrix discharge type PDP or coplanar discharge type PDP having display electrodes formed on the same surface, and has electrodes formed on ribs for defining discharge spaces.




As shown in

FIG. 26

, in a plasma discharge type display apparatus


501


, a gas mixture


51


for generating UV rays, which is prepared by mixing Xe as a main discharge gas and Ne as a discharge control gas such that the partial pressure of Xe becomes 15%, is injected into a space between a front substrate


511


having a display surface


511




a


and a counter substrate


531


opposing the front substrate


511


at an interval of, e.g., 200 μm at a predetermined pressure P.




A plurality of address electrodes


523


extending in the first direction (X-axis direction) are formed at a predetermined interval on the surface of the front substrate


511


opposing the counter substrate


531


. The address electrode


523


is a transparent electrode capable of passing visible light.




A dielectric layer


515


containing, e.g., MgO is formed on the surfaces of the address electrodes


523


opposing the counter substrate


531


to cover regions except regions defined by portions at and near the address electrodes


523


, i.e., portions where no address electrodes


523


are formed and the front substrate


511


is exposed. The dielectric layer


515


is formed to a thickness of, e.g., 100 nm or more.




A protective film


517


for protecting the electrodes


523


from ions generated by a plasma discharge is formed on the surface of the dielectric layer


515


opposing the counter substrate


531


at and near portions behind the electrodes


523


when the address electrodes


523


are viewed from the display surface


511




a


side of the front substrate


511


. The protective film


517


has substantially the same structure as that of the protective film in the above-described PDPs and is formed to a thickness of, e.g., 100 nm or more.




A UV reflection layer


519


for reflecting UV rays generated in discharge to the counter substrate


531


is formed at each portion where no address electrode


523


is formed, i.e., in a region where the dielectric layer


515


is exposed.




A plurality of ribs


537


extending in the second direction (Y-axis direction) perpendicular to the first direction in which the address electrodes


523


extend on the front substrate


511


and also standing almost vertically from the counter substrate


531


toward the front substrate


511


are formed on the counter substrate


531


. A region defined by two ribs


537


and counter substrate


531


forms a discharge space


539


between the counter substrate


531


and front substrate


511


.




First and second electrodes (display electrodes)


551




a


and


551




b


are formed at predetermined positions of the ribs


537


located almost at the center in the direction of height of the ribs


537


or on the counter substrate


531


side in the inner wall of each discharge space


539


to oppose each other in the discharge space


539


.




As in the above-described display apparatuses, a visible light reflection film


543


having a predetermined thickness is formed on the inner surface of the discharge space


539


, i.e., at a portion surrounded by two ribs


537


having two electrodes


551




a


and


551




b


opposing each other and the surface of the counter substrate


531


opposing the front substrate


511


, and a phosphor layer


541


having a predetermined thickness, which emits visible light in accordance with UV rays generated from exited Xe by the plasma discharge, is formed on the inner surface of the visible light reflection film


543


.




In the PDP


501


having display electrodes (first and second electrodes) integrated with the ribs, an erase pulse, a write pulse, and a sustaining pulse for causing initial discharge, write discharge, and sustaining discharge, respectively, are applied to the first and second display electrodes


551




a


and


551




b


and address electrodes


523


on the front substrate


511


side at a predetermined timing.





FIGS. 27A and 27B

are schematic sectional views showing a PDP having fourth electrodes, which is different from the above-described matrix discharge type PDP, PDP having display electrodes formed on the same surface, and PDP having display electrodes formed in the ribs.




As shown in

FIGS. 27A and 27B

, a PDP


601


has a front substrate


611


formed from a transparent material for passing the wavelength of visible light and having a predetermined number of first electrodes (X display electrodes)


613




a


extending in the first direction, second electrodes (Y display electrodes)


613




b


extending in parallel to the first electrodes


613




a,


and priming electrodes (fourth electrodes)


625


extending in parallel to the first and second electrodes, and a light-emitting substrate


631


opposing the front substrate


611


at a predetermined interval. A gas mixture


51


for UV discharge, which is prepared by mixing Xe as a main discharge gas and Ne as a discharge control gas such that the partial pressure of Xe becomes 15%, is injected into a space between the two substrates at a predetermined pressure P. A dielectric film


615


is formed on the surfaces of the substrate


611


and electrodes


613




a,




613




b,


and


625


. Protective films


617




a,




617




b,


and


617




c


containing, e.g., MgO are formed on the surfaces of the first electrodes


613




a,


second electrodes


613




b,


and priming electrodes


625


via the dielectric film


615


, respectively. Each of the protective films


617




a


to


617




c


is formed to a thickness of, e.g., 100 nm or more. Portions where a dielectric layer


615


is exposed (regions where none of the electrodes


613




a,




613




b,


and


625


are formed on the front substrate


611


) and the protective films


617




a


to


617




c


are covered with the UV reflection layer


619


.




A predetermined number of address electrodes


633


extending in a direction perpendicular to the first and second electrodes


613




a


and


613




b,


and priming electrodes


625


and used to execute predischarge in a space between each address electrode and a corresponding priming electrode


625


specify a discharge space


639


where UV rays must be generated from the gas mixture


51


injected into a space between the counter substrate


631


and front substrate


611


in accordance with the plasma discharge by the electrodes


613




a


and


613




b


for image display before the plasma discharge is caused by applying a predetermined voltage to the electrodes


613




a


and


613




b.


The address electrode


633


has substantially the same structure as that of the counter electrode in, e.g., the matrix discharge type PDP (electrode formed on a counter substrate).




In the PDP


601


having the fourth electrodes, an erase pulse, a write pulse, and a sustaining pulse for causing initial discharge, write discharge, and sustaining discharge, respectively, are applied to the first and second electrodes


613




a


and


613




b


and address electrodes


633


at a predetermined timing. Before application of a write pulse to each display electrode, predischarge and initial discharge are executed between the priming electrodes


625


and address electrodes


633


.





FIGS. 28

,


29


A, and


29


B are schematic views showing an embodiment different from all of the above-described PDPs.




As shown in

FIGS. 28

,


29


A, and


29


B, in a PDP


701


, a gas mixture


51


for UV discharge, which is prepared by mixing Xe as a main discharge gas and Ne as a discharge control gas such that the partial pressure of Xe becomes 15%, is injected into a space between a front substrate


711


having a display surface


711




a


and a light-emitting substrate


731


opposing the front substrate


711


at an interval of, e.g., 200 μm at a predetermined pressure P.




A plurality of display electrodes


713


extending in the X-axis direction at a predetermined interval and auxiliary electrodes


727


parallel to the display electrodes


713


are formed on the surface of the front substrate


711


opposing the light-emitting substrate


731


. A mask member


727




a


formed from black ink or the like is formed on the surface of each auxiliary electrode


727


on a display surface


711




a


side.




The display electrodes


713


and auxiliary electrodes


727


are covered with a dielectric layer


715


. A UV reflection layer


719


and a dielectric layer


717


are laminated on the dielectric layer


715


for preventing ions generated from the plasma discharge.




To display a color image, three counter electrodes


733


for R (red), G (green), and B (blue) display are formed on the light-emitting substrate


731


at a predetermined pitch for each pixel and protected from ions generated in the plasma discharge by the dielectric layer


735


. A plurality of barriers (ribs)


737


for forming discharge spaces


739


are formed at a predetermined interval in parallel to the counter electrodes in a direction in which the counter electrodes


733


extend.




A phosphor layer


741


for emitting visible light in accordance with the UV rays generated from exited Xe by the plasma discharge is formed on the inner wall of each discharge space


739


, and a visible light reflection layer


743


for reflecting visible light emitted from the phosphor layer


741


toward the front substrate


711


is formed between the inner wall of each discharge space


739


and the phosphor layer


741


. The phosphor layer


741


is covered with a phosphor layer protective film


745


containing, e.g., MgO and MgF


2


.




In the PDP


701


of this type, an erase pulse, a write pulse, and a sustaining pulse for causing initial discharge, write discharge, and sustaining discharge, respectively, are applied to the display electrodes


713


, auxiliary electrodes


727


, and counter electrodes


733


by a driving circuit as that shown in

FIG. 3

at a predetermined timing. In the display apparatus


701


shown in

FIG. 28

, the auxiliary electrodes


727


are formed parallel to the display electrode


713


, i.e., perpendicularly to the counter electrodes


733


. Hence, initial discharge (discharge by the erase pulse) is applied near the front substrate


711


, as shown in FIG.


29


B. Hence, the wall charges do not become 0, and the start of write (start of discharge) by the write pulse and sustaining discharge by the sustaining pulse are attained at a low voltage.





FIG. 30

is a schematic sectional view showing an embodiment different from all the above-described PDPs.




As shown in

FIG. 30

, in a PDP


801


, display electrodes


813


extending in the X-axis direction, a dielectric layer


815


covering the display electrodes


813


and a front substrate


811


, a plurality of high-resistance layers


829


extending along the Y-axis direction in the dielectric layer


815


at a predetermined interval, and a UV reflection layer


819


and a dielectric layer


817


which cover the high-resistance layers


829


and dielectric layer


815


are formed on the surface of the front substrate


811


on the opposite side of a display surface


811




a.


A counter substrate


831


has substantially the same structure as that of the above-described matrix discharge type PDP (

FIGS. 2A

,


22


, or


25


).




In each discharge space


839


, the high-resistance layer


829


is located at a position closer to a counter substrate


833


than a rib


837


. When viewed from the display surface


811




a


of the front substrate


811


, the high-resistance layer


829


is located to overlap the Y-axis direction region of a phosphor layer


841


formed in the discharge space


839


. That is, the high-resistance layer


829


is formed to partially cover the rib


837


when viewed from the display surface


811




a


side.




The PDP


801


of the type shown in

FIG. 30

stores an immediately preceding discharged state for a predetermined time after discharge is completed by increasing the time until wall charges (surface charges) remaining in the dielectric layer


815


covering the display electrodes


813


disappear.




More specifically, letting Vw be the potential difference generated by wall charges, Vc be the voltage applied between the display electrode


813


and counter electrode


833


, and Vb be the discharge start voltage, the respective voltages are set to satisfy








Vc+Vw≧Vb, Vc<Vb.








With this setting, the time for which the discharge space with residual wall charges is turned on can be prolonged by a predetermined time.




Since the amount of wall charges stored in the dielectric layer


815


covering the display electrodes


813


attenuates over time due to diffusion on the surface of the dielectric layer


815


or combination of charged particles, and the voltage Vw may not reach the expected level, the voltage Vc must be set to be relatively high. In this case, the wall charge remaining time, i.e., the margin of the memory function is expected to be small.




On the other hand, attenuation of wall charges due to diffusion in the direction of plane of the front substrate


811


is suppressed by the high-resistance layers


829


.




With this arrangement, the application voltage Vc can be set to be low. In addition, the margin of the memory function is ensured, and drive control can be stabilized.





FIGS. 31A and 31B

are schematic sectional views showing a modification of the PDP shown in FIG.


30


.




As shown in

FIGS. 31A and 31B

, in a PDP


901


, display electrodes


913


extending in the X-axis direction (first direction) on the surface of a front substrate


911


on the opposite side of a display surface


911




a,


a dielectric layer


915


covering the display electrodes


913


and front substrate


911


, front-substrate-side strap dielectric layers


951


formed almost parallel to the display electrode


913


(Z-axis direction) while sandwiching the dielectric layer


915


and having almost the same width (Y-axis direction) as that of the display electrode


913


, a UV reflection layer


919


covering the strap dielectric layers


951


and dielectric layer


915


, and a protective film


917


are formed in a predetermined order.




The dielectric constant of the strap dielectric layer


951


is preferably set to be 10 times that of a dielectric material of the dielectric layer


915


. That is, the strap dielectric layer


951


is made of a dielectric material having a dielectric constant about 10 times larger than that of the dielectric material used for the dielectric layer


915


.




On a counter substrate


931


, counter electrodes


933


extending in the Y-axis direction, a dielectric layer


935


covering the counter electrodes


933


and counter substrate


931


, and counter-electrode-side strap dielectric layers


953


formed almost parallel to the counter electrodes


933


(Y-axis direction) while sandwiching the dielectric layer


935


and having almost the same width (X-axis direction) as that of the display electrode


933


are formed. Each counter-substrate-side strap dielectric layer


953


is covered with a visible light reflection film


943


or a protective film (not shown) and sealed in each discharge space


939


by a phosphor layer


941


. The counter-substrate-side strap dielectric layer


953


is formed from a dielectric material having a dielectric constant about 10 times larger than that of the dielectric material used for the dielectric layer


935


.




In the PDP


901


having the form shown in

FIGS. 31A and 31B

, charges can be easily induced at the interfaces between the dielectric layers having a large dielectric constant difference, i.e., at the interface between the dielectric layer


915


and front-substrate-side strap dielectric layers


951


and at the interface between the counter-substrate-side strap dielectric layer


953


and dielectric layer


935


, so the magnitude Vw of residual charges after discharge can be increased. For this reason, the interelectrode application voltage Vc can be made low. In addition, since charges at the interface do not combine with charged particles in the gas space, the remaining time of the residual charges can be prolonged within a predetermined range.





FIGS. 32A and 32B

are schematic sectional views showing still another modification of the PDP shown in FIG.


30


.




As shown in

FIGS. 32A and 32B

, in a PDP


1001


, display electrodes


1013


extending in the X-axis direction, a dielectric layer


1015


covering the display electrodes


1013


and front substrate


1011


, a plurality of front-substrate-side auxiliary electrodes


1071


formed almost parallel to the display electrode


1013


while sandwiching the dielectric layer


1015


and having almost the same width (Y-axis direction) as that of the display electrode


1013


, and a UV reflection layer


1019


and protective film


1017


which cover the front-substrate-side auxiliary electrode


1071


and dielectric layer


1015


are formed on the surface of a front substrate


1011


on the opposite side of a display surface


1011




a.


A counter substrate


1031


has substantially the same structure as that of the above-described matrix discharge type PDP (

FIGS. 2A

,


22


, or


25


).




According to this arrangement, since predischarge is caused by the front-substrate-side auxiliary electrodes


1071


, the application voltage Vc can be set to be low.





FIG. 33

is a schematic sectional view showing still another modification of the PDP shown in FIG.


30


.




As shown in

FIG. 33

, in a PDP


1101


, display electrodes


1113


extending in the X-axis direction, high-dielectric solid layers


1181


extending in the Y-axis direction perpendicular to the display electrodes


1113


, and a dielectric layer


1115


covering the display electrodes


1113


, high-dielectric solid layers


1181


, and a front substrate


1111


are formed on the surface of the front substrate


1111


on the opposite side of a display surface


1111




a.


A protective film


1117


and a UV reflection layer


1119


are also formed on the dielectric layer


1115


as needed. A counter substrate


1131


has substantially the same structure as that of the above-described matrix discharge type PDP (

FIGS. 2A

,


22


, or


25


).




In the PDP


1101


shown in

FIG. 33

, the electric field near the front substrate


1111


including the high-dielectric solid layers


1181


is strong, and the discharge start voltage can be set to be low. Hence, as in the above examples, the interelectrode application voltage Vc can be made low, and drive control is stabilized.





FIGS. 34A and 34B

are schematic sectional views for explaining still another embodiment of the PDP having various forms as shown in

FIGS. 1

,


2


A,


2


B,


21


,


22


A,


22


B,


28


,


29


A,


29


B,


30


,


31


A,


31


B,


32


A,


32


B, and


33


.




As shown in

FIGS. 34A and 34B

, in a PDP


1201


, display electrodes


1213


extending in the X-axis direction, and a dielectric layer


1215


covering the display electrodes


1213


and a front substrate


1211


are formed on the surface of the front substrate


1211


on the opposite side of a display surface


1211




a.


The width (Y-axis direction) of the display electrode


1213


is set to almost equal the thickness (Z-axis direction) of the dielectric layer


1215


. That is, the width of the display electrode


1213


is defined to be smaller than that in most of the above-described PDPs. A UV reflection layer


1219


and a protective film


1217


are formed with a predetermined positional relationship on the dielectric layer


1215


.




Counter electrodes


1233


extending in the Y-axis direction, and a dielectric layer


1235


having a predetermined thickness and covering the counter electrodes


1233


and a counter substrate


1231


are stacked on the counter substrate


1231


. A protective film


1255


made of the same material as that of the protective film


1217


on the front substrate


1211


side is formed above the counter substrate


1231


as part of each discharge space


1239


defined by ribs


1237


. The width (X-axis direction) of the counter electrode


1233


is set to almost equal the thickness (Z-axis direction) of the dielectric layer


1235


. That is, the width of the counter electrode


1233


is defined to be smaller than that in most of the above-described PDPs.




In the PDP shown in

FIGS. 34A and 34B

, since the width of the display electrode


1213


or counter electrode


1233


is set to be smaller, the effective electrostatic capacitance between the front substrate


1211


and counter substrate


1231


is reduced. For this reason, the magnitude of a rush current required to charge/discharge the electrostatic capacitance between the counter substrate


1231


and front substrate


1211


can be made small. Hence, the magnitude of the rush current and power consumption upon applying a pulse voltage are also decreased.




In the PDP shown in

FIGS. 34A and 34B

, an image write corresponds to storage of wall charges on the display electrodes, and the wall charge amount for giving the required wall charge potential difference Vw is decreased by decreasing the electrode area. Hence, the discharge sustaining time necessary for storing wall charges is shortened. Consequently, the pulse time of a pulse voltage used for the image write can be shortened. This is advantageous in shortening the image write time when the number of scanning lines (the number of ribs and discharge spaces) increases along with an increase in, e.g., resolution and display area.




The pulse time (pulse width) is set to be about 2 μs or less including the pulse rise time, as described above.




Letting vd be the drift speed of ions in the gas mixture for discharge, and


1


be the distance between the front substrate


1211


and counter substrate


1231


, the pulse interval of write pulses or sustaining pulses, i.e., the time until the next pulse is supplied is preferably set to be at least 1/vd. When the duty ratio is 1:1, the pulse time (pulse width) is set to be 1/vd.





FIG. 35

is a timing chart for explaining a write pulse for writing an image in each pixel and an erase pulse for erasing a displayed image by using a driving circuit shown in, e.g.,

FIG. 3

in the PDPs of various types shown in

FIGS. 28

,


29


A,


29


B,


30


,


31


A,


31


B,


32


A,


32


B,


33


,


34


A, and


34


B.




As the characteristic feature of the write sequence shown in

FIG. 35

, a negative (write) pulse is applied to the front substrate as a write pulse, positive and negative sustaining pulses are alternately applied to the front substrate for a predetermined time to display an image, and at the end of one sequence, a positive erase pulse is applied to the front substrate. In the write sequence shown in

FIG. 35

, the counter substrate is grounded.




More specifically, as shown in

FIG. 35

, when a negative pulse is used as the write pulse, the magnitude (voltage) of the write pulse can be made small. Hence, when an erase pulse is applied every time one write sequence is ended, full lightening which is popularly used in known display apparatuses can be omitted, and the initial states of residual charges in the discharge spaces can be uniformed. Additionally, by using an erase pulse, the dark luminance and dark contrast are improved.




More specifically, in the above-described PDPs of various types, a protective film containing MgO and the like is formed on the surface of the front substrate on the opposite side of the display surface, i.e., on the surface of the front substrate


11


opposing the discharge space, and a protective film containing MgO and the like and a phosphor layer covering the protective film are formed on the surface of the counter substrate opposing the front substrate. Discharge is started due to a low voltage first on the front substrate side where MgO having a large secondary electron emission coefficient is located in the front. That is, when negative voltage application to the front substrate is compared with negative voltage application to the counter substrate, the discharge start voltage can be made lower in negative voltage application to the front substrate.




The erase pulse is effective to improve the phenomenon that the dark luminance and dark contrast lower due to the influence of full lightening which is regarded as an effective means for uniforming the initial states of charges in all discharge spaces.





FIG. 36

is a timing chart for explaining another example of the write and erase sequence shown in FIG.


35


.




As shown in

FIG. 36

, as the characteristic feature of this write sequence, a positive (write) pulse is applied to the counter substrate as a write pulse, positive and negative sustaining pulses are alternately applied to the front substrate for a predetermined time to display an image, and at the end of one sequence, a positive erase pulse is applied to the counter substrate.




According to the driving method shown in

FIG. 36

, the write pulse and sustaining pulse used to display an image are divisionally supplied to the front and counter substrates, respectively, and the number of semiconductor devices necessary as drivers is reduced.




As described with reference to

FIG. 35

as well, the erase pulse is effective to omit full lightening which is widely used in known display apparatuses, uniform the initial states of charges in the discharge spaces, and improve the dark luminance and dark contrast.





FIG. 37

is a timing chart for explaining another example of the image write and erase sequence described with reference to FIG.


35


.




As the characteristic feature of the sequence shown in

FIG. 37

, a positive (write) pulse is applied to the counter substrate as a write pulse, a positive sustaining pulse is continuously applied to the front and counter substrates for a predetermined time, and at the end of one sequence, a negative erase pulse is applied to the front substrate.




More specifically, a sustaining pulse Vs is normally set to satisfy








Vs+Vw≧Vb, Vc<Vb








where




Vw: magnitude of wall charges




Vb: discharge start voltage




Vc: potential difference between substrates




When an erase pulse Ve as the characteristic feature of the write sequence shown in

FIG. 37

is applied, the magnitude of the wall charges Vw becomes “0”. For this reason, the magnitude of a write pulse Vo required next changes to








Vo=Vb








The magnitude of the erase pulse Ve must be set such that wall charges Vw′ satisfying








Vs+Vw








remain after application of the erase pulse Ve.




More specifically, when a negative pulse is applied as the erase pulse Ve, the write pulse Vo subsequently required can be lowered:








Vo=Vb−Vw








When this relationship is satisfied, the memory function (by wall charges) in each discharge space is not damaged.





FIG. 38

is a timing chart for explaining a write pulse which can be applied to the write sequences shown in

FIGS. 35

to


37


.




As shown in

FIG. 38

, the write pulse rises almost to the sustaining pulse Vs at the first leading edge during the first pulse rise time of about 1 μs and rises to the discharge start voltage Vb at the second leading edge during the second pulse rise time of 100 ns shorter than the first pulse rise time.




As shown in

FIG. 38

, when rise of the pulse waveform is relaxed (preparing the first leading edge), the rush current to the electrostatic capacitance between the substance can be made small. At the second leading edge, the pulse abruptly rises, and the discharge characteristics are not adversely affected.





FIG. 39

is a timing chart for explaining a write pulse which can be applied to the write sequences shown in

FIGS. 35

to


37


.

FIG. 40

is a schematic circuit diagram for explaining a pulse generation circuit capable of providing the pulse shown in FIG.


39


.




As shown in

FIG. 39

, the write pulse steeply rises immediately before the start of discharge while decreasing the magnitude of the rush current.




More specifically, the write pulse rises due to series oscillation by an intersubstrate electrostatic capacitance C, a circuit resistance Ro, an internal resistance R


1


of a first switch S


1


, and an inductance L


1


. When dv/dt obtained by differentiating the change in voltage by time is maximized, the switch S


1


is switched to a second switch S


2


, and the sustaining voltage is divided by an internal resistance R


2


of the switch S


2


, intersubstrate electrostatic capacitance C, and circuit resistance Ro. In this case, the relationship between a voltage V


1


provided by the switch S


1


and a voltage V


2


divided by the switch S


2


is defined to be V


1


=V


2


.




That is, when the pulse generation circuit shown in

FIG. 40

is used, a pulse having a short rise time can be provided while regulating the magnitude of the rush current of the (write) pulse. When the pulse generation circuit shown in

FIG. 40

is used, the rise characteristics of the write pulse immediately before the start of discharge can be set steeply. This improves the discharge efficiency.





FIG. 41

is a timing chart showing another example of the write pulse shown in FIG.


39


.

FIG. 42

is a schematic circuit diagram for explaining a pulse generation circuit for generating the pulse shown in FIG.


41


.




As shown in

FIG. 41

, the write pulse quickly rises to suppress the rush current and falls such that the discharge characteristics at the time of falling (discharge) due to the intersubstrate electrostatic capacitance at the end of discharge become moderate.




More specifically, the write pulse rises due to series oscillation by the intersubstrate electrostatic capacitance C, circuit resistance Ro, internal resistance R


1


of the first switch S


1


, and inductance L


1


. The sustaining voltage is divided by an internal resistance R


3


of a switch S


3


, intersubstrate electrostatic capacitance C, and circuit resistance Ro. The voltage is attenuated by series oscillation provided by the internal resistance R


2


of the switch S


2


, intersubstrate electrostatic capacitance C, and circuit resistance Ro. In this example, a relation 2V


1


=2V


2


=V


3


holds between the voltages V


1


, V


2


, and V


3


provided by the respective switches.




That is, when the pulse generation circuit as shown in

FIG. 42

is used, moderate fall can be realized to relax the discharge characteristics in discharge while maintaining steep rise of the (write) pulse. A power consumption W in charge/discharge of the pulse generation circuit shown in

FIG. 42

is given by








W


=(π


V




2


/8)×{square root over ((


C/L


))}










L


=4


L




1








Hence, the power consumption at the time of fall can be reduced to ½ that at the time of rise.





FIG. 43

is a timing chart showing a write sequence capable of further reducing power consumption by using the pulse generation circuit shown in FIG.


42


.




As shown in

FIG. 43

, the write pulse rises to the first magnitude at the first leading edge during the first pulse rise time of 100 ns, and rises to the sustaining voltage at the second leading edge during the second pulse rise time of 100 ns equal to the first pulse rise time.




That is, as shown in

FIG. 43

, when the first and second leading edges are formed by the switches S


1


and S


2


, respectively, and the pulse is risen to the sustaining voltage by the switch S


3


, the power consumption and rush current can be further reduced as compared to the pulse shown in FIG.


41


. The pulse shown in

FIG. 43

can be easily obtained by the pulse generation circuit shown in

FIG. 42

under the conditions:








L




1


=


L




2


,


V




2


=2


V




1









FIG. 44

is a timing chart showing a write sequence capable of shortening the rise time by using the pulse generation circuit shown in FIG.


41


.




As shown in

FIG. 44

, the write pulse rises to the first magnitude at the first leading edge during the first pulse rise time of 115 ns and rises to the sustaining voltage at the second leading edge during the second pulse rise time of 100 ns shorter than the first pulse rise time.




That is, as shown in

FIG. 44

, when the first and second leading edges are formed by the switches S


1


and S


2


, respectively, and the write pulse is risen to the sustaining voltage by the switch S


3


, the write pulse can rise to the sustaining voltage in a shorter time as compared to the pulse shown in FIG.


41


. The pulse shown in

FIG. 44

can be easily obtained by the pulse generation circuit shown in

FIG. 42

under the conditions:






¾


L




1


=


L




2


,


V




2


=2


V




1








With this arrangement, the luminous efficiency is improved.





FIG. 45

is a timing chart for explaining a write pulse most suitable for the coplanar discharge type display apparatus shown in FIG.


25


and an erase pulse for erasing a displayed image.




As shown in

FIG. 45

, as the characteristic feature of this write sequence, a positive (write) pulse is applied to the address electrode as the write pulse, and a positive sustaining pulse is sequentially applied to the first and second electrodes for a predetermined time to display an image. While the sustaining pulse is applied to the first and second electrodes, a bias voltage with a predetermined magnitude, e.g., a magnitude of 5% to 45% and, preferably, 20% that of the sustaining pulse is applied to the address electrode.




More specifically, in the display apparatus having display electrodes on the front substrate, since potential differences are generated between the first electrode and address electrode and between the second electrode and address electrode during sustaining discharge between the two electrodes, wall charges are transferred to result in a loss that does not contribute to display. When a bias voltage is applied to the address electrode to suppress charge transfer between the first and second electrodes and address electrode, the loss is decreased, and luminous efficiency is improved.





FIG. 46

is a schematic sectional view showing an embodiment different from all the above-described PDPs.




As shown in

FIG. 46

, in a PDP


1301


, display electrodes


1313


extending in the X-axis direction, a dielectric layer


1315


covering the display electrodes


1311


and a front substrate


1311


, and a UV reflection layer


1319


and a dielectric layer


817


which cover dielectric layer


815


are formed on the surface of the front substrate


811


on the opposite side of a display surface


811




a.


(The front substrate


1311


has substantially the same structure as that of the above-described matrix discharge type PDP (

FIGS. 2A

,


22


, or


25


)).




A light-emitting substrate


1331


has a first and a second glass plate


1351


and


1355


.




Counter electrodes


1333


(R, G, and B) extending in a direction (Y-axis direction) perpendicular to the display electrodes


1313


are formed on the surface of the second glass plate


1355


opposing the front substrate


1311


at a pitch defined on the basis of the resolution required of the PDP


1301


. The counter electrode


1333


has a structure similar to that of the counter electrode


33


used for the PDP


1


shown in

FIGS. 1

,


2


A, and


2


B.




A dielectric layer


1335


is formed on the entire surface of the second glass plate


1355


.




On the dielectric layer


1335


, protective film


1357


for protecting the counter electrodes


1333


from ions generated by a plasma discharge are formed on the dielectric layer


1335


.




On the surface of the entire surface of the protective film


1357


, a plurality of ribs


1337


are formed at a predetermined interval to be parallel to the counter electrodes


1333


.




Each of ribs


1337


forms a discharge space


1339


(R, G and B) with the adjacent rib


37


.




Phosphor layers


1341


(R, G and B) are formed of the outer surface of the second glass plate


1355


.




Each of the phosphor layers


1341


are covered with a visible light reflection layer


1353


and sandwiched between the first glass plate


1351


and the second glass plate


1355


.




According to this arrangement, since the phosphor layers


1341


(R, G and B) are separated from the discharge plasma, to prevent the phosphor layer


1341


is damaged.





FIG. 47

is schematic sectional views showing a modification of the PDP shown in FIG.


30


.




As shown in

FIG. 47

, in a PDP


1401


, display electrodes


1413


extending in the X-axis direction (first direction) on the surface of a front substrate


1411


on the opposite side of a display surface


1411




a,


a dielectric layer


1415


covering the display electrodes


1413


and front substrate


1411


, a UV reflection layer


1419


covering the dielectric layer


1415


, and a protective film (not shown, see

FIG. 2A

) are formed in a predetermined order.




On the surface of the dielectric layer


1415


, a plurality of ribs


1437


are formed at a predetermined interval perpendicular to the display electrodes


1413


.




A counter substrate


1431


has substantially the same structure as that of the above-mentioned PDP


1301


(FIG.


46


), with out the structure of the ribs


1437


.




According to the structure, the arrangement of the ribs


1437


are easily formed.




As has been described above, in the plasma display panel of the present invention, a UV reflection film for reflecting UV rays generated in the plasma discharge toward a phosphor on the counter substrate is formed on the substrate on the display surface side, i.e., the front substrate, the partial pressure of Xe in the discharge gas is set within the range of 15% to 70%, and the average grain size of phosphor in each discharge space is made small. With this arrangement, discharge using a low discharge start voltage can be realized.




When the phosphor layer formed in each discharge space on the electrode of the counter substrate is partially removed, or the thickness of the phosphor layer in a specific region in the discharge space is made smaller than a predetermined thickness, the discharge start voltage can be lowered.




When auxiliary electrodes are formed on the front substrate or counter substrate, the discharge start voltage required for initialization of the discharge space, a write (formation of a wall field), discharge sustaining, and erasure can be set to be low.




Since a reflection layer having a thickness according to the light emission characteristics of each phosphor layer is formed in the discharge space for emitting light corresponding to a color component, the level of image brightness can be prevented from changing in units of colors.




Since the phosphor layer in each discharge space for emitting light corresponding to a color component has a specific thickness in accordance with its type to correct the light emission characteristics which change in units of phosphor types, the level of image brightness can be prevented from changing in units of colors.




The write pulse or sustaining pulse has a staircase waveform with which the voltage increases in two steps. Since the pulse has the first leading edge, first sustaining portion, second leading edge, second sustaining portion, and trailing edge, the magnitude of a rush current due to the electrostatic capacitance between the substrates is decreased. Hence, the power consumption is reduced.




Since the inner wall of each discharge space is covered with a visible light reflection layer, and the phosphor layers and display electrodes are protected by a dielectric protective film, the luminous efficiency can be prevented from lowering in a short period.




As a consequence, a PDP in which the luminous efficiency is high although the power consumption is low, the difference in image brightness between color components is small, and the luminous efficiency does not lower in a short period can be obtained.




Therefore, a plasma discharge type flat display apparatus having high luminous efficiency and screen luminance, low power consumption, uniform display image brightness, and long service life can be provided.




As has been described above, according to the present invention, there is provided a discharge type flat display apparatus comprising:




a display substrate having a display surface to pass light and output the light from the display surface;




a rear substrate opposing the display substrate via a discharge gas to generate light in correspondence with discharge between the rear substrate and display surface;




a display electrode arranged at a predetermined position on the display substrate or rear substrate to supply an electric field for discharge;




a counter electrode arranged at a predetermined position on the display substrate or rear substrate to supply an electric field for discharge in cooperation with the display electrode; and




an auxiliary electrode arranged at a predetermined position on the display substrate or rear substrate to supply an electric field for discharge in cooperation with the display electrode and counter electrode.




According to the present invention, there is also provided a discharge type flat display apparatus in which a gas mixture for UV discharge, which is prepared by mixing a main discharge gas and a discharge control gas such that the partial pressure of the main discharge gas becomes 15% or more, is injected into a space between a display substrate and a counter substrate, which oppose each other, at a predetermined pressure, and a plurality of first electrodes capable of specifying a position in the first direction on the substrate, a plurality of second electrodes capable of specifying a position in the second direction perpendicular to the first direction, and third electrodes equal in number to the first or second electrodes are arranged on at least one of the substrates at a predetermined interval,




wherein the apparatus provides a memory function of controlling to enable/disable discharge by a sustaining pulse using charges stored in a dielectric layer for isolating the electrodes from the gas mixture for discharge.




According to the present invention, there is also provided a discharge type flat display apparatus in which a UV discharge gas prepared by mixing a main discharge gas and a discharge control gas such that the partial pressure of the main discharge gas becomes 15% or more is injected into a space between a display substrate and a counter substrate, which oppose each other, at a predetermined pressure, and a plurality of first electrodes capable of specifying a position in the first direction on the substrate, a plurality of second electrodes capable of specifying a position in the second direction perpendicular to the first direction, and third electrodes equal in number to the first or second electrodes are arranged on at least one of the substrates at a predetermined interval, comprising:




a field enhancement structure for increasing the effect of an electric field in the discharge gas.




According to the present invention, there is also provided a discharge type flat display apparatus comprising:




a display substrate having a display surface to pass light and output the light from the display surface;




a rear substrate opposing the display substrate via a discharge gas to generate light in correspondence with discharge between the rear substrate and display surface;




a display electrode arranged at a predetermined position on the display substrate or rear substrate to supply an electric field for discharge;




a counter electrode arranged at a predetermined position on the display substrate or rear substrate to supply an electric field for discharge in cooperation with the display electrode;




an auxiliary electrode arranged at a predetermined position on the display substrate or rear substrate to supply an electric field for discharge in cooperation with the display electrode and counter electrode; and




a dielectric layer formed on each of the display substrate and the rear substrate to isolate the electrodes from the discharge gas,




wherein the width of the display electrode in the direction of plane of the display substrate and the width of the counter electrode in the direction of plane of the rear substrate are equal to or smaller than the thicknesses of the dielectric layers on the substrates, respectively.




According to the present invention, there is also provided a discharge type flat display apparatus which has a plurality of discharge generation portions arrayed in a matrix and having a memory function associated with a discharge enable or disable state and can control initialization of the discharge generation portions, a write in a memory, and discharge sustaining and memory erase operations on the basis of a voltage application sequence formed by an arbitrary combination of a write pulse, a sustaining pulse, and an erase pulse,




wherein the arbitrary voltage application sequence including at least the erase pulse allows to omit initialization operation with full lightening and perform the write in memory, discharge sustaining and memory erase operations.




According to the present invention, there is also provided a discharge type flat display apparatus which has a plurality of discharge generation portions arrayed in a matrix and having a memory function associated with a discharge enable or disable state and can control initialization of the discharge generation portions, a write in a memory, and discharge sustaining and memory erase operations on the basis of a voltage application sequence formed by an arbitrary combination of a write pulse, a sustaining pulse, and an erase pulse,




wherein the write pulse or sustaining pulse has a staircase waveform with which the voltage increases in two steps, and comprises a first leading edge, a first sustaining portion, a second leading edge, a second sustaining portion, and a trailing edge.




According to the present invention, there is also provided a discharge type flat display apparatus which has a plurality of discharge generation portions arrayed in a matrix and having a memory function associated with a discharge enable or disable state and can control initialization of the discharge generation portions, a write in a memory, and discharge sustaining and memory erase operations on the basis of a voltage application sequence formed by an arbitrary combination of a write pulse, a sustaining pulse, and an erase pulse,




wherein each of the write pulse, erase pulse, and sustaining pulse has a rectangular waveform comprising a leading edge, a sustaining portion, and a trailing edge,




the leading edge is formed from an oscillation waveform output from an LCR circuit,




the LCR circuit comprising:




the inductance of the circuit or an additive inductance element L;




the electrostatic capacitance between the display substrate and counter substrate or an electrostatic capacitance element C; and




the resistance of the circuit or an additive resistance element R, and




the sustaining portion is formed by switching operation having a period shorter than ½ the period of the oscillation waveform output from the LCR circuit, and a fraction of a power supply voltage determined by the time constant of the resistance of the circuit or the additive resistance element R and the electrostatic capacitance component C.




According to the present invention, there is also provided a discharge type flat display apparatus which has a plurality of discharge generation portions arrayed in a matrix and having a memory function associated with a discharge enable or disable state and can control initialization of the discharge generation portions, a write in a memory, and discharge sustaining and memory erase operations on the basis of a voltage application sequence formed by an arbitrary combination of a write pulse, a sustaining pulse, and an erase pulse,




wherein the apparatus comprises first and second electrodes mainly used to display an image, third electrodes formed independently of the first and second electrodes, and address electrodes formed independently of the first, second, and third electrodes, and initialization operation is performed between the third electrodes and first or second electrodes or address electrodes.




Additional advantages and modifications will readily occur to those skilled in the art. Therefore, the invention in its broader aspects is not limited to the specific details and representative embodiments shown and described herein. Accordingly, various modifications may be made without departing from the spirit or scope of the general inventive concept as defined by the appended claims and their equivalents.



Claims
  • 1. A flat type display apparatus using a plasma discharge, comprising:a first substrate capable of passing visible light; a second substrate opposed to said first substrate at a predetermined gap; a discharge gas formed of Xe excluding a halogen sealed in said gap; excitation means for exciting the discharge gas to generate UV rays, the excitation means including a first electrode arranged on a side of said first substrate opposing said second substrate, and a second electrode arranged on a side of said second substrate opposing said first substrate; and photoconversion means, including a phosphor layer formed on the second electrode, for emitting predetermined visible light on the basis of the UV rays, said phosphor layer including a first region emitting a red component of the visible light, a second region emitting a blue component of the visible light, and a third region emitting a green component of the visible light and wherein the thickness of the first, second and third regions are different, wherein the discharge gas is caused by said excitation means to perform excimer light emission for generating UV rays.
  • 2. An apparatus according to claim 1, wherein the discharge gas contains a main discharge gas and a discharge control gas for controlling discharge, and an amount of the main discharge gas is set to be not less than 15%.
  • 3. An apparatus according to claim 2, whereinthe main discharge gas contains Xe, and the discharge control gas contains at least one of Ne and He.
  • 4. An apparatus according to claim 3, whereina wavelength of excimer light emission by the discharge gas is about 172 nm.
  • 5. An apparatus according to claim 1, whereina visible light reflection film for reflecting the visible light is inserted between said second substrate and said phosphor layer.
  • 6. An apparatus according to claim 1, whereinsaid first substrate comprises a UV reflection film for passing the visible light and reflecting the UV rays.
  • 7. An apparatus according to claim 1, whereinsaid excitation means comprises an address electrode and a pair of discharge electrodes, which are arranged on inner major surfaces of said first and second substrates, respectively, to oppose each other.
  • 8. An apparatus according to claim 1, further comprisinga plurality of barriers formed on an inner major surface of at least one of said first and second substrates to form an excitation space for exciting the discharge gas.
  • 9. An apparatus according to claim 8, whereina black portion is formed in a region of the barrier opposing said first substrate.
  • 10. An apparatus according to claim 8, whereina black filter is formed in a region of said first substrate corresponding to the barrier.
  • 11. An apparatus according to claim 1, wherein letting d be the gap between said first and second substrates, and P be the pressure of the discharge gas,P·d≧7.5 (torr.cm) is satisfied.
Priority Claims (2)
Number Date Country Kind
10-085686 Mar 1998 JP
10-087068 Mar 1998 JP
US Referenced Citations (7)
Number Name Date Kind
4549109 Nighan et al. Oct 1985 A
4692662 Wada et al. Sep 1987 A
4703229 Nighan et al. Oct 1987 A
5661500 Shinoda et al. Aug 1997 A
5900694 Matsuzaki et al. May 1999 A
5932967 Chikazawa Aug 1999 A
5939826 Ohsawa et al. Aug 1999 A
Foreign Referenced Citations (4)
Number Date Country
62-157643 Jul 1987 JP
6-325697 Nov 1994 JP
8-293262 Nov 1996 JP
9-120776 May 1997 JP