JP2005301133A - Planar image display device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a large-scale planar image display device capable of displaying a configuration. <P>SOLUTION: In the planar image display device 101 in which a plurality of unit planar display elements are arranged, as to the unit planar display element 102A, at least part of the cells constituting the outermost peripheral pixels 104A is smaller in size compared with internal pixels 106, and a pitch P2 of the pixels in the outermost peripheral part on the basis of the external peripheral face of the unit planar display element is equal to a pixel pitch P1 of the internal pixels except the pixels in the outermost peripheral part. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a flat image display device in which a plurality of unit flat display elements such as unit plasma display elements are arranged to form a large display screen, and in particular, a large flat display capable of high-definition display. The present invention relates to an image display device.

As a means for displaying images such as televisions and computers, flat image display devices such as liquid crystal display devices, plasma display devices, field emission display devices, and electroluminescence display devices have been proposed instead of CRT display devices.
These display devices are characterized in that they are thinner and lighter and consume less power than the CRT type, and are being used instead of CRT display devices.
Although the flat type image display device is being increased in size, the increase in the size of the display screen requires a large-area member and various large-sized manufacturing apparatuses capable of manufacturing the same. There was a limit to the increase in size.

  In view of this, there has been proposed a large flat image display device in which a plurality of unit display elements are arranged in parallel, and an electric signal obtained by dividing an image is sent to each unit display device to display a large image as a whole. . As a large-sized flat image display device in which a large number of unit display elements are arranged, a device using a CRT or a projection type unit display device is used. An image is displayed between each unit display device. There is a problem that a region that is not displayed or a region where the image is discontinuous is generated, resulting in an unnatural image and lowering the display quality. In addition, when a CRT or a projection type display device is used as a unit display element, although it is a large display device, the thickness is large even when compared with the area, and there is a problem as a flat type image display device.

  The flat image display device is generally characterized in that the width of the peripheral portion of the display device is smaller than that of the CRT. However, by simply arranging the flat image display device to form a large flat image display device, it is not possible to eliminate a region where no image is displayed between the display devices. Therefore, various methods for arranging a plurality of display devices have been proposed. By gathering power supply terminals such as signals indispensable for the image display device at one end and arranging the other end side to face each other, the non-display area at the boundary between the unit display devices is reduced. A technique has been proposed (see, for example, Patent Document 1).

  However, even in such a display device, it is necessary to provide a terminal portion on at least one side. Therefore, the unit display element cannot be disposed in contact with the portion where the terminal portion is formed, and thus a large display device in which a large number of unit display elements are arranged vertically and horizontally cannot be formed.

In order to solve these problems, when a large number of unit flat display elements are arranged, the structure of the peripheral part of the unit flat display elements has a feature in order to make the joints between the unit flat display elements inconspicuous. A flat-type image display device has been proposed.
However, in the unit planar element that is the object of the present invention, the width of the non-display portion in the peripheral portion affects the interval between display pixels on the display surface. A large flat-type image display device cannot be formed by forming a sealing portion having a width of about 5 mm to 10 mm in the peripheral portion and joining the front plate and the rear plate to keep the inner space airtight and strength. The sealing part formed in the peripheral part of the unit display element constituting the sapphire cannot be made as wide as the conventional 40 type plasma display device.

  Therefore, the unit flat display element constituting the conventional large flat display device has a pixel pitch of about 3 mm. When a 100-type unit flat display device is manufactured using unit flat display elements having such pixels, a 480 × 640 VGA class display is obtained. The VGA display in the 100 type belongs to the highest definition of the current large-sized flat-type image display devices, but early on due to the trend toward higher definition, such as an increase in high-definition image content and higher definition of personal computer display. , High definition of 768 × 1024 XGA class is desired.

In the unit flat display element having a pixel pitch of about 3 mm, the display pixel interval is arranged at about 1 mm. Therefore, in order to prevent the boundary between adjacent unit flat display elements from affecting the display quality of the image, The size of the non-display portion at the periphery of the unit flat display element needs to be at least about ½ of the display pixel interval.
On the other hand, a width of at least 0.5 mm to 1.0 mm is required to maintain the sealing strength at the periphery of the unit flat display element that is sealed or bonded around the front and back glass plates. Was necessary.

Accordingly, it is extremely difficult to manufacture a unit flat display element having a pitch of 2 mm and capable of XGA class high-definition display in the 100 type while maintaining a practical strength in the peripheral sealing portion of the unit flat display element. It was thought to be.
JP-A-6-314066

  The present invention provides a large-sized flat image display device configured by arranging unit flat display elements and capable of XGA-class high-definition display even for a large image display of about 100 inches. An object of the present invention is to provide a flat-type image display device with good image display quality between unit flat display elements arranged adjacent to each other.

An object of the present invention is to provide a flat-type image display device in which a plurality of unit flat display elements are arranged, wherein the unit flat display element has at least some of the cells constituting the outermost peripheral pixel as compared with the cells of the internal pixels. The pixel pitch of the outermost peripheral portion with respect to the outer peripheral surface of the unit flat display element is small and can be solved by a flat-type image display device having the same pixel pitch as the internal pixels excluding the outermost peripheral pixel.
Each pixel of the unit flat display element is composed of cells that are long in the vertical direction, and the left and right outermost peripheral pixels are the size b of one cell in the horizontal direction of cells of three colors R, G, and B. Is smaller than the width a of other cells in the outermost peripheral part and the inner pixel, the distance d between the outermost peripheral part pixel and the outer peripheral surface of the unit flat display element, and the distance 2c between the outermost peripheral part pixel and the inner pixel. And the vertical length f of the upper and lower outermost peripheral pixels, the vertical length g of other pixels, and the uppermost or lowest pixel are adjacent to each other. In the flat image display device described above, there is a relationship of c + g = d + f between the vertical distance 2c from the pixel.

In addition, each pixel of the unit flat display element is composed of cells that are long in the vertical direction, and the left and right outermost peripheral pixels are the width b1 of two cells in the horizontal direction of the three color cells of R, G, and B, b2 is smaller than the width a of the other cells, and the distance d between the outermost peripheral pixel and the outer peripheral surface of the unit flat display element and the distance 2c between the outermost peripheral pixel and the inner pixel are 2a + c = b1 + b2 + d The vertical length f of the uppermost or lowest pixel of the outermost peripheral pixel, the vertical length g of the other pixels, the uppermost or lowest pixel of the vertical direction The flat-type image display device has a relationship of c + g = d + f between the adjacent pixel and the interval 2c between adjacent pixels.
Pixels that are long in the vertical direction at the left and right outermost peripheral parts are three cell sizes b1, b2, and b3 in the horizontal direction of cells of three colors R, G, and B. There is a relationship of 3a + c = b1 + b2 + b3 + d between the distance d between the outermost peripheral pixel and the outer peripheral surface of the unit flat display element, and the distance 2c between the outermost peripheral pixel and the inner pixel. C + g between the vertical length f of the outermost peripheral pixel, the vertical length g of the other pixels, and the vertical interval 2c between the uppermost or lowest pixel and the adjacent pixel. The flat-type image display device has a relationship of d = f.

Further, the brightness of the outermost peripheral pixel cell is the flat image display device described above, which is set to be the same as or higher than the cell brightness of the same color of the internal pixel.
The cell in the pixel of the unit flat display element is the flat image display device in which the color having the lowest luminous efficiency is arranged as the widest cell of the outermost peripheral pixel.
The flat-type image display device according to the above, wherein the color array of the cells in the pixel of the unit flat display element has a cell having the least efficient color arranged at the center of the pixel, and the central cell has the largest dimension in the outermost peripheral pixel. It is.
The cells in the pixel of the unit flat display element are the flat image display devices arranged in the order of R, B, and G.

  In the image display method of a flat-type image display device in which a plurality of unit flat display elements are arranged, the unit flat display element includes at least some of the cells constituting the outermost peripheral pixel, other cells of the outermost peripheral part, and cells of the inner pixel The distance between the outermost peripheral pixel and the adjacent pixel from the outer peripheral surface of the unit flat display element is equal to the pixel pitch of the internal pixels excluding the outermost peripheral pixel. An adjustment method for a flat-type image display device in which the luminance adjustment signal of the outer peripheral pixel is made larger than that of the inner pixel, and the luminance of the outermost peripheral cell of the same color and the luminance of the inner pixel cell are adjusted to be the same or higher. is there.

  In the flat image display device in which a plurality of unit flat display elements according to the present invention are arranged, the size of the outermost peripheral pixel of the unit flat display element constituting the flat image display device is made smaller than that of the internal pixels. By ensuring the distance from the outermost peripheral pixel and the outer peripheral surface of the unit flat display element to a length that can maintain the strength of the sealing portion between the front plate and the rear plate of the unit flat display element, the unit flat display Since the distance from the outer peripheral surface of the element to the middle between the outermost peripheral pixel and its internal pixel can be made equal to the internal pixel pitch, even if the pixel pitch is reduced, it has the same size as that having a large pixel pitch. It becomes possible to form a sealing part, and sufficient sealing performance is obtained.

  The flat image display device according to the present invention includes a plurality of unit flat display elements, and the unit flat display element is reduced by reducing the size of at least some of the cells forming the outermost peripheral pixels. In addition, the outer periphery of the front plate and the back plate that are sealed with a sealing portion that has high strength and does not impair hermetic sealing performance, has a small pixel pitch and is capable of high-definition display. The present inventors have found that it is possible to provide a flat image display device having excellent display quality between adjacent unit flat surface elements.

That is, when a unit flat display element capable of high-definition display with a small pixel pitch is manufactured as the unit flat display element, the size of the sealing portion at the outer peripheral portion of the front plate and the back plate of the unit flat display device As a result, the strength was insufficient and the production was practically impossible.
On the other hand, when the outer peripheral sealing portion is enlarged, the pixel pitch at the outer peripheral pixel of the inner pixel whose interval is reduced for high-definition display becomes uneven and the display quality deteriorates. The size of the cell constituting the pixel is reduced, the outer peripheral pixel is made smaller, and the outer peripheral pixel is made smaller by enlarging the sealing part between the front plate and the rear plate. is there.

  In addition, if the size of the cells constituting the outer peripheral pixels is reduced, the reduced cells emit light or have low luminance. Therefore, the voltage, current, number of pulses, and pulse width supplied to each pixel of the unit flat display element are reduced. Etc. are adjusted by emitting light so that a pixel including a small cell is recognized in the same manner as other pixels.

The present invention will be described below with reference to the drawings.
FIG. 1 is a diagram for explaining an embodiment of a flat image display device according to the present invention. FIG. 1 (A) shows the entire flat image display device, and FIG. 1 (B) shows adjacent units. The flat display element is shown partially at different scales.
A flat image display device 101 according to the present invention has a predetermined number of unit flat display elements 102 arranged adjacent to each other. FIG. 1 shows an example in which six unit flat display elements 102 are arranged and arranged in the horizontal direction and four in the vertical direction.
As shown in FIG. 1A, the unit flat display element 102A and the unit flat display element 102B are arranged with their end faces 103 in close contact with each other.
The right outermost peripheral pixel 104A, the left outermost peripheral pixel 104B, the upper and lower outermost peripheral pixels 105 positioned above and below the unit flat display element, and the left and right outermost peripheral pixels. It consists of internal pixels 106 excluding the outermost peripheral pixels. Each pixel is composed of vertically long pixels, and is composed of cells of three colors, a red (R) cell 110, a blue (B) cell 111, and a green (G) cell 112, from the left.

In the outermost peripheral pixel 104A on the right side of the unit flat display element 102A, the red cell 110 and the blue cell have the same width a as the internal cell, and only the green cell 112 located at the outermost periphery is more than a. It has a small width b. Each cell is arranged with a pixel interval e.
Further, as shown in the unit flat display element 102B, in the outermost peripheral pixel 104B on the left side, the red cell 110 located on the outermost periphery is based on the cell a of the other outermost peripheral part and the cell a of the internal pixel. Also, the width b is a small width, and the blue cell and the green cell have the width a similarly to the width of the internal pixel.

Although the arrangement of the three color cells constituting each pixel can be arbitrarily performed, in a display device that emits a phosphor such as a plasma display, an area of 9000K to 10000K which is the same color temperature as the CRT. Setting to be done. Under such conditions, a commonly used blue phosphor has lower luminous efficiency than a red or green phosphor. Therefore, when blue phosphors are arranged on the left and right outermost peripheral parts and the width of the cell is reduced, the luminance of a cell having a small area and low luminous efficiency is greatly reduced as compared with the luminance of other pixels. Therefore, when adjusting the light emission of a cell with a small width by adjusting the electric energy supplied to the cell in the same way as the others, the energy input for light emission becomes excessive, making it difficult to adjust sufficiently. There was a problem that the quality of the image was lowered.
Therefore, it is preferable to arrange a cell with low light emission efficiency in the center of the pixel so that the width is not reduced, and it is preferable to arrange a blue cell with low light emission efficiency in the cell at the center of the pixel.

Further, the interval between the left and right outermost peripheral pixels and the internal pixels and the interval between the respective internal pixels are all 2c, and are represented by the pixel pitch P1 in the horizontal direction of the pixels at the left and right outermost peripheral portions. Further, the horizontal pixel pitch P2 of the left and right outermost peripheral pixels represented by the distance from the lateral end face of the unit flat display element to the middle point of the interval between the outermost peripheral pixel and the internal pixel, and the cell width a , B, the pixel interval 2c, and the distance d between the end portion of the unit flat display element of the left and right outermost peripheral pixels and the end face of the unit flat display element,
P1 = 3a + 2c
P2 = 2a + b + c + d where a> b
In addition, since the pixel pitch is made equal throughout the flat image display device, the relationship of P1 = P2 is established.
From these relationships, a relationship of a + c = b + d d> c is obtained.

  As a result, in the conventional unit flat display element, in the unit flat display element of the present invention, the width d of the sealing portion of the end face is the same as c which is ½ of the pixel interval of the internal pixels. Can be made larger than that, and airtightness and strength can be sufficiently maintained at the sealing portion.

On the other hand, in the upper and lower outermost peripheral pixels, all the cells have the vertical length f, the vertical lengths g of all the other pixels, and a relationship of g> f.
The vertical spacing between the upper and lower outermost peripheral pixels and the internal pixels and the vertical spacing between the inner pixels are all 2c, and the vertical pixel pitch P3 of the pixels excluding the upper and lower outermost peripheral pixels is a unit. The vertical pixel pitch P4 of the upper and lower outermost peripheral pixels, which is the distance from the upper and lower end faces of the flat display element to the intermediate point between the upper and lower outermost peripheral pixels and the internal pixels, and the vertical lengths f and g of the pixels, Between the distance d between the end of the unit flat display element of the upper and lower peripheral pixels and the end face of the unit flat display element,
P3 = g + 2c
P4 = f + c + d where g> f
Since the pixel pitch is made equal throughout the entire flat image display device, P3 = P4

  From these relationships, the relationship g + c = f + d is obtained, and g> f. Therefore, in the conventional unit flat display element, the upper and lower width d of the sealing portion of the end face is 1/2 of the pixel interval of the internal pixels. However, in the unit flat display element of the present invention, it is possible to make it larger than that, and it is possible to maintain sufficient airtightness and strength at the sealing portion. It becomes possible to do.

For example, in order to realize XGA-class high-definition display in the 100 type, the following values can be given when pixels are formed at a pitch of 2 mm.
P = 2.02mm, a = 0.38mm, b = 0.27mm
The ratio of a to b is b / a = 0.71
c = 0.35mm, d = 0.46mm, e = 0.09mm
f = 1.21mm, g = 1.32mm
The ratio of f to g is f / g = 0.92

  In the above description, the example in which the width b of the cell located at the outermost peripheral portion of the outermost peripheral pixels is made smaller than the width a of the other cells has been described. It does not have to be located in any cell, and any cell may be used. If the light emission efficiency of the cells is different, reducing the width of the cell with high light emission efficiency will reduce the load when adjusting the voltage, current, number of pulses, pulse width, etc. This is preferable.

In any pixel, it is preferable in terms of control and the like that the arrangement order of the three color cells of R, G, and B is the same, but the width and width of the cells constituting the left and right outermost peripheral pixels are the same. Other conditions such as the arrangement position of small cells can be arbitrary. For example, when B is arranged in the center in the order of RBG as follows, the arrangement of the widths a and b has the following forms.
Left outermost pixel Right outermost pixel
R B G R B G
a / a / b a / a / b
a / a / b b / a / a
b / a / a a / a / b

FIG. 2 is a diagram for explaining another embodiment of the flat-type image display device of the present invention, which partially shows adjacent unit flat display elements.
The unit flat display element 102A and the unit flat display element 102B are arranged with their end faces 103 in close contact with each other.
The right outermost peripheral pixel 104A, the left outermost peripheral pixel 104B, the upper and lower outermost peripheral pixels 105 positioned above and below the unit flat display element, and the left and right outermost peripheral pixels. It is composed of internal pixels 106 excluding the outermost peripheral pixels, and each pixel is composed of vertically long pixels, which are red (R) cell 110, blue (B) green cell 111, and green (G) cell 112. It is composed of cells of three colors, and each cell is arranged with an interval e.

The red cell 110 of the right outermost pixel 104A has the same width a as the inner cell, and the outermost green cell 112 has a width b1 smaller than a, The blue cell 111 has a width b2 that is smaller than a. However, in the case of a plasma display, the blue cell phosphor b has a lower light emission efficiency, so the blue cell width b2 is smaller than b1. It is preferable to increase the size. In addition, the pixels are arranged at intervals of the pixel interval e.
Further, the green cell 112 of the left outermost peripheral pixel 104B has the same width a as the internal cell, and the red cell 112 at the outermost peripheral portion has a width b1 smaller than a, The blue cell 111 has a width b2 which is smaller than a.

Further, the distance between the left and right outermost peripheral pixels and the internal pixels, and the distance between the internal pixels are all 2c, and has a pixel pitch P1 in the horizontal direction of the pixels at the left and right outermost peripheral parts. The pixel pitch P2 in the horizontal direction of the left and right outermost peripheral pixels, which is the distance from the lateral end face of the unit flat display element to the middle point of the interval between the outermost peripheral pixel and the internal pixel, and the cell widths a, b1, b2 , The pixel interval 2c, and the distance d between the end face of the unit flat display element of the left and right outermost peripheral pixels and the end face of the unit flat display element,
P1 = 3a + 2c
P2 = a + b1 + b2 + c + d where a> b1 a> b2
Since the pixel pitch is the same throughout the flat image display device, the relationship P1 = P2 is established.
From these relationships, 2a + c = b1 + b2 + d
Since 2a> b1 + b2, the relationship d> c is obtained.
As a result, in the conventional unit flat display element, in the unit flat display element of the present invention, the width d of the sealing portion of the end face is the same as c which is ½ of the pixel interval of the internal pixels. Can be made larger than that, and airtightness and strength can be sufficiently maintained at the sealing portion. The vertical size of the upper and lower outermost peripheral pixels is the same as that shown in FIG.

As shown in FIG. 2, when the widths of the two cells b1 and b2 are reduced in the left and right outermost peripheral pixels, b1 has the same size as b shown in FIG. In this case, in the example shown in FIG. 2, the width d of the peripheral portion can be made larger than the width shown in FIG.
In addition, since the pixel interval c can be reduced in a state where the size of d in FIG. 2 is kept equal to the size in FIG. 1, a flat-type image display device capable of high-definition display with higher efficiency is manufactured. can do.
Also, when b1 and b2 have the same size and d is set in the same way as in FIG. 1, it can be made larger than b1 in FIG. Is possible.
The size of the upper and lower outermost peripheral pixels is the same as that shown in FIG.

For example, in order to realize XGA-class high-definition display in the 100 type, the following values can be given when pixels are formed at a pitch of 2 mm.
P = 2.02mm, a = 0.38mm, b1 = b2 = 0.325mm
The ratio of a to b1, b2 is b1 / a = 0.86
c = 0.35mm, d = 0.46mm, e = 0.09mm
f = 1.21mm, g = 1.32mm
The ratio of f to g is f / g = 0.92
Thus, in order to obtain the same distance between the outermost peripheral pixel and the end face as in the example shown in FIG. 1 by reducing the size of two cells among the outermost peripheral pixels, the cell width Can be realized by setting the ratio of decreasing 0.71 to 0.86, it is possible to reduce the luminance reduction rate in a cell with a reduced cell width.

In the above description, an example has been described in which the width b1 and b2 of the outermost cell and the two cells adjacent to the outermost pixel are smaller than the width a of the other cells. It is not essential that the cell having a large is in the position shown in FIG.
In addition, when the luminous efficiency of the cells is different, reducing the width of the cell having a large luminous efficiency reduces the load when adjusting the brightness by adjusting the voltage, current, number of pulses, pulse width, etc. Since it becomes a thing, it is preferable.

In any pixel, it is preferable in terms of control and the like that the arrangement order of the three color cells of R, G, and B is the same, but the width and width of the cells constituting the left and right outermost peripheral pixels are the same. Other conditions such as the magnitude relationship of can be arbitrary.
For example, even when B is arranged in the center in the following order of RBG, the arrangement of the widths a, b1, and b2 has the following forms.
Left outermost pixel Right outermost pixel
R B G R B G
b1 / a / b2 b1 / a / b2
b1 / a / b2 b2 / a / b1
b2 / a / b1 b2 / a / b1
b2 / a / b1 b1 / a / b2

FIG. 3 is a diagram for explaining another embodiment of the flat-type image display device of the present invention, which partially shows adjacent unit flat display elements.
The unit flat display element 102A and the unit flat display element 102B are arranged with their end faces 103 in close contact with each other.
The right outermost peripheral pixel 104A, the left outermost peripheral pixel 104B, the upper and lower outermost peripheral pixels 105 positioned above and below the unit flat display element, and the left and right outermost peripheral pixels. The pixel is composed of internal pixels 106 excluding the outermost peripheral pixel, and each pixel is composed of a vertically long pixel, and is a three-color cell including a red (R) cell 110, a blue (B) cell 111, and a green (G) cell 112. It is composed of

  All the pixels except the right and left outermost peripheral pixels 104A and 104B have a width a, and all the cells constituting the left and right outermost peripheral pixels 104A and 104B have a left and right width compared to the cells of the other pixels. It is a small thing. That is, in the right outermost pixel, the green cell 112 has a width b1 smaller than a, the blue cell 111 has a width b2 smaller than a, and the red cell 110 has a width smaller than a. It has a small width b3. In the left outermost pixel, the red cell 110 has a width b1 smaller than a, the blue cell 111 has a width b2 smaller than a, and the green cell 112 has a width smaller than a. Has a small width b3. Each cell is arranged with an interval of a pixel interval e.

Further, the distance between the left and right outermost peripheral pixels and the internal pixels, and the distance between the internal pixels are all 2c, and has a pixel pitch P1 in the horizontal direction of the pixels at the left and right outermost peripheral parts. The pixel pitch P2 in the horizontal direction of the left and right outermost peripheral pixels, which is the distance from the lateral end face of the unit flat display element to the middle point of the interval between the outermost peripheral pixel and the internal pixel, and the cell widths a, b1, b2 , B3, the pixel interval 2c, and the distance d between the end portion of the unit flat display element of the right and left outermost peripheral pixel and the end surface of the unit flat display element,
P1 = 3a + 2c
P2 = b1 + b2 + b3 + c + d
However, a> b1 a> b2 a> b3
Since the pixel pitch is equal throughout the flat image display device,
P1 = P2.
From these relationships, 3a + c = b1 + b2 + b3 + d
Since 3a> b1 + b2 + b3, the relationship d> c is obtained.

As a result, in the conventional unit flat display element, the width d of the sealing portion at the end face can be larger than c which is ½ of the pixel interval of the internal pixels. Even when it is made smaller than the above, it is possible to maintain sufficient airtightness and strength at the sealing portion.
In the case of a color plasma display, since the luminous efficiency of the blue phosphor used in the blue cell is smaller than that of other colors, the blue cell is arranged at the center and its width b2 is b1 and b3. It is preferable to make it larger.

In addition, when d having the same size as d in FIG. 1 is set, the cell width of the left and right outermost peripheral pixels is larger than that in FIG. Thus, a reduction in luminance due to a reduction in the cell width can be reduced.
Note that the sizes of the upper and lower outermost peripheral pixels are the same as those shown in FIG.

For example, in order to realize XGA-class high-definition display in the 100 type, the following values can be given when pixels are formed at a pitch of 2 mm.
P = 2.02 mm, b1 = b2 = b3 = 0.343 mm
The ratio of a to b1, b2, b3 is b1 / a = 0.91
c = 0.35mm, d = 0.46mm, e = 0.09mm
f = 1.21mm, g = 1.32mm
The ratio of f to g is f / g = 0.92

In this way, by reducing the size of all the cells of the outermost peripheral pixel, in order to obtain the same distance between the outermost peripheral pixel and the end face as in the example shown in FIG. Since the ratio of the ratio of 0.71 to 0.71 can be set to 0.91, it is possible to reduce the luminance reduction rate in a cell with a reduced cell width.
Alternatively, by reducing the cell width of the outermost peripheral pixel, the size of d can be made larger than that shown in FIG. 1, and a sealing portion with higher strength can be formed.

In the above description, the example in which the left and right outermost peripheral pixels are arranged with the widths b1, b2, and b3 in order from the cell closest to the end face has been described. However, the order of the widths is not necessarily limited to this order. Instead, the cells may be arranged in the order of different widths in the left and right final pixels.
In addition, when the luminous efficiency of the cells is different, reducing the width of the cell having a large luminous efficiency reduces the load when adjusting the brightness by adjusting the voltage, current, number of pulses, pulse width, etc. Since it becomes a thing, it is preferable.

In any pixel, it is preferable in terms of control and the like that the arrangement order of the three color cells of R, G, and B is the same, but the width and width of the cells constituting the left and right outermost peripheral pixels are the same. Other conditions such as the magnitude relationship of can be arbitrary. For example, as described below, even when B is arranged in the center in the order of RBG and the width b2 of the cell B is maximized, the arrangement of the widths b1, b2, and b3 has the following forms.
Left outermost pixel Right outermost pixel
R B G R B G
b3 / b2 / b1 b3 / b2 / b1
b3 / b2 / b1 b1 / b2 / b3
b1 / b2 / b3 b1 / b2 / b3
b1 / b2 / b3 b3 / b2 / b1

FIG. 4 is a diagram for explaining a unit flat display element structure of the flat image display device of the present invention. FIG. 4 (A) is a plan view of a part of the color plasma display, and FIG. 4A is a sectional view taken along line XX ′ in FIG. 4A, and FIG. 4C is a sectional view taken along line YY ′ in FIG.
The example shown in FIG. 4 is a diagram showing pixels located at the outermost peripheral portion at the upper left portion of the unit flat display element 102B shown in FIG.
A left outermost peripheral pixel 104B, an upper outermost peripheral pixel 105B, and an internal pixel 106 are shown. The pixels are composed of three color cells, a red (R) cell 110, a blue (B) 111, and a green (G) cell 112. .
As shown in FIG. 4B, the unit cell is displayed from the red cell 110 of the outermost peripheral pixel 104B by setting the width b of the red cell 110 of the left outermost peripheral pixel 104B to be smaller than the width a of other cells. The width d to the end face of the element can be larger than c which is 1/2 of 2c of the pixel interval, and the thickness of the sealing material 120 provided at the end can be made sufficient. Therefore, even when the pixel interval is reduced, the strength of the sealing portion of the unit flat display element can be made sufficient.

  Further, as shown in FIG. 4C, the length of the upper outermost peripheral pixel 105B is set to f, which is smaller than the length g of the inner pixel 106, and therefore, from the upper outermost peripheral pixel to the end surface of the unit flat display element. Can be made larger than the size of c, which is 1/2 of the pixel interval 2c, and the thickness of the sealing material 120 provided at the end can be made sufficient.

Next, a description will be given of a method of adjusting luminance non-uniformity that occurs when the cell width is reduced in the flat image display device of the present invention.
FIG. 5 is a diagram for explaining a method of adjusting the luminance of the flat-type image display device of the present invention.
A CCD camera formed on the display surface of the flat-type image display device 1, and each of a marker 7 and a display image 9 indicating the periphery of the display image are arranged at a predetermined distance from the display surface of the flat-type image display device Images are taken at the same magnification by the imaging means 11 such as. Imaging may be performed by analog imaging means without using digital imaging means such as a CCD camera, and a digital image may be formed by A / D conversion.
The pixel information is interpolated and rearranged based on the captured image information 13 and the image information indicating the size of the image determined by the image information by the marker 7, and according to the information of each pixel of the display image. An interpolated image is formed.
The reference luminance information is set from the interpolated arrangement image, and the difference from the reference luminance information is calculated by the luminance distribution correction coefficient processing circuit 15 and stored in the correction coefficient memory 17.

On the other hand, after the video input signal 19 is corrected by the γ correction circuit 21, the luminance signal of each pixel is corrected in the luminance correction arithmetic circuit 23 based on the correction coefficient for each pixel stored in the correction coefficient memory 17. The
Next, the luminance-corrected data is expanded in the video signal frame memory 25 and transmitted to the display data array conversion processing circuit 27 to be data corresponding to each unit flat display element 5.
Then, the data is transmitted from the display data transmission circuit 29 to the display control circuit 31 of the unit flat display elements 5-1 to 5 -n, and is driven from the display control circuit to the address drive circuit 33, the scan drive circuit 35, and the sustain drive circuit 37. A signal is transmitted and an image is displayed.
Each drive circuit is supplied with an address drive voltage Va, a sustain drive voltage Vs, a scan drive voltage Vw, and the like from a power supply 39 formed of a DC / DC converter.

In luminance correction, all pixels on the display screen can be corrected to be uniform. Focusing on the joint between the arranged unit flat display elements and evaluating the luminance value of the outermost peripheral pixel and the ease of visual recognition of the joint, the inconspicuous luminance value is the brightness value of the inner pixel Bn, the outermost peripheral pixel Let Bg be the luminance value of
1.1 ≧ Bg / Bn ≧ 1.0
Since it is recognized that it is better to correct so as to satisfy the above relationship, it is preferable to correct the correction coefficient in consideration of this point. This is considered that a non-display part slightly wider than the non-display part based on each non-display part d is formed between the adjacent unit flat display elements, which affects the visibility.
On the other hand, if Bg / Bn is larger than 1.1, the outermost peripheral portion is excessively corrected, and that portion is visually recognized as a bright line, which is not desirable.
The following examples illustrate the invention.

The unit flat display element has dimensions of 192 mm vertically and 256 mm horizontally, has a pixel configuration of 96 pixels vertically × 128 pixels horizontally, and has a pixel pitch of 2.02 mm vertically and horizontally.
By arranging eight unit flat display elements in the vertical and horizontal directions, a large-sized image display device equivalent to 100 type capable of XGA class display of 768 pixels in the vertical direction and 1024 pixels in the horizontal direction can be configured.
The width of one cell of the outermost peripheral cell is reduced so as to correspond to FIG. 1 of the unit flat display element.
The horizontal pixel pitch is
P1 = 3a + 2c + 2e
P2 = 2a + b + c + d + 2e
Where P1 = P2
The vertical pixel pitch is
P3 = 2c + g
P4 = c + d + f
Where P3 = P4

The following settings were made to satisfy the above relationship.
P = 2.02mm, a = 0.38mm, b = 0.27mm
c = 0.35mm, d = 0.46mm, e = 0.09mm
f = 1.21mm, g = 1.32mm
Inside the cell, a light emitting layer made of a phosphor is formed in the order of red, blue, and green from the left. It is advantageous for the luminance correction of the flat-type image display device that the blue portion having the lowest efficiency among the three colors is set at the center and does not become the left and right outermost peripheral portions of the unit flat display element.
Each light-emitting layer, the red phosphor _{(Y x · Gd 1-x} ) BO 3: Eu 3+, a blue phosphor BaMgAl ₁₀ O _17: Eu ^2+, green _phosphor, Zn ₂ SiO _4: formed using Mn A unit flat display element of a plasma display of an AC type three-electrode structure was manufactured by sealing a mixed gas of neon and xenon containing 7% by volume of xenon as a discharge gas at a pressure of 66.7 kPa.

Next, this unit flat display element was discharge-displayed on all pixels at a sustain voltage of 200 V and a frequency of 50 kHz, and the luminance characteristics of each pixel were measured, and stable display characteristics of 670 cd / m ² and 5140 K were obtained at the central pixel.
In particular, the luminance of the pixels shown in FIG. 6 is a pixel of the corners of the outer peripheral portion of the unit flat display device, 698cd / m ² in the pixel 1, 645cd / m ² in the pixel ^2, 587cd / m 2 in the pixel 3, With the pixel 4, 635 cd / m ² was obtained. The minimum luminance at the corner is about 84% of the luminance at the central portion, and the luminance can be sufficiently corrected when a plurality of unit flat display elements are arranged to form a large flat display device.
Thus, this unit flat display element can secure a sealing width that maintains a stable glass sealing strength as the non-display portion width of the outermost peripheral portion while forming a high-definition pixel capable of XGA display with a 100 type, A highly reliable high-definition unit flat display element can be obtained.

Eight unit vertical display elements composed of color plasma display elements each having a size of 192 mm in length and 256 mm in width and having a pixel configuration of 96 pixels × 128 pixels and manufactured in accordance with Example 1 are arranged in close contact with each other. A flat image display device corresponding to 100 type was produced.
The total number of pixels of the flat image display device is 768 pixels × 1024 pixels, and XGA pixel display is performed. Next, all pixels are turned on on this display surface to obtain an all-white display screen. When the luminance distribution is measured by the method shown in FIG. 5, it is positioned at the outermost peripheral pixel from the luminance distribution of R, B, and G single colors. For red and green, the minimum value of the luminance distribution was 77% of the maximum value, and the fluctuation was larger than 91% of blue. Uniformity correction was performed for each of R, B, and G based on this minimum luminance value. The luminance distribution of the obtained all-white display screen is a uniform screen within ± 3%, and in particular, a high-definition integrated screen capable of good XGA display with no luminance step between the unit flat display elements is obtained.

  In the flat image display device in which a plurality of unit flat display elements according to the present invention are arranged, the outermost peripheral pixels are reduced by reducing the size of the outermost peripheral pixels of the unit flat display elements compared to the internal pixels. The distance from the outer peripheral surface of the unit flat display element is secured to a length that can maintain the strength of the sealing portion between the front plate and the rear plate of the unit flat display element, and from the outer peripheral surface of the unit flat display element to the outermost periphery. Since the distance to the middle between a pixel and its internal pixel can be made equal to the internal pixel pitch, even if the pixel pitch is reduced, it is possible to form a sealing portion having the same size as that having a large pixel pitch. Since it becomes possible and sufficient sealing performance is obtained, a flat image display device capable of high-definition display can be provided.

FIG. 1 is a diagram for explaining an embodiment of the flat image display apparatus of the present invention. FIG. 2 is a diagram for explaining another embodiment of the flat image display apparatus of the present invention. FIG. 3 is a diagram for explaining another embodiment of the flat image display device of the present invention. FIG. 4 is a diagram for explaining a unit flat display element structure of the flat image display device of the present invention. FIG. 5 is a diagram for explaining a method of adjusting the luminance of the flat-type image display device of the present invention. FIG. 6 is a diagram illustrating a pixel of the unit flat display element of the embodiment.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Planar image display apparatus, 3 ... Plasma display element, 5,5-1, 5-n ... Unit plane display element, 7 ... Marker, 9 ... Display image, 11 ... Imaging means, 13 ... Captured image information, 15 ... Luminance distribution correction coefficient processing circuit, 17... Correction coefficient memory, 19... Video input signal, 21... Γ correction circuit, 23. , 29 ... Display data transmission circuit, 31 ... Display control circuit, 33 ... Address drive circuit, 35 ... Scan drive circuit, 37 ... Sustain drive circuit, 39 ... Power supply, 41 ... Display pixel, 42 ... Moving imaging means 101 ... Planar type Image display device, 102, 102A, 102B ... unit flat display element, 103 ... end face, 104 ... left and right outermost peripheral pixel, 104A ... right outermost peripheral pixel, 104B ... left outermost peripheral image , 105,105B ... vertical outermost pixel, 106 ... interior pixels, 110 ... red (R) cell, 111 ... blue (B) cell, 112 ... green (G) cell, 120 ... sealing material

Claims (9)

In a flat type image display device in which a plurality of unit flat display elements are arranged, the unit flat display element has at least some of the cells constituting the outermost peripheral pixel smaller in size than the cells of the internal pixels, and the unit flat display element A flat-type image display device characterized in that the pitch of pixels at the outermost peripheral portion with reference to the outer peripheral surface is equal to the pixel pitch of internal pixels excluding the pixels at the outermost peripheral portion. Each pixel of the unit flat display element is composed of cells that are long in the vertical direction, and the left and right outermost peripheral pixels have a size b of one cell in the horizontal direction of three color cells of R, G, and B, The distance d between the outermost peripheral pixel and the outer peripheral surface of the unit flat display element, and the distance 2c between the outermost peripheral pixel and the inner pixel is smaller than the width a of the other peripheral cells and the inner pixel. Includes a relationship of a + c = b + d, the vertical length f of the upper and lower outermost peripheral pixels, the vertical length g of the other pixels, and a pixel adjacent to the uppermost or lowest pixel. 2. The flat image display apparatus according to claim 1, wherein there is a relationship of c + g = d + f between the vertical interval 2c. Each pixel of the unit flat display element is composed of cells that are long in the vertical direction, and the left and right outermost peripheral pixels have widths b1 and b2 of two cells in the horizontal direction of cells of three colors R, G, and B, respectively. The relationship of 2a + c = b1 + b2 + d is smaller than the width a of other cells, and the distance d between the outermost peripheral pixel and the outer peripheral surface of the unit flat display element and the distance 2c between the outermost peripheral pixel and the inner pixel And the vertical length f of the uppermost or lowest pixel in the vertical direction of the outermost peripheral pixel, the vertical length g of other pixels, and adjacent to the uppermost or lowest pixel in the vertical direction 2. The flat image display device according to claim 1, wherein a relationship of c + g = d + f is established between the pixel and the interval 2c. Pixels that are long in the vertical direction at the left and right outermost peripheral parts are three cell sizes b1, b2, and b3 in the horizontal direction of cells of three colors R, G, and B. There is a relationship of 3a + c = b1 + b2 + b3 + d between the distance d between the outermost peripheral pixel and the outer peripheral surface of the unit flat display element and the distance 2c between the outermost peripheral pixel and the inner pixel. Between the vertical length f of the upper and lower outermost peripheral pixels, the vertical length g of other pixels, and the vertical interval 2c between the uppermost or lowest pixel and the adjacent pixel The flat image display device according to claim 1, wherein a relationship of c + g = d + f is established. 5. The flat-panel image display device according to claim 1, wherein the brightness of the outermost peripheral pixel cell is set to be the same as or higher than the cell brightness of the same color of the internal pixel. 6. The flat image display device according to claim 2, wherein a cell in a pixel of the unit flat display element has a color having the smallest luminous efficiency arranged as the widest cell of the outermost peripheral pixel. . The color arrangement of the cells in the pixel of the unit flat display element is such that the cell having the least efficient color is arranged at the center of the pixel, and the center cell has the largest dimension in the outermost peripheral pixel. The flat image display device according to any one of 1 to 6. 8. The flat image display device according to claim 1, wherein the three color cells in the pixel of the unit flat display element are arranged in the order of R, B, and G. In the image display method of a flat-type image display device in which a plurality of unit flat display elements are arranged, the unit flat display element includes at least some of the cells constituting the outermost peripheral pixel, other cells of the outermost peripheral part, and cells of the inner pixel The distance from the outer peripheral surface of the unit flat display element to the middle of the outermost peripheral pixel and the adjacent pixel is equal to the pixel pitch of the internal pixels excluding the outermost peripheral pixel. The brightness adjustment signal of at least some of the pixels of the pixel is made larger than that of the internal pixel, and the brightness of the outermost peripheral cell of the same color and the brightness of the cell of the internal pixel are adjusted to be the same or higher. Method for adjusting a flat image display device.

Images