KR100858907B1 - Light emitting tube array type display unit and driving method therefor - Google Patents

Abstract

The present invention provides a light emitting tube array type display device comprising: a light emitting tube array in which a plurality of light emitting tubes in which discharge gas is enclosed are disposed, and the light emitting tube array is brought into contact with at least one of a display surface side and a back side of the light emitting tube array. A plurality of display electrodes disposed on an adjacent support between the support body, the light emitting tube and the light emitting tube, for generating opposite discharge in the light emitting tube by applying a voltage from each side to each light emitting tube, and the display surface of the light emitting tube A plurality of scan electrodes arranged on the side in a stripe shape in a direction intersecting the longitudinal direction of the light emitting tube, and forming a light emitting region at an intersection with the light emitting tube, and for selecting a light emitting region arranged on the back side of each light emitting tube It consists of a plurality of address electrodes.

Light tube array, support, display electrode, scan electrode, address electrode

Description

LIGHT EMITTING TUBE ARRAY TYPE DISPLAY UNIT AND DRIVING METHOD THEREFOR}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a light emitting tube array type display device and a driving method thereof, and more particularly to light emission in which a phosphor layer is disposed inside a tubular tube having a diameter of about 0.5 mm to 5 mm and a discharge gas is encapsulated. A light emitting tube array type display device for arranging a plurality of tubes (also called "display tubes" or "gas discharge tubes") in parallel to display an arbitrary image, and a driving method thereof.

As such a light-emitting tube array type display apparatus, the thing of Unexamined-Japanese-Patent No. 2003-86141, the Unexamined-Japanese-Patent No. 2003-86142, etc. are known. This example is shown in FIG. 17 and FIG. FIG. 18 is a partial cross-sectional view of FIG. 17 illustrating a state in which the display device is cut in a direction perpendicular to the longitudinal direction of the light emitting tube.

In this light emitting tube array type display device, a plurality of light emitting tubes 1 (light emitting tube array) arranged in parallel are inserted between a pair of flat support members 31 and 32 such as glass or resin. In this way, the display panel is configured. It is also known to use a transparent film sheet as a support. Inside the light emitting tube 1, a red phosphor layer R, a green phosphor layer G, and a blue phosphor layer B are disposed, and a discharge gas is enclosed.

In these display devices, a discharge is generated inside the light emitting tube, and an electrode therefor is formed on the light emitting tube array facing surface of the support to bring the electrode into contact with the surface of the light emitting tube.

This electrode is usually arranged on the opposite side of the light emitting tube array of the support 32 on the rear side, along with the address electrodes (referred to as data electrodes) A along each light emitting tube, and on the front side (display side) of the support 31 A plurality of display electrode pairs (X, Y) for surface discharge are arranged on the opposite side of the light emitting tube array in the direction of crossing the address electrodes (A). Each display electrode is formed of a transparent electrode 12 made of an ITO film, a SnO ₂ film, or the like and a bus electrode 13 made of a metal film. Each address electrode A is formed of a metal film.

At the time of display, the Y electrode of the display electrode pair is used as the scanning electrode, and address discharge is generated at the intersection of the Y electrode and the address electrode A to select the light emitting region. Next, display discharge (also referred to as sustain discharge or sustain discharge) is generated in the display electrode pairs X and Y by using wall charges formed on the inner surface of the tube by the address discharge. Do it. As a result, as shown by the arrow in FIG. 18, the red light 33, the green light 34, and the blue light 35 are emitted from the light emitting tube 1. The address discharge is an opposite discharge generated in the light emitting tube 1 between the opposing Y electrode and the address electrode A with the light emitting tube 1 interposed therebetween, and the display discharge is two display electrodes arranged in parallel on the plane. It is a surface discharge generated in the light emitting tube 1 between (X, Y). Such an electrode arrangement makes it possible to form a plurality of light emitting regions (unit light emitting regions) in the longitudinal direction of the light emitting tube.

However, in the light emitting tube array of this electrode arrangement, since the display discharge is surface discharge, a high discharge voltage is required. In addition, although a phosphor layer is formed on the back side inside the light emitting tube, since the surface discharge region is separated from the phosphor layer, vacuum ultraviolet rays for excitation are not sufficiently supplied to the phosphor layer. In addition, since two display electrodes are arranged on the front side of the light emitting tube array in one light emitting region, the light shielding rate is large and the light emitting efficiency is low.

In addition, adhesion failure between the display electrode and the light emitting tube tends to occur due to unevenness due to the unevenness of the tube diameter of the light emitting tube. As a result, the discharge start voltage nonuniformity is large for each light emitting region, so that a large operating margin can be secured. There is no such problem.

In addition, in the case of the PDP (plasma display panel) of the type which forms a cell by partitioning the discharge space provided between a pair of board | substrates by a partition rather than the above light tube array type display apparatus, it is related with this invention. As the patent, a PDP as described in Japanese Patent Laid-Open No. 2000-331615 is known. In this PDP, the display electrode is arrange | positioned at the side surface of a partition.

The present invention has been made in view of the above circumstances, and the discharge voltage is reduced by separately providing the scan electrode and the display discharge electrode pair, and disposing the display discharge electrode pair on the side of the light emitting tube to form a four-electrode structure. It aims at reducing and aiming at the improvement of luminous efficiency.

The present invention supports a light emitting tube array in which a plurality of light emitting tubes in which discharge gas is enclosed in a juxtaposition and a light emitting tube array in contact with at least one of a display surface side and a back side of the light emitting tube array. A plurality of display electrodes arranged on an adjacent portion between the support body, the light emitting tube and the light emitting tube, for generating opposite discharge in the light emitting tube by applying a voltage from each side to each light emitting tube, and the display surface side of the light emitting tube. A plurality of scan electrodes arranged in a stripe shape in a direction intersecting the longitudinal direction of the light emitting tube, forming a light emitting region at an intersection with the light emitting tube, and a plurality of light emitting region selections arranged on the back side of each light emitting tube; A light emitting tube array type display device including an address electrode of a light emitting device.

In addition, the present invention provides a driving method of the above-described light tube array type display device. In screen display, one frame is constituted by a plurality of subfields having different luminance, and each subfield is configured to emit all light. And a reset period for initializing the charge of the region, an address period for selecting the light emitting region to emit light, and a sustaining period for emitting the selected light emitting region, and in the reset period, voltage pulses are applied to all electrodes in all the light emitting regions. Discharges are generated, and during the address period, scan pulses are sequentially applied to the scan electrodes, and address pulses are then applied to the desired address electrodes to generate address discharges between the scan electrodes and the address electrodes. In the sustain period, the light emitting tube is interposed between the display electrodes facing each other. The display is alternately performed by applying sustain pulses alternately to generate sustain discharge in the light emitting tube, and the reset period is constituted by the write period and the charge compensation period, and in the write period, between the scan electrode and the address electrode. Discharge is generated between two opposing display electrodes with the light emitting tube interposed therebetween to remove residual charge and form new charge. In the charge compensation period, the charge formed in the writing period is transferred to the next address. A discharge method for driving a light-emitting tube array type display device characterized by generating a discharge for bringing it into a state suitable for discharge.

According to the present invention, the discharge between the display electrodes is performed as the counter discharge. Therefore, the discharge voltage between the display electrodes can be lowered and the number of electrodes disposed on the display surface side of the light emitting tube array can be lowered compared with the light emitting tube array type display device in which discharge between the display electrodes is performed by surface discharge. The light shielding rate of light emitted from the light tube array can be reduced. As a result, it is possible to obtain a light emitting tube array type display device having higher luminance and better light emission efficiency utilizing low discharge voltage and low light shielding rate.

BRIEF DESCRIPTION OF THE DRAWINGS Explanatory drawing which shows the whole structure of the light emitting tube array type display apparatus of this invention.

FIG. 2 is a cross-sectional view of the light emitting tube array type display device illustrated in FIG. 1.

3 is an explanatory diagram showing an example of the configuration of an electrode;

4 is an explanatory diagram showing a pattern example of a display electrode;

5 is an explanatory diagram showing a pattern example of a display electrode;

6 is an explanatory diagram showing a pattern example of a display electrode;

7 is an explanatory diagram showing a pattern example of a display electrode;

8 is an explanatory diagram showing a pattern example of a display electrode;

9 is an explanatory diagram showing a pattern example of a display electrode;

10 is an explanatory diagram showing a pattern example of a scan electrode;

11 is an explanatory diagram showing a pattern example of a scan electrode;

12 is an explanatory diagram showing a pattern example of a scan electrode;

13 is an explanatory diagram showing a comparative example of a driving method.

14 is an explanatory diagram showing an example of a basic drive waveform of the drive method of the present invention;

15 is an explanatory diagram showing an example of another drive waveform of the drive method of the present invention;

16 is an explanatory diagram showing an example of a driving circuit arrangement;

Fig. 17 is a perspective view showing the entire surface discharge type light emitting tube array type display device.

FIG. 18 is a partial cross-sectional view of the light emitting tube array type display device of FIG. 17.

In the light emitting tube array type display device of the present invention, the light emitting tube array may be formed by juxtaposing a plurality of light emitting tubes in which discharge gas is enclosed. Although the thing of any diameter may be used for the fine pipe used as the pipe | tube body of this light emitting tube, The thing of glass about 0.5 mm-about 5 mm in diameter is applied. The shape of the customs tube may have a cross section of any shape such as a circular cross section, a flat elliptic cross section, a square cross section, or the like.

The support may be in contact with at least one of the display surface side and the back side of the light emitting tube array to support the light emitting tube array. As this support body, the resin flexible sheet and the glass substrate can be applied, for example. Examples of the flexible sheet made of resin include a light transmissive film sheet and the like. As a film used for this film sheet, a commercial PET (polyethylene terephthalate) film etc. can be applied. Examples of glass substrates include soda-lime glass substrates.

The support is preferably composed of a pair of supports capable of supporting the light emitting tube array from both sides of the display surface side and the back side. In this case, it is not necessary to manufacture both with the thing of the same material, and arbitrary structures are possible, such as forming one resin and the other glass.

The size of the support is preferably in the form of a sheet or a flat plate so as to support the entire light emitting tube array, and a size that substantially covers the entire light emitting tube array.

The display electrode may be disposed at an adjacent portion between the light emitting tube and the light emitting tube, and may be configured to generate a counter discharge in the light emitting tube by applying a voltage from both sides to each light emitting tube.

This display electrode can be formed using various materials known in the art. As the material used for the electrodes, examples thereof include an electrically conductive material of metal such as a transparent conductive material such as ITO, SnO _2, or, Ag, Au, Al, Cu, Cr. As a method of forming the electrode, various methods known in the art can be applied. For example, it may be formed using a thick film forming technique such as printing, or may be formed using a thin film forming technique comprising a physical deposition method or a chemical deposition method. As a thick film formation technique, the screen printing method etc. are mentioned. As a physical deposition method in a thin film formation technique, a vapor deposition method, sputtering method, etc. are mentioned. As a chemical deposition method, thermal CVD method, optical CVD method, plasma CVD method, etc. are mentioned.

The display electrodes may be formed on the outer wall surfaces on both sides of the light emitting tube, or may be formed on the outer wall surface of one of the light emitting tubes, and may be configured to share one display electrode between adjacent light emitting tubes.

It is preferable to comprise a display electrode with the thick electrode part corresponding to a light emitting area part, and the thin electrode part corresponding to a non-light emitting area part. In this case, it is preferable to set it as the structure which provided the thin electrode part in the vicinity of the back surface of a light emitting tube array.

The scan electrode may be arranged on the display surface side of the light emitting tube in a stripe shape in a direction crossing the longitudinal direction of the light emitting tube, and may form a light emitting region at an intersection with the light emitting tube. In order to facilitate formation, it is preferable that this scan electrode is formed on the light emitting tube opposing surface of the support body disposed on the display surface side of the light emitting tube array.

The address electrode may be disposed on the back side of each light emitting tube for selecting the light emitting region. This address electrode is preferably composed of a thick electrode portion corresponding to the light emitting region portion and a thin electrode portion corresponding to the non-light emitting region portion. In addition, in order to facilitate formation, it is preferable that the address electrode is formed on the light emitting tube facing surface of the support body disposed on the back side of the light emitting tube array.

These scan electrodes and address electrodes can also be formed using various materials and methods known in the art.

In addition, the present invention provides a driving method of the above-described light tube array type display device, wherein when a screen is displayed, one frame is composed of a plurality of subfields having different luminance, and each subfield is initialized with charges in all light emitting regions. A reset period, an address period for selecting a light emitting area to emit light, and a sustaining period for emitting the selected light emitting area, and in the reset period, voltage pulses are applied to all electrodes to generate discharge in all light emitting areas, In the address period, scan pulses are sequentially applied to the scan electrodes, while address pulses are applied to the desired address electrodes to generate address discharges between the scan electrodes and the address electrodes, thereby accumulating wall charges in the light emitting area to be emitted. Alternating between opposing display electrodes with light tubes interposed The display is performed by applying a sustain pulse to generate sustain discharge in the light emitting tube, and the reset period is constituted by the writing period and the charge compensation period, and in the writing period, between the scan electrode and the address electrode and the light emitting tube. Discharges are generated between two opposing display electrodes with each other interposed therebetween to remove residual charges and form new charges. In the charge compensation period, the charges formed in the write period are set to a state suitable for the next address discharge. A drive method for a light emitting tube array type display device, characterized by generating discharge.

In this driving method, it is preferable that, in the writing period, the voltage pulse applied between the scan electrode and the address electrode and the voltage pulse applied between the two display electrodes are each above the discharge start voltage.

In this writing period, when a voltage pulse is applied between the scan electrode and the address electrode, the voltage pulse applied to the scan electrode may be an obtuse wave. In this case, the obtuse wave means a voltage pulse in which the crest value gradually rises. The degree of elevation may be linear or curved (exponential). In the writing period, when a voltage pulse is applied between two display electrodes, the voltage pulse applied to one display electrode may be an obtuse wave. The obtuse wave in this case also means a voltage pulse in which the crest gradually rises, and the degree of the rise may be linear or curved (exponential). The voltage value of these obtuse waves is preferably about 1.5 to 3 times the respective static discharge start voltage.

The voltage pulse applied in the charge compensation period includes a charge compensation pulse between display electrodes for generating a discharge between two display electrodes facing each other with a light emitting tube therebetween, and an address scan for generating a discharge between the scan electrode and the address electrode. It is preferable to comprise by the charge compensation pulse between electrodes.

The charge compensation pulse between the display electrodes and the charge compensation pulse between the address and scan electrodes may be blunt. In this case, the obtuse wave means a voltage pulse in which the crest value gradually decreases. The degree of descent may be linear or curved (exponential).

The charge compensation pulse between the display electrodes is preferably preceded by the charge compensation pulse between the address and scan electrodes.

In addition, when a charge compensation pulse is applied between the display electrodes, it is preferable to apply a fixed potential to the address electrode and the scan electrode, respectively. The fixed potential applied to the address electrode is preferably the same as the peak value of the address pulse, and the fixed potential applied to the scan electrode is preferably equal to the peak value of the sustain pulse.

In the address period, when the scan pulses are sequentially applied to the scan electrodes and the address pulses are applied to the desired address electrodes during this time, it is preferable to provide a fixed potential to the opposite display electrodes with the light emitting tubes interposed therebetween. In this case, the fixed potentials respectively applied to the opposite display electrodes with the light emitting tube interposed therebetween are more than the peak values of the sustain pulses and are less than or equal to the discharge start voltage between the two electrodes, and discharge is generated between the address electrodes and the scan electrodes. In this case, it is preferable that the electric charge formed by the discharge is a potential that can cause sustain discharge.

In the sustain period, it is preferable to apply a fixed potential to the scan electrode and the address electrode, respectively, when applying a sustain pulse alternately between opposing display electrodes with the light emitting tube interposed therebetween.

In the light emitting tube array type display device, the present invention aims to lower the driving voltage and improve the light emission efficiency.

Specifically, a scanning electrode (hereinafter referred to as a scan electrode), an address electrode (hereinafter referred to as an address electrode), and a pair of main electrodes (hereinafter referred to as an address electrode) in each light emitting region of one light emitting tube The display electrode). Then, a pair of display electrodes are disposed on the side wall of the light emitting tube, and a scan electrode is disposed on the front side of the light emitting tube in a direction crossing the longitudinal direction of the light emitting tube, and an address electrode is arranged on the rear side of the light emitting tube. Place parallel to the longitudinal direction. The address discharge is generated between the scan electrode and the address electrode and, due to its priming effect, sustain discharge is generated between the pair of display electrodes.

With such a four-electrode structure, all of the address discharge to the sustain discharge can be performed by counter discharge. Since the sustain discharge (counter-discharge) is generated from the display electrode pairs arranged on the side wall of the light emitting tube, the voltage of the sustain discharge can be lowered. In addition, since the sustain discharge is generated in the vicinity of the phosphor layer, the phosphor excitation efficiency due to vacuum ultraviolet rays is increased, and the improvement of the luminous efficiency can be expected. In addition, since only one scan electrode is disposed in each light emitting region on the display surface, the light shielding rate by the electrode is lowered as compared with the surface discharge type light tube array type display device, whereby the luminous efficiency can be improved.

EMBODIMENT OF THE INVENTION Hereinafter, this invention is demonstrated in detail based on the Example shown in drawing. In addition, this invention is not limited by this, A various deformation | transformation is possible.

BRIEF DESCRIPTION OF THE DRAWINGS It is explanatory drawing which showed the whole structure of the light emitting tube array type display apparatus of this invention. The display device 10 has a light emitting tube array type for arranging a plurality of light emitting tubes containing a discharge gas in parallel while disposing a phosphor layer inside glass tubules having a diameter of about 0.5 mm to 5 mm and displaying an arbitrary image. It is a display device.

In Fig. 1, reference numeral 31 denotes a support (substrate) on the front side (display surface side), reference numeral 32 denotes a support (substrate) on the back side, reference numeral 1 denotes a light emitting tube, reference numeral S denotes a scan electrode, and Reference numerals X and Y denote display electrodes, and reference numeral A denotes an address electrode.

The light emitting tube array type display device comprises a plurality of light emitting tubes 1 arranged in parallel to form a light emitting tube array, and the light emitting tube array is interposed between the front support 31 and the back support 32. It is an inserted structure.

The support body 31 on the front side and the support body 32 on the back side are made of a flexible sheet such as a PET film. The support body 31 on the front side is transparent. It is preferable that the support body 32 on the back side is opaque because of the relationship of display contrast. The tube of the light emitting tube 1 is made of borosilicate glass or the like.

A plurality of scan electrodes S are formed on the light emitting tube facing surface of the support body 31 on the front side. The scan electrode S is provided in contact with the light emitting tube 1 in the direction crossing the address electrode A. As shown in FIG. The scan electrode (S) is constituted by a bus electrode made of a metal such as a transparent electrode, a nickel, copper, aluminum, chromium, such as ITO or SnO _2. In addition, the scan electrode S may be an electrode formed only of a metal electrode without using a transparent electrode.

The address electrode A is formed on the opposing surface of the light emitting tube of the support body 32 on the rear side. The address electrode A is provided in contact with the light emitting tube 1 along the longitudinal direction of the light emitting tube 1. This address electrode A is formed using nickel, copper, aluminum, silver, or the like.

Display electrodes X and Y are disposed between the light emitting tube 1 and the light emitting tube 1. The display electrodes X and Y are formed directly on the outer wall surface of the light emitting tube by sputtering, vapor deposition, plating, printing, etc. using nickel, copper, aluminum, silver, or the like.

As described above, in the light emitting tube array type display device, the scan electrode S is disposed on the front side of the light emitting tube 1, and the address electrode A is disposed on the rear side of the light emitting tube 1, and the light emitting tube is disposed. The display electrodes X and Y are disposed on the side surface of (1). The scan electrodes S and the address electrodes A are arranged to be orthogonal to each other when the display device is viewed in a plan view, and the intersection of the address electrodes A and the scan electrodes S is a unit light emitting region (unit discharge region). do. Therefore, the electrode structure of the light emitting tube array type display device can be said to be a four-electrode structure in which the scan electrode S, the address electrode A, and the display electrodes X and Y are arranged in one light emitting region. .

The display is configured to generate an address discharge at an intersection of the scan electrode S and the address electrode A to select a light emitting region, and to display the display electrode (using a wall charge formed on the inner surface of the tube in accordance with the address discharge). This is performed by generating a sustain discharge between X and Y). The address discharge is a counter discharge generated in the light emitting tube 1 between the scan electrode S and the address electrode A, and the sustain discharge is between the display electrodes X and Y disposed on the side of the light emitting tube 1. It is a counter discharge generated in the light emitting tube 1 of.

2 is an explanatory view showing a cross section of a light emitting tube array display device. 2 shows a cross section perpendicular to the longitudinal direction of the light emitting tube.

The tube of the light emitting tube 1 uses glass tubules. This tubular tube has a circular cross section, and is made of Pyrex (registered trademark: heat-resistant glass manufactured by Corning, USA) to a tube diameter of 0.7 mm to 1.5 mm, a thickness of 0.07 mm to 0.1 mm, and a length of 220 mm to 300 mm. It is manufactured.

A customs tube, which is a tube of the light emitting tube 1, manufactures a cylindrical tube by a Danner method, heat-forms the cylindrical tube, and forms a glass base material similar in shape to the custom tube to be manufactured. Is prepared, and it is produced by redraw (extension) while heating and softening it.

In the discharge space inside the light emitting tube 1, R (red), G (green), and B (blue) phosphor layers are provided for each color on the back side, and a discharge gas containing neon and xenon is introduced to both ends. This is sealed, and the discharge space is formed in the inside of a light emitting tube by this.

At the time of display, the red light 33, the green light 34, and the blue light 35 are emitted from the light emitting tube 1, and three adjacent light emitting tubes for R, G, and B are set as one set. The pixel is constructed. As for the interior of the light emitting tube, a structure known in the art as described in JP-A-2003-86142 can be applied.

The display electrodes X and Y are not directly formed on the outer wall surface of the light emitting tube, and electrodes are formed on both surfaces of a resin sheet or the like by low temperature sputtering, printing, or the like, and the light emitting tubes are used as the display electrodes X and Y. It may be inserted between the light emitting tube and the side of the light emitting tube. However, this display electrode is preferably formed directly on the light emitting tube in order to increase the contact area with the light emitting tube.

In FIG. 2, an example in which one display electrode is shared by adjacent light tubes is shown. However, display electrodes may be formed on the outer wall of the light emitting tube, respectively. In this case, since the display electrodes of adjacent light emitting tubes are in contact with each other, a voltage is applied to two display electrodes that are in contact with each other at the same time with sustained discharge at the same polarity.

3 is an explanatory diagram showing a configuration example of an electrode. 3 shows only one light tube.

The light emitting tube of this example is rectangular in cross section, but the light emitting tube is not limited thereto, and the light emitting tube may have any shape such as circular, elliptical, square, trapezoidal or the like.

The scan electrode S is formed on the support on the front side, and the address electrode A is formed on the support on the back side. The display electrodes X and Y are formed directly on the side of the light emitting tube 1.

The display electrodes X and Y are thick electrode portions Xa and Ya in order to improve discharge characteristics of the light emitting region portions of the intersections of the scan electrodes S and the address electrodes A, and portions other than the light emitting regions. The thin electrode portions Xb and Yb are defined as follows. The thick electrode portions Xa and Ya are formed in the center portion of the outer wall surface of the light emitting tube. The thin electrode portions Xb and Yb are formed near the rear side of the outer wall of the light emitting tube.

In this manner, the two display electrodes X and Y periodically change the width of the electrode so as to partition the light emitting regions (light emitting cells), and are disposed so that the thick electrode portions Xa and Ya face each other. This is because the light emitting area is defined by using the discharge voltages different depending on the area of the opposite electrodes.

4-9 are explanatory drawing which showed the example of the pattern of a display electrode.

The electrode pattern shown in FIG. 4 is a basic pattern in which the discharge region portion, that is, the thick electrode portions Xa and Ya are formed of a metal solid film. The thin electrode portions Xb and Yb are all the same pattern with respect to Figs.

In the electrode pattern shown in FIG. 5, the thick electrode portions Xa and Ya are formed in the shape of a comb teeth. In the electrode pattern shown in Fig. 6, the thick electrode portions Xa and Ya are formed in a ladder shape.

7 and 8 are modified examples of the electrode patterns shown in FIGS. 4 to 6, and the connecting portions Xc and Yc connecting the thicker electrode portions Xa and Ya to the thinner electrode portions Xb and Yb. Install it.

FIG. 7 shows the coarse electrode portions Xa and Ya formed of a metal solid film, FIG. 8 shows the coarse electrode portions Xa and Ya in a comb-tooth shape, and FIG. 9 shows the coarse electrode portions Xa and Ya. Ya) is formed in a ladder shape.

The electrode patterns of FIGS. 5 and 6 are used for the reduction of the capacitance, the discharge current, the improvement of the luminous efficiency, the improvement of the operating margin, and the like for the electrode pattern of FIG. 4. The electrode patterns of FIGS. 8 and 9 are similarly used for the reduction of the capacitance, the reduction of the discharge current, the improvement of the luminous efficiency, the improvement of the operating margin, and the like of the electrode pattern of FIG. 7.

The thick electrode portions Xa and Ya of the display electrodes X and Y are not limited to the above examples, and may be any shape as long as the area is larger than the thin electrode portions Xb and Yb.

10-12 are explanatory drawing which showed the example of the pattern of a scan electrode.

Since the scan electrode S is on the front side of the light emitting tube array, the lower the light shielding rate, the higher the brightness is obtained. For this reason, it is good that the width of an electrode is as narrow as possible. However, if the width of the electrode is narrow, the area of the intersection portion between the scan electrode S and the address electrode A is narrowed, leading to an increase in the discharge start voltage and a decrease in the discharge probability. In order to improve this, it is preferable that by a scanning electrode (S) to a narrow width bus electrode made of ITO film or the SnO ₂ film or the like is wide transparent electrode and a metal film formed of a width.

10 shows an example in which the scan electrode S is formed of only a metal film. 11 and 12 show an example in which the scan electrode S is formed of the bus electrode S1 and the transparent electrode S2. The difference between FIG. 11 and FIG. 12 is that the transparent electrode S2 is provided in the entire scan electrode in FIG. 11, whereas in FIG. 12, the transparent electrode S2 is provided only in the light emitting region.

When the transparent electrode S2 is provided only in the light emitting region, the capacitance can be reduced as compared with the case where the transparent electrode S2 is provided throughout.

Since the intersection of the scan electrode S and the address electrode A becomes a light emitting area, it is preferable to make the corresponding portion of the light emitting area wider than the other parts for the address electrode A as well.

In this way, the display electrodes are provided on the outer wall of the light emitting tube so that the sustain discharge is the counter discharge, and the number of the scan electrodes is one for one light emitting area, thereby generating surface discharge between the display electrodes. Compared with the tube array type display device, it is possible to provide a display device with higher luminance and better luminous efficiency by utilizing a low discharge start voltage and a low light shielding rate.

Next, a driving method of the light emitting tube array type display device of the present invention will be described.

The driving method of the present invention is the driving method of the light-emitting tube array type display apparatus of the four-electrode structure described above, which uses a structural advantage of the light-emitting tube and low discharge start voltage of counter discharge. As a result, the decrease in the luminous efficiency due to the high driving voltage and the high light shielding rate, which have been a problem in the light emitting tube array type display device in which sustain discharge is generated by surface discharge, is improved.

That is, in this driving method, an address discharge is generated between the scan electrode S and the address electrode A, and the sustaining is performed between two display electrodes X and Y formed on the outer wall of the light emitting tube by the priming effect. Generates a discharge. By this driving method, it is possible to perform all of the counter discharge from the address discharge to the sustain discharge. When sustain discharge is performed on the electrode formed on the outer wall of the light emitting tube, since the discharge discharge voltage is low because the opposite discharge is generated, and the discharge is generated in the vicinity of the phosphor layer, the phosphor excitation efficiency by vacuum ultraviolet light is increased, thereby improving the light emission efficiency. Can be expected. In addition, since only one scan electrode S is formed on each display area in the display surface, the light blocking rate is reduced as compared with the surface discharge type light emitting tube array type display device, and the light emission efficiency can be increased by reducing the light blocking rate. have.

Hereinafter, the present driving method will be described in detail.

In screen display, one frame is composed of a plurality of subfields having different luminance, and each subfield is composed of a reset period for initializing charges of all light emitting regions, an address period for selecting a light emitting region to emit light, And a sustain period for emitting the selected light emitting region.

In the reset period, voltage pulses are applied to all electrodes to generate discharge in all light emitting regions. In the address period, scan pulses are sequentially applied to the scan electrodes S, while address pulses are applied to the desired address electrodes A to generate address discharge between the scan electrodes S and the address electrodes A. Wall charges are accumulated in the light emitting area to be made. In the sustain period, sustain pulses are alternately applied between display electrodes X and Y facing each other with the light emitting tube interposed therebetween to generate sustain discharge in the light emitting region in which the wall charges are accumulated, thereby causing the light emitting region to emit light. Light emission of this light emitting region is performed by exciting the phosphor with ultraviolet rays generated by the sustain discharge and generating visible light of a desired color from the phosphor.

It is explanatory drawing which shows the comparative example of a drive method. FIG. 13 shows driving waveforms of the surface discharge type light emitting tube array display device shown in FIGS. 17 and 18. The drive waveform shown in the figure represents a period of one subfield.

Unlike the driving method of the present invention, the driving method of this comparative example generates reset discharge between the display electrodes X and Y in the reset period, and addresses between the address electrode A and the display electrode Y in the address period. A discharge is generated, and a sustain discharge is generated between the display electrodes X and Y in the sustain period.

Fig. 14 is an explanatory diagram showing an example of basic driving waveforms of the driving method of the present invention.

Since this driving method is a driving method of a light emitting tube array type display device having a four-electrode structure, research for that is required. Details will be described later.

The driving waveform is largely divided into three steps: a reset period, an address period, and a sustain period. However, the reset period is composed of a write period and a charge compensation period, and the sustain period is again divided into a sustain preprocessing period and a sustain loop. Configure by Hereinafter, the voltage applied in each period is demonstrated.

① Reset period

(a) Entry period

In the writing period, it is an object to generate discharge in all light emitting regions regardless of the remaining charge state in the sustain period of the previous subfield.

Since it is a four-electrode structure, it is necessary to perform write discharge in accordance with the role of four electrodes. Here, it is divided into two sets of display electrodes X and Y which perform sustain discharge, and a set of scan electrodes S and address electrodes A which perform address discharge. Therefore, a voltage pulse is applied to exceed each discharge start voltage in each electrode set.

In the next address period, it is preferable that negative charge is accumulated on the scan electrode S, and positive charge is accumulated on the address electrode A. FIG. Therefore, a positive write pulse is applied to the scan electrode S. FIG. In addition, the two display electrodes X and Y also need to accumulate positive and negative charges on the respective electrodes in the next address period. Therefore, a positive write pulse is applied to any one of the display electrodes. The applied voltage value is set to satisfy the following conditions.

Vsw> Vfs-a

| Vxw | + | Vyw |> Vfx-y

Here, Vsw is a voltage applied to the scan electrode S, and Vfs-a is a discharge start voltage between scan and address electrodes. Vxw is a voltage applied to the display electrode X, Vyw is a voltage applied to the display electrode Y, and Vfx-y is a discharge start voltage between the display electrodes X and Y.

The voltage Vsw applied to the scan electrode S and the voltage Vyw applied to the display electrode Y in the writing period are obtuse waves and are voltages which rise linearly.

When the write voltage waveform is a blunt wave, the value of the voltage Vsw applied to the scan electrode S, the voltage Vxw applied to the display electrode X, and the absolute value of the voltage Vyw applied to the display electrode Y are shown. The sum | Vxw | + | Vyw | is preferably about 1.5 to 3 times the respective static discharge start voltage.

(b) charge compensation period

After the writing period, the state of charge suitable for the address discharge is the charge compensation period. This charge compensation period is redivided again, so that the charge compensation of the display electrode which generates a discharge between the display electrodes X and Y, and the address scan electrode which generates a discharge between the address electrode A and the scan electrode S This is done by dividing the charge with the liver.

Here, it is necessary to prevent a false discharge from occurring even when a half selection pulse (Va, Vy, Vsc is applied alone) in the address period. Specifically, when voltage Va is applied to the address electrode A, no misdischarge is caused between the address electrode A and any of the display electrodes X (or Y) of negative charge. Therefore, after the fixed potential of the voltage Va is applied to the address electrode A, charge compensation discharge between the display electrodes X and Y is performed.

In addition, during sustain discharge, it is necessary to prevent erroneous discharge from occurring in the light emitting region which does not have address discharge. For this reason, the arrival potential of the charge compensation discharge between the display electrodes X and Y needs to be equal to or greater than the value of the applied voltage Vs at the time of the sustain discharge. Therefore, the applied voltage value is set to satisfy the following conditions.

| Vax | + | Vay | ≥Vs

Here, Vax is a voltage applied to the display electrode X, and Vay is a voltage applied to the display electrode Y.

In addition, in the charge compensation period, it is necessary to increase the potential of the scan electrode S. However, in order to reduce the number of power sources, the scan electrode S may be kept at the voltage Vsw or may be the voltage Vs at the sustain discharge. .

② Address period

In the address period, an address discharge is generated between the address electrode A and the scan electrode S, and an amount of charges that can generate a sustain discharge between the display electrodes X and Y by triggering this discharge is formed in the light emitting region. Let's do it.

③ sustain period

In the sustain period, it is divided into a sustain pretreatment period and a sustain loop in which discharge is repeated. In the sustain pretreatment period, since the wall charges formed by the address discharge are unstable, the charges are shaped so that stable sustain discharge can be performed. Therefore, in the first pulse, in addition to the voltage Vs, the voltage Vxd is added to reliably generate discharge. In addition, it is preferable to apply several voltage pulses having a pulse width wider than the pulse width in the sustain loop until the sustain loop is started.

15 is an explanatory diagram showing an example of another drive waveform of the drive method of the present invention.

This drive waveform is based on the premise that the display electrodes (X, Y) do not generate write discharge in the reset period, but use the residual charge when the light is emitted in the previous subfield. Therefore, although it is also possible to use it alone, when one frame is constituted by a plurality of subfields and displayed, the driving waveform shown in FIG. 14 is applied to the first subfield in one frame and viewed from the second and subsequent subfields. This is done by applying a drive waveform.

Since the remaining charge in the previous subfield is used, the write discharge is caused to occur only between the scan electrode S and the address electrode A in the write period. In this case, a pulse having the same polarity as that of the write pulse is applied to the display electrodes X and Y so that erroneous discharge does not occur between the scan electrode S and the display electrode X (or Y). After the charge compensation period, the same operation as that of the driving waveform of FIG. 14 is performed.

16 is an explanatory diagram showing an example of a driving circuit arrangement.

In this arrangement, the scan drive SD for the scan electrode S is placed next to the light emitting tube array type display device 10, the address drive AD for the address electrode A is below, and the display electrodes X and Y are disposed below. Place the sustain driver (TD) thereon. Since the address electrode A, the scan electrode S, and the display electrodes X and Y are completely independent, respective dedicated substrates can be manufactured, so that mutual interference such as noise, thermal countermeasures, and the like can be more easily performed. I can stand it.

Claims (20)

A light emitting tube array in which a plurality of light emitting tubes in which discharge gas is enclosed are juxtaposed; A support for supporting the light emitting tube array in contact with at least one of the display surface side and the back side of the light emitting tube array; A plurality of display electrodes disposed in an adjacent portion between the light emitting tube and the light emitting tube, for applying opposite voltage to each light emitting tube to generate counter discharge in the light emitting tube; A plurality of scan electrodes arranged in a stripe shape on a display surface side of the light emitting tube in a direction crossing the longitudinal direction of the light emitting tube, and forming a light emitting region at an intersection with the light emitting tube; And a plurality of address electrodes for selecting a light emitting area arranged on the back side of each light emitting tube, The display electrode is formed on the outer wall surface on both sides of the light emitting tube, The display electrode is formed on the outer wall surface of one light emitting tube, and adjacent light emitting tubes share one display electrode located therebetween, A light emitting tube array type display device, wherein the display electrode comprises a thick electrode portion corresponding to the light emitting region portion and a thin electrode portion corresponding to the non-light emitting region portion. delete delete delete The method of claim 1, A light emitting tube array type display device, wherein a thin electrode portion of a display electrode is formed on a back side of a light emitting tube array. The method of claim 1, A light emitting tube array type display device, wherein the address electrode comprises a thick electrode portion corresponding to the light emitting region portion and a thin electrode portion corresponding to the non-light emitting region portion. The method of claim 1, The support is composed of a front side support body disposed on the display surface side of the light emitting tube array and a back side support body disposed on the rear side of the light emitting tube array, and a scan electrode is formed on the light emitting tube opposite surface of the front side support body, A light emitting tube array display device formed on a light emitting tube facing surface of a back side support. A driving method of the light emitting tube array type display device according to claim 1, In screen display, one frame is constituted by a plurality of sub-fields having different luminance, and each subfield is selected for a reset period for initializing the charges of all the light emitting regions and a light emitting region to emit light. And a sustain period for emitting the selected light emitting area, In the reset period, voltage pulses are applied to all electrodes to generate discharge in all light emitting regions, and in the address period, scan pulses are sequentially applied to the scan electrodes, and address pulses are then applied to the desired address electrodes. By generating an address discharge, wall charges are accumulated in a light emitting area to emit light, and in a sustain period, a display pulse is generated by alternately applying a sustain pulse between display electrodes facing each other with a light emitting tube interposed therebetween to generate a sustain discharge in the light emitting tube. By doing, The reset period is constituted by the writing period and the charge compensation period. In the writing period, discharge is generated between the scan electrode and the address electrode and between two display electrodes facing each other with the light emitting tube therebetween, thereby remaining charge. Removing and forming new electric charges, wherein a discharge for causing the electric charges formed in the writing period to be ready for the next address discharge is generated in the electric charge compensation period. The method of claim 8, A method of driving a light-emitting tube array display device in which a voltage pulse applied between a scan electrode and an address electrode and a voltage pulse applied between two display electrodes each exceed a discharge start voltage in a writing period. The method of claim 8, A method of driving a light-emitting tube array display device in which a voltage pulse applied to a scan electrode is an obtuse wave when a voltage pulse is applied between the scan electrode and the address electrode in the writing period. The method of claim 8, A method of driving a light-emitting tube array display device in which a voltage pulse applied to one display electrode is an obtuse wave when a voltage pulse is applied between two display electrodes in a writing period. The method of claim 10 or 11, A method of driving a light-emitting tube array type display device, wherein the oblique wave voltage value is about 1.5 to 3 times the respective static discharge start voltage. The method of claim 8, The voltage pulse applied in the charge compensation period includes charge compensation pulses between display electrodes for generating a discharge between two display electrodes facing each other with a light emitting tube therebetween, an address electrode for generating a discharge between the scan electrode and the address electrode; A method of driving a light emitting tube array type display device comprising charge compensation pulses between scan electrodes. The method of claim 13, A method of driving a light emitting tube array display device, wherein the charge compensation pulse between the display electrodes and the charge compensation pulse between the address electrode and the scan electrode are obtuse waves. The method of claim 13, A method of driving a light emitting tube array type display device, wherein the charge compensation pulse between the display electrodes is preceded by the charge compensation pulse between the address electrode and the scan electrode. The method of claim 13, A method of driving a light-emitting tube array type display device which applies a fixed potential to an address electrode and a scan electrode, respectively, when a charge compensation pulse is applied between display electrodes. The method of claim 16, The fixed potential applied to the address electrode has the same crest value as the crest value of the address pulse, and the fixed potential applied to the scan electrode has the same crest value as the crest value of the sustain pulse. Driving method. The method of claim 8, In the address period, when a scan pulse is sequentially applied to the scan electrodes and an address pulse is applied to the desired address electrodes during the time period, the light emitting tube array type display apparatus which imparts a fixed potential to each of the opposing display electrodes with the light emitting tube therebetween. Driving method. The method of claim 18, The fixed potentials respectively applied to the opposite display electrodes across the light emitting tube are equal to or greater than the peak value of the sustain pulse, and equal to or less than the discharge start voltage between the two electrodes, and the discharge is generated between the address electrode and the scan electrode. A method of driving a light-emitting tube array type display device, the potential of which sustain discharge can occur by using a charge formed by the discharge as a trigger. The method of claim 8, A driving method of a light emitting tube array display device in which a fixed potential is applied to a scan electrode and an address electrode when a sustain pulse is alternately applied between display electrodes facing each other with a light emitting tube interposed therebetween.

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