Patent Application
20050052116
The present invention relates to a backlight of the type used in combination with a liquid crystal element; and, more particularly, the invention relates to a flat panel backlight forming a field emission light emitting element which uses a cold cathode material which generates an electron emission in a relatively low electric field, particularly to a carbon-oriented material, such as carbon nanotubes, fine carbon fibers, diamond or the like, without being heated to a high temperature, and the invention relates further to a liquid crystal display device which combines the flat panel backlight and a liquid crystal element.
A thin light source, which utilizes the emission of light obtained by the radiation of electron beams emitted from a cathode (a linear cathode) to a phosphor, in the same manner as a cathode ray tube, as a backlight of a liquid crystal display device, is described in Japanese Unexamined Patent Publication Sho63(1988)-10458 (patent literature 1). In this patent literature 1, a thin light source is described which includes a plurality of linear electron sources and a plurality of mesh-like electrodes and which makes the whole screen produce a monochroic uniform light emission by adjusting the brightness with control of the width of drive pulses.
Further, Japanese Unexamined Patent Publication Hei11(1999)-7016 (patent literature 2) discloses a liquid crystal display device which is capable of performing a color display by arranging phosphors of different light emitting colors in conformity with pixels of a using liquid crystal element without providing color filters on the liquid crystal element side. Further, Japanese Unexamined Patent Publication Hei11(1999)-64820 (patent literature 3) discloses a liquid crystal display device which uses field emission electron sources as cathodes and includes a phosphor screen capable of selectively emitting lights of a plurality of colors, thus enabling a color display to be produced by performing light emission control of a flat panel backlight and display pixel control of a liquid crystal element in synchronism.
As indicated in the above-mentioned publications, by making use of the emission of light, which is obtained by radiating electron beams to phosphors, as the backlight of a liquid crystal element, it is possible to obtain a liquid crystal display device which can perform brightness control with high brightness. Accordingly, it is possible to obtain a liquid crystal display device having a high image quality with high peak brightness compared to a liquid crystal display device which uses fluorescent lamps, a light guide plate and a dispersion plate as a backlight.
However, in the structure disclosed in patent literature 1, since it is necessary to arrange a plurality of linear electron sources at given positions in a distributed manner, the density of the electron linear sources is increased, whereby it is difficult to increase the uniformity, thus increasing the manufacturing cost. Further, the light emission state of a phosphor screen is uniform over the whole screen, and, hence, to avoid degradation of the image quality when a moving image is displayed, that is, to prevent moving image blurring, the method of driving the liquid crystal element becomes complicated.
Further, to construct a structure which allows for selective emission of lights of plural colors, as disclosed in patent literature 2, it is necessary to strictly align the loci of electron beams which constitute an excitation source of the phosphors with the arrangement of the phosphors and, further, with the arrangement of pixels of the liquid crystal element; and, hence, a restriction is imposed on the setting of the strength of the electron beams, or the manufacturing cost is increased due to this alignment.
A measure to cope with the moving image blurring problem is disclosed in patent literature 3. In patent literature 3, the emission of lights of a plurality of colors is sequentially performed on a panel, and a non-light-emission state is inserted at the time of rewriting the pixels of the liquid crystal element so as to suppress the generation of moving image blurring. However, in patent literature 3, it is also necessary to selectively emit lights of a plurality of colors, and, hence, in the same manner as patent literature 2, it is necessary to align the loci of the electron beams with the arrangement of the phosphors. Due to this alignment, a restriction is imposed on the setting of the strength of the electron beams. Further, since the color images are sequentially displayed on the panel, it is necessary to drive the display device at a speed three times or more faster than the speed of the usual driving method. Because of the necessity for alignment, the necessity of providing a panel structure which enables high-speed driving and the necessity of providing a drive device which can cope with the high-speed driving, the manufacturing cost is increased.
Accordingly, it is an object of the present invention to provide a flat panel backlight which can generate uniform illumination light with high brightness over the whole light emitting surface, and a liquid crystal display device of high quality which uses such a flat panel backlight.
To achieve the above-mentioned object, the flat panel backlight of the present invention is constituted of a cathode panel including cathodes which have field emission electron sources formed of a material capable of emitting electrons with a low electric field and control electrodes which control the strength of electron beams emitted from the cathodes, and a phosphor screen panel including a light emitting surface which has a phosphor capable of emitting light with the same color over the whole light emitting surface and an anode to which a potential is supplied necessary for the phosphor. Further, the liquid crystal display device of the present invention, which uses the flat panel backlight, can suppress moving image blurring by allowing the selective light emission of a portion of the whole light emitting surface, thus realizing a moving image display of high quality.
As the above-mentioned electron emission material which enables the acquisition of electron emission with a low electric field, field emission electron sources which use diamond, carbon nanotubes, fine carbon fibers or the like are used as the cathodes. Then, by adopting a drive method which enables the selective light emission of a portion of the whole light emitting surface of the phosphor screen panel by controlling the voltage applied to the control electrodes and the cathodes, it is possible to obtain a liquid crystal display device of high quality which exhibits a high brightness and which can reduce the moving image blurring. Representative constitutions of the present invention.
The flat panel backlight of the present invention divides the light emitting surface, having white as a light emitting color, into three or more regions, and only some divided regions of the light emitting surface are selectively allowed to emit light.
The cathodes and the control electrodes are substantially formed on the same plane and the difference between the length of a perpendicular which is extended downwardly onto an anode surface from a first point, which is an arbitrary point on the cathode, and the length of a perpendicular which is extended downwardly onto the anode surface from a second point, which is an arbitrary point on the control electrode closest to the first point on the cathode, is equal to or smaller than either larger film thickness out of the film thickness of the cathode at the first point and the film thickness of the control electrode at the second point.
Further, in the liquid crystal display device of the present invention, at least one of the number of divisions of the light emitting surface and the flickering periods of respective divided regions is changed in response to at least one of the selection signals obtained, based on a selection signal or a video signal received from the outside with respect to the flat panel backlight. Further, the liquid crystal display device of the present invention includes a drive device which can select the light emission strength of the phosphor of the flat panel backlight and the optical transmissivity of the liquid crystal element.
The present invention is not limited to the above-mentioned constitutions and the constitutions of embodiments to be explained later, and various modifications can be made without departing from the technical concept of the present invention.
As has been explained heretofore, according to the present invention, by adopting a flat panel light emitting element, which uses field emission electron sources that are capable of performing line-scanning-type monochroic light emission, as a backlight which illuminates a liquid crystal panel part, it is possible to obtain a flat panel backlight which is capable of obtaining an image display with the least degradation of image quality, such as blurring on the moving image, in particular. Further, by setting the light emission strength of the flat panel backlight at a high brightness partially and for a short time so as to properly control the optical transmissivity of the liquid crystal element, it is possible to effectively improve the contrast with only a slight increase of the power consumption, and, hence, it is possible to provide a liquid crystal display device which is capable of producing a high quality display.
Preferred embodiments of the display device of the present invention will be explained in detail hereinafter in conjunction with the drawings.
Further,
In this embodiment, to ensure the required conductivity in a region which corresponds to the light emitting region on an electron beam source panel glass substrate 11, a silver paste is printed and baked to form a background having a thickness of 5 μm. Thereafter, a paste containing 10% by weight of carbon fibers, mainly formed of the carbon nanotubes having a length of 5 μm, is printed and baked, thus forming cathodes 12. Over these cathodes 12, insulation stripes 14 are printed and formed at an interval of 1 mm using a dielectric paste, such that the insulation stripe 14 has a height of 30 μm and a width of 50 μm. Over the insulation stripes 14, control electrodes 13, each of which is formed of a thin plate made of Invar material in which opening portions having a diameter of 50 μm are formed by etching, are arranged in the direction orthogonal to the insulation stripes 14 and are fixed using frit glass (not shown in the drawing), thus forming a cathode panel, that is, an electron beam source panel 1.
On the other hand, with respect to the phosphor screen panel 2, phosphor 22 is formed on a light emitting region over a phosphor screen panel glass substrate 21 by printing, and, thereafter, the phosphor 22 is baked. Then, aluminum which constitutes an anode 23 is formed on the phosphor 22 by a vapor deposition method. The electron beam source panel 1 and the phosphor screen panel 2, which are formed in the above-mentioned manner, are bonded to each other by way of a frame glass 7 and spacers 8, and the inside is evacuated to create a vacuum state therein. The spacers 8 used in this embodiment have a rib shape with a trapezoidal cross section in which the width thereof on the electron beam source panel 1 side is 500 μm and the width thereof on the phosphor screen panel 2 side is 300 μm and the height thereof is 6 mm. Further, the spacers 8 are arranged to be parallel to the insulation stripes 14.
The cathodes 12 are set to 0V, while 20 kV is applied to the anode 23 using an anode power source 105. Since a plurality of control electrodes 13 are provided, the control electrodes 13 are connected with a control electrode drive circuit 101; and, as shown in
Here, although not shown in the drawing, the liquid crystal element 5 includes a plurality of selection line electrodes and a plurality of signal line electrodes, which intersect the selection line electrodes on an inner surface of one of two glass substrates, and active elements, such as thin film transistors, are formed on intersecting portions between the selection line electrodes and the signal line electrodes. Video data transmitted from the signal line electrodes is written in the thin film transistors of the lines selected by the selection line electrodes. Further, the control electrodes 13 (see
However, since the electron beams are not radiated to regions where the spacers 8 shown in
In the combination for constituting the liquid crystal display device by combining the flat panel backlight part 300 and the liquid crystal panel part 400, out of the matrix structure which is constituted of the selection line electrodes and the pixel data electrodes for performing the rewriting of the pixel data of the liquid crystal element 5, the selection line electrodes are formed in parallel with the above-mentioned control electrodes 13 of the flat panel backlight part 300.
Due to the above-mentioned constitution, by radiating the electron beams 201 from the electron beam source panel 1 to the phosphor screen panel 2, the emission of light from the phosphor 202 becomes uniform due to the effect of the light scattering plate 3, and the transmitting light 203 is generated only in the light required regions through the lower polarizer 4, the liquid crystal element 5 and the upper polarized 4′; and, thereafter, the emission of light is colored by the color filters 6, thus realizing the display of a color image.
The flat panel backlight part 300 side merely sequentially emits light, and so it is unnecessary to provide any correspondence with the pixels on the liquid crystal panel part 400 side; and, hence, the accurate alignment of the flat panel backlight part 300 and the liquid crystal panel part 400 is unnecessary even at the time of assembling. In driving the liquid crystal display device, while taking into consideration the synchronism between the line electrode selection signal for rewriting the pixel data of the liquid crystal element 5 and the selection signal of the control electrode drive circuit 101 of the flat panel backlight part 300, the liquid crystal display device is driven by shifting the phases of these signals to prevent these signals from simultaneously selecting the same regions. Accordingly, at the time of rewriting the pixels of the liquid crystal element 5, it is possible to perform driving such that the emission of light at the corresponding regions of the flat panel backlight part 300 is stopped, whereby it is possible to suppress the generation of a deterioration of a moving image (so-called moving image blurring) attributed to the simultaneous recognition of the states of pixels before and after the rewriting.
Here, in the liquid crystal display device of this embodiment, the control electrodes 13 are divided into six electrodes, and the emission of light is performed only at some divided sections. In this case, the division number may be set to a most proper number by taking the light emission characteristics of the phosphor 22 and the constitution of the control electrode drive circuit 101 into consideration. However, it is difficult to obtain a light extinction state in which the emission of light is completely stopped at boundary portions between the divided regions, and, hence, it is desirable to surely hold the light emission stop state by dividing the control electrodes 13 into three or more electrodes.
In the flat panel backlight of this embodiment, on the electron beam source panel glass substrate 11, background electrodes having a width of 100 μm are printed at an interval of 20 μm using a silver paste and are baked. Thereafter, the cathodes 12 having a thickness of 5 μm are formed on the background electrodes using a paste containing 10% by weight of carbon fibers. Further, insulation stripes 14, having a width of 40 μm and a height of 40 μm, are formed by focusing on the spacer portions between the cathodes such that the insulation stripes 14 are arranged parallel to the longitudinal direction of the cathodes 12 using a dielectric paste. Onto the insulation stripes 14, the control electrodes 13 are fixed using frit glass. Here, the control electrodes 13 are formed of a thin plate which has opening portions with a diameter of 50 μm over the whole region thereof, to which electrons from the cathodes are emitted. The electron beam source panel 1, which is formed in the above-mentioned manner, is combined with the phosphor screen panel in the same manner as the first embodiment, and the inside thereof is evacuated to create a vacuum state therein.
In driving the flat panel backlight, the control electrodes 13 are set to 0V, and 20 kV is applied to the anodes 23 from the anode power source 105. Since a plurality of cathodes 12 are provided, the cathodes 12 are connected with a cathode drive circuit 102; and, as shown in
The flat panel backlight part 300, which is obtained in the above-mentioned manner, in the same manner as the liquid crystal display device of the first embodiment, in combined with the liquid crystal panel part 400 shown in
First of all, background electrodes 15 having a thickness of 5 μm are formed on the electron beam source panel glass substrate 11 in a stripe pattern such that both the line width and the interval thereof become 30 μm.
Thereafter, a paste containing 10% by weight of carbon nanotubes is printed on every other background electrode 15 and is baked, thus forming carbon nanotube layers 12A having a thickness distribution which has the center thereof at approximately 2 μm. Due to such a constitution, it is possible to obtain an electron beam source panel 1 in which the carbon nanotube layers 12A constitute the cathodes 12 and the electrodes on which the paste is not printed directly constitute the control electrodes 13.
Here, among the group of background electrodes 15 which are arranged in a stripe pattern, it is necessary to use the background electrodes 15 arranged at both sides of the background electrode 15 on which the carbon nanotube layers 12A are formed as the control electrodes 13.
Accordingly, the total number of effective control electrodes 13 and cathodes 12 becomes an odd number. Further, in this embodiment, the difference in height between the control electrodes 13 and the cathodes 12 is generated as a difference in film thickness between the control electrodes 13 and the cathodes 12, including the thickness of the carbon nanotubes. However, it is ideal when the heights of the control electrodes 13 and the cathodes 12 are equal.
When the difference in height between the control electrodes 13 and the cathodes 12 is large, there exists a possibility that an unnecessary diffusion of electron beams is induced, and, hence, it is desirable to set the difference in height between them to a small value. Even when the difference may become large, the difference should be suppressed to approximately the film thickness of either one of the control electrodes 13 and the cathode 12 having the larger thickness. To this end, the formation thickness of the carbon nanotube layer 12 is set to be smaller than the formation thickness of the background electrodes 15.
The obtained electron beam source panel 1, in the same manner as the first embodiment, is bonded to the phosphor screen panel 2 by way of the frame glass 7 and the spacer 8, and the inside thereof is evacuated to create a vacuum. The spacers 8 used in this embodiment are substantially the same as the spacers 8 of the first embodiment shown in
In driving the flat panel backlight, all control electrodes 13 are set to 0V, and 20 kV is applied to the anodes 23 by the anode power source 105. The cathode drive circuit 102 is connected with the anodes 12. To the cathodes 12 which are selected for generating an electron emission, a voltage is applied such that these cathodes 12 assume the same potential as the control electrodes 13, and the cathodes 12 in a non-selected state, which are not allowed to emit the electrons, assume the positive potential (+200V in this embodiment). The cathodes 12 of this embodiment, which are formed by printing a paste which uses the carbon nanotubes 12A as the electron emission material, have characteristics such that the cathodes 12 can obtain the required electron emission strength with an electric field of 3V/μm, which is generated due to the potential difference between the anode 23 and the cathode 12. Required electron emission is obtained from the cathodes 12 in the selected state to which the potential of 0V is applied.
On the other hand, the average electric field between the anodes 23 and the cathodes 12 is shielded by the neighboring control electrodes 13;
The liquid crystal display device is formed by combining the flat panel backlight part 300 having the above-mentioned constitution with the optical scattering plate 3 and the liquid crystal panel part 400 shown in
In this embodiment, in the same manner as the above-mentioned second embodiment, the cathode side is divided in plural numbers. However, in the second embodiment, it is necessary to form the insulation stripes 14 using a dielectric paste which exhibits an inferior printing accuracy, and so it is necessary to manufacture the control electrodes 13 having the opening portions separately. To the contrary, in the liquid crystal display device which adopts the electrode structure of this embodiment, the electrodes can be formed by printing without using a dielectric paste. Accordingly, it is possible to obtain an advantageous effect in that the flat panel backlight part 300 can be manufactured at a lower cost.
It has been known that, in the display of a moving image, by producing a display of high brightness instantaneously and partially, the contrast of the image can be enhanced, and, hence, a viewer can improve the image quality that he/she recognizes. The liquid crystal display device according to the present invention is superior to the related art also with respect to this point.
In the above-mentioned embodiments, as shown in
| Number | Date | Country | Kind |
|---|---|---|---|
| 2003-318207 | Sep 2003 | JP | national |
