JP2003330104A - Self-emission type image display device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a lightweight self-emission type image display device which has a relatively simple constitution, a large screen size, and high resolution, and gives a bright display. <P>SOLUTION: The image display device comprises: a screen 20 provided by mixing a plurality of kinds of phosphors 11, 12, and 13 which are activated with ultraviolet rays of different wavelengths from one another to emit visible light beams of different wavelengths from one another; ultraviolet-ray source systems 31, 32, and 33 which emit all the ultraviolet rays of different wavelengths; one or more spatial optical modulating elements 40 which modulate the ultraviolet rays of the different-wavelengths respectively and transmit or reflect the modulated ultraviolet rays; and an ultraviolet-ray projection optical system 70 which projects the modulated ultraviolet rays on the screen 20. The device displays an image on the screen 20 by using the visible-light emission of the phosphors 11, 12, and 13. <P>COPYRIGHT: (C)2004,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a self-luminous image display device that displays an image on a screen by emitting visible light from a phosphor.

[0002]

2. Description of the Related Art Currently, there is a demand for an ultra-high-definition display that exceeds HDTV for broadcasting, medical, CAD /
It is increasing in display devices for CAM and design,
A display device with high resolution is required. As this display device, a cathode ray tube (CRT), which is a direct-viewing self-luminous display device having the highest resolution at present, is often used.

A CRT is a plasma display (PD
P), a light emitting diode (LED) display, an electroluminescence (EL) display, and the like, as compared with other direct-viewing self-luminous image display devices, good image quality, good color tone, high-speed response, high resolution, and display. It is superior in terms of brightness and low price, and maintains an overwhelmingly high market share. In addition, the full-color display of the CRT is capable of easily realizing multi-gradation and displays an image by scanning with an electron beam, so that the number of connecting contact electrodes is smaller than that of the matrix system. . Furthermore, the CRT can obtain its brightness and contrast relatively sufficiently, and its gradation can be controlled arbitrarily and easily.

On the other hand, in addition to these self-luminous image display devices, various projection display devices have come to be used. The projection type display device is roughly classified into a CRT projection type, a liquid crystal projection type, and a display device using a spatial light modulator (light valve). Among various spatial light modulators,
Di is a semiconductor device in which a large number of minute optical mirrors are arranged.
digital Micromirror Device
(DMD) devices were developed and rapidly spread by Texas Instruments Incorporated in the United States. (L.J.Hom
beck: Current status of th
e digital micromirror dev
ice for projection televis
ion applications, Int. Eect
ronDevices Tech. Dig. pp. 1
5.1.1-15.1.4 (1983). ) This projection type display device is widely used as a projector for presentations and home theaters, in addition to being used in place of a commercial projector using film.

[0005]

However, even with a CRT having a relatively high resolution, the number of pixels, that is, the resolution is insufficient for displaying an ultra-high-definition image exceeding HDTV. In addition, the CRT requires a heavy, thick and thick glass container having sufficient mechanical strength to maintain a high vacuum inside. Since this glass container occupies a large volume mechanically, when manufacturing a large CRT with a large screen, the entire CRT becomes very heavy. Further, the CRT requires a relatively high driving voltage to obtain a bright image for display, and has the drawbacks that the resolution in the peripheral portion of the screen is deteriorated, X-rays are emitted, and there is an influence of geomagnetism. . Further, jitter, flicker, leakage of electromagnetic field, etc. may occur due to deflection scanning of the electron beam. Therefore, there is an increasing demand for a large-sized moving image display as an ultra-high-definition display that surpasses high-definition, but the current full-color CRT display has insufficient resolution and brightness, and also weighs against the size of the screen. There are problems such as being heavy.

On the other hand, a projection type display device which projects an image on a screen using a spatial light modulator, for example, a DMD element, displays an image using a light scattering type projection screen. Therefore, in the projection type display device using the spatial light modulator, the light scattering on the screen is large, and the modulation transfer which is an index of the resolution of the display image.
It is known that the r function (MTF) is worse than that of a CRT which is a direct-view self-luminous display device. In addition, the projection display device has a darker image than the self-luminous display device due to light scattering on the screen. Therefore, the projection type display device using the spatial light modulator has insufficient screen resolution and brightness.

Further, in the projection type display device using the liquid crystal, the light of the lamp light source is transmitted through the liquid crystal and projected on the screen, so that the brightness of the image is dark and the resolution is reduced by the light scattering on the screen. .

Further, in JP-A-2000-180960, a screen coated with a phosphor that emits visible light when excited by ultraviolet rays is provided at a position corresponding to each pixel of the spatial light modulator, and the ultraviolet beam is used as a spatial light modulator. There has been proposed an image display device which is modulated by the method and projected on a screen. However, in this image display device, since three types of phosphors that emit the three primary colors are separately coated on the screen at positions corresponding to the respective pixels of the spatial light modulator, the pixels of the display image become coarse. As described above, the image displayed on the image display device has a problem in terms of brightness and resolution, so that the image display device has not been realized yet.

The present invention has been made in view of the above problems, and provides a self-luminous image display device having a relatively simple structure, a large screen size, a high resolution, a bright display, and a light weight. The purpose is to

[0010]

The invention according to claim 1 is
In a self-luminous image display device that displays an image on a screen by emitting visible light of a phosphor, a plurality of kinds of phosphors that are excited by ultraviolet rays of different wavelengths and emit visible light of different wavelengths are mixed and provided. Screen, an ultraviolet source system for generating all of the ultraviolet rays of different wavelengths, one or more spatial light modulators for transmitting or reflecting the modulated ultraviolet rays of the ultraviolet rays of different wavelengths, and the modulated light. And an ultraviolet ray projection optical system for projecting ultraviolet rays onto the screen.

According to the first aspect of the invention, a screen provided with a mixture of a plurality of types of phosphors that are excited by ultraviolet rays having different wavelengths and emit visible light having different wavelengths, the ultraviolet rays having different wavelengths UV source system for generating all of the above, one or a plurality of spatial light modulators for transmitting or reflecting the modulated ultraviolet rays by respectively modulating the ultraviolet rays of different wavelengths, and ultraviolet rays for projecting the modulated ultraviolet rays on the screen Since the projection optical system is provided, it is possible to provide a self-luminous image display device having a relatively simple configuration, a large screen size, high resolution, bright display, and light weight.

According to a second aspect of the present invention, in the self-luminous image display device according to the first aspect, the plurality of types of phosphors are excited by at least three types of ultraviolet rays having different wavelengths, and visible rays having different wavelengths are excited. It is a phosphor that emits light, and the visible light emitted by the at least three types of phosphors includes red light, green light, and blue light.

According to the second aspect of the present invention, the plurality of types of phosphors are at least three types of phosphors that are excited by ultraviolet rays of different wavelengths and emit visible light of different wavelengths. Since the visible light emitted by at least three kinds of phosphors includes red light, green light, and blue light, a full-color image can be displayed on the screen.

According to a third aspect of the present invention, in the self-luminous image display device according to the first or second aspect, the ultraviolet source system includes lasers that generate ultraviolet rays having different wavelengths.

According to the third aspect of the present invention, since the ultraviolet ray source system has the lasers for generating the ultraviolet rays having the different wavelengths from each other, it is possible to obtain a sufficient amount of the ultraviolet rays and also to emit the monochromatic light of the ultraviolet rays. Can be easily obtained.

According to a fourth aspect of the present invention, in the self-luminous image display device according to the first or second aspect, the ultraviolet source system emits ultraviolet rays having different wavelengths from each other at different wavelengths of the ultraviolet rays. In this case, each of the ultraviolet rays having different wavelengths is individually modulated by the spatial light modulating element.

According to the fourth aspect of the present invention, the ultraviolet source system has an ultraviolet source for individually generating the ultraviolet rays having the different wavelengths for each of the different wavelengths of the ultraviolet ray. The ultraviolet rays having different wavelengths are individually modulated by the spatial light modulator for each ultraviolet ray having different wavelengths, so that a full-color image with higher brightness can be displayed.

According to a fifth aspect of the present invention, in the self-luminous image display device according to the fourth aspect, at least one of the ultraviolet light sources is a laser that emits ultraviolet light having different wavelengths.

According to the invention of claim 5, since at least one of the ultraviolet sources is a laser for generating the ultraviolet rays having different wavelengths from each other, it is possible to obtain a sufficient amount of the ultraviolet rays, and at the same time, it is possible to obtain a monochromatic ultraviolet ray. Light can be easily obtained. it can.

According to a sixth aspect of the present invention, in the self-luminous image display device according to the third or fifth aspect, at least one of the lasers is a semiconductor laser.

According to the sixth aspect of the invention, since at least one of the lasers is a semiconductor laser, the size of the entire image display device can be further reduced.

According to a seventh aspect of the present invention, in the self-luminous image display device according to the sixth aspect, at least one of the semiconductor lasers is a surface emitting laser.

According to the invention of claim 7, at least one of the semiconductor lasers is a surface emitting laser.
You can easily get a sufficient amount of ultraviolet light,
Other optical systems in the image display device can be assembled relatively easily.

According to an eighth aspect of the present invention, in the self-luminous image display device according to the first or second aspect, the ultraviolet source system includes an ultraviolet source that simultaneously generates all of the ultraviolet rays having different wavelengths, and It has a plurality of filters that individually pass the ultraviolet rays of different wavelengths, each of the ultraviolet rays of different wavelengths, through each of the filters that individually transmit the ultraviolet rays of different wavelengths, respectively. It is characterized by being obtained from an ultraviolet ray source.

According to an eighth aspect of the present invention, the ultraviolet source system includes an ultraviolet source that simultaneously generates all of the ultraviolet rays having different wavelengths, and a plurality of ultraviolet rays that individually transmit the ultraviolet rays having different wavelengths. Since each of the ultraviolet rays having different wavelengths has a filter and is obtained from the ultraviolet ray source through each of the filters individually transmitting the ultraviolet rays having different wavelengths, the manufacturing method is simple. It is possible to provide an image display device that is easy to operate.

According to a ninth aspect of the present invention, in the self-luminous image display device according to the fourth or eighth aspect, at least one of the ultraviolet sources is an ultraviolet discharge tube.

According to the invention of claim 9, since at least one of the ultraviolet sources is an ultraviolet discharge tube, the ultraviolet source can be provided at a low cost.

The invention as defined in claim 10 is defined by claim 1 through claim 9.
In the self-luminous image display device according to any one of claims 1 to 3, the display area of the screen is divided into a plurality of divided display areas, and all of the ultraviolet rays having different wavelengths are individually divided into the divided display areas. It is characterized in that it is modulated by a spatial light modulator and is projected individually by the ultraviolet projection optical system for each of the divided display areas.

According to the tenth aspect of the present invention, the display area of the screen is divided into a plurality of divided display areas, and all of the ultraviolet rays having different wavelengths are individually provided in the space for each divided display area. Since the light is modulated by the light modulator and is projected individually by the ultraviolet projection optical system for each of the divided display areas, it is possible to display a high resolution image in each of the divided display areas and the divided display. It is possible to provide a large-screen image display device in which the boundaries of regions are inconspicuous.

[0030]

DESCRIPTION OF THE PREFERRED EMBODIMENTS Next, embodiments of the present invention will be described with reference to the drawings.

The configuration of the first embodiment of the self-luminous image display device of the present invention will be described with reference to FIG. First, the full-color image display device of this embodiment will be described with reference to FIG. The full-color image display device according to the present embodiment is excited by ultraviolet rays having different wavelengths (ranges) from each other, and emits red, green, and blue (three primary colors of light) phosphors (red-emitting phosphor 11 and green-emitting phosphor, respectively). The fluorescent substance 12 and the blue light-emitting fluorescent substance 13 are used). The full-color image display device of the present embodiment includes a screen 20 coated with a mixture of these red-light-emitting phosphor 11, green-light-emitting phosphor 12, and blue-light-emitting phosphor 13, ultraviolet rays of a wavelength (range) that excites each phosphor ( Three UV light sources (each of which is referred to as red light emission UV light, green light emission UV light, and blue light emission UV light) (red excitation UV light source 3).
1. Green excitation ultraviolet source 32, blue excitation ultraviolet source 33
(Hereinafter, referred to as a)), the single spatial light modulator 40 having a plurality of pixels that selectively transmit or reflect the ultraviolet rays. In the present embodiment, the reflective spatial light modulator 40 is used. The ultraviolet source system described in the claims means an aggregate of one or a plurality of ultraviolet sources, and in the present embodiment, for example, the three ultraviolet sources 31, 32, 33.
Is. The ultraviolet projection optical system is an optical system that projects the ultraviolet light modulated by the spatial light modulator on the screen, and is, for example, the projection lens 70 in the present embodiment.

Further, in the full-color image display device of this embodiment, three condenser lenses 51, 52, 5 are provided in order in the optical path from the three ultraviolet sources to the spatial light modulator.
3, having one UV mirror 61 or two UV half mirrors 62, 63, the spatial light modulator 40 and the screen 2
It has a projection lens 70 between 0 and it. The three condenser lenses 51, 52, 53 and the projection lens 70 are made of quartz glass so as to transmit ultraviolet rays.

Here, one condenser lens (51, 52, or 53) is arranged between one ultraviolet source (31, 32, or 33) and the spatial light modulator 40. Further, there is one UV mirror 61 or UV half mirror (62 or 63) on the axis passing through one ultraviolet source (31, 32, or 33) and one condenser lens (51, 52, or 53). Here, the UV mirror 61
As for the arrangement of the UV half mirrors 62 and 63, the two UV half mirrors 6 are arranged in order from the spatial light modulator.
3, 62 and one UV mirror 61 are arranged on the same optical path. UV mirror 61 and UV half mirror 6
2 and 63 are condenser lenses 51 and 52,
UV sources 31, 32, 33 arranged via 53
UV half mirrors 62, 63 that reflect the ultraviolet rays from the
Transmits ultraviolet rays other than the ultraviolet rays from the ultraviolet sources 31 and 32 arranged via the condenser lens.

Next, the operation of the full-color image display device of this embodiment will be described with reference to FIG. In this embodiment, the three ultraviolet light sources 31, 32, 33 are alternately turned on in time series. That is, three ultraviolet sources 31, 32, 3
When one of the three UV light sources is on, the other two UV light sources are off, and the UV light sources to be turned on are sequentially replaced. For example, at the same time as turning on the red excitation ultraviolet source 31,
The green excitation ultraviolet source 32 and the blue excitation ultraviolet source 33 are turned off. Next, the green excitation ultraviolet source 32 is turned on,
The red excitation ultraviolet source 31 and the blue excitation ultraviolet source 33 are turned off. Next, in the same manner, the blue excitation ultraviolet source 33 is turned on, and this is repeated.

The ultraviolet rays emitted from the ultraviolet sources 31, 32, 33 are collimated through the condenser lenses 51, 52, 53, reflected by the UV mirror 61 or the UV half mirrors 62, 63, and the (UV half mirror 62, 63
Illuminate the spatial light modulator 40. Here, since the three ultraviolet light sources 31, 32, and 33 are alternately turned on, the spatial light modulation element 40 receives one of ultraviolet light for red light emission, green light emission, and blue light emission. It is released in sequence.

Ultraviolet rays that excite one phosphor (11, 12, or 13) with which the spatial light modulation element 40 is irradiated, in the spatial light modulation element 40, emit the phosphor (11, 12, or 13).
Alternatively, a color image corresponding to the emitted color of 13) is formed. For example, when the spatial light modulator 40 is irradiated with the red light emitting ultraviolet ray, only the portion of the red light emitting ultraviolet ray forming the red image is modulated so as to be projected toward the screen 20. The same applies to green-emitting ultraviolet light and blue-emitting ultraviolet light.

The ultraviolet light having the image information modulated by the spatial light modulator 40 is magnified by the projection lens 70 and projected on the screen 20. Thus, in the screen 20, the ultraviolet rays excite the phosphors (11, 12 or 13) of the corresponding color to emit light, and a color image of that color is formed on the screen 20. For example, when the red light emitting ultraviolet light modulated by the spatial light modulator 40 is projected onto the screen 20, only the red light emitting phosphor 11 in the portion of the screen 20 forming a red image emits red light. In this way, a red image can be formed on the screen 20. The modulated ultraviolet light for green light emission or ultraviolet light for blue light emission is modulated by the screen 20.
A green image or a blue image is formed in the same manner when the light is illuminated upward. That is, the red light emitting phosphors 11 in the portion corresponding to each color image on the screen 20,
The green light emitting phosphor 12 and the blue light emitting phosphor 13 can be excited and emit light independently of each other.

Ultraviolet rays that excite each of the phosphors 11, 12, and 13 are alternately irradiated in time series, modulated by the spatial modulator 40, and projected onto the screen 20, so that three kinds of phosphors 11, 12 are emitted. 12 and 13 emit light alternately in time series, and three-color images are alternately formed in time series on the screen 20. Here, the lighting of the three ultraviolet light sources 31, 32, 33 and the modulation of the corresponding ultraviolet rays in the spatial light modulator 40 are synchronized. The switching of the three color images on the screen 20 is so fast that the human eyes cannot recognize the switching, and the observer overlaps the red image, the green image and the blue image on the screen 20. Observe the full-color image.

Next, the phosphor and screen used in the present invention will be described in detail with reference to FIG. The self-luminous image display device of the present invention uses three types of phosphors that are excited by ultraviolet light and emit light of the three primary colors (red, green, and blue) of the additive light. The three types of phosphors are excited by ultraviolet light having wavelengths (ranges) different from each other.

FIG. 2 shows an excitation spectrum and an emission spectrum when Y ₂ O ₃ is used as a base material, as an example of the material of the phosphor coated on the screen of the self-luminous image display device of the present invention. 2A to 2C, the horizontal axis represents wavelength (nm) and the vertical axis represents relative emission intensity. FIG. 2A shows a phosphor (Y) doped with Eu.
₂ O ₃ : Eu) excitation spectrum (200 to 450 n)
m) and emission spectrum (450-700 nm),
(B) is an Er-doped phosphor (Y ₂ O ₃ : Er)
Excitation spectrum (200 nm to 450 nm) and emission spectrum (450 to 700 nm), (c) shows that the phosphor doped with Tm is (Y ₂ O ₃ : Tm) excitation spectrum (200 to 400 nm) and emission spectrum (400).
.About.500 nm).

From the emission spectra of FIGS. 2 (a) to 2 (c), when each phosphor is excited by an appropriate ultraviolet ray, Y of FIG.
₂ O ₃ : Eu is red light (611 nm), (b) Y ₂ O
₃ : Er is green light (563 nm), Y ₂ O _{3 in} (c):
It can be seen that Tm emits blue light (453 nm).

From the excitation spectra of FIGS. 2 (a) to 2 (c), the wavelength of the main ultraviolet rays exciting the respective phosphors of (a) to (c) is Y ₂ O ₃ of (a): 253 nm for Eu (red), Y ₂ O ₃ : Er of (b)
380 nm for (green), Y ₂ O ₃ : T of (c)
It is 362 nm for m (blue). In this way, since the wavelengths (ranges) of ultraviolet rays that excite each phosphor are independent of each other, by using monochromatic light having the excitation wavelength for each phosphor as the excitation light of the phosphor, each phosphor (red The phosphors that emit light, green light, and blue light) can be excited independently to emit light. Therefore, full-color image formation can be realized by using these phosphors and monochromatic light of each excitation wavelength.

In the present invention, a mixture obtained by mixing the phosphors emitting red light, green light and blue light in an appropriate ratio is applied uniformly over the entire screen. The mixing ratio of each phosphor is determined by the luminous efficiency of each phosphor. Therefore, unlike the conventional CRT, it is not necessary to separately apply the phosphors in stripes or dots for each phosphor that emits red light, green light, and blue light, and the structure and configuration of the screen is very simple. In addition, the screen manufacturing process is significantly simplified.

Also, unlike the image display device disclosed in Japanese Patent Laid-Open No. 2001-180960, it is not necessary to separately paint three types of phosphors that emit three primary colors on the screen. Accordingly, in the present invention, since three types of phosphors are not arranged to form pixels on the screen, the resolution of the image is not limited by the screen, and a high-resolution full-color image display device can be provided. it can. Similarly, the three types of phosphors are not arranged, and the phosphors coated on the entire screen are used to form and superimpose each color image, so that a full-color image display device with bright display can be provided.

The emission of the phosphor used in the present invention is
Unlike the light emission (cathode luminescence) accompanied by the excitation of the phosphor by the electron beam of the CRT (cathode luminescence), the light emission (photoluminescence) is accompanied by the excitation (photoexcitation) of the phosphor by the ultraviolet rays. (Note that the projection display only projects light and does not use luminescence.) Therefore, a vacuum unlike the conventional CRT is not necessary, and light emission can be obtained even in a gas at atmospheric pressure. As a result, in the image display device of the present invention, it is not necessary to use a thick and thick glass container having sufficient mechanical strength and airtightness for holding a vacuum. Since the airtightness of the entire display device can be maintained with a material having a mechanical strength that can hold a gas at atmospheric pressure and a light weight, for example, a lightweight material such as plastic, an image display that is much lighter than a CRT A device can be provided. Therefore, it is possible to increase the size of the entire image display device safely and at low cost.

In addition, in the present invention, instead of scanning the face plate with an electron beam using a magnetic deflection yoke in a CRT,
For scanning the screen with ultraviolet light, for example, a spatial light modulator using a minute reflecting mirror or reflecting surface is used. Conventionally, the spatial light modulation element used for the projection type image display device has been used for the projection of visible light. The spatial light modulator used in the present invention may be an element having any structure, whether it is a transmission type or a reflection type, as long as it is an element capable of two-dimensionally modulating ultraviolet light.

As a spatial light modulator currently available and most suitable for the present invention, a digital micromirror device (DMD) element can be mentioned. However, in order to use a conventional spatial light modulator, for example, a DMD element in the ultraviolet range, it is necessary to remove the glass cover on the DMD element or change to a quartz glass cover that transmits ultraviolet rays. By using the spatial light modulation element improved for this ultraviolet ray, it becomes possible to project the ultraviolet ray on the screen.
In DMD element, input pulse width (time width)
The high-precision control of gradation (gray scale) is performed by the on / off operation of the micromirror by the modulation of.

The conventional projection type display device using the DMD element is not a direct-view type because it projects visible light rays onto a projection screen to display an image, and the projection light is limited to visible light. However, in the image display device of the present invention, ultraviolet rays are projected on the screen to excite the phosphors on the screen and directly emit them. That is,
The full-color image display device of the present invention is a direct-view image display device capable of directly seeing the image formed by the light emission of the phosphor on the screen without projecting the image on the projection screen. Further, in the present invention, since the phosphor is directly made to emit light on the screen to form an image, the device is a self-luminous image display device like the CRT. It goes without saying that the image display device of the present invention can display both moving images and still images.

Further, although the image display device of the present invention uses ultraviolet light, the wavelength of ultraviolet light is shorter than the wavelength of visible light, so that the diameter of the ultraviolet light beam projected on the screen can be made extremely small. Further, the image display device of the present invention utilizes the light emission of the phosphor and does not utilize the light scattering unlike the conventional projection display device. In addition, since the ultraviolet absorption rate of the phosphor is high, it is possible to reduce light scattering on the screen, which is a problem of the conventional projection display device. Therefore, it is possible to prevent a decrease in MTF, which is a problem of the conventional projection display device. As a result, the full-color image display device of the present invention can display an image having a higher resolution than the image of the conventional image display device using light scattering.

As the ultraviolet ray sources 31, 32, 33 used in the full-color image display device of this embodiment, it is conceivable to use a semiconductor laser or the like which emits ultraviolet rays. recent years,
It has become possible to obtain a solid-state laser that efficiently emits intense and continuous ultraviolet light. The laser can obtain a sufficient amount of ultraviolet rays, and can easily obtain monochromatic light of ultraviolet rays included in the wavelength range for exciting the phosphor. Further, since semiconductor lasers have been downsized, a plurality of semiconductor lasers can be used for all of the ultraviolet light sources that emit the ultraviolet light that excites the three phosphors, and the image display device can be made more compact. can do.

Among the semiconductor lasers, it is particularly preferable to use a surface emitting laser as the ultraviolet source of the present invention.
The surface emitting laser is a laser that emits ultraviolet light in a vertical direction (surface emission) from a surface-shaped element, unlike a normal laser that emits a single laser beam. Since the surface-emitting laser emits light over a wider area than an ordinary laser, it is possible to easily obtain a sufficient amount of ultraviolet rays by oscillating the laser. Further, since light is emitted from a relatively large area, other optical systems in the image display device such as a condenser lens and a UV (half) mirror can be assembled relatively easily. In the present embodiment, the ultraviolet sources 31, 32,
It is also possible to use an ultraviolet discharge tube (ultraviolet lamp) for 33. The ultraviolet discharge tube generates ultraviolet rays of continuous wavelength from the gas enclosed by the discharge. Therefore, when the ultraviolet discharge tube is used in the present embodiment, it is necessary to obtain a monochromatic light of ultraviolet rays by using a filter that transmits ultraviolet rays that excite the phosphor.

In the full-color image display device of this embodiment, the phosphors 11 and 1 for the three primary colors of light (red, green and blue) are used.
Three UV sources 31, 3 for exciting 2 and 13 respectively
2, 33, and three ultraviolet sources 31, 32, 33 and the spatial light modulation element 40 need to be synchronized, but one spatial light modulation element 40 is used for image color (emission of the phosphors 11, 12, 13). It is possible to provide an image display device that displays an image with good image quality, good color tone, and high MTF value by controlling color) and gradation.

Next, a second embodiment of the full-color image display device of the present invention will be described with reference to FIG. First, the configuration of the full-color image display device of this embodiment will be described with reference to FIG. Also in the full-color image display device of the present embodiment, as in the first embodiment, one spatial light modulation element 40, a projection lens 70 made of quartz glass, a red light emitting phosphor 11, a green light emitting phosphor 12, The screen 20 coated with the mixture of the blue light emitting phosphors 13 is used, and the projection lens 7 is provided between the spatial light modulator 40 and the screen 20.
Place 0.

However, the full-color image display device of this embodiment uses only one ultraviolet source 30.
The ultraviolet light source 30 emits all ultraviolet light having a wavelength (range) capable of exciting three types of phosphors (red light emitting phosphor 11, green light emitting phosphor 12, and blue light emitting phosphor 13). For example, there is an ultraviolet discharge tube (ultraviolet lamp) that emits ultraviolet light in a wide band including wavelengths (ranges) that excite three kinds of phosphors 11, 12, and 13. The ultraviolet discharge tube is a most easily available and inexpensive ultraviolet source, though it outputs a smaller amount of ultraviolet light than a laser.

Two condenser lenses 5 made of quartz glass are provided in the ultraviolet light source 30, the spatial light modulator 40 and the optical path.
A rotary disk 90 in which 1, 52 are arranged, and three band pass filters 81, 82, 83 which transmit ultraviolet rays are incorporated between the two condenser lenses 51, 52.
Is provided. Three bandpass filters 81, 82,
Reference numeral 83 denotes a filter that selectively transmits only red light emission ultraviolet light, green light emission ultraviolet light, and blue light emission ultraviolet light (referred to as a red light emission filter 81, a green light emission filter 82, and a blue light emission filter 83, respectively). Do)
Is. Each of the three filters 81, 82, 83 is evenly provided on the rotating disk 90 at an angle. The center of the rotating disk 90 is separated from the optical paths of the two condenser lenses 51 and 52 by a necessary amount. Further, in the rotating disc 90, all the ultraviolet rays emitted from the ultraviolet source 30 and transmitted through the first condenser lens 51 are integrated into the rotating disc 90 by one filter (8).
1, 82 or 83) and is incident on the second condenser lens 52. In this embodiment, the UV half mirror and the UV mirror are not always necessary.

Next, the operation of the full-color image display device of this embodiment will be described with reference to FIG. In this embodiment, when displaying an image, one ultraviolet source 30 is continuously turned on. Broad band ultraviolet light including all of red light emitting UV light, green light emitting UV light, and blue light emitting UV light passes through the first condenser lens 51 and is one filter (81, 82, or 83) incorporated in the rotating disk. Converge towards. The converged broadband ultraviolet rays are
It is transmitted through the filter (81, 82, or 83). At this time, the filter (81, 8
2 or 83), only the ultraviolet rays of the wavelength (range) selectively transmitted by 2) enter the second condenser lens.
For example, when passing through the red light emission filter, only the red light emission ultraviolet rays enter the second condenser lens 52.

The ultraviolet rays of the wavelength (range) selected by the filter (81, 82, or 83) are collimated by the second collimator lens 52 and are applied to the spatial light modulator 40. In the spatial light modulator 40, a phosphor (11, 1) excited by ultraviolet rays having a wavelength (band) selected by the filter (81, 82, or 83).
2 or 13) to form a color image corresponding to the emitted color. The ultraviolet light having the image information modulated by the spatial light modulator 40 is magnified by the projection lens 70 and projected on the screen 20 as in the first embodiment. Thereby, in the screen 20, the phosphor (11, 12, or 13) of the corresponding color is generated by the ultraviolet rays.
Are excited to emit light, and an image of that color is formed on the screen 20. That is, in the present embodiment, by rotating the rotating disk 90 incorporating the three band pass filters 81, 82, 83, the three types of phosphors 11, 12, 13 are excited individually in a time division manner. And can emit light.

Here, the rotary disk 90 is rotated at a constant speed. Further, the rotation of the rotating disk 90 and the formation of the corresponding color image in the spatial light modulator 40 are synchronized. When the rotating disk 90 is rotated, the broadband ultraviolet rays emitted from the ultraviolet source 30 are emitted from the rotating disk 9
The three filters 81, 82, 83 incorporated in 0 are alternately transmitted in time series. Therefore, the spatial light modulation element 40 is alternately irradiated with one of the ultraviolet rays for red light emission, the ultraviolet ray for green light emission, and the ultraviolet ray for blue light emission in chronological order as the rotating disk 90 rotates. Here, the spatial light modulation element 40 is controlled so that the ultraviolet rays that are alternately emitted are excited by the phosphors (11, 12,
Alternatively, a red image, a green image, or a red image is displayed on the screen 20 by modulating a color image corresponding to the emitted color of 13).
Blue images can be formed alternately in time series.

For example, when broadband ultraviolet rays pass through the red light emission filter 81, the spatial light modulation element 40 is irradiated with red light emission ultraviolet rays to form a red image. Next, when the rotary disc 90 is rotated by 120 °, a wide band of ultraviolet rays passes through the green light emitting filter 82, and the spatial light modulation element 40 is irradiated with green light emitting ultraviolet rays to form a green image. Subsequently, when the rotating disk is rotated by 120 °, the ultraviolet light in the wide band passes through the blue light emitting filter 83, the spatial light modulation element 40 is irradiated with the blue light emitting ultraviolet light, and a blue image is formed.

In this way, the image radiated to the spatial light modulation element 40 by using the rotating disk 40 is switched between the red light emitting ultraviolet light, the green light emitting ultraviolet light, and the blue light emitting ultraviolet light, as in the first embodiment. Screen 20
A red image, a green image, and a blue image are formed alternately and at high speed to obtain a full-color image.

In the full-color image display device of this embodiment, the rotary disc 90 in which the three bandpass filters 81, 82, and 83 are incorporated, and the rotary disc 90 and the spatial light modulator 40 need to be synchronized, but the ultraviolet light source is used. Only one of 30 and the spatial light modulator 40 is required. Also UV
No need to use mirrors or UV half mirrors. Therefore, it is possible to realize a full-color image display device having a simple structure and easy to manufacture.

Next, a third embodiment of the full-color image display device of the present invention will be described with reference to FIG. First, the full-color image display device of this embodiment will be described with reference to FIG. Also in the full-color image display device of this embodiment, the screen 20 coated with the mixture of the red light emitting phosphor 11, the green light emitting phosphor 12, and the blue light emitting phosphor 13 is used.

In the present embodiment, there are three ultraviolet sources such as a red excitation ultraviolet source 31, a green excitation ultraviolet source 32, and a blue excitation ultraviolet source 33 such as an ultraviolet laser, red emission ultraviolet light, green emission ultraviolet light, and blue emission light. Three spatial light modulators for modulating each of the ultraviolet light for use in the space (respectively, a red light spatial light modulator 41, a green light spatial light modulator 42,
A blue light emitting spatial light modulator 43) is used. Also, three condenser lenses 51, 52, 53 and three projection lenses 71, 7 made of quartz glass are used.
Use 2, 73. Three condenser lenses 51,
Each of 52 and 53 includes one spatial light modulator (41, 4 or 4) corresponding to one ultraviolet source (31, 32, or 33).
2 or 43) in the optical path. Each of the three projection lenses (71, 72, or 73) includes one spatial light modulator (41, 42, or 43) and the screen 2.
It is arranged in the optical path between 0 and 0.

Next, the operation of the full-color image display device of this embodiment will be described with reference to FIG. In this embodiment,
When displaying an image, three ultraviolet light sources 31, 32, 33
All are continuously lit. Three UV sources 3
The ultraviolet light emitted from each of 1, 32, and 33 is collimated by a collimator lens (51, 52, or 53), and one optical spatial modulator (41, 42, 42) in the optical path is formed.
Or 43). The spatial light modulator (41,
At 42 or 43), the irradiated ultraviolet light is modulated into a color image corresponding to the color of the phosphor (11, 12 or 13) excited by the ultraviolet light. The modulated ultraviolet light having image information is transmitted through one projection lens (71, 71) in the optical path.
72 or 73) enlarges and projects the entire screen 20. As a result, the phosphor (11, 12, or 13) excited by the ultraviolet rays can be caused to emit light, and a color image of the color emitted by the phosphor (11, 12, or 14) can be formed. Here, each of the three projection lenses 71, 72 and 73 has three spatial light modulation so that the ultraviolet light modulated by the spatial light modulation element (41, 42 or 43) may land on the screen 20. The red image, the green image, and the blue image formed by the ultraviolet rays modulated by the elements 41, 42, and 43 are arranged so that they overlap to form one full-color image.

Specifically, the red light emitting ultraviolet light emitted from the red exciting ultraviolet light source 31 is emitted from the condenser lens 5
1, the red light emitting spatial light modulating element 41 is irradiated and modulated, and is projected onto the screen 20 through the projection lens 71. Based on the modulation, the red light emitting phosphor 11 is excited to emit light, and the screen is displayed. 20 to form a red image. Similarly, the green light emitting ultraviolet light emitted from the green light emitting ultraviolet light source 32 is emitted from the green light emitting spatial light modulator 42.
And is modulated to form a green image on the screen 20. The blue light emitting ultraviolet light emitted from the blue excitation ultraviolet light source 33 is emitted by the blue light emitting spatial modulator 43.
And is modulated to form a blue image on the screen 20.

Here, three ultraviolet sources 31, 32, 33
Emits ultraviolet light for red light emission, ultraviolet light for green light emission, and ultraviolet light for blue light emission at the same time and continuously, and the spatial light modulator 41 for red light emission, the spatial light modulator for green light emission 42, and the spatial light modulator for blue light emission are generated. The element 43 can modulate the simultaneously irradiated ultraviolet rays based on the red image signal, the green image signal, and the blue image signal which are simultaneously input to each of them, and project the ultraviolet rays onto the screen 20 at the same time. Therefore, on the screen 20, the red light emitting phosphor 11, the green fluorescent light emitting body 12, and the blue fluorescent light emitting body 13 simultaneously emit light based on the modulated ultraviolet rays, and a red image, a green image, and a blue image are simultaneously formed. Full color images can be displayed. As described above, since the red image, the green image, and the blue image are formed at the same time, the full-color image display device according to the present embodiment has a full-color image with a brightness three times or more that of the first and second embodiments. Images can be displayed.

In this embodiment, the ultraviolet sources 31, 32, 3 are used.
3, spatial light modulators 41, 42, 43, condenser lenses 51, 52, 53, and projection lenses 71, 72, 7
It is necessary to arrange three for each of the three lenses, and it is necessary to arrange the three projection lenses 71, 72, and 73 at accurate positions with respect to the screen 20, but the UV mirror and the UV half mirror are not necessarily required, and the light space modulation is performed. Elements 41, 42, 43
There is no need to synchronize the UV source with other elements such as a rotating disc incorporating a filter or a filter. In addition, this embodiment can display a full-color image with higher brightness than the first and second embodiments.

Next, a fourth embodiment of the full-color image display device of the present invention will be described with reference to FIG.

In the image display device of the present invention, the resolution of the image is determined mainly by the size of the particles of the applied phosphor, the wavelength of the ultraviolet rays, and the number of pixels of the spatial light modulator (eg, in the case of DMD, the value of Number) etc. In particular, when ultraviolet rays of a specific wavelength are used and phosphor particles are uniformly applied to the screen, the resolution of the image is determined by the number of pixels of the spatial light modulator. Currently, the maximum number of pixels of DMD elements is 2048 × 1152. As a further high-resolution image display device, as shown in FIG. 5 below, there is an image display device that displays a full-color image for each screen of a screen 20 divided into a plurality of areas, optionally independently or in association with each other. .

FIG. 5 shows an image display device in which the display area of the screen 20 is divided into four equal areas, as an example of the image display apparatus in which the display area of the screen 20 is divided. Here, for simplification, an area obtained by dividing the display area of the entire screen into a plurality of areas will be appropriately referred to as a divided display area. These divided display areas 21, 22, which are evenly divided into four,
23, 24 are illuminated with ultraviolet light that excites the phosphor to emit light to form four full color images, optionally independently or in association.

The image display apparatus for forming a full-color image on each of the divided display areas 21, 22, 23, and 24 of the screen 20 in this embodiment is almost the same as that of the first embodiment, but three ultraviolet light sources 31 are used. , 32, and 33 that irradiate the three types of phosphors are excited by four sets of 12 mirrors (11 UV half mirrors and 1 UV mirror) 60, and four spatial light beams. Modulation elements 41, 42,
43 and 44 are irradiated. Spatial light modulators 41, 42,
The ultraviolet rays applied to 43 and 44 are modulated in the same manner as in the first embodiment, and the spatial light modulators 41, 42, 43 and 4 are emitted.
4 and the projection lens 7 provided between the screen 20
1, 72, 73, 74, the corresponding four divided display areas 21, 22, 23, 24 of the screen 20.
Projected on. Therefore, three UV sources 31, 32, 3
Emission of ultraviolet light from 3 and four spatial light modulators 41, 4
By synchronizing the control of Nos. 2, 43, and 44 in the same manner as in the first embodiment, the four divided display areas 2 are divided.
For each 1, 22, 23, 24, a full-color image can be displayed, independently or associated with each other.

As described above, the ultraviolet rays are modulated by the corresponding spatial light modulators and projected onto each of the display areas divided into a plurality of areas, and the resolution is multiplied by the number of spatial light modulators. The image of can be displayed. That is, as shown in FIG. 5, the area of the screen is divided into four, and the four spatial light modulators 41, 42, 4 are formed.
When ultraviolet rays are modulated by 3 and 44 and projected, a self-luminous type capable of displaying an image having a resolution four times as high as that of an image projected by using one spatial light modulator 40 shown in FIG. A display device can be provided.

Further, the image display device of the present embodiment displays a high-resolution image to form a large-screen image, independently or in association with each other, for each of a plurality of divided display areas on the screen. can do.

In a conventional large-screen image display device having a high resolution, it has been actively attempted to mechanically bond a plurality of display panels. However, when a plurality of display panels are simply mechanically bonded together, the boundary part of the bonding becomes conspicuous and the image quality is deteriorated. In the present invention, a display panel (screen)
As shown in FIG. 5, the display area of one large screen is divided into a plurality of areas, and each of the divided display areas is exposed to ultraviolet light by an individual spatial light modulator, as shown in FIG. Modulate and project.

As described above, in the present invention, a large single screen is used, and since the ultraviolet rays projected from the adjacent projection lenses overlap at the boundaries of the divided areas, the divided display on the screen is performed. It is possible to display a large image with significantly high image quality and high resolution without making the boundaries of the regions conspicuous. In particular, the full-color image display device according to the present embodiment is suitable for displaying a large screen image having a diagonal size of, for example, 40 inches or more.

The full-color image display device of the present invention has various advantages as described below as compared with the CRT. (1) The resolution and the limit brightness of a display image mainly depend on the spatial light modulator, and if a spatial light modulator such as a DMD device having a large number of pixels is developed in the future, the resolution of the human eye and the present stage There is a possibility that it is possible to realize an image display device that exceeds the brightness of any display device in. (2) Since no vacuum is required, the weight of the entire device can be reduced. (3) Pollution-free and environmentally friendly. (4) There is no limit to the size of the screen. (5) The screen and the projection unit can be separately configured, and a portable or flexible image display device can be manufactured. (6) It is not necessary to replace the entire CRT electron gun due to the life of the electron gun, and it is possible to replace only the ultraviolet source and the spatial light modulator. (7) A multi-screen without boundaries can be assembled. (8) It is safe without generating X-rays or using a high voltage power supply. (9) Not affected by geomagnetism.

Further, the full-color image display device of the present invention has various advantages as described below as compared with the visible light projection type display using the spatial light modulator. (1) Light scattering by the screen is small, and a high-resolution image with a high MTF value can be obtained. (2) No flicker on the screen and little eye strain on the observer. (3) There is no directivity from the screen. (4) Not polarized.

Further, the full-color image display device of the present invention has a screen in which a phosphor is applied at a position corresponding to each pixel of the spatial light modulator, and an ultraviolet beam is modulated by the spatial light modulator and projected on the screen. Conventional method
-180960) has the following features as compared with the photoluminescent display. (1) Moire that occurs due to the relationship between the number of pixels of the spatial light modulator and the number of dots (stripe) of the phosphor does not occur. (2) It is not necessary to separately coat the phosphors of the three primary colors, the screen structure is simple and inexpensive, and there is no limitation in resolution due to the separate coating of the phosphors. (3) It is not necessary to dispose the phosphors of the three primary colors on a plane,
It is possible to easily realize screens of various shapes. (4) There is no color shift due to mislanding of the ultraviolet beam. (5) No color drift due to temperature change. (6) The utilization efficiency of the excitation ultraviolet light is high and the brightness is high. (7) The color tone does not depend on the distance between the observer and the screen.

The self-luminous image display device of the present invention has been described above with reference to some embodiments, but the present invention is not limited to these embodiments, and the gist and scope of the present invention are not limited thereto. It goes without saying that combinations of these embodiments and various modifications and applications can be made without departing from the scope. For example, by combining a plurality of self-luminous image display devices according to the first, second, or third embodiments of the present invention, a large-screen image display including a plurality of divided areas as shown in the fourth embodiment is displayed. The device may be formed. Further, in the embodiment of the present invention, three kinds of phosphors are used, but four or more kinds of phosphors may be used in order to adjust the color tone of the emitted primary color. Therefore, the number of components such as the ultraviolet light source, the spatial light modulator, the projection lens, and the filter can be increased as necessary. For example, in the second embodiment of the present invention, one ultraviolet light source is used, but if the brightness is insufficient, a plurality of the same ultraviolet light sources may be used. Further, in the embodiment of the present invention, the ultraviolet projection optical system is the projection lens, but it goes without saying that it may include elements other than the lens.

[0080]

According to the present invention, with a relatively simple structure,
Large screen size, high resolution, bright display,
It is possible to provide a lightweight self-luminous image display device.

[0081]

[Brief description of drawings]

FIG. 1 is a diagram illustrating a configuration of a first embodiment of a color image display device of the present invention.

FIG. 2 shows Y ₂ O ₃ as a base material as a material example of a phosphor applied to a screen of a full-color image display device of the present invention.
It is a figure which shows the excitation spectrum and emission spectrum at the time of using.

FIG. 3 is a diagram illustrating the configuration of a second embodiment of the color image display device of the present invention.

FIG. 4 is a diagram illustrating a configuration of a third embodiment of a color image display device of the present invention.

FIG. 5 is a diagram illustrating a configuration of a fourth embodiment of a color image display device of the present invention.

[Explanation of symbols]

11, 12, 13 Phosphor 20 Screen 21, 22, 23, 24 Divided display areas 30, 31, 32, 33 Ultraviolet light sources 40, 41, 42, 43, 44 Spatial light modulators 51, 52, 53 Condenser lens 60, 61, 62, 63 UV mirror or UV half mirror 70, 71, 72, 73, 74 Projection lens 81, 82, 83 Filter 90 Rotating disk

   ─────────────────────────────────────────────────── ─── Continued front page    F-term (reference) 2H021 BA21                 2K103 AA01 AA07 AA14 AA17 AB04                       BA11 CA01                 5C058 BA05 BA23 BA25 EA01 EA11                       EA12 EA14 EA27 EA32

Claims (10)

[Claims] 1. A screen provided with a mixture of a plurality of types of phosphors that are excited by ultraviolet rays of different wavelengths and emit visible light of different wavelengths, an ultraviolet source system that generates all the ultraviolet rays of different wavelengths, An ultraviolet projection optical system for projecting the modulated ultraviolet rays onto the screen, and one or a plurality of spatial light modulators for transmitting or reflecting the modulated ultraviolet rays respectively modulating the ultraviolet rays having different wavelengths. A self-luminous image display device characterized in that an image is displayed on the screen by the emission of the visible light of the phosphor. 2. The plurality of types of phosphors are at least three types of phosphors that are excited by ultraviolet rays of different wavelengths to emit visible light of different wavelengths, and the at least three types of phosphors emit light. The self-luminous image display device according to claim 1, wherein the visible light includes red light, green light, and blue light. 3. The self-luminous image display device according to claim 1, wherein the ultraviolet light source system includes lasers that generate ultraviolet light having different wavelengths. 4. The ultraviolet source system has an ultraviolet source that individually generates ultraviolet rays having different wavelengths from each other for each of the different wavelengths of the ultraviolet ray, and the ultraviolet rays having different wavelengths from each other, The self-luminous image display device according to claim 1 or 2, wherein each of the ultraviolet rays having different wavelengths is individually modulated by the spatial light modulator. 5. The self-luminous image display device according to claim 4, wherein at least one of the ultraviolet light sources is a laser which generates ultraviolet light having different wavelengths. 6. The self-luminous image display device according to claim 3, wherein at least one of the lasers is a semiconductor laser. 7. At least one of the semiconductor lasers comprises:
The self-luminous image display device according to claim 6, which is a surface emitting laser. 8. The ultraviolet source system includes an ultraviolet source that simultaneously generates all of the ultraviolet rays having different wavelengths, and a plurality of filters that individually transmit the ultraviolet rays having different wavelengths. 3. The self-luminous image according to claim 1, wherein the ultraviolet rays having different wavelengths are obtained from the ultraviolet ray source through the respective filters individually transmitting the ultraviolet rays having different wavelengths. Display device. 9. The self-luminous image display device according to claim 4, wherein at least one of the ultraviolet sources is an ultraviolet discharge tube. 10. The display area of the screen is divided into a plurality of divided display areas, and all of the ultraviolet rays having different wavelengths are individually modulated by the spatial light modulator for each of the divided display areas, 10. The ultraviolet projection optical system individually projects each of the divided display areas.
The self-luminous image display device according to claim 1.