Display device employing ultraviolet-beam scanning and color separator

Information

  • Patent Grant
  • 6329966
  • Patent Number
    6,329,966
  • Date Filed
    Thursday, October 10, 1996
    28 years ago
  • Date Issued
    Tuesday, December 11, 2001
    23 years ago
Abstract
A display device scans a phosphor screen with three independently modulated ultraviolet beams. The screen is coated with three types of light-emitting phosphor dots, each emitting a different color of visible light when illuminated by ultraviolet light. A color separator such as an aperture mask or lens array directs each ultraviolet beam onto phosphor dots of one of these three types. Two or more of these display devices can be combined to obtain a larger screen size.
Description




BACKGROUND OF THE INVENTION




The present invention relates to a display device that scans a color phosphor screen with a laser beam.




Display devices of this type can display video and other color images similar to those displayed by a conventional cathode-ray tube. The advantage of scanning a color phosphor screen with a laser beam is that a laser beam does not require a large, evacuated glass tube for propagation. Issues must be addressed, however, in these display devices relating to modulating the laser beam and separating of the different colors in the display.




U.S. Pat. No. 5,003,179 describes a display device in which the intensities of three infrared laser beams are independently modulated, the intensity of each beam being selectively blanked to illuminate only phosphors which produce light of the desired color. Such a display device has drawbacks, however, because the need for selectively blanking light beams intensities is inconvenient.




Japanese Patent Kokai Publication No. 323686/1992 describes a display device that modulates the intensity of a single laser beam, which illuminates red, green, and blue phosphors. This system requires that the beam be modulated at three times the normal rate, and is inconsistent with conventional video signal processing.




Japanese Patent Kokai Publication No. 323686/1992 discloses a display device that scans a phosphor screen with a single ultraviolet beam, which is generated by converting the wavelength an infrared laser beam. This system is similarly inconsistent with conventional video signal processing.




SUMMARY OF THE INVENTION




It is accordingly an object of the present invention to display an image by scanning a screen with ultraviolet beams modulated by conventional red, green, and blue video signals.




Another object of the invention is to improve color separation in the displayed image.




A further object is to improve the brightness of the displayed image.




A still further object is to obviate the need for blanking of the ultraviolet beams.




The invented display device has a transparent screen coated with three types of phosphors. When illuminated by ultraviolet light, each type of phosphor emits visible light of a different color. The display device also has a light source for producing three beams of ultraviolet light, three modulating means for independently modulating the intensity of these three ultraviolet beams, a scanning means for scanning the three ultraviolet beams across the transparent screen in a two-dimensional pattern, and a color separator disposed between the scanning means and transparent screen, for directing the three ultraviolet beams onto phosphors of the respective types on the transparent screen.




The light source comprises, for example, three infrared lasers and a wavelength conversion means. The color separator comprises, for example, an aperture mask, or a lens array. The scanning means comprises, for example, a pair of movable mirrors, or a pair of acousto-optic elements.




A filter that transmits ultraviolet light but reflects visible light may be provided between the color separator and the transparent screen to improve the brightness of the display. A focusing lens may also be provided, to focus the three ultraviolet beams.




Two or more of the invented display devices can be combined to form a display apparatus with a larger screen size.











BRIEF DESCRIPTION OF THE DRAWINGS




In the attached drawings:





FIG. 1

illustrates a display device according to a first embodiment of the invention;





FIG. 2

illustrates an acousto-optic element employed in the scanning means in

FIG. 1

;





FIG. 3

illustrates the aperture mask, phosphor coating, and transparent screen in

FIG. 1

;





FIG. 4

illustrates a lens array in a display device according to a second embodiment of the invention;





FIG. 5

illustrates the screen assembly in a display device according to a third embodiment of the invention;





FIG. 6

illustrates the screen assembly in a display device according to a fourth embodiment of the invention;





FIG. 7

illustrates a display device according to a fifth embodiment of the invention;





FIG. 8

illustrates the screen assembly in the fifth embodiment;





FIG. 9

illustrates a display device according to a sixth embodiment of the invention;





FIG. 10

illustrates a display device according to a seventh embodiment of the invention; and





FIG. 11

illustrates a display apparatus according to an eighth embodiment of the invention.











DETAILED DESCRIPTION OF THE INVENTION




Embodiments of the invention will be described with reference to the attached illustrative drawings.




Referring to

FIG. 1

, a first embodiment of the invention is a display device


10


comprising three yttrium-aluminum-garnet (YAG) laser light sources


1


, three non-linear optical elements


2


such as potassium-titanate-phosphate crystals serving as wavelength conversion means, three acousto-optic modulators


3


, a scanning mechanism


4


having a horizontal scanning mirror


4




a


and a vertical scanning mirror


4




b,


an aperture mask


5


serving as a color separator, and a transparent screen


7


with a phosphor coating


6


. The aperture mask


5


, phosphor coating


6


, and transparent screen


7


form a screen assembly


8


. The scanning mechanism


4


and acousto-optic modulators


3


are controlled by a controller


9


.





FIG. 2

illustrates the structure of one of the acousto-optic modulators


3


in more detail. This acousto-optic modulator


3


comprises an acoustic medium


18


such as a crystal of tellurium oxide (TeO


2


) or lead molybdenide (PbMo


4


), or a glassy material such as fused quartz (SiO


2


), tellurite glass, or chalcogenide glass, to which an ultrasonic resonator


19


is attached. The ultrasonic resonator


19


is linked to the controller


9


by a signal line


20


, and generates ultrasonic waves


21


in the acoustic medium


18


with an intensity controlled by the controller


9


. Incident light


22


is partially diffracted by the ultrasonic waves


21


, so that a diffracted beam


23


and non-diffracted beam


23




a


emerge.




The operation of the display device


10


can be described as follows.




The three YAG laser light sources


1


emit three coherent beams


11




a,




11




b,


and


11




c


of infrared light with wavelengths of one thousand sixty-four nanometers (1064 nm). The three non-linear optical elements


2


convert these three coherent beams


11




a,




11




b,


and


11




c


to three ultraviolet beams


12




a,




12




b,


and


12




c


with the fourth-harmonic wavelength of two hundred sixty-six nanometers (266 nm). The three acousto-optic modulators


3


independently modulate the intensity of these three ultraviolet beams


12




a,




12




b,


and


12




c


according to red, green, and blue video signals received from the controller


9


to produce three modulated beams


13




a,




13




b,


and


13




c.






In each acousto-optic modulator, the appropriate video signal is supplied through the signal line


20


to the resonator


19


in

FIG. 2

, and controls the intensity of the ultrasonic waves


21


. The intensity of the ultrasonic waves


21


in turn controls the amount of ultraviolet light that is diffracted, thus determining the intensity of the diffracted beam


23


. The diffracted beam


23


in

FIG. 2

is one of the three modulated beams


13




a,




13




b,


and


13




c


in

FIG. 1

, while the incident beam


22


is one of the three ultraviolet beams


12




a,




12




b,


and


12




c.






In the scanning mechanism


4


, the horizontal scanning mirror


4




a


deflects the three modulated beams


13




a,




13




b,


and


13




c


horizontally in response to a horizontal drive signal from the controller


9


. The resulting horizontally scanned beams


14




a,




14




b,


and


14




c


are then scanned vertically by the vertical scanning mirror


4




b


in response to a vertical drive signal from the controller


9


. The horizontal scanning mirror


4




a


is, for example, a polygon mirror. The vertical scanning mirror


4




b


is, for example, a galvano-mirror. The scanning mechanism


4


thus produces three ultraviolet beams


15




a,




15




b,


and


15




c


that are scanned horizontally and vertically in a two-dimensional pattern.

FIG. 1

shows these three ultraviolet beams


15




a,




15




b,


and


15




c


in three different scanning positions.





FIG. 3

illustrates the detailed structure and operation of the aperture mask


5


and the phosphor coating


6


on the transparent screen


7


. The phosphor coating


6


comprises red phosphor dots


6




a,


green phosphor dots


6




b,


and blue phosphor dots


6




c


separated by a black matrix


6




d.


The apertures in the aperture mask


5


are positioned so that ultraviolet beam


15




a


illuminates only red phosphor dots


6




a,


ultraviolet beam


15




b


illuminates only green phosphor dots


6




b,


and ultraviolet beam


15




c


illuminates only blue phosphor dots


6




c.


When illuminated, a red phosphor dot


6




a


emits red light


16




a,


a green phosphor dot


6




b


emits green light


16




b,


and a blue phosphor dot


6




c


emits blue light


16




c.






An ultraviolet sensor (not visible in

FIG. 1

) is disposed between the scanning mechanism


4


and the screen assembly


8


, at a point that does not interfere with the display. When the ultraviolet beams


15




a,




15




b,


and


15




c


illuminate this sensor, a signal is returned to the controller


9


, which thereby learns the position of the beams. This signal enables the controller


9


to synchronize the operation of the scanning mechanism


4


with the red, green, and blue video signals supplied to the acousto-optic modulators


3


. This ultraviolet sensor is similar to a well-known sensor used for a similar purpose in laser printers.




If necessary, a plurality of ultraviolet sensors can be provided. Separate sensors can be provided for horizontal scanning and vertical scanning, for example.




As the above description shows, the phosphor screen


6


, like the screen of a conventional color television set, is scanned by three independently modulated beams. These three beams can be modulated by conventional red, green, and blue video signals, and a conventional scanning sequence can be employed. Because of the aperture mask


5


, there is no need to blank the beams to avoid having them illuminate the wrong phosphor dots.




The apertures in the aperture mask


5


may be round, or may have the form of oblong slots. Similarly, the phosphor dots in the phosphor coating


6


may be either round or oblong in shape.




Next a second embodiment will be described. The second embodiment is identical to the first embodiment except that the color separation means is a lens array, instead of an aperture mask. The description of the second embodiment will be confined to the structure and operation of the lens array.




Referring to

FIG. 4

, the lens array


50


comprises a plurality of microlenses disposed in positions corresponding to the apertures in the aperture mask


5


of the first embodiment. As the drawing shows, these microlenses focus the ultraviolet beams


15




a,




15




b,


and


15




c


onto phosphors of the respective types that emit red light


16




a,


green light


16




b,


and blue light


16




c.


The same color-separating effect is obtained as in the first embodiment, with the added advantage that all of the light in the ultraviolet beams


15




a,




15




b,


and


15




c


is directed onto the phosphor coating


6


, so a brighter display is obtained.




The lenses in the lens array may be round, or may have an oblong shape or any other suitable shape.




Next a third embodiment will be described. The third embodiment differs from the first embodiment only in the structure of the screen assembly


8


, so the description will be confined to this point.




Referring to

FIG. 5

, the screen assembly


8


in the third embodiment has the same aperture mask


5


, transparent screen


7


, and phosphor coating


6


as in the first embodiment, and also has a transparent plate


17


disposed between the aperture mask


5


and phosphor coating


6


. The transparent plate


17


supports the aperture mask


5


and maintains an exact positional relationship between the aperture mask


5


and phosphor coating


6


. This ensures accurate color separation.




The third embodiment can also simplify the fabrication of the aperture mask


5


. The aperture mask


5


can be formed by evaporation deposition or printing of an opaque substance on the transparent plate


17


.




Next a fourth embodiment will be briefly described. Referring to

FIG. 6

, the fourth embodiment combines the features of the second and third embodiments, having a lens array


50


supported on a transparent plate


17


. The lens array


50


and transparent plate


17


may be combined into a single structure, by processing the surface of the transparent plate


17


to form an array of lenses.




Next, a fifth embodiment will be described.





FIG. 7

shows a display device


26


according to the fifth embodiment, using the same reference numerals as in

FIG. 1

for elements that are the same as in the first embodiment. The fifth embodiment differs from the first embodiment only in the structure of the screen assembly


25


. The fifth embodiment provides a filter


24


between the aperture mask


5


and phosphor coating


6


. This filter


24


transmits ultraviolet light, but reflects visible light.





FIG. 8

illustrates the operation of the filter


24


in the fifth embodiment. Ultraviolet beam


15




b


passes through an aperture in the aperture mask


5


, passes through the filter


24


, and illuminates a green phosphor dot


6




b.


The phosphor dot


6




b


emits green light, with an intensity responsive to the intensity of the ultraviolet beam


15




b,


but the light is emitted in all directions. Green light


27




b


emitted toward the filter


24


is reflected back, and the reflected green light


28




b


passes through the transparent screen


7


to enhance the intensity of the light


16




b


emitted directly through the transparent screen


7


.




Red and blue light are similarly reflected from the filter


24


, which thus improves the overall brightness of the display.




For clarity,

FIG. 8

shows a gap between the filter


24


and phosphor coating


26


, but the filter


24


may be disposed in contact with the phosphor coating


6


.




The fifth embodiment can be combined with the second, third, or fourth embodiment, by employing a lens array


50


instead of an aperture mask


5


, and/or by adding a transparent plate between the filter


24


and the aperture array


5


or lens array


50


.




Next a sixth embodiment will be described.





FIG. 9

illustrates the sixth embodiment, using the same reference numerals as in

FIG. 1

for elements that are the same as in the first embodiment. To the structure of the first embodiment, the sixth embodiment adds a focusing lens


29


made, for example, of fused quartz. This focusing lens


29


focuses the ultraviolet beams


15




a,




15




b,


and


15




c


to points on the phosphor coating


6


, thereby increasing the amount of light that gets through the aperture mask


5


and enhancing the brightness of the display.




The focusing lens


29


in

FIG. 9

is shown as a simple meniscus lens, but a compound lens may be used instead. The lens material is not restricted to fused quartz; any material capable of focusing ultraviolet light may be used.




The focusing lens


29


need not be disposed between the scanning mechanism


4


and screen assembly


8


; other locations are possible. For example, the focusing lens


29


may be disposed between the horizontal scanning mirror


4




a


and vertical scanning mirror


4




b.


Alternatively, a first focusing lens may be provided between the horizontal scanning mirror


4




a


and vertical scanning mirror


4




b,


and a second lens may be provided between the vertical scanning mirror


4




b


and the screen assembly


8


.




The sixth embodiment can be combined with the second, third, fourth, or fifth embodiment, by adding a similar focusing lines


29


to any of those embodiments.




Next, a seventh embodiment will be briefly described. Referring to

FIG. 10

, the seventh embodiment has infrared laser light sources


1


, non-linear optical elements


2


for wavelength conversion, acousto-optic modulators


3


, a scanning mechanism


4


, and a screen assembly


8


as in the first embodiment, and a reflecting plate


30


. The reflecting plate


30


reflects the ultraviolet beams output from the scanning means, thereby directing the ultraviolet beams onto the screen assembly


8


. In this way, the back-to-front length of the display device is reduced, as compared with the preceding embodiments.




The seventh embodiment is not limited to a single reflecting plate


30


. Two or more reflecting plates may be provided, allowing a long Light path to be obtained in a confined space.




The reflecting plate


30


of the seventh embodiment can be used in combination with any of the preceding six embodiments.




Next, an eighth embodiment will be briefly described. Referring to

FIG. 11

, the eighth embodiment is a display apparatus employing four of the display devices


10


of the first embodiment. Each of these display devices


10


has its own infrared laser light sources


1


, non-linear optical elements


2


, acousto-optic modulators


3


, scanning mechanism


4


, and screen assembly


8


. Compared with the first embodiment, the eighth embodiment doubles the height, width, and resolution of the display.




The eighth embodiment is not limited to a combination of four display devices


10


. Any number of display devices may be combined in a similar manner, to form a display screen of any desired size.




The screen assemblies


8


in

FIG. 11

may abut directly against one another to form a large, continuous display area, an arrangement which would be impossible with conventional cathode-ray tubes. Alternatively, the screen assemblies


8


can be held in a supporting framework, like the panes of glass in a window. The display devices


10


may be housed in a single cabinet, or in separate cabinets.




The display devices are not restricted to the display devices


10


of the first embodiment. Display devices as described in any of the other preceding embodiments can be similarly combined.




The invention is not restricted to the embodiments above. Further variations are possible, such as the following.




The modulating means need not be acousto-optic modulators as described in the embodiments above. Optical intensity modulators employing electro-optic elements, for example, are well known, and may be used instead of acoustic modulators.




The scanning mechanism


4


may be replaced by an acousto-optic scanning means, employing acousto-optic elements of the same type as shown in FIG.


2


. Scanning can be accomplished by varying the frequency at which the ultrasonic resonator


19


is driven, thus varying the angle at which the ultraviolet beams are diffracted. This acousto-optic scanning method has the advantage of eliminating moving mirrors and other moving parts.




The scanning mechanism


4


may also be replaced by an electro-optic scanning means using prisms with refractive indices that vary in response to an applied voltage.




The embodiments above produced ultraviolet beams by wavelength conversion of infrared light, but the invention can also be practiced with ultraviolet light sources, in which case wavelength conversion is unnecessary.




Those skilled in the art will recognize that still further variations are possible within the scope claimed below.



Claims
  • 1. A display device, comprising:a transparent screen coated with three types of phosphors, for emitting visible light of three corresponding colors when illuminated by ultraviolet light; a light source for producing three beams of ultraviolet light; three modulators, each for modulating an intensity of a corresponding ultraviolet beam; a scanner for scanning said ultraviolet beams across said transparent screen in a two-dimensional pattern; and a color separator disposed between said scanner and said transparent screen, for directing said three ultraviolet beams onto corresponding phosphor types on said transparent screen.
  • 2. The display device of claim 1, wherein said light source comprises:three laser light sources for producing three coherent light beams; and three wavelength converters for converting said coherent light beams to ultraviolet beams.
  • 3. The display device of claim 1, wherein said color separator comprises:an aperture mask having apertures disposed so that each of said ultraviolet beams, after passing through said apertures, illuminates phosphors of just one of said three types.
  • 4. The display device of claim 1, wherein said color separator comprises:an array of lenses for focusing said ultraviolet beams so that each of said ultraviolet beams, after passing through said array of lenses, illuminates phosphors of just one of said three types.
  • 5. The display device of claim 1, wherein said color separator is mounted on a transparent substrate.
  • 6. The display device of claim 1, wherein said scanner has a first mirror for scanning said ultraviolet beams horizontally, and a second mirror for scanning said ultraviolet beams vertically.
  • 7. The display device of claim 1, wherein said scanner has a first acousto-optic element for scanning said ultraviolet beams horizontally, and a second acousto-optic element for scanning said ultraviolet beams vertically.
  • 8. The display device of claim 1, further comprising:a filter disposed between said color separator and said transparent screen, for transmitting ultraviolet light and reflecting visible light.
  • 9. The display device of claim 1, further comprising:a focusing lens disposed between said scanner and said transparent screen, for focusing said ultraviolet beams onto said screen.
  • 10. The display device of claim 1, further comprising:a reflecting plate for reflecting said ultraviolet beams onto said transparent screen after said ultraviolet beams have been scanned by said scanner.
  • 11. A compound display apparatus comprising a plurality of display devices disposed in a two-dimensional array, each of said display devices having:a transparent screen coated with three types of phosphors, for emitting visible light of three corresponding colors when illuminated by ultraviolet light; a light source for producing three beams of ultraviolet light; three modulators, each for modulating an intensity of a corresponding ultraviolet beam; a scanner for scanning said ultraviolet beams across said transparent screen in a two-dimensional pattern; and a color separator disposed between said scanner and said transparent screen, for directing said three ultraviolet beams onto corresponding phosphor types on said transparent screen.
  • 12. The display apparatus of claim 11, wherein each said light source comprises:three laser light sources for producing three coherent light beams; and three wavelength converters for converting said coherent light beams to ultraviolet beams.
  • 13. The display apparatus of claim 11, wherein each said color separator comprises:an aperture mask having apertures disposed so that each of said ultraviolet beams, after passing through said apertures, illuminates phosphors of just one of said three types.
  • 14. The display apparatus of claim 11, wherein each said color separator comprises:an array of lenses for focusing said ultraviolet beams so that each of said ultraviolet beams, after passing through said array of lenses, illuminates phosphors of just one of said three types.
  • 15. The display apparatus of claim 11, wherein each said color separator is mounted on a transparent substrate.
  • 16. The display apparatus of claim 11, wherein each said scanner has a first mirror for scanning said ultraviolet beams horizontally, and a second mirror for scanning said ultraviolet beams vertically.
  • 17. The display apparatus of claim 11, wherein each said scanner has a first acousto-optic element for scanning said ultraviolet beams horizontally, and a second acousto-optic element for scanning said ultraviolet beams vertically.
  • 18. The display apparatus of claim 11, each said display device further having:a filter disposed between said color separator and said transparent screen, for transmitting ultraviolet light and reflecting visible light.
  • 19. The display apparatus of claim 11, each said display device further having:a focusing lens disposed between said scanner and said transparent screen, for focusing said ultraviolet beams onto said screen.
  • 20. The display apparatus of claim 11, further comprising:at least one reflecting plate for reflecting said ultraviolet beams onto the transparent screen of each of said plurality of display devices after said ultraviolet beams have been scanned by said scanner.
Priority Claims (1)
Number Date Country Kind
7-271576 Oct 1995 JP
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