Viewing optical system and image display apparatus using the same
First Claim
1. A viewing optical system comprising:
- reflection type image display constructed and arranged to display an image by reflecting an illuminating light beam incident from a front side of a display surface for forming an image for observation; and
an ocular optical system for leading said image to a pupil position where an observer'"'"'s eyeball is to be placed, wherein said image display comprises;
an illuminator; and
an illuminating light guide optical system constructed and arranged to guide a light beam emitted from said illuminator so that said light beam can be applied to said display surface from a front side thereof; and
wherein said ocular optical system includes a prism member, said prism member comprising;
an entrance surface through which a display light beam reflected from said reflection type image display enters said prism member after passing through said illuminating light guide optical system;
at least one reflecting surface reflecting the light beam in said prism member; and
an exit surface through which the light beam exits from said prism member, wherein said at least one reflecting surface of said prism member is decentered with respect to an optical axis and has a rotationally asymmetric curved surface configuration that corrects decentration aberrations due to decentration of said at least one reflecting surface and gives a power to the light beam, and wherein a spacing between the entrance surface of said prism member and the display surface of said reflection type image display satisfies the following condition to lead said image to said pupil position;
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Accused Products
Abstract
A compact, bright and high-performance viewing optical system and an image display apparatus using the same. The viewing optical system uses an ocular optical system, which is formed from a decentered prism, and a reflection type image display device. The image display device has a light source and an illuminating light guide prism for guiding a light beam from the light source so that the light beam is applied to the display surface from the front side thereof. The ocular optical system includes a prism having an entrance surface through which a light beam reflected from the display surface enters the prism after passing through the illuminating light guide prism. The prism further has a reflecting surface and an exit surface through which the light beam exits from the prism. The reflecting surface is decentered with respect to the optical axis and has a rotationally asymmetric curved surface configuration that corrects decentration aberrations due to the decentration of the reflecting surface and gives a power to the light beam. The spacing between the entrance surface of the prism and the display surface satisfies a predetermined condition to lead the image to the pupil position.
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Citations
53 Claims
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1. A viewing optical system comprising:
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reflection type image display constructed and arranged to display an image by reflecting an illuminating light beam incident from a front side of a display surface for forming an image for observation; and
an ocular optical system for leading said image to a pupil position where an observer'"'"'s eyeball is to be placed, wherein said image display comprises;
an illuminator; and
an illuminating light guide optical system constructed and arranged to guide a light beam emitted from said illuminator so that said light beam can be applied to said display surface from a front side thereof; and
wherein said ocular optical system includes a prism member, said prism member comprising;
an entrance surface through which a display light beam reflected from said reflection type image display enters said prism member after passing through said illuminating light guide optical system;
at least one reflecting surface reflecting the light beam in said prism member; and
an exit surface through which the light beam exits from said prism member, wherein said at least one reflecting surface of said prism member is decentered with respect to an optical axis and has a rotationally asymmetric curved surface configuration that corrects decentration aberrations due to decentration of said at least one reflecting surface and gives a power to the light beam, and wherein a spacing between the entrance surface of said prism member and the display surface of said reflection type image display satisfies the following condition to lead said image to said pupil position;
- View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17)
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18. A viewing optical system comprising:
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an image forming member for forming a first image to be viewed by an observer;
an ocular optical system arranged to lead the image formed by said image forming member to an observer'"'"'s eyeball; and
a see-through optical element placed closer to a second image, which is different from said first image, than said ocular optical system so as to lead said second image to the observer'"'"'s eyeball, wherein said ocular optical system has at least one reflecting surface with a curved surface configuration arranged to reflect a light beam from said first image and to lead it toward the observer'"'"'s eyeball, said reflecting surface having a transmitting action to allow a light beam from said second image to enter said ocular optical system after passing through said see-through optical element, and said see-through optical element is placed closer to said second image than said reflecting surface at a distance from said reflecting surface, and wherein when the light beam from said second image passes through said see-through optical element and said ocular optical system, a combined optical power P of said see-through optical element and said ocular optical system is approximately zero, and a combined angular magnification β
of said see-through optical element and said ocular optical system is approximately 1.- View Dependent Claims (19, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, 30, 31, 32, 33, 34)
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20. A viewing optical system according to claim 18, wherein the reflecting surface of said ocular optical system has a rotationally asymmetric curved surface configuration that corrects decentration aberrations, said rotationally asymmetric curved surface configuration being one of an anamorphic surface and a plane-symmetry free-form surface having only one plane of symmetry.
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21. A viewing optical system according to any one of claims 18 to 20, wherein said ocular optical system has at least a prism member filled with a medium having a refractive index larger than 1, said prism member including at least three optical surfaces having at least either one of a transmitting optical action and a reflecting optical action, said three optical surfaces including:
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a third surface through which a light beam from said first image enters said prism member;
a second surface disposed to face said see-through optical element at a distance, said second surface having a transmitting action to allow a light beam from said second image to enter said prism member after passing through said see-through optical element, said second surface further having a reflecting action to reflect the light beam from said first image in said prism member, and said second surface having said at least one reflecting surface with a curved surface configuration; and
a first surface through which the light beam from said first image exits from said prism member.
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22. A viewing optical system according to claim 21, wherein said third surface has a rotationally asymmetric curved surface configuration that corrects decentration aberrations, said rotationally asymmetric curved surface configuration being one of an anamorphic surface and a plane-symmetry free-form surface having only one plane of symmetry.
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23. A viewing optical system according to claim 21, wherein said first surface has a rotationally asymmetric curved surface configuration that corrects decentration aberrations, said rotationally asymmetric curved surface configuration being one of an anamorphic surface and a plane-symmetry free-form surface having only one plane of symmetry.
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24. A viewing optical system according to claim 21, wherein said first surface serves as both a reflecting surface and a transmitting surface for reflecting and transmitting a light beam in said prism member.
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25. A viewing optical system according to claim 24, wherein said first surface serving as both a reflecting surface and a transmitting surface is a totally reflecting surface arranged so that a reflected light beam is incident on said first surface at an angle exceeding a total reflection critical angle, and thereafter, the light beam reflected back from the reflecting surface is incident on said first surface at an angle not exceeding the total reflection critical angle to exit from said prism member.
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26. A viewing optical system according to claim 21, wherein said ocular optical system and said see-through optical element are arranged so that a first image viewing field range determined by the light beam from said first image as it exits from said ocular optical system is formed within a second image viewing field range determined by the light beam from said second image as it passes through said see-through optical element and a part of said ocular optical system.
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27. A viewing optical system according to claim 21, wherein an optical diameter of said see-through optical element is set smaller than the reflecting surface of said ocular optical system, which is placed to face said see-through optical element, and said see-through optical element is placed to face a region of said reflecting surface closer to said image forming member so that a light beam transmitting region of said reflecting surface that transmits the light beam entering through said see-through optical element shifts toward said image forming member with respect to a light beam reflecting region of said reflecting surface, and further a portion of said reflecting surface that does not directly face said see-through optical element is provided with a light-blocking coating to prevent entrance of flare rays from an outside world.
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28. A viewing optical system according to claim 21, wherein a light-blocking member capable of switching between transmission and cutoff of a light beam from an outside world image or switching between transmission and dimming of said light beam is placed at at least either one of positions in front of and behind said see-through optical element so that said second image is the outside world image.
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29. A viewing optical system according to claim 21, wherein a display device for forming an image different from said first image is placed on a side of said see-through optical element remote from said ocular optical system so that said second image is formed by said display device.
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30. A viewing optical system according to claim 21, wherein a light-blocking member capable of switching between transmission and cutoff of a light beam from an outside world image or switching between transmission and dimming of said light beam is placed at at least either one of positions in front of and behind said see-through optical element so that said second image is the outside world image, and a display device for displaying a third image is provided between said outside world image and said see-through optical element.
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31. A viewing optical system according to claim 21, further comprising a line-of-sight detector constructed and arranged to detect an observer'"'"'s line-of-sight, said line-of-sight detector including:
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a light source for pupil illumination; and
a light-receiving element for receiving an image of said pupil, said light source for pupil illumination and said light-receiving element being disposed at respective positions out of an optical path in said ocular optical system for leading the light beam from said first image and an optical path in said see-through optical element for leading the light beam from said second image.
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32. A viewing optical system according to claim 31, wherein said line-of-sight detector is arranged such that at least the image of said pupil is passed through the optical path in said ocular optical system and separated from an optical path between said ocular path between said ocular optical system and said first image so as to be led to said light-receiving element.
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33. A viewing optical system according to claim 21, wherein said ocular optical system, said see-through optical element and said exit pupil are positioned so as to satisfy the following condition:
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34. A head-mounted viewing optical apparatus comprising:
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an apparatus body unit including said viewing optical system according to claim 21, wherein said ocular optical system, said see-through optical element, and said image forming member for forming said first image are retained with required spacings therebetween by a retainer; and
a support structure constructed and arranged to support said apparatus body unit on a head of an observer.
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35. A viewing optical system comprising:
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an image forming member for forming a first image to be viewed by an observer;
an ocular optical system arranged to lead the image formed by said image forming member to an observer'"'"'s eyeball; and
a see-through optical element placed closer to a second image, which is different from said first image, than said ocular optical system so as to lead said second image to the observer'"'"'s eyeball, wherein said ocular optical system has at least one reflecting surface with a curved surface configuration arranged to reflect a light beam from said first image and to lead it toward the observer'"'"'s eyeball, said reflecting surface having a transmitting action to allow a light beam from said second image to enter said ocular optical system after passing through said see-through optical element; and
said see-through optical element is placed closer to said second image than said reflecting surface in such a manner as to be in close contact with said reflecting surface, and wherein when the light beam from said second image passes through said see-through optical element and said ocular optical system, a combined optical power P of said see-through optical element and said ocular optical system is approximately zero. - View Dependent Claims (37, 39, 40, 41, 42, 43, 44, 45, 46, 47, 48, 49, 50, 51, 52, 53)
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39. A viewing optical system according to any one of claims 35 to 38, wherein the reflecting surface of said ocular optical system has a rotationally asymmetric curved surface configuration that corrects decentration aberrations, said rotationally asymmetric curved surface configuration being one of an anamorphic surface and a plane-symmetry free-form surface having only one plane of symmetry.
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40. A viewing optical system according to any one of claims 35 to 38, wherein said ocular optical system has at least a prism member filled with a medium having a refractive index larger than 1, said prism member including at least three optical surfaces having at least either one of a transmitting optical action and a reflecting optical action, said three optical surfaces including:
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a third surface through which a light beam from said first image enters said prism member;
a second surface disposed in close contact with said see-through optical element, said second surface having a transmitting action to allow a light beam from said second image to enter said prism member after passing through said see-through optical element, said second surface further having a reflecting action to reflect the light beam from said first image in said prism member, and said second surface having said at least one reflecting surface with a curved surface configuration; and
a first surface through which the light beam from said first image exits from said prism member.
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41. A viewing optical system according to any one of claims 35 to 38, wherein said third surface has a rotationally asymmetric curved surface configuration that corrects decentration aberrations, said rotationally asymmetric curved surface configuration being one of an anamorphic surface and a plane-symmetry free-form surface having only one plane of symmetry.
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42. A viewing optical system according to any one of claims 35 to 38, wherein said first surface has a rotationally asymmetric curved surface configuration that corrects decentration aberrations, said rotationally asymmetric curved surface configuration being one of an anamorphic surface and a plane-symmetry free-form surface having only one plane of symmetry.
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43. A viewing optical system according to claim 39, wherein said first surface serves as both a reflecting surface and a transmitting surface for reflecting and transmitting a light beam in said prism member.
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44. A viewing optical system according to claim 43, wherein said first surface serving as both a reflecting surface and a transmitting surface is a totally reflecting surface arranged so that a reflected light beam is incident on said first surface at an angle exceeding a total reflection critical angle, and thereafter, the light beam reflected back from the reflecting surface is incident on said first surface at an angle not exceeding the total reflection critical angle to exit from said prism member.
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45. A viewing optical system according to any one of claims 35 to 38, wherein said ocular optical system and said see-through optical element are arranged so that a first image viewing field range determined by the light beam from said first image as it exits from said ocular optical system is formed within a second image viewing field range determined by the light beam from said second image as it passes through said see-through optical element and a part of said ocular optical system.
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46. A viewing optical system according to any one of claims 35 to 38, wherein an optical diameter of said see-through optical element is set smaller than the reflecting surface of said ocular optical system, which is placed to face said see-through optical element, and said see-through optical element is placed to face a region of said reflecting surface closer to said image forming member so that a light beam transmitting region of said reflecting surface that transmits the light beam entering through said see-through optical element shifts toward said image forming member with respect to a light beam reflecting region of said reflecting surface, and further a portion of said reflecting surface that does not directly face said see-through optical element is provided with a light-blocking coating to prevent entrance of flare rays from an outside world.
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47. A viewing optical system according to any one of claims 35 to 38, wherein a light-blocking member capable of switching between transmission and cutoff of a light beam from an outside world image or switching between transmission and dimming of said light beam is placed in front of said see-through optical element so that said second image is the outside world image.
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48. A viewing optical system according to any one of claims 35 to 38, wherein a display device for forming an image different from said first image is placed on a side of said see-through optical element remote from said ocular optical system so that said second image is formed by said display device.
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49. A viewing optical system according to any one of claims 35 to 38, wherein a light-blocking member capable of switching between transmission and cutoff of a light beam from an outside world image or switching between transmission and dimming of said light beam is placed in front of said see-through optical element so that said second image is the outside world image, and a display device for displaying a third image is provided between said outside world image and said see-through optical element.
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50. A viewing optical system according to any one of claims 35 to 38, further comprising a line-of-sight detector constructed and arranged to detect an observer'"'"'s line-of-sight, said line-of-sight detector including:
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a light source for pupil illumination; and
a light-receiving element for receiving an image of said pupil;
said light source for pupil illumination and said light-receiving element being disposed at respective positions out of an optical path in said ocular optical system for leading the light beam from said first image and an optical path in said see-through optical element for leading the light beam from said second image.
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51. A viewing optical system according to claim 50, wherein said line-of-sight detector is arranged such that at least the image of said pupil is passed through the optical path in said ocular optical system and separated from an optical path between said ocular optical system and said first image so as to be led to said light-receiving element.
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52. A viewing optical system according to any one of claims 35 to 38, wherein said ocular optical system, said see-through optical element and said exit pupil are positioned so as to satisfy the following condition:
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53. A head-mounted viewing optical apparatus comprising:
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an apparatus body unit including said viewing optical system according to any one of claims 35 to 38, wherein said ocular optical system, said see-through optical element, and said image forming member for forming said first image are retained with required spacings therebetween by a retainer; and
a support structure constructed and arranged to support said apparatus body unit on a head of an observer.
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36. A viewing optical system comprising:
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an image forming member for forming a first image to be viewed by an observer;
an ocular optical system arranged to lead the image formed by said image forming member to an observer'"'"'s eyeball; and
a see-through optical element placed closer to a second image, which is different from said first image, than said ocular optical system so as to lead said second image to the observer'"'"'s eyeball, wherein said ocular optical system has at least one reflecting surface with a curved surface configuration arranged to reflect a light beam from said first image and to lead it toward the observer'"'"'s eyeball, said reflecting surface having a transmitting action to allow a light beam from said second image to enter said ocular optical system after passing through said see-through optical element, and said see-through optical element is placed closer to said second image than said reflecting surface in such a manner as to be in close contact with said reflecting surface, and wherein when the light beam from said second image passes through said see-through optical element and said ocular optical system, a combined angular magnification β
of said see-through optical element and said ocular optical system is approximately 1.- View Dependent Claims (38)
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Specification