EFFICIENT COLLIMATION OF LIGHT WITH OPTICAL WEDGE
Embodiments of optical collimators are disclosed. For example, one disclosed embodiment comprises an optical waveguide having a first end, a second end opposing the first end, a viewing surface extending at least partially between the first end and the second end, and a back surface opposing the viewing surface. The viewing surface comprises a first critical angle of internal reflection, and the back surface is configured to be reflective at the first critical angle of internal reflection. Further, an end reflector is disposed at the second end of the optical waveguide, and includes a faceted lens structure to cause a majority of the viewing surface to be uniformly illuminated when uniform light is injected into the first end and also to cause a majority of the injected light to exit the viewing surface.
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This application claims priority to U.S. Provisional Application Ser. No. 61/235,922, entitled EFFICIENT COLLIMATION OF LIGHT WITH OPTICAL WEDGE, filed Aug. 21, 2009, the entire disclosure of which is herein incorporated by reference.
BACKGROUNDAn optical collimator is a device which collects rays from a point source of light such as a light bulb or light emitting diode and causes those rays to emerge in parallel from a surface. Examples of collimators include lenses or curved mirrors found in a flashlight or car headlamp. In these examples, a volume of space exists between the point source and the surface from which the collimated light exits. In some use environments, this space may be inconvenient, as it may increase the overall size of an optical device that utilizes the collimator.
SUMMARYAccordingly, various embodiments are disclosed herein that relate to optical collimators. For example, one disclosed embodiment provides an optical collimator comprising an optical waveguide having a first end including a first light interface, a second end opposing the first end, a viewing surface that includes a second light interface extending at least partially between the first end and the second end, and a back surface opposing the viewing surface. The viewing surface comprises a first critical angle of internal reflection with respect to a normal of the viewing surface, and the back surface is configured to be reflective at the first critical angle of internal reflection. Further, an end reflector is disposed at the second end of the optical waveguide, and includes a faceted lens structure comprising a plurality of facets angled to cause a majority of the viewing surface to be uniformly illuminated when uniform light is injected into the first end and also to cause a majority of the injected light to exit the viewing surface.
This summary is provided to introduce a selection of concepts in a simplified form that are further described below in the detailed description. This summary is not intended to identify key features or essential features of the claimed subject matter, nor is it intended to be used to limit the scope of the claimed subject matter. Furthermore, the claimed subject matter is not limited to implementations that solve any or all disadvantages noted in any part of this disclosure.
Various embodiments of optical collimators are disclosed herein in the form of wedge-shaped light guides, or optical wedges. An optical wedge is a light guide that conducts light between one light interface at an end of the wedge and another light interface at a face of the wedge via total internal reflection. The embodiments disclosed herein each utilize a folded optical path to allow light to fan out to a desired size before collimation, which may allow the reduction in size of the volume between a light source and surface (e.g. wedge face) where the collimated light exits. Such optical wedges may find various uses, including but not limited to as a backlight for a liquid crystal display (LCD).
The subject matter of the present disclosure is now described by way of example and with reference to certain illustrated embodiments. In the accompanying figures, it will be noted that the views of the illustrated embodiments may not be drawn to scale, and the aspect ratios of some features may be exaggerated to make selected features or relationships easier to see.
To provide display functionality, optical system 10 may be configured to project a visible image onto touch-sensitive display surface 12. To provide input functionality, the optical system may be configured to capture at least a partial image of objects placed on the touch-sensitive display surface—fingers, electronic devices, paper cards, food, or beverages, for example. Accordingly, the optical system may be configured to illuminate such objects and to detect the light reflected from the objects. In this manner, the optical system may register the position, footprint, and other properties of any suitable object placed on the touch-sensitive display surface.
Optical system 10 includes optical wedge 100, light director 20, light valve 22, diffuser 24, and light source 102. Light source 102 and light valve 22 may be operatively coupled to controller 16 and configured to provide a visual display image to touch-sensitive display surface 12. Light source 102 may be any illuminant configured to emit visible light, such as one or more light emitting diodes, for example. Light from light source 102 is projected through optical wedge 100 and directed to light valve 22 via light director 20. In some embodiments, light director 20 may comprise a film of prisms configured to direct light in a direction normal to light valve 22. The numerous light-gating elements of light valve 22 may be used to modulate light from light director 20 with respect to color and intensity. In some embodiments, the light valve may comprise a liquid-crystal display device, but other light-modulating devices may be used as well. In this manner, the light source and the light valve may together create a display image. The display image is projected through diffuser 24 and is thereby provided to touch-sensitive display surface 12.
Optical system 10 may be further configured to provide input functionality to controller 16. Accordingly, the illustrated optical system includes detector 38, infrared emitters 72, and illuminating light guide 74. Detector 38 may comprise a camera, such as an infrared-sensitive digital camera, for example, or any other suitable image sensing device. Infrared emitters 72 may comprise one or more infrared light-emitting diodes, for example, or any other suitable light source. The illuminating light guide may be any optic configured to receive an injection of infrared light at one or more entry zones 76 and to transmit infrared light reflected off of objects touching the display screen through exit zone 78.
For example, infrared light may be injected by infrared emitters 72 into entry zone 76 of illuminating light guide 74. The infrared light may travel through illuminating light guide 74 via total internal reflection and may leak out along the touch-sensitive display surface 12 (e.g. due to diffusing elements, not shown, arranged along the touch-sensitive display surface 12) until striking one or more objects in contact with touch-sensitive display surface 12, such as object 40. A portion of the infrared light may reflect off of the one or more objects and exit illuminating light guide 74 at exit zone 78. The infrared light may travel from exit zone 78, through diffuser 24 and light valve 22, and strike a surface of optical wedge 100, which may be configured to direct incident infrared light onto detector 38. It will be understood however, that numerous other illumination configurations are possible, and are within the scope of the present disclosure.
Referring next to
Optical wedge 100 is configured such that light rays injected into a light interface of thin end 110 may fan out as they approach thick end 120 comprising end reflector 125. The light rays are delivered to end reflector 125 via total internal reflection from viewing surface 150 and the back surface. In the preferred embodiment, end reflector 125 is curved with a uniform radius of curvature having center of curvature 200, and light source 102 injecting light at the focal point of end reflector 125, the focal point being at one half the radius of curvature. At thick end 120, each of the light rays reflects off of end reflector 125 parallel to each of the other light rays. The light rays travel from thick end 120 toward thin end 110 until the light rays intersect viewing surface 150 at a critical angle of reflection of viewing surface 150 and the light rays exit as collimated light. In an alternative embodiment, end reflector 125 may be parabolic or have other suitable curvature for collimating light.
In other embodiments, a plurality of light sources may be disposed adjacent to and along thin end 110. The use of a plurality of light sources may increase the brightness of the collimated light exiting viewing surface 150 compared to the use of a single light source. In such embodiments, to correct for field curvature and/or spherical aberration, it may be desirable to slightly shorten sides 130 and 140 of optical wedge 100 so that a light source to either side of center line 210 may stay in the focal point of end reflector 125. Shortening sides 130 and 140 may make thin end 110 convex, as illustrated by curve 115. A suitable curvature may be found by using a ray-tracing algorithm to trace rays at a critical angle of reflection of viewing surface 150 of optical wedge 100 back through optical wedge 100 until the rays come to a focus near thin end 110.
Rays 300 and 400 exit viewing surface 150 once the rays 300 and 400 intersect viewing surface 150 at an angle less than or equal to a critical angle of internal reflection with respect to a normal of viewing surface 150. This critical angle may be referred to herein as the “first critical angle.” Likewise, rays reflect internally in optical wedge 100 when the rays intersect viewing surface 150 at an angle greater than the first critical angle of internal reflection with respect to the normal of viewing surface 150. Further, rays reflect internally in optical wedge 100 when the rays intersect back surface 160 at an angle greater than a critical angle of internal reflection with respect to the normal of back surface 160. This critical angle may be referred to herein as the “second critical angle.”
As explained in more detail below with reference to
Any suitable material or materials may be used as cladding layers to achieve desired critical angles of internal reflection for the viewing and/or back surfaces of an optical wedge. In an example embodiment, optical wedge 100 is formed from polymethyl methacrylate, or PMMA, with an index of refraction of 1.492. The index of refraction of air is approximately 1.000. As such, the critical angle of a surface with no cladding is approximately 42.1 degrees. Next, an example cladding layer may comprise Teflon AF (EI DuPont de Nemours & Co. of Wilmington, Del.), an amorphous fluoropolymer with an index of refraction of 1.33. The critical angle of a PMMA surface clad with Teflon AF is 63.0 degrees. It will be understood that these examples are described for the purpose of illustration, and are not intended to be limiting in any manner.
In other embodiments, back surface 160 may include a mirror. As non-limiting examples, the mirror may be formed by applying a reflective coating to back surface 160 or by placing a mirror adjacent to back surface 160. In this manner, back surface 160 may reflect incident light intersecting back surface 160. When back surface 160 is configured to reflect some or all incident light, back surface 160 may be referred to herein as the “reflective back surface.” Non-limiting examples of a reflective back surface include a back surface having a mirrored surface, a mirror placed adjacent to the back surface, a back surface having a second critical angle of internal reflection with respect to a normal of the back surface, wherein the second critical angle of reflection is less than the first critical angle of reflection, or any other configuration in which the back surface is reflective to internally incident light at the first critical angle of internal reflection.
The configuration of optical wedge 100 and end reflector 125 may be configured to cause a majority of viewing surface 150 to be uniformly illuminated when uniform light is injected into thin end 110, and also to cause a majority of the injected light to exit viewing surface 150. As mentioned above, optical wedge 100 is tapered along its length such that rays injected at thin end 110 travel to end reflector 125 via total internal reflection. End reflector 125 comprises a faceted lens structure configured to decrease the ray angle relative to a normal to each of viewing surface 150 and back surface 160. In addition, the diminishing thickness of optical wedge 100 from thick end 120 to thin end 110 causes ray angles to diminish relative to the normal of each surface as rays travel toward thin end 110. When a ray is incident on viewing surface 150 at less than the first critical angle, the ray will exit viewing surface 150.
In some embodiments, light source 102 may be positioned at a focal point of end reflector 125. In such embodiments, end reflector 125 may be curved with a radius of curvature that is twice the length of optical wedge 100. In the embodiment of
In the depicted embodiment, end reflector 125 is spherically curved from side 130 to side 140 and from viewing surface 150 to back surface 160. In other embodiments, end reflector 125 may be cylindrically curved with a uniform radius of curvature from viewing surface 150 and back surface 160 and a center of curvature where viewing surface 150 and back surface 160 would meet if extended. A cylindrically curved end reflector may resist sag more strongly than a spherically curved end reflector 125, which may be beneficial in large format applications. Other suitable curvatures may be used for end reflector 125, such as parabolic, for example. Additionally, the curvature of end reflector 125 in the plane perpendicular to sides 130 and 140 may differ from the curvature of end reflector 125 in the plane parallel to sides 130 and 140.
As mentioned above, it may be desirable for the critical angles of reflection of viewing surface 150 and back surface 160 to be different. This may help to prevent loss of light through back surface 160, as illustrated in
The height of each of the plurality of facets may affect the uniformity and the brightness of collimated light exiting viewing surface 150. For example, larger facets may create optical paths that differ from the ideal focal length, which may cause Fresnel banding. As such, in embodiments where such banding may pose issues, it may be desirable to make the height of each of the plurality of facets less than 500 microns, for example, so that such banding is less visible.
Likewise, the angle of each of the plurality of facets also may affect the uniformity and brightness of collimated light exiting viewing surface 150. Ray 500 illustrates how facet angles may affect the path of a ray through optical wedge 100. Ray 500 is injected into thin end 110, travel through optical wedge 100 and strikes end reflector 125. Half of ray 500 strikes facet 530 facing viewing surface 150. The portion of ray 500 striking facet 530 is reflected as ray 510 toward viewing surface 150. Ray 510 intersects viewing surface 150 at an angle less than or equal to the first critical angle of internal reflection with respect to a normal of viewing surface 150, and thus exits the viewing surface 150 as ray 512.
The other half of ray 500 strikes facet 540 facing back surface 160. The portion of ray 500 striking facet 540 is reflected as ray 520 toward back surface 160. Because of the difference between the critical angles of viewing surface 150 and back surface 160, ray 520 intersects back surface 160 at an angle greater than the second critical angle of internal reflection with respect to a normal of back surface 160, and thus reflects as ray 522 toward viewing surface 150. Ray 522 then intersects viewing surface 150 at an angle less than or equal to the first critical angle of internal reflection with respect to a normal of viewing surface 150, and thus exits as ray 524. In this manner, a majority (and in some embodiments, substantially all) of the light that reflects from end reflector 125 exits viewing surface 150.
Due to light being separately reflected by facets facing viewing surface 150 and facets facing back surface 160, overlapping, superimposed first and second images arranged in a head-to-tail orientation may be formed at viewing surface 150. The degree of overlap between these images may be determined by the angles of the facets 530 and 540. For example, the two images are completely overlapping when each facet has an angle relative to a normal of a surface of the end reflector of three-eighths of a difference between ninety degrees and the first critical angle of reflection, as explained in more detail below. In this instance, substantially all light input into optical wedge 100 exits the viewing surface 150. Varying the facets from this value decreases the amount of overlap between images, such that only one or the other of the two images is displayed where the angles of the facets are ¼ or ½ of the difference between 90 degrees and the first critical angle of reflection. Further, varying the angles of the facets from three-eighths of the difference between ninety degrees and the first critical angle of reflection also causes some light to exit from the thin end of optical wedge 100, rather than from viewing surface 150. Where the angles of the facets are ¼ or ½ of the difference between 90 degrees and the first critical angle of reflection, the viewing surface also may be uniformly illuminated, but half of the light exits from the thin end of optical wedge 100, and is therefore lost. It will be understood that, depending upon the desired use environment, it may be suitable to use facet angles other than three-eighths of the difference between ninety degrees and the first critical angle of reflection to produce collimated light. Such use environments may include, but are not limited to, environments in which any regions of non-overlapping light (which would appear to have a lower intensity relative to the overlapping regions) are not within a field of view observed by a user.
In an alternative embodiment, the faceted lens structure of end reflector 125 may comprise a diffraction grating. The grating equation may be used to calculate an angle of diffraction for a given angle of incidence and a given wavelength of light. Since the angle of diffraction is dependent on the wavelength of the light, an end reflector comprising a diffraction grating may be desirable when the injected light is monochromatic.
For the viewing surface to be uniformly illuminated (e.g. where the images reflected from facets 530 and 540 are fully overlapping), a ray injected at the thin end and travelling horizontally toward the end reflector, coincident with a normal of the end reflector, reflects off of a facet facing the viewing surface and travels to the center of the viewing surface, intersecting the viewing surface at the critical angle of the viewing surface.
Any suitable light source may be used to inject light into optical wedge 100. Examples include, but are not limited to, light emitting diodes (LED). It will be noted that light radiates from a bare LED in a Lambertian pattern. However, for increased optical efficiency relative to a bare LED, it may be desired for light to be injected into the optical wedge so that all rays are at angles between the two solid line rays 650 and 660 shown in
In some embodiments, a plurality of light sources may be positioned adjacent to and along a thin end of the optical wedge to increase an intensity of output collimated light. The output from optical wedge 100 of such an array of light sources may be analyzed by analyzing each of light sources and then combining the results using the superposition principle. This may help in the design of a system that produces uniform collimated light using such an array of light sources, as illustrated by
In
In
When light sources 802 and 902 are positioned similar distances from centerline 850, the borders of the “Reflection” region in
Returning to
Due to the angle at which facets on the end reflector are angled, at 1040, a first portion of light may be emitted from the viewing surface, the first portion of light intersecting the viewing surface at the first critical angle of reflection. At 1050, a second portion of light may be internally reflected from the back surface at an angle equal to the first critical angle of reflection when the second critical angle of reflection is less than the first critical angle of reflection. At 1060, the second portion of light may then be emitted from the viewing surface after internally reflecting from the back surface.
Among the potential uses of such a flat panel collimator is that of illuminating a liquid crystal panel. A liquid crystal display is an inexpensive way of displaying video and comprises a liquid crystal panel behind which is placed a backlight. Past wedge backlights have utilized a slim transparent wedge with light sources along the thick end and films which direct light through the liquid crystal panel to the viewer so that they may see the displayed image. Considerable effort is taken to ensure that emission from the backlight is sufficiently diffuse so that the displayed image can be seen from a wide field of view. For example, some past wedges were filled with scattering sites. With diffuse illumination, however, it is difficult to use the liquid crystal panel in anyway other than as a conventional display.
There exist many applications where it is desirable to project a video image. This may be done by placing a lens in front of a liquid crystal display. However, if the illumination is diffuse, the lens has to be large and therefore expensive. A flat panel collimator can be a slim way of illuminating a small liquid crystal panel or other spatial light modulator with collimated light which may be condensed through a small projection lens. If the spatial light modulator is reflective, as in the case of a digital micromirror device, no beam splitter or other space for illumination is needed. Therefore, the projection lens may be brought as close to in the light modulator as desired.
In some applications, it may be desired to project an image only a few millimeters onto a screen. This may be done in the same way that the sun projects the shadow of trees onto the ground: illuminate a large liquid crystal panel with collimated light, and its shadow, e.g. an image, can be formed on a diffuser spaced a few millimeters away from the liquid crystal panel. One application for this is where it is desired that there be a video image on every key of a keyboard. Were a separate display screen to be formed on each keyboard key, the cost of so many small displays may be prohibitive. However, using a collimating optical wedge backlight as described above, transparent keys may be provided with diffusive surfaces and placed over a liquid crystal panel with a collimated backlight. In this manner, an image may be projected up to each key from different areas of a single large but low cost panel.
Another example application for shadow projection is in the projection of an image onto a diffuser where fingers or objects which touch the diffuser are to be sensed with an infrared camera behind. Devices such as Microsoft's SURFACE, developed and sold by the Microsoft Corporation of Redmond, Wash., comprise a video projector, infrared lamp, camera and diffuser. The projector creates a video image on the diffuser, and the lamp illuminates objects nearby so that they appear blurred when off the diffuser but sharp at the moment of touch. The imaging optics can be made slim by pointing the camera at the diffuser via an optical wedge, such as the embodiments described above. If the liquid crystal display is illuminated by diffuse light, the projected image may be spatially separate from the diffuser, and therefore may be blurred. Therefore, the liquid crystal panel may be illuminated with collimated light as disclosed above so that a visible image without blurring forms at the diffuser. In some embodiments, the panel for providing collimated visible illumination and detecting the infrared image are the same, and the end reflector comprises facets at an angle according to this disclosure that reflect visible light but transmit infrared light, and beyond these are placed facets or equivalent which reflect infrared light and are angled so as to form a single unambiguous image.
It will be understood that the configurations and/or approaches described herein are exemplary in nature, and that these specific embodiments or examples are not to be considered in a limiting sense, because numerous variations are possible. The subject matter of the present disclosure includes all novel and nonobvious combinations and subcombinations of the various processes, systems and configurations, and other features, functions, acts, and/or properties disclosed herein, as well as any and all equivalents thereof.
Claims
1. An optical collimator comprising:
- an optical waveguide having a first end comprising a first light interface; a second end opposite the first end; a viewing surface comprising a second light interface extending at least partially between the first end and the second end and having a first critical angle of internal reflection with respect to a normal of the viewing surface; a back surface opposing the viewing surface, the back surface being configured to be reflective to internally incident light at the first critical angle of internal reflection; and an end reflector arranged at the second end of the optical waveguide, wherein the end reflector comprises a faceted lens structure comprising a plurality of facets angled to cause a majority of the viewing surface to be uniformly illuminated when uniform light is injected into a first end and also to cause a majority of the injected light to exit the viewing surface.
2. The optical collimator of claim 1, wherein the first end of the optical waveguide is a thin end and the second end of the optical waveguide is a thick end.
3. The optical collimator of claim 1, wherein the end reflector is spherically curved.
4. The optical collimator of claim 1, wherein the plurality of facets of the faceted lens structure of the end reflector includes a plurality of facets facing the viewing surface and a plurality of facets facing the back surface, each facet facing the viewing surface being positioned adjacent to a facet facing the back surface.
5. The optical collimator of claim 4, wherein each facet facing the viewing surface forms an angle relative to a normal of a surface of the end reflector of three-eighths of a difference between 90 degrees and the first critical angle.
6. The optical collimator of claim 4, wherein each facet facing the back surface forms an angle relative to a normal of a surface of the end reflector equal to three-eighths of a difference between 90 degrees and the first critical angle.
7. The optical collimator of claim 4, wherein each facet facing the viewing surface has a height of less than 500 microns and each facet facing the back surface has a height of less than 500 microns.
8. The optical collimator of claim 1, wherein the back surface includes a second critical angle of internal reflection with respect to a normal of the reflective back surface, wherein the second critical angle of reflection is less than the first critical angle of reflection.
9. The optical collimator of claim 1, wherein the viewing surface of the optical waveguide includes a cladding.
10. The optical collimator of claim 1, wherein the back surface of the optical waveguide includes a cladding.
11. The optical collimator of claim 1, wherein the back surface includes a mirror.
12. The optical collimator of claim 1, wherein the optical waveguide further comprises a first reflective side and a second reflective side, the first reflective side opposite the second reflective side, each reflective side extending from the first end to the second end and from the viewing surface to the back surface.
13. An optical collimator comprising:
- an optical wedge having a thin end comprising a first light interface; a thick end opposite the thin end; a viewing surface comprising a second light interface extending at least partially between the thin end and the thick end and having a first critical angle of internal reflection with respect to a normal of the viewing surface; a back surface opposing the viewing surface and having a second critical angle of internal reflection with respect to a normal of the back surface, wherein the second critical angle of reflection is less than the first critical angle of reflection; and an end reflector arranged at the thick end of the optical wedge, wherein the end reflector comprises a faceted lens structure comprising a plurality of facets arranged at an angle relative to a surface of the thick end, the plurality of facets alternating between facets facing the viewing surface and facets facing the back surface, and the facets having an angle relative to a normal of a surface of the end reflector of three-eighths of a difference of ninety degrees and the first critical angle.
14. The optical collimator of claim 13, wherein the end reflector is spherically curved.
15. The optical collimator of claim 13, wherein the end reflector of the optical wedge is cylindrically curved.
16. The optical collimator of claim 13, wherein each facet facing the viewing surface includes a height of less than 500 microns and each facet facing the back surface includes a height of less than 500 microns.
17. The optical collimator of claim 13, wherein the optical wedge further comprises a first reflective side and a second reflective side, the first reflective side opposite the second reflective side, each reflective side extending from the thin end to the thick end and from the viewing surface to the back surface.
18. A method of collimating light via an optical waveguide, the optical waveguide comprising a first end, a second end opposite the first end and comprising an end reflector, a viewing surface extending between the first end and the second end, and a back surface opposing the viewing surface, the method comprising:
- injecting light into the first end of the optical waveguide;
- delivering the light to the end reflector via total internal reflection;
- internally reflecting the light off of the end reflector;
- emitting a first portion of light from the viewing surface at a critical angle of reflection;
- internally reflecting a second portion of light from the back surface at an angle equal to the critical angle of reflection, and then emitting the second portion of light from the viewing surface after internally reflecting the second portion of light from the back surface.
19. The method of claim 18, wherein reflecting light off the end reflector comprises reflecting light from a first set of facets and a second set of facets, wherein each facet of the first set of facets comprises a normal that points at least partially toward the viewing surface, and wherein each facet of the second set of facets comprises a normal that points at least partially toward the back surface.
20. The method of claim 19, wherein each of the first set of facets has an angle of three-eighths of a difference between 90 degrees and the critical angle of reflection and each of the second set of facets has an angle of three-eighths of the difference between 90 degrees and the critical angle of reflection.
Type: Application
Filed: Nov 18, 2009
Publication Date: Feb 24, 2011
Applicant: MICROSOFT CORPORATION (Redmond, WA)
Inventors: Adrian Travis (Seattle, WA), Timothy Large (Bellevue, WA), Neil Emerton (Redmond, WA), Steven Bathiche (Kirkland, WA)
Application Number: 12/621,399
International Classification: G02B 6/26 (20060101); G02B 27/30 (20060101);