Bibliographic Details
| Title: |
Dimpled Light Collection and Concentration System, Components Thereof, and Methods |
| Document Number: |
20100329619 |
| Publication Date: |
December 30, 2010 |
| Appl. No: |
12/490417 |
| Application Filed: |
June 24, 2009 |
| Abstract: |
A light guide apparatus includes a light guide layer further including light injection elements and respective light bypass elements disposed optically upstream of the light injection elements. The light injection elements and/or the bypass elements can take the form of injection facets (air prisms), surface diffraction elements, volume diffraction elements, and gradient index profiles. A light collection and concentration system comprises a single light guide apparatus, a light-transmitting medium layer disposed immediately adjacent the single light guide apparatus, and a primary light concentrator component disposed adjacent the light-transmitting medium layer, including a plurality of primary concentrator elements each of which is in optical registration with a respective one of the light injection elements of the single light guide apparatus. |
| Inventors: |
Moore, Duncan T. (Fairport, NY, US); Schmidt, Greg R. (Gates, NY, US); Unger, Blair L. (Rochester, NY, US) |
| Assignees: |
University of Rochester (Rochester, NY, US) |
| Claim: |
1. A light guide apparatus, comprising: a light guide layer having a top surface and a bottom surface, at least one of which is a substantially planar surface, and a transversely oriented side-end surface that forms an output aperture of the light guide, characterized by an index of refraction, n1, further characterized by a length dimension in an intended light propagation direction towards the output aperture; a plurality of light injection elements disposed in at least one of the top and bottom surfaces; and a respective plurality of by-pass elements disposed within the light guide layer optically upstream from each respective light injection element. |
| Claim: |
2. The light guide apparatus of claim 1, wherein the light injection elements are air prisms. |
| Claim: |
3. The light guide apparatus of claim 2, wherein the by-pass elements are air prisms. |
| Claim: |
4. The light guide apparatus of claim 3, wherein each by-pass element has a head end that coincides with its respective light injection element and a tail end extending rearwardly therefrom. |
| Claim: |
5. The light guide apparatus of claim 1, wherein each by-pass element has at least one surface extending between the head and tail ends. |
| Claim: |
6. The light guide apparatus of claim 5, wherein the at least one side surface is curved. |
| Claim: |
7. The light guide apparatus of claim 5, wherein the at least one side surface includes two flat surfaces. |
| Claim: |
8. The light guide apparatus of claim 1, wherein at least one of the plurality of light injection elements is tilted (clocked) in an x-axis direction (width dimension) of the light guide. |
| Claim: |
9. The light guide apparatus of claim 1, further comprising a light-transmitting medium layer characterized by an index of refraction, nmed, where nmed is less than n1, disposed immediately adjacent at least one of the top and bottom surfaces of the light guide layer. |
| Claim: |
10. The light guide apparatus of claim 9, wherein the light-transmitting medium layer is air. |
| Claim: |
11. The light guide apparatus of claim 9, wherein the light-transmitting medium layer is solid. |
| Claim: |
12. The light guide apparatus of claim 1, wherein at least one of the light injection elements has a curved face surface. |
| Claim: |
13. The light guide apparatus of claim 1, wherein the plurality of light injection elements and the respective plurality of bypass elements are integrally disposed in the light guide layer. |
| Claim: |
14. The light guide apparatus of claim 1, wherein the plurality of light injection elements and the respective plurality of bypass elements are integrally disposed in a separate material layer that is attached to the light guide layer and, which, forms at least one of the top and bottom surfaces of the light guide layer. |
| Claim: |
15. The light guide apparatus of claim 1, wherein the light injection elements are volume diffraction elements. |
| Claim: |
16. The light guide apparatus of claim 1, wherein the bypass elements are volume diffraction elements. |
| Claim: |
17. The light guide apparatus of claim 1, wherein each of the bypass elements is one of a linear and a parabolic gradient index profile that is uniform across an x-z plane of the guide layer. |
| Claim: |
18. The light guide apparatus of claim 1, wherein each of the bypass elements is one of a linear and a parabolic gradient index profile along a z-axis direction with the gradient varying in an x-direction and having a minimum index at a z-axis location of each injection element and a maximum index at a location between adjacent injection elements. |
| Claim: |
19. A light guide apparatus, comprising: a light guide layer having a top surface and a bottom surface, at least one of which is a substantially planar surface, and a transversely oriented side-end surface that forms an output aperture of the light guide, characterized by an index of refraction, n1, further characterized by a length dimension in an intended light propagation direction towards the output aperture; and a plurality of diffraction grating light injection elements disposed in the light guide layer. |
| Claim: |
20. The light guide apparatus of claim 19, wherein the diffraction grating light injection elements are disposed in at least one of the top and bottom surface in the plane of said surface. |
| Claim: |
21. The light guide apparatus of claim 19, wherein the diffraction grating light injection elements are disposed between the top and bottom surfaces along a longitudinal plane of the guide layer. |
| Claim: |
22. A light collection and concentration system, comprising: a single light guide component comprising: a light guide layer having a top surface and a bottom surface, at least one of which is a substantially planar surface, and a transversely oriented side-end surface that forms an output aperture of the light guide, characterized by an index of refraction, n1, further characterized by a length dimension in an intended light propagation direction towards the output aperture; a plurality of light injection elements disposed in at least one of the top and bottom surfaces; and a respective plurality of bypass elements disposed within the light guide layer optically upstream from each respective light injection element; a light-transmitting medium layer characterized by an index of refraction, nmed, where nmed is less than n1, disposed immediately adjacent at least one of the top and bottom surfaces of the light guide layer; and a primary light concentrator component disposed adjacent the light-transmitting medium layer including a plurality of primary concentrator elements each of which is in optical registration with a respective one of the light injection elements. |
| Claim: |
23. The light collection and concentration system of claim 22, wherein the light-transmitting medium layer is disposed intermediate the primary light concentrator component and the top surface of the light guide layer. |
| Claim: |
24. The light collection and concentration system of claim 23, wherein the plurality of light injection elements are disposed in the bottom surface of the light guide layer. |
| Claim: |
25. The light collection and concentration system of claim 23, wherein the plurality of light injection elements are disposed in the top surface of the light guide layer, further comprising a reflective material layer disposed adjacent the bottom surface of the light guide layer. |
| Claim: |
26. The light collection and concentration system of claim 22, wherein the primary light concentrator component is a refractive lenslet array. |
| Claim: |
27. The light collection and concentration system of claim 26, wherein each of the lenslets have curvature in two dimensions. |
| Claim: |
28. The light collection and concentration system of claim 27, wherein the curvatures are equal. |
| Claim: |
29. The light collection and concentration system of claim 22, wherein the primary light concentrator component is an array of Fresnel lenses. |
| Claim: |
30. The light collection and concentration system of claim 22, wherein the primary light concentrator component has optical characteristics that provide converging light on the injection elements from a substantially plane wave input light. |
| Claim: |
31. The light collection and concentration system of claim 22, wherein the light injection elements are air prisms. |
| Claim: |
32. The light collection and concentration system of claim 22, wherein the bypass elements are air prisms. |
| Claim: |
33. The light collection and concentration system of claim 22, wherein the light injection elements are volume diffraction elements. |
| Claim: |
34. The light collection and concentration system of claim 22, wherein the bypass elements are volume diffraction elements. |
| Claim: |
35. The light collection and concentration system of claim 22, wherein each of the bypass elements is one of a linear and a parabolic gradient index profile that is uniform across an x-z plane of the guide layer. |
| Claim: |
36. The light collection and concentration system of claim 22, wherein each of the bypass elements is one of a linear and a parabolic gradient index profile along a z-axis direction with the gradient varying in an x-direction and having a minimum index at a z-axis location of each injection element and a maximum index at a location between adjacent injection elements. |
| Current U.S. Class: |
385/129 |
| Current International Class: |
02 |
| Accession Number: |
edspap.20100329619 |
| Database: |
USPTO Patent Applications |
