Light trapping optical structure

What is claimed is: 1. An optical article for redistributing light, comprising: a rectangular optically transmissive sheet configured to guide light using total internal reflection and having a first broad-area surface, a second broad-area surface which is parallel to the first broad-area surface, a thickness between a fraction of a millimeter and several millimeters, and length and width dimensions of 100 millimeters or more; an artificial light source configured to illuminate the optically transmissive sheet; a plurality of rounded ridges formed in the first broad-area surface and extending along parallel straight lines between two opposing edges of the optically transmissive sheet; a two-dimensional pattern of discrete cavities formed in the second broad-area surface; a light converting layer extending parallel to the optically transmissive sheet and disposed in an energy receiving relationship with respect to the optically transmissive sheet, the light converting layer comprising a first transparent wall, a second transparent wall, and a partially transmissive layer sandwiched between the first and second transparent walls; a reflective back cover which is approximately coextensive with the optically transmissive sheet and the light converting layer; and a total internal reflection surface located at a distance from the optically transmissive sheet and configured to reflect light using total internal reflection, wherein at least one of the rounded ridges defines a cylindrical lens having an arcuate cross-sectional profile, wherein an area occupied by each of the discrete cavities is less than an area occupied by each of the rounded ridges, and wherein the partially transmissive layer comprises light absorbing elements distributed within an optically transmissive material and configured for absorbing and converting light emitted by the artificial light source. 2. The optical article for redistributing light as recited in claim 1 , wherein the partially transmissive layer comprises titanium dioxide. 3. The optical article for redistributing light as recited in claim 1 , wherein the partially transmissive layer is configured to absorb a first portion of incident light and transmit a second portion of the incident light without absorption, and wherein the light absorbing elements are configured to absorbs less light in a first wavelength than in a second wavelength which is different than the first wavelength. 4. The optical article for redistributing light as recited in claim 1 , wherein the optically transmissive sheet is flexible and is formed into a curved shape. 5. The optical article for redistributing light as recited in claim 1 , wherein the light converting layer is configured for absorbing and converting a portion of light emitted by the artificial light source and transmitting a second portion of the light without absorption. 6. The optical article for redistributing light as recited in claim 1 , wherein the light converting layer is disposed between the optically transmissive sheet and the reflective back cover. 7. The optical article for redistributing light as recited in claim 1 , wherein the light converting layer is approximately coextensive with the total internal reflection surface and is disposed between the first broad-area surface and the total internal reflection surface. 8. The optical article for redistributing light as recited in claim 1 , wherein the second broad-area surface is configured to receive light both on the discrete cavities and on spacing areas separating the discrete cavities, and wherein the light converting layer is configured for absorbing a first portion of light emitted by the artificial light source in a first pass and further absorbing a second portion of the light in a second pass. 9. The optical article for redistributing light as recited in claim 1 , wherein each of the discrete cavities has an elongated shape and a curved wall sloped at an angle with respect to the second broad-area surface, wherein at least some of the discrete cavities are positioned adjacent to or in a proximity to each other along a length or width dimension of the optically transmissive sheet so as to form one or more parallel bands, and wherein a longitudinal axis of at least one of the discrete cavities is aligned parallel to the one or more parallel bands. 10. The optical article for redistributing light as recited in claim 1 , wherein at least some of the discrete cavities have a generally round shape and a curved wall sloped at an angle with respect to the second broad-area surface. 11. The optical article for redistributing light as recited in claim 1 , comprising a regular array of prismatic surface relief features each having a triangular shape in a cross-section. 12. The optical article for redistributing light as recited in claim 1 , comprising a regular array of prismatic surface relief features each having a triangular shape in a cross-section and being configured to refractively and reflectively deflect light. 13. The optical article for redistributing light as recited in claim 1 , comprising light diffusing or light scattering elements. 14. The optical article for redistributing light as recited in claim 1 , wherein the optically transmissive material is extending continuously along length and width dimensions of the optically transmissive sheet. 15. The optical article for redistributing light as recited in claim 1 , wherein at least one of the discrete cavities is configured to receive light propagating within the optically transmissive sheet and direct at least a portion of the light out of the optically transmissive sheet at an angle with respect to a normal to the second broad-area surface. 16. The optical article for redistributing light as recited in claim 1 , wherein at least one of the discrete cavities has a major dimension which is less than a major dimension of the cylindrical lens, and wherein the arcuate cross-sectional profile enables focusing a parallel beam of light into a linear focal area located within boundaries of the optically transmissive sheet. 17. The optical article for redistributing light as recited in claim 1 , wherein the light converting layer is continuous and defines a broad-area light input surface and an opposing broad-area light output surface approximately coextensive with the first and second broad area surfaces, wherein a thickness of the partially transmissive layer is selected to be sufficiently low so as to cause at least a substantial portion of light received on the light input surface to pass through the optically transmissive layer without being absorbed and to exit from the light output surface. 18. The optical article for redistributing light as recited in claim 1 , wherein the light converting layer comprises a plurality of discrete light absorbing areas separated from each other by non-absorbing spacing areas. 19. The optical article for redistributing light as recited in claim 1 , wherein the second transparent wall is disposed in contact with ambient air. 20. A method of making an optical article for redistributing light, comprising: providing a planar optically transmissive sheet having a rectangular shape with four edges, a thickness between a fraction of a millimeter and several millimeters, and a width and/or length of 100 millimeters or more, wherein a first surface of the planar optically transmissive sheet has a parallel array of rounded ridges and an second surface of the planar optically transmissive sheet has a two-dimensional pat