Hybrid Concentrator for a Backlight

What is claimed is: 1 . A backlight for a display, the backlight comprising: a light guide; a plurality of light sources positioned along an input end of the light guide; and a plurality of hybrid concentrators, each hybrid concentrator positioned between a corresponding light source and the light guide and configured to concentrate light from the corresponding light source into the light guide, and each hybrid concentrator comprising: a lens in a central region of the hybrid concentrator; and one or more total-internal-reflection (TIR) zones, each of the one or more TIR zones including a reflective wall configured to reflect high-angle light into the light guide. 2 . The backlight of claim 1 , wherein the central region is configured to receive low-angle light from the corresponding light source and refract the low-angle light through the lens into the light guide. 3 . The backlight of claim 1 , wherein the central region is configured to receive high-angle light from the corresponding light source and refract the high-angle light into one of the TIR zones. 4 . The backlight of claim 3 , wherein each of the one or more TIR zones is bound by a refractive sidewall and the reflective wall. 5 . The backlight of claim 1 , wherein the central region is bound by two refractive sidewalls, each refractive sidewall configured to refract high-angle light from the corresponding light source into one of the TIR zones. 6 . The backlight of claim 5 , wherein the refractive sidewalls are substantially perpendicular to the input end of the light guide. 7 . The backlight of claim 5 , wherein the refractive sidewalls are tilted to reduce the reflection of light off of the refractive sidewalls. 8 . The backlight of claim 1 , wherein the central region includes a low refractive index gap between the corresponding light source and the lens. 9 . The backlight of claim 8 , further comprising reflective top and bottom layers that cover the low refractive index gap between the corresponding light source and the lens. 10 . The backlight of claim 1 , wherein at least one of the hybrid concentrators includes one TIR zone positioned on each side of the central region. 11 . The backlight of claim 1 , wherein at least one of the hybrid concentrators includes two TIR zones positioned on each side of the central region. 12 . The backlight of claim 1 , wherein the plurality of hybrid concentrators are cut into the input end of the light guide. 13 . A display device comprising: a display comprising: a modulating display panel; a backlight configured to illuminate the modulating display panel, the backlight comprising: a light guide comprising an input end and a reflective end; a plurality of light sources positioned along the input end of the light guide; and a plurality of hybrid concentrators, each hybrid concentrator positioned between a corresponding light source and the light guide, and each hybrid concentrator comprising a lens in a central region of the hybrid concentrator and one or more total-internal-reflection (TIR) zones, each of the one or more TIR zones including a reflective wall configured to reflect high-angle light into the light guide; a controller configured to control the plurality of light sources to inject light into the light guide via the plurality of concentrators to cause the light guide to illuminate the display panel. 14 . The display device of claim 13 , wherein the central region is configured to receive low-angle light from the corresponding light source and refract the low-angle light through the lens into the light guide. 15 . The display device of claim 13 , wherein the central region is configured to receive high-angle light from the corresponding light source and refract the high-angle light into one of the TIR zones. 16 . The display device of claim 13 , wherein each of the one or more TIR zones is bound by a refractive sidewall and the reflective wall. 17 . A method comprising: controlling one or more light sources to inject light into a light guide via a plurality of hybrid concentrators, each of the hybrid concentrators positioned between the light guide and a corresponding light source, and each hybrid concentrator including a lens in a central region and one or more total-internal-reflection (TIR) zones, each of the one or more TIR zones including a reflective wall configured to reflect high-angle light into the light guide; and controlling a display panel positioned between a viewer and the light guide to use light received from the light guide to project images for viewing to the viewer. 18 . The method of claim 17 , wherein the central region is configured to receive low-angle light from the corresponding light source and refract the low-angle light through the lens into the light guide. 19 . The method of claim 17 , wherein the central region is configured to receive high-angle light from the corresponding light source and refract the high-angle light into one of the TIR zones. 20 . The method of claim 17 , wherein each of the one or more TIR zones is bound by a refractive sidewall and the reflective wall.