Optical system for batwing distribution

We claim: 1. A radiation distribution system, comprising: a lens along an x-axis and on a mount surface, said lens comprising a width along a y-axis, wherein said y-axis is perpendicular to said x-axis, and a height along a z-axis perpendicular to both the x-axis and the y-axis, said lens comprising a dielectric surface and comprising: a width along a y-axis, wherein said width of said lens is tapered inward toward the middle of said lens; a middle section comprising a concave center region that is tapered in along both the y-axis and the z-axis, said lens configured such that at least some emitted light initially impinging on said middle section of said lens is emitted through a surface of said middle section of said lens; and two rounded end sections, each of said rounded end sections extending farther away from said mount surface in a direction parallel to the z-axis than said middle section, one of said end sections on each side of said middle section; and at least two elongated reflective surfaces external to said lens and proximate to said lens, said elongated reflective surfaces comprising a length along said x-axis, a width along a y-axis, and a height along a z-axis, and wherein said length is larger than each of said width and said height; and wherein light emitted from a radiative source interacts with said two rounded end sections of said lens and said elongated reflective surfaces to yield a batwing distribution pattern. 2. The radiation distribution system of claim 1 , wherein said radiative source is on said mount surface such that a portion of radiation emitted from said radiative source interacts with said lens, wherein the primary emission of said radiative source is along said z-axis or an axis parallel to said z-axis. 3. The radiation distribution system of claim 2 , wherein said radiative source comprises a light emitting diode (LED). 4. The radiation distribution system of claim 2 , wherein said radiative source comprises a plurality of LEDs. 5. The radiation distribution system of claim 2 , wherein a portion of said radiation that interacts with said lens is redirected by said elongated reflective surfaces. 6. The radiation distribution system of claim 2 , further comprising a heat sink in thermal contact with said radiative source such that said heat sink does not obstruct radiation emitted from said radiative source. 7. The radiation distribution system of claim 2 , further comprising an encapsulant on said light source, said lens fitting over said encapsulant. 8. The radiation distribution system of claim 7 , wherein said encapsulant is dome-shaped and fits inside a dome-shaped cavity of said lens. 9. The radiation distribution system of claim 1 , said dielectric surface comprising symmetry with respect to a longitudinal axis and a transverse plane. 10. The radiation distribution system of claim 9 , wherein said lens is longer along the longitudinal direction than in the transverse plane. 11. The radiation distribution system of claim 1 , said at least two reflective surfaces comprising first and second elongated reflective surfaces, said first and second reflective surfaces proximate to said lens on opposite sides such that said first reflective surface faces said second reflective surface. 12. The radiation distribution system of claim 11 , wherein said first and second elongated reflective surfaces are concave. 13. The radiation distribution system of claim 1 , wherein said elongated reflective surfaces comprise a high thermal conductivity material. 14. The radiation distribution system of claim 1 , wherein said elongated reflective surfaces comprise aluminum. 15. The radiation distribution system of claim 1 , said dielectric surface comprising symmetry with respect to a longitudinal axis, wherein said lens is longer along the longitudinal direction than along a direction orthogonal to the longitudinal direction. 16. The radiation distribution system of claim 1 , said dielectric surface comprising a saddle-point at said middle section.