LED illumination assembly with collimating optic

What is claimed: 1. A beam forming optic for use in conjunction with an LED having an optical axis centered on an area of light emission from which light is emitted in a hemispherical emission pattern surrounding said optical axis, said light emitted to one side of a first plane behind said LED and perpendicular to said optical axis, said beam forming optic comprising: a lens centered on said optical axis and defined by a light entry surface, a light emission surface and a convoluted lens bypass surface at the periphery of said lens and extending between said light entry surface and said light emission surface, said light entry surface configured to cooperate with said light emission surface to re-direct light divergent from said optical axis into a direction substantially parallel with said optical axis; a reflector having a polygonal periphery and a concave reflecting surface constructed from segments extending between reflector bypass surfaces radially projecting from the optical axis, each segment defined by a curve having a focus at the area of light emission and rotated about the optical axis, and adjacent segments being defined by curves having different equations, said reflector surrounding said lens and configured to reflect light into a direction substantially parallel with said optical axis, wherein said light entry surface is configured to refract light having a trajectory that is not incident upon said reflecting surface. 2. The beam forming optic of claim 1 , wherein said equations are parabolic equations. 3. The beam forming optic of claim 1 , wherein said light entry surface is concave and said light emission surface is convex and said convoluted lens bypass surface coincides with a path of light from the area of light emission having the smallest angle relative to the optical axis that will be reflected by said reflecting surface. 4. The beam forming optic of claim 1 , wherein said reflecting surface and said lens are included on a solid molded from light transmissive material. 5. The beam forming optic of claim 1 , wherein said reflecting surface is an internal reflecting surface and said beam forming optic defines a pocket including said light entry surface. 6. The beam forming optic of claim 1 , wherein said equations include a first and second equation and said reflecting surface is defined by alternating segments defined by said first and second equations. 7. The beam forming optic of claim 6 , wherein said first and second equations are parabolic equations. 8. The beam forming optic of claim 6 , wherein said polygonal periphery is rectangular and first segments of reflecting surface defined by said first equation form the reflecting surface at each corner of said rectangle, while second segments of said reflecting surface defined by said second equation form the reflecting surface intermediate said first segments. 9. The beam forming optic of claim 8 , wherein said second segments are closer to an optical axis of the beam forming optic coincident with the optical axis of the LED. 10. An LED light assembly comprising: an LED having an optical axis centered on an area of light emission from which light is emitted in a hemispherical emission pattern surrounding said optical axis, said light emitted to one side of a first plane behind said LED and perpendicular to said optical axis; a lens centered on said optical axis and defined by a light entry surface, a light emission surface and a non-circular lens bypass surface at the periphery of said lens and extending between said light entry surface and said light emission surface, said light entry surface configured to cooperate with said light emission surface to re-direct light divergent from said optical axis into a direction substantially parallel with said optical axis; a reflector having a polygonal periphery and a concave reflecting surface defined by an equation having a focus at the area of light emission, said reflector surrounding said lens and configured to reflect light into a direction substantially parallel with said optical axis, wherein said lens bypass surface coincides with a path of light from the area of light emission having the smallest angle relative to the optical axis that will be reflected by said reflecting surface.