LED lamp incorporating remote phosphor with heat dissipation features

We claim: 1. A lamp, comprising: a light source; a planar phosphor carrier remote to said light source and comprising a thermally conductive material at least partially transparent to light from said light source, and a conversion material that absorbs light from said light source and emits different wavelengths of light; and a heat sink structure which forms walls of an optical cavity and comprising fins which extend from said walls of said optical cavity in a direction parallel to said planar phosphor carrier, said phosphor carrier thermally coupled to said heat sink structure, said light source mounted within said optical cavity; wherein said phosphor carrier comprises a carrier layer and a phosphor layer, said carrier layer comprising a first surface adjacent said phosphor layer and a second surface opposite said phosphor layer; wherein a portion of said first surface is uncovered by said phosphor layer, said uncovered portion of said first surface contacting said heat sink such that said first surface of said carrier layer and said phosphor layer are adjacent to said heat sink and said second surface of said carrier layer is opposite said heat sink. 2. The lamp of claim 1 , wherein said phosphor carrier comprises scattering particles. 3. The lamp of claim 1 , wherein said phosphor carrier comprises a separate layer containing scattering particles. 4. The lamp of claim 1 , wherein said phosphor carrier comprises a surface that is roughened. 5. The lamp of claim 1 , wherein heat from said phosphor carrier conducts into said heat sink structure through said thermal coupling. 6. The lamp of claim 1 , wherein said light source comprises an LED based light source. 7. The lamp of claim 1 , wherein said light source comprises a blue emitting LED and said phosphor carrier comprises a phosphor that absorbs blue light and re-emits a different wavelength of light, said lamp emitting a perceived white light combination of blue LED light and conversion material light. 8. The lamp of claim 1 , said phosphor carrier mounted over an opening in said optical cavity, with light from said light source passing through said phosphor carrier. 9. The lamp of claim 8 , wherein said optical cavity comprises reflective surfaces. 10. A light emitting diode (LED) based lamp, comprising: an LED light source; a planar phosphor remote to said light source such that light emitted from said light source passes through said phosphor and is converted by said phosphor; a heat sink which forms the walls of an optical cavity, said light source mounted within said cavity; wherein said planar phosphor comprises a phosphor carrier and said phosphor carrier comprises a phosphor layer and a carrier layer and, said carrier layer comprising a first surface adjacent said phosphor layer and a second surface opposite said phosphor layer, wherein a portion of said first surface is uncovered by said phosphor layer; and a thermally conductive path to conduct phosphor conversion heat away from said planar phosphor and to dissipate said heat, wherein a portion of said first surface is uncovered by said phosphor layer, said uncovered portion of said first surface contacting said thermally conductive path, wherein said first surface of said carrier layer and said phosphor layer are adjacent to said thermally conductive path and said second surface of said carrier layer is opposite said thermally conductive path. 11. The lamp of claim 10 , said thermally conductive path at least partially comprising said heat sink. 12. The lamp of claim 10 , wherein said phosphor carrier comprises a thermally conductive transparent material. 13. The lamp of claim 10 , further comprising scattering particles. 14. The lamp of claim 10 , wherein said light source comprises a blue emitting LED and said phosphor layer absorbs blue light and re-emits a different wavelength of light, said lamp emitting a perceived white light combination of blue LED light and phosphor light. 15. The lamp of claim 10 , said planar phosphor over an opening in said cavity, with light from said light source passing through said planar phosphor. 16. The lamp of claim 15 , wherein said optical cavity comprises reflective surfaces. 17. A lamp, comprising: a heat sink structure comprising fins, said heat sink structure forming an optical cavity; a light emitting diode (LED) based light source in said cavity; a conversion material comprising a planar phosphor layer and a carrier layer, said carrier layer comprising a first surface adjacent to said phosphor layer and a second surface opposite said phosphor layer, said conversion material remote to said light source and which absorbs light from said light source and re-emits light in different wavelengths, such that said fins extend from said optical cavity in a direction parallel to said planar phosphor layer, wherein a portion of said first surface is uncovered by said phosphor layer, said uncovered portion of said first surface contacting said heat sink such that said first surface of said carrier layer and said phosphor layer is adjacent to said heat sink and said second surface of said carrier layer is opposite said heat sink; and a first thermally conductive path to conduct conversion generated heat away from said conversion material to said heat sink; wherein said planar phosphor layer is between said light source and said carrier layer. 18. The lamp of claim 17 , said conversion material on an optical cavity opening, with light from said light source passing through said conversion material. 19. The lamp of claim 18 , further comprising a platform within said optical cavity, said light source mounted on said cavity with heat dissipating from said light source through said platform. 20. The lamp of claim 18 , wherein said optical cavity comprises reflective surfaces. 21. The lamp of claim 17 , wherein heat from said first light source is conducted away from said light source through a second thermally conductive path. 22. The lamp of claim 21 , wherein said first and second thermally conductive paths are coupled. 23. The lamp of claim 21 , wherein said first and second thermally conductive paths are de-coupled.