Apparatus having blue light source, dichroic mirror and phosphor converter to generate white light

What is claimed is: 1. An apparatus comprising: a first blue light source configured to provide a first blue light beam, the first blue light source being a blue laser light source, and the first blue light beam being a blue laser light beam; a collimating lens, optically coupled to the first blue light source, configured to collimate the first blue light beam into a collimated blue light beam; an optical diffuser, optically coupled to the collimating lens, configured to optically homogenize the collimated blue light beam into a top hat spatially distributed beam; a yellow phosphor converter configured to convert the top hat spatially distributed beam into a phosphor-emitted light beam, at least a majority of the phosphor-emitted light beam being yellow light converted from blue light of the top hat spatially distributed beam; condensing and collimating lenses, optically coupled to the yellow phosphor converter, configured to condense and collimate the phosphor-emitted light beam into a condensed and collimated phosphor-emitted light beam; a dichroic mirror, optically coupled to the condensing and collimating lenses, configured to filter the condensed and collimated phosphor-emitted light beam into a dichroic-filtered light beam passed by the dichroic mirror, including by passing yellow light and reflecting at least some blue light; and a second blue light source, optically coupled to the dichroic mirror, configured to provide a second blue light beam, the dichroic mirror configured to reflect the second blue light beam in a same direction as the dichroic-filtered light beam to generate a white light beam. 2. The apparatus of claim 1 , wherein the yellow phosphor converter is one selected from a group consisting of a yellow phosphor plate and a yellow phosphor wheel. 3. The apparatus of claim 1 , wherein the second blue light source includes a blue light emitting diode. 4. The apparatus of claim 1 , wherein a portion of the phosphor-emitted light beam is unconverted blue laser light. 5. The apparatus of claim 1 , wherein the dichroic mirror is configured to reflect all blue light. 6. The apparatus of claim 1 , wherein the apparatus is a component of a headlamp. 7. The apparatus of claim 1 , wherein the phosphor-emitted light beam has a same direction as the top hat spatially distributed beam. 8. A headlamp, comprising: a first blue light source configured to provide a first blue light beam, the first blue light source being a blue laser light source, and the first blue light beam being a blue laser light beam; a collimating lens, optically coupled to the first blue light source, configured to collimate the first blue light beam into a collimated blue light beam; an optical diffuser, optically coupled to the collimating lens, configured to optically homogenize the collimated blue light beam into a top hat spatially distributed beam; a yellow phosphor converter configured to convert the top hat spatially distributed beam into a phosphor-emitted light beam, at least a majority of the phosphor-emitted light beam being yellow light converted from blue light of the top hat spatially distributed beam; condensing and collimating lenses, optically coupled to the yellow phosphor converter, configured to condense and collimate the phosphor-emitted light beam into a condensed and collimated phosphor-emitted light beam; a dichroic mirror, optically coupled to the condensing and collimating lenses, configured to filter the condensed and collimated phosphor-emitted light beam into a dichroic-filtered light beam passed by the dichroic mirror, including by passing yellow light and reflecting at least some blue light; and a second blue light source, optically coupled to the dichroic mirror, configured to provide a second blue light beam, the dichroic mirror configured to reflect the second blue light beam in a same direction as the dichroic-filtered light beam to generate a white light beam; a spatial light modulator configured to modulate the white light beam at a pixel level to generate an image; illumination optics, optically coupled between the dichroic mirror and the spatial light modulator, the illumination optics configured to illuminate the spatial light modulator with the white light beam; and projection optics, optically coupled to the spatial light modulator, configured to receive the generated image and project a larger version of the generated image at a distance away from the headlamp. 9. The headlamp of claim 8 , wherein the spatial light modulator is a digital micromirror device. 10. The headlamp of claim 8 , wherein the yellow phosphor converter is one selected from a group consisting of a yellow phosphor plate and a yellow phosphor wheel. 11. The headlamp of claim 8 , wherein a portion of the phosphor-emitted light beam is unconverted blue laser light. 12. The headlamp of claim 8 , wherein the dichroic mirror is configured to reflect all blue light. 13. The headlamp of claim 8 , wherein the phosphor-emitted light beam has a same direction as the top hat spatially distributed beam. 14. A method comprising: providing a first blue light beam, the first blue light beam being a blue laser light beam; with a collimating lens, collimating the first blue light beam into a collimated blue light beam; with an optical diffuser, optically homogenizing the collimated blue light beam into a top hat spatially distributed beam; with a yellow phosphor converter, converting the top hat spatially distributed beam into a phosphor-emitted light beam, at least a majority of the phosphor-emitted light beam being yellow light converted from blue light of the top hat spatially distributed beam; condensing and collimating the phosphor-emitted light beam into a condensed and collimated phosphor-emitted light beam; with a dichroic mirror, filtering the condensed and collimated phosphor-emitted light beam into a dichroic-filtered light beam passed by the dichroic mirror, including by passing yellow light and reflecting at least some blue light; providing a second blue light beam; and with the dichroic mirror, reflecting the second blue light beam in a same direction as the dichroic-filtered light beam to generate a white light beam. 15. The method of claim 14 , wherein the phosphor-emitted light beam has a same direction as the top hat spatially distributed beam.