Laser illumination lighting device with solid medium freeform prism or waveguide

What is claimed is: 1. A lighting device comprising: a luminaire comprising: a laser light source configured to be driven by electrical power to emit laser light rays; a phosphor plate; and a solid medium freeform prism or waveguide to confine incoming laser light rays emitted from the laser light source inside the solid medium freeform prism or waveguide until conversion into illumination lighting by the phosphor plate, the solid medium freeform prism or waveguide including: an input surface or lens coupled to the laser light source to shape the incoming laser light rays passing through and entering inside the solid medium waveguide freeform prism or waveguide into shaped laser light rays; an output surface; a highly reflective internal surface to reflect the shaped laser light rays to propagate inside the solid medium freeform prism or waveguide until emission through the output surface; and wherein the output surface emits the reflected shaped laser light rays to the phosphor plate; wherein the phosphor plate is coupled to the output surface of the solid medium freeform prism or waveguide to convert the reflected shaped laser light rays into the illumination lighting to emit from the luminaire; and a laser light source driver coupled to the laser light source to selectively control the laser light source to emit the laser light rays. 2. A lighting device comprising: a luminaire comprising: a laser light source configured to be driven by electrical power to emit laser light rays; a phosphor plate; and a solid medium freeform prism to confine incoming laser light rays emitted from the laser light source inside the solid medium freeform prism until conversion into illumination lighting by the phosphor plate, the solid medium freeform prism including: an input surface coupled to the laser light source to shape the incoming laser light rays passing through and entering inside the solid medium freeform prism into shaped laser light rays; an output surface; a highly reflective internal surface to reflect the shaped laser light rays to propagate inside the solid medium freeform prism until emission through the output surface; and wherein the output surface emits the shaped laser light rays to the phosphor plate; wherein the phosphor plate is coupled to the output surface of the solid medium freeform prism to convert the reflected shaped laser light rays into the illumination lighting to emit from the luminaire; and a laser light source driver coupled to the laser light source to selectively control the laser light source to emit the laser light rays. 3. The lighting device of claim 2 , wherein: the phosphor plate is a transmissive coating or layer deposited directly or indirectly on the output surface; the luminaire further includes a reflector or lens coupled to the phosphor plate on the output surface to shape a beam pattern of the emitted illumination lighting; the input surface is an aspherical or spherical shape and includes a first antireflective coating; the input surface and the laser light source are coupled together without an air gap in between; the highly reflective internal surface is a half TIR lens shape; and the output surface includes a second antireflective coating. 4. A lighting device comprising: a luminaire comprising: a laser light source configured to be driven by electrical power to emit laser light rays; a phosphor plate; a solid medium waveguide to confine incoming laser light rays emitted from the laser light source inside the solid medium waveguide until conversion into illumination lighting by the phosphor plate, the solid medium waveguide including: an input surface coupled to the laser light source for incoming laser light rays emitted by the laser light source to enter the solid medium waveguide; an output surface; and a highly reflective internal surface to steer the laser light rays passing through the solid medium waveguide to the phosphor plate, the highly reflective internal surface including an initial highly reflective internal surface portion to initially reflect the laser light rays to propagate inside a remainder the solid medium waveguide; wherein the phosphor plate is coupled to the solid medium waveguide to convert the reflected laser light rays into the illumination lighting; and a laser light source driver coupled to the laser light source to selectively control the laser light source to emit the laser light rays. 5. The lighting device of claim 4 , wherein: the input surface is in an optical path between the laser light source and the initial highly reflective internal surface portion; the input surface includes an aspherical or spherical shape to collimate the incoming laser light rays emitted by the laser light source passing through and entering inside the solid medium waveguide into collimated laser light rays prior to striking the initial highly reflective internal surface portion; and the input surface and the laser light source are coupled together without an air gap in between. 6. The lighting device of claim 4 , wherein the luminaire further comprises: a collimating lens in an optical path between laser light source and the input surface to collimate the incoming laser light rays emitted by the laser light source passing through and entering inside the solid medium freeform waveguide into collimated laser light rays prior to striking the input surface. 7. The lighting device of claim 4 , wherein the input surface includes an antireflective coating. 8. The lighting device of claim 4 , wherein: the solid medium waveguide is formed of acrylic, glass, silicone, fused silica, or a combination thereof; the initial highly reflective internal surface portion includes a total internal reflection (TIR) shape; and the highly reflective internal surface includes at least one highly reflective optical coating or layer. 9. The lighting device of claim 8 , wherein the at least one highly reflective optical coating or layer includes a dichroic film, a silvered mirror, or a combination thereof. 10. The lighting device of claim 4 , wherein the solid medium waveguide is a wedge shape and the initial highly reflective internal surface portion includes a tapered surface of the wedge shape to initially reflect the laser light rays to propagate inside the remainder of the solid medium waveguide. 11. The lighting device of claim 4 , wherein: the luminaire further comprises a holographic reflective optical element coupled to the output surface of the solid medium waveguide; the phosphor plate includes a phosphor layer deposited on a reflective substrate; and the holographic reflective optical element is wavelength sensitive to selectively emit illumination lighting reflected from the phosphor plate through the output surface of the solid medium waveguide and substantially exclude the reflected laser light rays from emission through the output surface of the solid medium waveguide. 12. The lighting device of claim 11 , wherein: the phosphor layer includes a ceramic powder phosphor or a single-crystal phosphor; and the reflective substrate includes aluminum oxide. 13. The lighting device of claim 4 , wherein: the highly reflective internal surface includes a holographic reflective optical element to reflect the laser light rays towards the phosphor plate; the phosphor plate is transmissive and is coupled to the output surface of the solid medium waveguide; and the luminaire further includes a reflector or lens coupled to the transmissive phosphor plate on the output surface to shape a beam pattern of the emitted illumination lighting.