Tungsten-halogen electromagnetic radiation optical systems source

The invention claimed is: 1. A tungsten-halogen electromagnetic radiation source, comprising: a sealed transparent polycrystalline ceramic envelope defining an interior volume; a tungsten filament disposed within the interior volume; and a fill gas in the interior volume wherein the fill gas contains at least a gaseous halogen compound; wherein the transparent polycrystalline ceramic envelope is made from an aluminum oxynitride material. 2. The tungsten-halogen electromagnetic radiation source of claim 1 wherein the transparent polycrystalline ceramic envelope further comprises at least one optical element integrally formed into the envelope. 3. The tungsten-halogen electromagnetic radiation source of claim 2 wherein the at least one optical element integrally formed into the envelope is chosen from the group consisting of: an optical mirror, an optical lens, and an optical electromagnetic radiation guide. 4. The tungsten-halogen electromagnetic radiation source of claim 3 wherein the optical mirror is chosen from the group consisting of: a spherical mirror and a parabolic mirror. 5. The tungsten-halogen electromagnetic radiation source of claim 3 wherein the optical lens is chosen from the group consisting of: a convex lens, a concave lens and a Fresnel lens. 6. The tungsten-halogen electromagnetic radiation source of claim 3 wherein the optical mirror further comprises a reflective coating deposited thereon. 7. The tungsten-halogen electromagnetic radiation source of claim 1 , wherein the gaseous halogen compound comprises a fluoride compound. 8. The tungsten-halogen electromagnetic radiation source of claim 7 wherein the fluoride compound is chosen from the group consisting of: a fluoroform (CHF3, a silver (II) fluoride (AgF2), and a silver subfloride (Ag2F) compound. 9. A system for detecting at least one characteristic of a reservoir sample comprising: a flow conduit; an electromagnetic radiation source having a tungsten filament and a sealed optically transparent aluminum oxynitride envelope, the sealed optically transparent envelope defining an interior volume; an integrated computational optical element positioned opposite the flow conduit from the radiation source to receive a sample interacted electromagnetic radiation from the electromagnetic radiation source; a radiation transducer positioned to receive the sample interacted electromagnetic radiation from the integrated computational optical element. 10. The system of claim 9 further comprising a fill gas in the interior volume of the electromagnetic radiation source wherein the fill gas contains at least one gaseous fluoride compound chosen from the group consisting of: a fluoroform (CHF3) compound, a silver (II) fluoride (AgF2) compound, and a silver subfloride (Ag2F) compound. 11. The system of claim 9 wherein the sealed optically transparent envelope of the electromagnetic radiation source further comprises at least one optical element integrally formed into the sealed optically transparent envelope. 12. The system of claim 11 wherein the at least one optical element integrally formed into the sealed optically transparent envelope is chosen from the group consisting of: an optical mirror, an optical lens, and an optical electromagnetic radiation guide. 13. The system of claim 12 wherein the optical mirror is chosen from the group consisting of: a spherical mirror and a parabolic mirror. 14. The system of claim 12 wherein the optical lens is chosen from the group consisting of: a convex lens, concave lens, and a Fresnel lens. 15. The system of claim 9 further comprising a controller to relate an output signal from the radiation transducer to at least one characteristic of the reservoir sample. 16. A tungsten-halogen electromagnetic radiation source, comprising: a sealed transparent aluminum oxynitride envelope defining an interior volume; at least one optical element integrally formed into the aluminum oxynitride envelope; a tungsten filament; and a fill gas in the interior volume wherein the fill gas contains at least a gaseous fluoride compound. 17. The tungsten-halogen electromagnetic radiation source of claim 16 wherein the at least one optical element integrally formed into the aluminum oxynitride envelope is chosen from the group consisting of: an optical mirror, an optical lens, and an optical electromagnetic radiation guide. 18. The tungsten-halogen electromagnetic radiation source of claim 17 wherein the optical mirror is chosen from the group consisting of: a spherical mirror and a parabolic mirror. 19. The tungsten-halogen electromagnetic radiation source of claim 17 wherein the optical lens is chosen from the group consisting of: a convex lens; a concave lens, and a Fresnel lens. 20. The tungsten-halogen electromagnetic radiation source of claim 16 wherein the gaseous fluoride compound is chosen from the group consisting of: a fluoroform (CHF3) compound, a silver (II) fluoride (AgF2) compound, and a silver subfloride (Ag2F) compound.