Patent Number: 
Section: claims

1. An optic assembly, comprising:an optic device for transmitting a desired range of X-ray energies though total internal reflection, comprising at least three conformal solid phase layers, wherein interfaces between said solid phase layers are gapless and wherein said at least three conformal solid phase layers include at least one X-ray redirection region; anda filtering mechanism for filtering out certain energies from a beam transmitted by said optic device, wherein said filtering mechanism is at least one of a filtering apparatus external to said optic device and a filtering apparatus integral to said optic device. 2. The assembly of claim 1, wherein said filter apparatus comprises at least one roughened interface surface. 3. The assembly of claim 1, wherein said filter apparatus comprises a filter wheel. 4. The assembly of claim 1, wherein said filter apparatus comprises a dopant. 5. The assembly of claim 1, wherein said filter apparatus comprises a vapor deposited or chemically plated material on an input or an output face of said optic device. 6. The assembly of claim 1, wherein said filter apparatus comprises a choice of different materials in said optic device that determine the critical angle for total internal reflection, wherein the critical angle determines the highest X-ray energies transmitted by said optic device. 7. An array of optic devices, comprising:a first optic portion for transmitting first optic X-ray energies though total internal reflection; anda second optic portion for transmitting second optic X-ray energies, said second optic X-ray energies less than or equal to said first optic X-ray energies,wherein either or both of said first and second optic portions comprises at least three conformal solid phase layers, wherein interfaces between said solid phase layers are gapless and wherein said at least three conformal solid phase layers include at least one X-ray redirection region, and wherein at least two of said layers have different indices of refraction. 8. The array of claim 7, wherein said first and second optic portions comprise opposing halves of a single optic device. 9. The array of claim 7, wherein said first optic portion is formed of materials that pass X-ray energies greater than said second optic X-ray energies. 10. A method for forming a limited energy spectrum image by:taking an image with x-ray energies transmitted though an optic device using total internal reflection;taking a second image with fewer x-ray energies that have been transmitted by the optic device utilizing a filtering mechanism, wherein said filtering mechanism is at least one of a filtering apparatus external to said optic device and a filtering apparatus integral to said optic device, andsubtracting the second image from the first image. 11. A multi-energy imaging system, comprising:a source of electrons;a target for forming X-rays upon being struck by electrons from said source of electrons;a vacuum chamber housing the target;a window though which the X-rays may exit the vacuum chamber;at least one optic device configured to transmit a desired range of X-ray energies, said at least one optic device comprises:a first optic portion for redirecting first optic X-rays though total internal reflection; anda second optic portion for redirecting second optic X-rays, said second optic X-rays being at a lower energy level than said first optic X-rays; andwherein said at least one optic device comprises at least three conformal solid phase layers, wherein interfaces between said solid phase layers are gapless. 12. The multi-energy imaging system of claim 11, wherein:said first optic portion is configured for producing a first optic energy spectrum; andsaid second optic portion is configured for producing a second optic energy spectrum, wherein said first optic energy spectrum contains energies less than or equal to the energies in the said second optic energy spectrum. 13. The multi-energy imaging system of claim 11, comprising a filtering mechanism for filtering out certain energies from a beam transmitted by said at least one optic device, wherein said filtering mechanism is at least one of a filtering apparatus external to said optic device and a filtering apparatus integral to said optic device. 14. The multi-energy imaging system of claim 13, wherein said filter apparatus comprises at least one roughened interface surface. 15. The multi-energy imaging system of claim 11, wherein said at least one optic device comprises at least three conformal solid phase layers, wherein interfaces between said solid phase layers are gapless and wherein said at least three conformal solid phase layers include at least one X-ray redirection region. 16. The multi-energy imaging system of claim 15, wherein said filter apparatus comprises a filter wheel. 17. The multi-energy imaging system of claim 15, wherein said filter apparatus comprises a dopant. 18. The multi-energy imaging system of claim 15, wherein said filter apparatus comprises a vapor deposited or chemically plated material on an input or an output face of said optic device. 19. The multi-energy imaging system of claim 15, wherein said filter apparatus comprises a choice of different materials in said optic device that determine the critical angle for total internal reflection, wherein the critical angle determines the highest X-ray energies transmitted by said optic device. 20. The multi-energy imaging system of claim 11, wherein said at least one optic device comprises a pair of optic devices. 21. A method for manufacturing a multi-energy imaging system for filtering different energy level X-rays through total internal reflection in an imaging system, comprising:providing a target configured to form X-rays upon being struck with electron beams; andproviding at least one optic device in optical communication with the target, the at least one optic device being formed to transmit one level of X-ray energies, wherein said at least one optic device comprises at least three conformal solid phase layers, wherein interfaces between said solid phase layers are gapless and wherein said at least three conformal solid phase layers include at least one X-ray redirection region. 22. The method of claim 21, comprising providing a filter for selectively separating the different energy level X-rays. 23. The method of claim 22, wherein said filter comprises at least one roughened interface surface. 24. The method of claim 22, wherein said filter apparatus comprises a filter wheel. 25. The method of claim 22, wherein said filter apparatus comprises a dopant. 26. The method of claim 22, wherein said filter apparatus comprises a vapor deposited or chemically plated material on an input or an output face of said optic device. 27. The method of claim 22, wherein said filter apparatus comprises a choice of different materials in said optic device that determine the critical angle for total internal reflection, wherein the critical angle determines the highest X-ray energies transmitted by said optic device.