Multi order diffractive devices

What is claimed: 1. A Fizeau interferometer comprising: a light source configured to generate light; a diffractive lens configured to receive the light from the light source and to generate first diffracted light; a mirror, spaced apart from the diffractive lens, the mirror configured to reflect the first diffracted light toward the diffractive lens, the diffractive lens configured to direct the first diffracted light reflected by the mirror to an image surface of the diffractive lens; and a detector positioned proximate the image surface of the diffractive lens, wherein the diffractive lens is configured to reflect a portion of light directed from the image surface back to the image surface as second diffracted light, the second diffracted light having a different diffraction order than the first diffracted light, and the detector is configured to detect interference between the first diffracted light and the second diffracted light. 2. The Fizeau interferometer of claim 1 wherein the first diffracted light has an nth diffraction order and the second diffracted light has a 2nth diffraction order, where n is a positive or negative integer. 3. The Fizeau interferometer of claim 1 wherein the diffractive lens includes a transmissive diffractive lens. 4. The Fizeau interferometer of claim 1 wherein the diffractive lens includes a reflective diffractive lens. 5. The Fizeau interferometer of claim 1 further comprising: an optic under test positioned in a cavity formed between the diffractive lens and the mirror. 6. The Fizeau interferometer of claim 5 wherein the detector is configured to characterize at least one of the Fizeau interferometer or the optic under test based on the interference between the first diffracted light and the second diffracted light. 7. The Fizeau interferometer of claim 5 , further comprising at least one moving stage configured to move at least one of the mirror, the diffractive lens, the detector, or the optic under test. 8. The Fizeau interferometer of claim 1 wherein the detector includes at least one camera configured to detect an interference pattern between the first diffracted light and the second diffracted light. 9. The Fizeau interferometer of claim 1 , further comprising at least one moving stage configured to move at least one of the mirror, the diffractive lens, or the detector. 10. An in-flight metrology system comprising: at least one diffractive focusing element configured to: receive collimated or near collimated light from a first light source and generate first diffracted light, the first diffracted light directed to an image surface of the at least one diffractive focusing element, and reflect a portion of light directed from the image surface back to the image surface as second diffracted light, the second diffracted light having a different diffraction order than the first diffracted light; and a diagnostic measuring device configured to receive the second diffracted light and to characterize the metrology system based on the received second diffracted light. 11. The system of claim 10 wherein: the metrology system is configured to adjust at least one component of the metrology system based on the characterization by the diagnostic measuring device. 12. The system of claim 10 wherein the diagnostic measuring device includes at least one of an interferometer or a wavefront sensor. 13. The system of claim 10 , wherein the at least one diffractive focusing element includes a transmissive element or a reflective element. 14. The system of claim 10 wherein the first diffracted light has an nth diffraction order and the second diffracted light has a 2nth diffraction order, where n is a positive or negative integer. 15. The system of claim 10 further comprising a second light source positioned at the image surface for generating the portion of light directed from the image surface back to the image surface as second diffracted light. 16. An imaging system, comprising: the in-flight metrology system of claim 10 , and an imaging sensor configured to receive the first diffracted light and generate at least one image of an area imaged by the metrology system. 17. The imaging system of claim 16 further comprising: a beam splitter positioned proximate the image surface of the at least one diffractive focusing element, the beam splitter configured to direct the first diffracted light to the imaging sensor and direct the second diffracted light to the diagnostic measuring device. 18. The imaging system of claim 16 , wherein the at least one diffractive focusing element comprises an array of diffractive focusing elements. 19. The imaging system of claim 18 , wherein the array is a transmissive diffractive array. 20. The imaging system of claim 18 , wherein the array is a reflective diffractive array. 21. A method of testing an optical system including at least one diffractive focusing element, the method comprising the steps of: directing light to interact with the at least one diffractive focusing element; modifying the light by the at least one diffractive focusing element to form first diffracted light; directing the first diffracted light to an image surface of the at least one diffractive focusing element; reflecting, by the at least one diffractive focusing element, a portion of light directed from the image surface back to the image surface as second diffracted light, the second diffracted light having a different diffraction order than the first diffracted light; and detecting the second diffracted light to characterize the optical system. 22. The method of claim 21 the method further including: prior to directing the first diffracted light to the image surface, reflecting the first diffracted light back towards the at least one diffractive focusing element by a mirror spaced apart from the at least one diffractive focusing element, such that the first diffracted light reflected by the mirror is directed by the at least one diffractive focusing element to the image surface of the at least one diffractive focusing element, wherein the detecting of the second diffracted light includes interfering the first diffracted light with the second diffracted light to characterize the optical system. 23. The method of claim 21 the method further including: directing the first diffracted light to an imaging sensor configured to generate at least one image of an area to be imaged via the at least one diffractive focusing element; and adjusting at least one of the imaging sensor or the at least one diffractive focusing element based on the characterization of the optical system via the detected second diffracted light. 24. The method of claim 21 wherein the first diffracted light has an nth diffraction order and the second diffracted light has a 2nth diffraction order, where n is a positive or negative integer.