Method and apparatus for stabilizing a line of sight of a radiant energy system

What is claimed is: 1. An apparatus comprising: a first optical system that positions a line of sight of a main beam based on a reference beam that is inertially stabilized in a selected direction, wherein the first optical system comprises a first reflector and a second reflector, wherein the second reflector comprises a reflective surface positioned to reflect the main beam and a back surface; a reference beam generator that generates and emits the reference beam in the selected direction, wherein the reference beam generator is located outside of an optical path of the main beam, and the reference beam is reflected off of the back surface of the second reflector and directed into the optical path of the main beam; and a second optical system that stabilizes the line of sight of the main beam using the reference beam to counteract a number of disturbances created within the optical path of the main beam. 2. The apparatus of claim 1 , further comprising: a retroreflector located outside of the optical path of the main beam, wherein the retroreflector receives the reference beam reflected off of the back surface of the second reflector and reflects the reference beam through the second reflector into the optical path of the main beam. 3. The apparatus of claim 1 , wherein the first reflector and the second reflector are planar mirrors that form a coelostat-type reflector system. 4. The apparatus of claim 1 further comprising: a first rotatable system that rotates the first reflector about an azimuth axis to control an azimuth angle of the line of sight of the main beam; and a second rotatable system that rotates the second reflector about an elevation axis to control an elevation angle of the line of sight of the main beam. 5. The apparatus of claim 1 , wherein the second optical system comprises: a sensor device that generates a measured correction parameter for the reference beam after the reference beam has encountered each of a plurality of optical elements along the optical path of the main beam. 6. The apparatus of claim 1 further comprising: a reference sensor system that measures an angular position of the reference beam generator; and a control system that determines whether a relative difference between an angular position of the reference beam generator and an angular position of the second reflector is outside of selected tolerances, wherein at least one of the first reflector or the second reflector is rotated to align the line of sight of the main beam with the selected direction of the reference beam based on the relative difference measured. 7. The apparatus of claim 2 , further comprising: a reflective element on the back surface of the second reflector that receives the reference beam from the reference beam generator and reflects the reference beam onto the retroreflector. 8. The apparatus of claim 5 , wherein the sensor device is a position sensing device that measures an angle of incidence of the reference beam on the position sensing device. 9. The apparatus of claim 8 , wherein the second optical system further comprises: a correcting device that corrects for any deviation of the measured correction parameter from a desired correction parameter that is outside of selected tolerances, thereby adjusting the line of sight of the main beam with respect to at least one of azimuth or elevation. 10. The apparatus of claim 9 , wherein the correcting device is a fast steering mirror that is rotatable in both azimuth and elevation. 11. A radiant energy system comprising: a coelostat-type reflector system that controls a line of sight of a main beam and comprising a first reflector and a second reflector, wherein the second reflector comprises a reflective surface positioned to reflect the main beam and a back surface; and a reference beam generator located outside of an optical path of the main beam, wherein the reference beam generator emits a reference beam that is inertially stabilized in a selected direction, wherein the reference beam is reflected off of the back surface of the second reflector and directed into the optical path of the main beam, and wherein the coelostat-type reflector system controls a positioning of the line of sight of the main beam based on the selected direction of the reference beam. 12. The radiant energy system of claim 11 further comprising: an injection system that sends the reference beam into the optical path of the main beam. 13. The radiant energy system of claim 11 , wherein: the first reflector has a first reflective surface that is positioned to reflect the main beam and that is substantially planar; and the reflective surface of the second reflector that is positioned to reflect the main beam is substantially planar. 14. The radiant energy system of claim 12 , wherein the coelostat-type reflector system is part of a first optical system and further comprising: a second optical system that stabilizes the line of sight of the main beam using the reference beam to counteract a number of disturbances created within the optical path of the main beam. 15. A method for stabilizing a line of sight of a radiant energy system, the method comprising: positioning the line of sight of a main beam using a first reflector and a second reflector based on a reference beam that is inertially stabilized in a selected direction, wherein the second reflector comprises a reflective surface positioned to reflect the main beam and a back surface, and wherein the reference beam is reflected off of the back surface of the second reflector and directed into an optical path of the main beam; and stabilizing the line of sight of the main beam using the reference beam to counteract a number of disturbances created within the optical path of the main beam. 16. The method of claim 15 further comprising: emitting the reference beam in the selected direction from a reference beam generator located outside of the optical path of the main beam. 17. The method of claim 15 , wherein positioning the line of sight comprises: controlling an azimuth angle of the line of sight by rotating the first reflector about an azimuth axis; and controlling an elevation angle of the line of the sight by rotating the second reflector about an elevation axis. 18. The method claim 15 , wherein positioning the line of sight further comprises: measuring a relative difference between angular positions of the second reflector and a reference beam generator that emits the reference beam; and rotating at least one of the first reflector or the second reflector to substantially align the line of sight of the main beam with the selected direction of the reference beam based on the relative difference measured. 19. The method of claim 15 , wherein stabilizing the line of sight comprises: generating a measured correction parameter for the reference beam after the reference beam has encountered each of a plurality of optical elements along the optical path of the main beam. 20. The method of claim 19 , wherein stabilizing the line of sight further comprises: correcting for any deviation of the measured correction parameter from a desired correction parameter that is outside of selected tolerances to thereby adjust the line of sight of the main beam with respect to at least one of azimuth or elevation.