IPC분류정보
국가/구분 |
United States(US) Patent
등록
|
국제특허분류(IPC7판) |
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출원번호 |
US-0491830
(2006-07-22)
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등록번호 |
US-7413147
(2008-08-19)
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발명자
/ 주소 |
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출원인 / 주소 |
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대리인 / 주소 |
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인용정보 |
피인용 횟수 :
5 인용 특허 :
5 |
초록
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The invention is a system and method for propellantless, ultrahigh precision satellite formation flying based on ultrahigh precision intracavity laser thrusters and tethers with an intersatellite distance accuracy of nanometers at maximum estimated distances of tens of kilometers. The repelling forc
The invention is a system and method for propellantless, ultrahigh precision satellite formation flying based on ultrahigh precision intracavity laser thrusters and tethers with an intersatellite distance accuracy of nanometers at maximum estimated distances of tens of kilometers. The repelling force of the intracavity laser thruster and the attracting force of tether tension between satellites form the basic forces to stabilize matrix structures of satellites. Users of the present invention can also use the laser thruster for ultrahigh precision laser interferometric metrology, resulting in simplification and payload weight reduction in integrating the thruster system and the metrology system.
대표청구항
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What is claimed is: 1. A method to stabilize a distance between a first apparatus and a second apparatus, comprising: attaching a laser thrust system to said first apparatus and said second apparatus; activating said laser thrust system, wherein said laser thrust system provides a repelling force t
What is claimed is: 1. A method to stabilize a distance between a first apparatus and a second apparatus, comprising: attaching a laser thrust system to said first apparatus and said second apparatus; activating said laser thrust system, wherein said laser thrust system provides a repelling force that repels said first apparatus and said second apparatus away from one another; and attaching a tether system to said first apparatus and said second apparatus, wherein said tether system provides an attracting force that attracts said first apparatus and said second apparatus towards one another, wherein said repelling force and said attracting force are substantially equal to stabilize said distance of said first apparatus and said second apparatus, and wherein attaching said laser thrust system to said first apparatus and said second apparatus comprises: attaching a laser to said first apparatus; attaching a first mirror to said first apparatus; attaching a second mirror to said second apparatus; and positioning said first mirror and said second mirror, wherein a laser beam generated by said laser transmits through a back of said first mirror to form an intracavity laser beam, and wherein said intracavity laser beam reflects off of a front of said first mirror and a front of said second mirror a plurality of times. 2. The method of claim 1, wherein attaching said laser to said first apparatus comprises: attaching a laser gain media to said laser thrust system; and positioning said gain media to amplify said laser beam. 3. The method of claim 2, wherein attaching said laser gain media to said laser thrust system comprises attaching said laser gain media to a back of said first mirror. 4. The method of claim 1, further comprising thermally maintaining a temperature of said first mirror. 5. The method of claim 1, further comprising shaping and positioning said first mirror and said second mirror to form a confocal resonator, wherein a radius of curvature of said first mirror and said second mirror is substantially equal to an ideal distance between said first mirror and said second mirror. 6. The method of claim 1, further comprising shaping and positioning said first mirror and said second mirror to form a parabolic resonator, wherein a focal length of said first mirror and said second mirror is substantially equal to an ideal distance between said first mirror and said second mirror. 7. The method of claim 1, further comprising shaping and positioning said first mirror and said second mirror to form a hemispherical resonator, wherein a focal length of said first mirror is substantially equal to an ideal distance between said first mirror and said second mirror. 8. The method of claim 1, further comprising shaping and positioning said first mirror and said second mirror to form a hemispherical resonator, wherein a focal length of said second mirror is substantially equal to an ideal distance between said first mirror and said second mirror. 9. The method of claim 1, further comprising: detecting a defect in a laser diode of said laser; and replacing a laser diode of said laser when a defect is detected in said laser diode. 10. The method of claim 9, further comprising attaching a carousel of laser diodes to said laser thrust system, wherein replacing a laser diode of said laser when a defect is detected in said laser diode further comprises replacing said laser diode of said laser with a laser diode from said carousel of laser diodes. 11. The method of claim 1, further comprising: attaching a laser power meter to said second apparatus; and positioning a lens between a back of said second mirror and said laser power meter, wherein a percentage of said intracavity laser beam transmits through said second mirror to form an extracavity laser beam, and wherein said extracavity laser beam is focused towards a receiving input area of said laser power meter. 12. A method to stabilize a distance between a first apparatus and a second apparatus, comprising: attaching a laser thrust system to said first apparatus and said second apparatus; activating said laser thrust system, wherein said laser thrust system provides a repelling force that repels said first apparatus and said second apparatus away from one another; and attaching a tether system to said first apparatus and said second apparatus, wherein said tether system provides an attracting force that attracts said first apparatus and said second apparatus towards one another, wherein said repelling force and said attracting force are substantially equal to stabilize said distance of said first apparatus and said second apparatus, and, wherein attaching a tether system to said first apparatus and said second apparatus comprises: attaching a tether to said first apparatus and said second apparatus; and attaching a piezoelectric translator to said tether for fine tuning an extended length of said tether. 13. The method of claim 12 wherein attaching a tether system to said first apparatus and said second apparatus further comprises attaching a stepper motor to said tether for coarse tuning an extended length of said tether. 14. The method of claim 12, wherein attaching a tether system to said first apparatus and said second apparatus further comprises attaching an inchworm motor to said tether for coarse tuning an extended length of said tether. 15. The method of claim 14, further comprising: attaching an electromechanical clamp to said tether for securing a length of said tether, and attaching an electromechanical damper to said tether for absorbing vibration energy of said tether. 16. The method of claim 14, further comprising: attaching an electromagnetic clamp to said tether for securing a length of said tether, and attaching an electromagnetic damper to said tether for absorbing vibration energy of said tether. 17. The method of claim 14, further comprising: attaching an electromechanical clamp to said tether for securing a length of said tether, and attaching an electromagnetic damper to said tether for absorbing vibration energy of said tether. 18. The method of claim 14, further comprising: attaching an electromagnetic clamp to said tether for securing a length of said tether, and attaching an electromechanical damper to said tether for absorbing vibration energy of said tether. 19. The method of claim 15, wherein said tether is wrapped around a reel. 20. The method of claim 1, further comprising: positioning a reflecting mirror behind a back of said second mirror, wherein a percentage of said intracavity laser beam transmits through said second mirror to form an extracavity laser beam; directing said extracavity laser beam towards an interferometer system with said reflecting mirror; and measuring said distance between said first apparatus and said second apparatus with said interferometer system. 21. The method of claim 20, further comprising adjusting said repelling force of said laser thrust system when said distance between said first apparatus and said second apparatus is not substantially equal to an ideal distance between said first apparatus and said second apparatus. 22. The method of claim 20, further comprising adjusting said attracting force of said tether system when said distance between said first apparatus and said second apparatus is not substantially equal to an ideal distance between said first apparatus and said second apparatus. 23. The method of clam 20, further comprising: monitoring said distance between said first apparatus and said second apparatus with a computer system; adjusting said repelling force of said laser thrust system when said distance between said first apparatus and said second apparatus is not substantially equal to an ideal distance between said first apparatus and said second apparatus; and adjusting said attracting force of said tether system when said distance between said first apparatus and said second apparatus is not substantially equal to an ideal distance between said first apparatus and said second apparatus. 24. A satellite system, comprising: a first satellite; a second satellite, positioned opposite said first satellite; a laser thrust system for providing a repelling force that repels said first satellite away from said second satellite; and a tether system for providing an attracting force that attracts said first satellite towards said second satellite. 25. The satellite system of claim 24, wherein said laser thrust system comprises: a laser pumping system adapted to generate a laser beam, attached to said first satellite; a first mirror, attached to said first satellite, comprising a back side adapted to transmit said laser beam to form an intracavity laser beam, and a front side adapted to reflect said intracavity laser beam; and a second mirror, attached to said second satellite, comprising a front side adapted to reflect said intracavity laser beam, wherein said intracavity laser beam reflects a plurality of times between said front side of said first mirror and said front side of said second mirror to generate said repelling force. 26. The satellite system of claim 25, wherein said first mirror and said second mirror are curved to form a confocal resonator and wherein a radius of curvature of said first mirror and said second mirror is substantially equal to an ideal distance between said first mirror and said second mirror. 27. The satellite system of claim 25, wherein said first mirror and said second mirror are curved to form a parabolic resonator, wherein a focal length of said first mirror and said second mirror is substantially equal to an ideal distance between said first mirror and said second mirror. 28. The satellite system of claim 25, wherein said first mirror is curved to form a hemispherical resonator, wherein a focal length of said first mirror is substantially equal to an ideal distance between said first mirror and said second mirror. 29. The satellite system of claim 25, wherein said second mirror is curved to form a hemispherical resonator, wherein a focal length of said second mirror is substantially equal to an ideal distance between said first mirror and said second mirror. 30. The satellite system of claim 25, wherein said laser pumping system comprises a laser gain media, wherein said laser gain media is positioned to generate optical gain for said laser beam. 31. The satellite system of claim 30, wherein said laser gain media is axially positioned between a generator of said laser beam and said back of said first mirror. 32. The satellite system of claim 30, wherein said laser gain media is attached to a back of said first mirror. 33. The satellite system of claim 32, wherein said laser pumping system further comprises a thermal management system for thermal regulation of said first mirror. 34. The satellite system of claim 30, wherein said laser gain media comprises a solid state laser crystal. 35. The satellite system of claim 34, wherein said solid state laser crystal is selected from a group consisting of Nd:YAG, Er:YAG, Nd:YLF, Nd:YCa4O, Nd:Glass, Ti:sapphire, Tm:YAG, Yb:YAG, Ho:YAG, Ce:LiCAF, U:CaF2, Sm:CaF2, and Nd:YVO4. 36. The satellite system of claim 30, wherein said laser pumping system further comprises a laser diode for generating said laser beam. 37. The satellite system of claim 30, wherein said laser pumping system further comprises a carousel of replacement diodes for said laser diode. 38. The satellite system of claim 30, wherein said tether system comprises: a tether, attached to said first apparatus and said second apparatus; a reel, wherein said tether is at least partially wrapped around said reel; a clamp, abutting said tether for preventing an extension of said tether; and a motor, attached to said tether for adjusting a length of said tether. 39. The satellite system of claim 38, wherein said clamp comprises an electromechanical clamp. 40. The satellite system of claim 38, wherein said clamp comprises an electromagnetic clamp. 41. The satellite system of claim 38, wherein said motor comprises a coarse precision motor and a fine precision motor. 42. The satellite system of claim 41, wherein said coarse precision motor comprises a stepper motor and said fine precision motor comprises a piezoelectric translator. 43. The satellite system of claim 41, wherein said coarse precision motor comprises an inchworm, and said fine precision motor comprises a piezoelectric translator. 44. The satellite system of claim 38, wherein said tether system further comprises a damper. 45. The satellite system of claim 44, wherein said damper comprises an electromechanical damper. 46. The satellite system of claim 44, wherein said damper comprises an electromagnetic damper. 47. The satellite system of claim 38, wherein said tether comprises quartz, Kevlar, Vectran, carbon nanotubes, tungsten, and carbon fiber. 48. The satellite system of claim 38, further comprising an interferometry system. 49. The satellite system of claim 48, wherein said interferometry system comprises a mirror to deflect a percentage of said laser beam towards an interferometer. 50. The satellite system of claim 48, wherein said front of second mirror is adapted to transmit a percentage of said intracavity laser beam to form an extracavity laser beam, and wherein said interferometry system comprises a mirror to deflect a percentage of said extracavity laser beam towards an interferometer. 51. The satellite system of claim 50, wherein said interferometer comprises: a first interferometry partial mirror, attached to said second satellite, adapted to reflect a first percentage of said extracavity laser beam towards a second interferometry mirror, and transmit a second percentage of said extracavity laser beam towards a fourth interferometry partial mirror; a second interferometry mirror, attached to said first satellite, adapted to reflect said first percentage of said extracavity laser beam towards a third interferometry mirror; a third interferometry mirror, attached to said first satellite, adapted to reflect said first percentage of said extracavity laser beam towards said fourth interferometry partial mirror; and a fourth interferometry partial mirror, attached to said second satellite, adapted to reflect said second percentage of said extracavity laser beam towards a photodetector, and adapted to transmit said first percentage of extracavity laser beam towards said photodetector. 52. A method to stabilize a distance between a first apparatus and a second apparatus, comprising: attaching a laser thrust system to said first apparatus and said second apparatus, comprising attaching a first mirror to said first apparatus, attaching a second mirror to said second apparatus, attaching a laser to said first apparatus, comprising attaching a laser gain media to said first mirror, and positioning said gain media to amplify a laser beam, attaching a carousel of laser diodes to said laser, and shaping and positioning said first mirror and said second mirror to form a parabolic resonator, wherein a focal length of said first mirror and said second mirror is substantially equal to an ideal distance between said first mirror and said second mirror, wherein said laser beam generated by said laser transmits through a back of said first mirror to form an intracavity laser beam, and wherein said intracavity laser beam reflects off of a front of said first mirror and a front of said second mirror a plurality of times; activating said laser thrust system, wherein said laser thrust system provides a repelling force that repels said first apparatus and said second apparatus away from one another; thermally maintaining a temperature of said first mirror; detecting a defect in a laser diode of said laser; replacing a laser diode of said laser from said carousel of laser diodes when a defect in said laser diode is detected; attaching a laser power meter to said second apparatus; positioning a lens between a back of said second mirror and said laser power meter, wherein a percentage of said intracavity laser beam transmits through said second mirror to form an extracavity laser beam, and wherein said extracavity laser beam is focused towards a receiving input area of said laser power meter; attaching a tether system to said first apparatus and said second apparatus comprising attaching a tether to said first apparatus and said second apparatus, attaching a piezoelectric translator to said tether and to said second apparatus for fine tuning an extended length of said tether, attaching an inchworm motor to said tether and to said second apparatus for coarse tuning an extended length of said tether, attaching an electromechanical clamp to said first apparatus abutting said tether for securing a length of said tether, attaching an electromechanical damper to said first apparatus abutting said tether for absorbing vibration energy of said tether, and attaching a reel to said first apparatus, wherein said tether is at least partially wrapped around said reel, wherein said tether system provides an attracting force that attracts said first apparatus and said second apparatus towards one another, and wherein said repelling force and said attracting force are substantially equal to stabilize said distance of said first apparatus and said second apparatus; positioning a reflecting mirror behind a back of said second mirror, wherein a percentage of said intracavity laser beam transmits through said second mirror to form an extracavity laser beam; directing said extracavity laser beam towards an interferometer system with said reflecting mirror; measuring said distance between said first apparatus with said interferometer system; monitoring said distance between said first apparatus and said second apparatus with a computer system; adjusting said repelling force of said laser thrust system when said distance between said first apparatus and said second apparatus is not substantially equal to an ideal distance between said first apparatus and said second apparatus; and adjusting said attracting force of said tether system when said distance between said first apparatus and said second apparatus is not substantially equal to an ideal distance between said first apparatus and said second apparatus.
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