IPC분류정보
국가/구분 |
United States(US) Patent
등록
|
국제특허분류(IPC7판) |
|
출원번호 |
US-0047667
(2011-03-14)
|
등록번호 |
US-8718105
(2014-05-06)
|
발명자
/ 주소 |
- Weida, Miles James
- Arnone, David F.
|
출원인 / 주소 |
|
대리인 / 주소 |
|
인용정보 |
피인용 횟수 :
3 인용 특허 :
90 |
초록
▼
A laser source (10) for emitting an output beam (12) includes a first gain medium (16B) that generates a first beam (16A), a second gain medium (18B) that generates a second beam (18A), a common feedback assembly (28) positioned in the path of the first beam (16A) and the second beam (18), and a con
A laser source (10) for emitting an output beam (12) includes a first gain medium (16B) that generates a first beam (16A), a second gain medium (18B) that generates a second beam (18A), a common feedback assembly (28) positioned in the path of the first beam (16A) and the second beam (18), and a control system (32). The common feedback assembly (28) redirects at least a portion of the first beam (16A) back to the first gain medium (16B), and at least a portion of the second beam (18A) back to the second gain medium (18B). The control system (32) selectively and individually directs power to the first gain medium (16B) and the second gain medium (18). Additionally, the common feedback assembly (28) can include a feedback mover (46) that continuously adjusts the angle of incidence of the first beam (16A) and the second beam (18A) on the feedback assembly (28). Moreover, the control system (32) can selectively direct pulses of power to the gain mediums (16B) (18B) based on the position of the feedback assembly (28).
대표청구항
▼
1. A laser source for emitting an output beam that consists of a plurality of output pulses of light, with at least some of the output pulses having a different center wavelength, the laser source comprising: a first gain medium having a first facet, the first gain medium generating a first beam tha
1. A laser source for emitting an output beam that consists of a plurality of output pulses of light, with at least some of the output pulses having a different center wavelength, the laser source comprising: a first gain medium having a first facet, the first gain medium generating a first beam that exits the first facet; wherein the first gain medium includes a second facet and the first beam exits the second facet; wherein the second facet is at least partly reflective;a second gain medium having a first facet, the second gain medium generating a second beam that exits the first facet; wherein the second gain medium includes a second facet and the second beam exits the second facet; wherein the second facet is at least partly reflective;a common feedback assembly positioned in the path of the first beam and the second beam, the common feedback assembly redirecting at least a portion of the first beam back to the first gain medium and at least a portion of the second beam back to the second gain medium; wherein the common feedback assembly includes a reflector assembly that redirects at least a portion of the first beam to the first gain medium and at least a portion of the second beam to the second gain medium; wherein for the first gain medium, the second facet defines a first end of a first external cavity and the common feedback assembly defines a second end of the first external cavity; wherein for the second gain medium, the second facet defines a first end of a second external cavity and the common feedback assembly defines a second end of the second external cavity;a feedback mover that rotates the reflector assembly to continuously adjusts an angle of incidence of the beams on at least a portion of the common feedback assembly to adjust each external cavity simultaneously;a position detector that generates a first position signal when the reflector assembly is at a first device position, and a second position signal when the reflector assembly is at a second device position; anda control system that selectively and individually directs power to the first gain medium and the second gain medium; wherein the control system directs a first pulse of power to the first gain medium upon receipt of the first position signal to generate a first pulse of light having a first center wavelength, and wherein the control system directs a second pulse of power to the second gain medium upon receipt of the second position signal to generate a second pulse of light having a second center wavelength that is different than the first center wavelength. 2. The laser source of claim 1 wherein the position detector that generates a position signal that relates to the angle of incidence of the beams on the common feedback assembly; and wherein the control system selectively directs power to the gain mediums based on the position signal from the position detector. 3. The laser source of claim 2 wherein the control system determines a center wavelength of the beams based on the position signal. 4. The laser source of claim 1 further comprising a beam redirector assembly that redirects the first beam the exits the second facet from the first gain medium, and the second beam that exits the second facet from the second gain medium so that the beams are approximately coaxial. 5. The laser source of claim 1 further comprising a third gain medium having a first facet and a partly reflective second facet, the third gain medium generating a third beam that exits the first facet and the second facet; wherein the common feedback assembly is positioned in the path of the third beam, the feedback assembly redirecting at least a portion of the third beam back to the third gain medium; wherein for the third gain medium, the second facet defines a first end of a third external cavity and the common feedback assembly defines a second end of the third external cavity; and wherein the control system also selectively and individually directs power to the third gain medium. 6. The laser source of claim 5 wherein the position detector generates a third position signal when the reflector assembly is at a third device position; and wherein the control system directs a third pulse of power to the third gain medium upon receipt of the third position signal. 7. The laser source of claim 1 wherein the common feedback assembly includes a first diffraction grating, a second diffraction grating that is separate from the first diffraction grating, and a third diffraction grating that is separate from the first diffraction grating and the second diffraction grating; wherein the reflector assembly directs a portion of the first beam at the first diffraction grating and the first diffraction grating redirects a portion of the first beam back at the reflector assembly; wherein the reflector assembly directs a portion of the second beam at the second diffraction grating and the second diffraction grating redirects a portion of the second beam back at the reflector assembly; and wherein the reflector assembly directs a portion of the third beam at the third diffraction grating and the third diffraction grating redirects a portion of the third beam back at the reflector assembly. 8. The laser source of claim 7 wherein the first diffraction grating defines the second end of the first external cavity, the second diffraction grating defines the second end of the second external cavity, and the third diffraction grating defines the second end of the third external cavity. 9. The laser source of claim 1 wherein the reflector assembly includes a multi-faceted mirror. 10. A method for generating an output beam that consists of a plurality of output pulses of light, with at least some of the output pulses having a different center wavelength, the method comprising the steps of: generating a first beam with a first gain medium, the first gain medium having a first facet and a partly reflective second facet, the first gain medium generating a first beam that exits the first facet and second facet;generating a second beam with a second gain medium, the second gain medium having a first facet and a partly reflective second facet, the second gain medium generating a second beam that exits the first facet and second facet;positioning a common feedback assembly in the path of the first beam and the second beam, the common feedback assembly redirecting at least a portion of the first beam back to the first gain medium and at least a portion of the second beam back to the second gain medium; wherein the common feedback assembly includes a reflector assembly that redirects at least a portion of the first beam to the first gain medium and at least a portion of the second beam to the second gain medium; wherein for the first gain medium, the second facet defines a first end of a first external cavity and the common feedback assembly defines a second end of the first external cavity; wherein for the second gain medium, the second facet defines a first end of a second external cavity and the common feedback assembly defines a second end of the second external cavity; androtating the reflector assembly with a feedback mover to continuously adjust an angle of incidence of the beams on at least a portion of the feedback assembly to adjust each external cavity simultaneously;generating a first position signal when the reflector assembly is at a first device position and a second position signal when the reflector assembly is at a second device position with a position detector; andselectively and individually directing power to the first gain medium and the second gain medium with a control system; the control system directing a first pulse of power to the first gain medium upon receipt of the first position signal to generate a first pulse of light having a first center wavelength, and the control system directing a second pulse of power to the second gain medium upon receipt of the second position signal to generate a second pulse of light having a second center wavelength that is different than the first center wavelength. 11. The method of claim 10 further comprising the step of generating a third beam with a third gain medium, the third gain medium having a first facet and a partly reflective second facet, the third gain medium generating a third beam that exits the first facet and second facet; wherein the common feedback assembly is positioned in the path of the third beam, the feedback assembly redirecting at least a portion of the third beam back to the third gain medium; wherein for the third gain medium, the second facet defines a first end of a third external cavity and the common feedback assembly defines a second end of the third external cavity; and wherein the control system also selectively and individually directs power to the third gain medium. 12. The method of claim 11 further comprising the step of generating a third position signal when the reflector assembly is at a third device position; wherein the step of selectively and individually directing power includes directing a third pulse of power to the third gain medium upon receipt of the third position signal. 13. A laser source for emitting an output beam that consists of a plurality of output pulses of light, with at least some of the output pulses having a different center wavelength, the laser source comprising: a first gain medium having a first facet and a second facet, the first gain medium generating a first beam that exits the first facet and the second facet;a second gain medium having a first facet and a second facet, the second gain medium generating a second beam that exits the first facet and the second facet;a third gain medium having a first facet and a second facet, the third gain medium generating a third beam that exits the first facet and second facet;a common feedback assembly positioned in the path of the first beam, the second beam, and the third beam, the common feedback assembly redirecting at least a portion of the first beam back to the first gain medium, at least a portion of the second beam back to the second gain medium, and at least a portion of the third beam back to the third gain medium; wherein the common feedback assembly includes a reflector assembly that redirects at least a portion of the first beam to the first gain medium, at least a portion of the second beam to the second gain medium, and at least a portion of the third beam to the third gain medium; wherein for the first gain medium, the common feedback assembly defines an end of the first external cavity; wherein for the second gain medium, the common feedback assembly defines an end of the second external cavity; and wherein for the third gain medium, the common feedback assembly defines an end of the third external cavity;a feedback mover that rotates the reflector assembly to continuously adjusts an angle of incidence of the beams on at least a portion of the feedback assembly to adjust each external cavity simultaneously;a position detector that generates a first position signal when the reflector assembly is at a first device position, a second position signal when the reflector assembly is at a second device position; and a third position signal when the reflector assembly is at a third device position; anda control system that selectively and individually directs power to the first gain medium, the second gain medium, and the third gain medium;a control system that selectively and individually directs power to the first gain medium, the second gain medium, and the third gain medium; wherein the control system directs a first pulse of power to the first gain medium upon receipt of the first position signal to generate a first pulse of light having a first center wavelength, directs a second pulse of power to the second gain medium upon receipt of the second position signal to generate a second pulse of light having a second center wavelength that is different than the first center wavelength, and directs a third pulse of power to the third gain medium upon receipt of the third position signal to generate a third pulse of light having a third center wavelength that is different than the first center wavelength and the second center wavelength. 14. The laser source of claim 13 wherein the control system sequentially directs pulses of power to the gain mediums. 15. The laser source of claim 13 wherein the common feedback assembly includes a grating assembly, wherein the reflector assembly directs a portion of each beam at the grating assembly and the grating assembly redirects a portion of each beam back at the reflector assembly. 16. The laser source of claim 15 wherein the grating assembly includes a first diffraction grating, a second diffraction grating that is separate from the first diffraction grating, and a third diffraction grating that is separate from the first diffraction grating and the second diffraction grating. 17. The laser source of claim 16 wherein the first diffraction grating defines the end of the first external cavity, the second diffraction grating defines the end of the second external cavity, and the third diffraction grating defines the end of the third external cavity. 18. The laser source of claim 13 wherein the reflector assembly includes a multi-faceted mirror. 19. The laser source of claim 13 further comprising a beam redirector assembly that redirects the first beam the exits the second facet from the first gain medium, the second beam that exits the second facet from the second gain medium, and the third beam that exits the second facet from the third gain medium so that the beams are approximately coaxial.
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