초록 ▼

An external cavity laser having a set atmosphere is disclosed. In an embodiment, the laser system includes a gain medium to emit light in response to an applied current, a wavelength selective reflector configured to resonate the light that is emitted from the gain medium, and a chamber containing a

An external cavity laser having a set atmosphere is disclosed. In an embodiment, the laser system includes a gain medium to emit light in response to an applied current, a wavelength selective reflector configured to resonate the light that is emitted from the gain medium, and a chamber containing a set atmosphere, the chamber being optically connected to the gain medium and the wavelength selective reflector such that the light that is emitted from the gain medium passes through the chamber.

대표청구항 ▼

What is claimed is: 1. A laser system comprising: a gain medium that emits light in response to an applied current; a wavelength selective reflector, in optical communication with said gain medium, configured to resonate said light that is emitted from said gain medium; and a chamber containing a s

What is claimed is: 1. A laser system comprising: a gain medium that emits light in response to an applied current; a wavelength selective reflector, in optical communication with said gain medium, configured to resonate said light that is emitted from said gain medium; and a chamber containing a set atmosphere, said chamber being optically coupled to said gain medium and said wavelength selective reflector such that said light that is emitted from said gain medium passes through said chamber, said set atmosphere having known optical properties, wherein said set atmosphere is a wavelength selective atmosphere; wherein said set atmosphere has known spectral features across a wavelength range of interest and further including: an optical power monitor, in optical communication with light that passes through said chamber, which measures optical power of said light; and a calibration system, in signal communication with said optical power monitor, which calibrates an output wavelength of said laser system in response to said optical power measurements. 2. The laser system of claim 1 wherein said chamber encapsulates said gain medium and said wavelength selective reflector. 3. The laser system of claim 2 wherein said set atmosphere is an inert atmosphere. 4. The laser system of claim 1 wherein said chamber is located in an optical path of said resonated light. 5. The laser system of claim 4 wherein said set atmosphere is a wavelength selective atmosphere. 6. The laser system of claim 5 wherein said set atmosphere is selected from the group consisting of acetylene and hydrogen cyanide. 7. The laser system of claim 4 further comprising a second chamber to encapsulate said gain medium, said wavelength selective reflector and said chamber. 8. The laser system of claim 7 wherein said second chamber encloses a second set atmosphere. 9. The laser system of claim 1 wherein said chamber is gas-tight. 10. The laser system of claim 1 wherein said set atmosphere comprises an inert atmosphere. 11. The laser system of claim 1 wherein said wavelength selective reflector comprises a diffraction grating. 12. The laser system of claim 12 further comprising a partially reflective mirror to reflect a portion of said resonated light into said chamber. 13. The laser system of claim 13 further comprising a monitor to monitor spectral features of said resonated light in said chamber. 14. A method of operating an external cavity laser comprising: emitting tight; resonating said light; passing said resonated light through a set atmosphere, said set atmosphere having known optical properties; providing an atmosphere with known spectral features across a wavelength range, of interest as said set atmosphere; monitoring spectral features of said resonated light; comparing the spectral features of said resonated light against the known spectral features of the set atmosphere; and calibrating all output wavelength of said laser based upon results of said comparing. 15. The method of claim 14 further comprising providing an atmosphere void of spectral features across a wavelength range of interest as said set atmosphere. 16. The method of claim 14 wherein said known spectral features comprise absorption characteristics. 17. A laser system comprising: a gain medium for emitting light; a plurality of optical reflectors, in optical communication with said gain medium, for resonating said light that is emitted from said gain medium; an enclosing means, in optical communication with said gain medium and said plurality of optical reflectors, for enclosing a set atmosphere through which said resonated light is to pass, said set atmosphere having known optical properties, a wherein said set atmosphere has known spectral features across a wavelength range of interest; an optical power monitor, in optical communication with said resonated light, which measures optical power of said resonated light; and a calibration system, in signal communication with said optical power monitor, which calibrates an output wavelength of said laser system in response to said optical power measurements. 18. The laser system of claim 17 wherein said enclosing means encapsulates said plurality of optical reflectors and said gain medium. 19. The laser system of claim 18 wherein said set atmosphere is void of spectral features across a wavelength range of interest. 20. The laser system of claim 17 wherein said enclosing means is located in an optical path of said resonated light. 21. The laser system of claim 17 wherein said set atmosphere has known spectral features across a wavelength: range of interest.