Claims
- 1. A laser having a lasing medium, the laser comprising:
a resonant cavity comprising a discharge space elongated along a longitudinal axis and first and second mirrors, the first and second mirrors being disposed toward opposing ends of the discharge space along the longitudinal axis and forming a stable resonator with respect to a first axis traverse to the longitudinal axis and an unstable resonator with respect to a second axis transverse to both the longitudinal axis and the first axis, at least a portion of the lasing medium being within the discharge space; and a first electrode and a second electrode extending along the longitudinal axis and being on opposing sides of the discharge space, the first and second electrodes being separated by a substantially non-waveguiding inter-electrode gap with respect to the first axis, the first and second electrodes being configured to define at least in part the discharge space such that the discharge space is substantially non-waveguiding with respect to the second axis, the first and second electrodes being shaped along the longitudinal axis to vary the inter-electrode gap such that a laser beam produced by the laser has a desired mode having the highest power level of any mode present in the laser beam throughout operation of the laser.
- 2. The laser of claim 1 wherein the first and second electrodes are shaped such that the desired mode of the laser beam has a power level of at least 85% of a total power level of the laser.
- 3. The laser of claim 1, further comprising a sealed housing to contain the lasing medium.
- 4. The laser of claim 1 wherein the laser has Fresnel numbers of over 0.35 with respect to the inter-electrode gap.
- 5. The laser of claim 1 wherein the first and second electrodes include planar and bowed sections.
- 6. The laser of claim 1 wherein the first and second electrodes are symmetric with respect to the longitudinal axis.
- 7. The laser of claim 1 wherein the first and second mirrors are tilted other than 90 degrees from the longitudinal axis.
- 8. The laser of claim 1, further comprising a plurality of spacers positioned between the first and second electrodes contacting pad surfaces of electrode pads of the first and second electrodes at positions along the longitudinal axis, some of the spacers having at least one of different thicknesses and pad surfaces transversely positioned differently to space portions of the first and second electrodes at different distances from each other to define the inter-electrode gap along the longitudinal axis.
- 9. The laser of claim 1 wherein the first and second electrodes are shaped such that the desired mode is the theoretical fundamental transverse mode of the laser.
- 10. A laser comprising:
a set of one more sections of lasing media; a resonant cavity comprising a set of one or more discharge spaces and first and second mirrors, the first and second mirrors being disposed toward opposing ends of the set of discharge spaces and forming a stable resonator with respect to a first axis and an unstable resonator with respect to a second axis transverse to the first axis, at least a portion of the lasing medium being within the set of discharge spaces; and a first set of one or more electrodes paired with a second set of one or more electrodes, each pair of electrodes from the first and second sets of electrodes being on opposing sides of the discharge spaces of the set of discharge spaces, and sharing one of a set of one or more longitudinal axes being transverse to the first axes, each pair of electrodes being separated by a substantially non-waveguiding inter-electrode gap with respect to the first axis, and being shaped along the longitudinal axis thereof to continuously vary one or more portions of the inter-electrode gap such that a laser beam produced by the laser has a desired mode having the highest power level of any mode present in the laser beam throughout operation of the laser.
- 11. The laser of claim 10 wherein each pair of electrodes has first and second inner surfaces that are parallel along the longitudinal axis thereof.
- 12. The laser of claim 10, further comprising a third mirror positioned to receive the laser beam from the first and second mirrors and wherein the longitudinal axes of some of the pairs of electrodes are other than parallel with the longitudinal axes of other of the pairs of electrodes.
- 13. The laser of claim 10 wherein the desired mode is the TM01 mode of the laser.
- 14. The laser of claim 10 wherein the desired mode is one order higher than the theoretical fundamental transverse mode of the laser.
- 15. A laser comprising:
a resonant cavity comprising a gain region and front and rear mirrors, the front and rear mirrors being disposed toward opposing ends of the gain region and forming a stable resonator in a first axis and an unstable resonator in a second axis traverse to the first axis; and a lasing medium having a substantially non-waveguiding size with respect to the second axis, a substantially non-waveguiding size with respect to the first axis, and a length along a longitudinal axis traverse to the first axis, the lasing medium occupying at least a portion of the gain region, the lasing medium being shaped so that the thickness of at least some portion of the lasing medium varies according to its position along the longitudinal axis such that a laser beam produced by the laser has a desired mode having the highest power level of any mode present in the laser beam throughout operation of the laser.
- 16. The laser of claim 15 wherein the size of the lasing medium with respect to positions along the longitudinal axis approximates the theoretical fundamental transverse mode of the laser.
- 17. The laser of claim 15 wherein the lasing medium has first and second planar surfaces arranged symmetric about the longitudinal axis.
- 18. The laser of claim 15 wherein the first and second mirrors are tilted other than 90 degrees from the longitudinal axis.
- 19. The laser of claim 15 wherein the desired mode is higher than the theoretical fundamental transverse mode of the laser.
- 20. A laser comprising:
a resonant cavity comprising a set of one or more gain regions and first and second mirrors, the first and second mirrors being disposed toward ends of the set of gain regions and forming a stable resonator with respect to a first axis and an unstable resonator with respect to a second axis transverse to the first axis; and a set of one or more sections of lasing media, each lasing media section having a substantially non-waveguiding size with respect to the second axis, a substantially non-waveguiding size with respect to the first axis, and a length along a longitudinal axis transverse to the first axis thereof, the lasing media section occupying at least a portion of one of the gain regions, one or more of the lasing media sections being shaped such that the thickness thereof varies according to the position thereof along the respective longitudinal axis to produce a stable laser beam with a total power that fluctuates less than plus and minus 10% of an average total power level of the laser beam.
- 21. The laser of claim 20 wherein each lasing media section has surfaces adjacent to one of the gain regions, the surfaces including planar and bowed surface portions.
- 22. The laser of claim 20 wherein each lasing media section is symmetrically shaped with respect to the respective longitudinal axis.
- 23. The laser of claim 20 wherein the longitudinal axes of the set of lasing media sections are parallel.
- 24. The laser of claim 20 wherein at least one of the longitudinal axes of the set of lasing media sections are non-parallel with others of the longitudinal axes.
- 25. The laser of claim 20 wherein the size of one or more of the lasing media sections further varies according to position thereof along the respective longitudinal axis to produce the laser beam with the total power of the laser beam fluctuating equal to or less than plus and minus 7% of the average total power level.
- 26. A laser having a lasing medium, the laser comprising:
a resonant cavity comprising a discharge space elongated along a longitudinal axis and first and second mirrors, the first and second mirrors being disposed toward opposing ends of the discharge space along the longitudinal axis and forming a stable resonator with respect to a first axis traverse to the longitudinal axis and an unstable resonator with respect to a second axis transverse to the first axis, at least a portion of the lasing medium being within the discharge space; and a first electrode and a second electrode extending along the longitudinal axis and being on opposing sides of the discharge space, the first and second electrodes being separated by a substantially non-waveguiding inter-electrode gap with respect to the first axis, the first and second electrodes being configured to define at least in part the discharge space such that the discharge space is substantially non-waveguiding with respect to the second axis, the first and second electrodes being shaped along the longitudinal axis to vary the inter-electrode gap to produce a stable laser beam with a total power level that fluctuates less than plus and minus 10% of an average total power level of the laser beam.
- 27. The laser of claim 26 wherein the inter-electrode gap is further shaped along the longitudinal axis to vary the inter-electrode gap to produce a total power stability of a laser beam produced by the laser such that total power of the laser beam fluctuates no greater than plus and minus 7% of the average total power level.
- 28. The laser of claim 26 wherein the laser has Fresnel numbers of over 0.35 with respect to the inter-electrode gap.
- 29. The laser of claim 26 wherein the first and second electrodes include planar and bowed sections.
- 30. The laser of claim 26 wherein the first and second electrodes are symmetric with respect to the longitudinal axis.
- 31. A method of forming a laser comprising:
providing a resonant cavity comprising a set of one or more discharge spaces and first and second mirrors, the first and second mirrors so shaped and positioned to form a stable resonator in a first axis and an unstable resonator in a second axis transverse to the first axis; providing a first set of one or more electrodes each having first inner surfaces; providing a second set of one or more electrodes each having second inner surfaces; and positioning the first and second sets of electrodes in opposing relation with each of the first inner surfaces being paired with one of the second inner surfaces, each of the paired first and second inner surfaces extending along a longitudinal axis thereof transverse to the first axis, the first and second inner surfaces of each of the paired first and second inner surfaces being on opposing sides of one of the discharge spaces of the set of discharge spaces to form a substantially non-waveguiding inter-electrode gap between the first and second inner surfaces thereof with a gap width with respect to the first axis, which varies in shape along portions of the respective longitudinal axis such that a laser beam produced by the laser has a desired mode having the highest power level of any mode present in the laser beam throughout operation of the laser.
- 32. The method of claim 31, further comprising positioning the first and second sets of electrodes so that the shape of the inter-electrode gap therebetween approximates the shape of the theoretical fundamental transverse mode of the laser.
- 33. The method of claim 31, further comprising providing the first and second sets of electrodes with planar sections.
- 34. The method of claim 31, further comprising positioning the first and second sets of electrodes with the paired first and second inner surfaces thereof having at least a plurality of their longitudinal axes arranged non-parallel with others of the longitudinal axes.
- 35. The method of claim 31, further comprising positioning the electrodes of the first and second sets of electrodes to vary portions of the inter-electrode gap therebetween along at least one of the longitudinal axes such that the desired mode has a power level at least 85% of a total power level of the laser beam.
- 36. The method of claim 31 further comprising providing the first and second sets of electrodes with shapes such that the order of the desired mode is higher than the theoretical fundamental transverse mode of the laser.
- 37. A method of forming a laser comprising:
providing a resonant cavity comprising a discharge space and first and second mirrors with at least a portion of the discharge space therebetween, the first and second mirrors so shaped and positioned to form a stable resonator in a first axis and an unstable resonator in a second axis transverse to the first axis; providing a first electrode having a first inner surface; providing a second electrode having a second inner surface; and positioning the first and second electrodes in opposing relation and extending along a longitudinal axis transverse to both the first axis and the second axis to form a substantially non-waveguiding inter-electrode gap, the first and second inner surfaces having a gap width varying in shape along portions of the longitudinal axis to produce a stable laser beam with a total power that fluctuates less than plus and minus 10% of an average total power level of the laser beam.
- 38. The method of claim 37, further comprising positioning the first and second electrodes so that the shape of the inter-electrode gap therebetween approximates the shape of one desired mode of the laser.
- 39. The method of claim 37 further comprising positioning the first and second electrodes with the gap width of the inter-electrode gap varying in shape such that the total power of the laser beam fluctuates no greater than plus and minus 7% of the average total power level.
- 40. A method of forming a laser comprising:
providing a resonator comprising first and second mirrors, the resonator configured to be stable with respect to a first axis and unstable with respect to a set of one or more second axes transverse to the first axis; providing a set of one or more lasing media sections; positioning the set of lasing media sections with respect to the resonator such that each of the lasing media sections has a non-waveguiding size along one of the second axes, has a non-waveguiding size along the first axis, and has a size along a longitudinal axis transverse to the first axis; and providing the set of lasing media sections with varying sizes along the longitudinal axis to produce a stable laser beam with a total power level that fluctuates less than plus or minus 10% of an average total power level of the laser beam.
- 41. The method of claim 40, further comprising providing one or more of the lasing media sections with a size varying to approximate the shape of the theoretical fundamental transverse mode of the laser.
- 42. The method of claim 40, further comprising providing one or more of the lasing media sections with a size varying to approximate the shape of a desired mode of the laser.
- 43. The method of claim 40, further including providing one or more of the lasing media sections with a size varying such that the total power of the laser beam fluctuates no greater than plus and minus 7% of the average total power level.
- 44. A method of forming a laser comprising:
providing an resonator comprising first and second mirrors, the resonator configured to be stable with respect to a first axis and unstable with respect to a set of second axes transverse to the first axis; providing a set of one or more lasing media sections; positioning the set of lasing media sections between the first and second mirrors such that each of the lasing media sections has non-waveguiding size along the first axis, each of the lasing media sections having non-waveguiding size along at least one of the second axes and each of the lasing media sections has a size along a longitudinal axis of a set of one or more longitudinal axes transverse to the first axis; and providing one or more of the lasing media sections with a size varying along its respective longitudinal axis to produce a stable laser beam having a desired mode with the highest power level of any mode present in the laser beam throughout operation of the laser.
- 45. The method of claim 44, further comprising providing one or more of the lasing media sections with a size varying to approximate the shape of the theoretical fundamental transverse mode of the laser.
- 46. The method of claim 44, further comprising providing one or more of the lasing media sections with a size varying to approximate the shape of the desired mode of the laser.
- 47. The method of claim 44, further comprising providing one or more of the lasing media sections with a size varying along their respective longitudinal axes such that the desired mode has a power level at least 85% of a total power level of the laser beam.
- 48. The method of claim 44 further comprising providing one or more of the lasing media sections with a size varying along their respective longitudinal axes such that the desired mode is of a higher order than the fundamental theoretical mode of the laser.
- 49. In a laser having a lasing medium in a discharge space and first and second mirrors, the first and second mirrors being disposed toward opposing ends of the discharge space along a longitudinal axis, the first and second mirrors forming a stable resonator with respect to a first axis traverse to the longitudinal axis and forming an unstable resonator with respect to a second axis transverse to both the longitudinal axis and the first axis, a plurality of electrodes comprising:
means for applying energy received from an energy source to the lasing medium to excite the lasing medium to produce a laser beam; means for non-waveguiding the laser beam with respect to the first axis; and means for decreasing power levels of selected modes of the laser beam such that a desired mode has the highest power level of any mode present in the laser beam throughout operation of the laser.
- 50. In a laser having a lasing medium in a discharge space and first and second mirrors, the first and second mirrors being disposed toward opposing ends of the discharge space along a longitudinal axis, the first and second mirrors forming a stable resonator with respect to a first axis traverse to the longitudinal axis and forming an unstable resonator with respect to a second axis transverse to both the longitudinal axis and the first axis, a plurality of electrodes comprising:
means for applying energy received from an energy source to the lasing medium to excite the lasing medium to produce a laser beam; means for non-waveguiding the laser beam with respect to the first axis; and means for stabilizing the laser beam such that the stable laser beam has a total power level that fluctuates less than plus and minus 10% of an average total power level of the laser beam.
- 51. The plurality of electrodes of claim 51 further comprising means for stabilizing the laser beam such that the stable laser beam has a total power level that fluctuates less than plus and minus 7% of an average total power level of the laser beam.
- 52. For a laser having a lasing medium in a discharge space and first and second mirrors, the first and second mirrors being disposed toward opposing ends of the discharge space along a longitudinal axis, the first and second mirrors forming a stable resonator with respect to a first axis traverse to the longitudinal axis and forming an unstable resonator with respect to a second axis transverse to both the longitudinal axis and the first axis, a method of operating the laser comprising:
applying energy to the lasing medium through a plurality of electrodes to excite the lasing medium to produce a laser beam; non-waveguiding the laser beam with respect to the first axis; and stabilizing the laser beam through interaction of the laser beam with the plurality of electrodes such that the stable laser beam has a total power level that fluctuates less than plus and minus 10% of an average total power level of the laser beam.
- 53. The method of claim 52 further comprising stabilizing the laser beam through interaction of the laser beam with the plurality of electrodes such that the stable laser beam has a total power level that fluctuates less than plus and minus 7% of an average total power level of the laser beam.
- 54. For a laser having a lasing medium in a discharge space and first and second mirrors, the first and second mirrors being disposed toward opposing ends of the discharge space along a longitudinal axis, the first and second mirrors forming a stable resonator with respect to a first axis traverse to the longitudinal axis and forming an unstable resonator with respect to a second axis transverse to both the longitudinal axis and the first axis, a method of operating the laser comprising:
applying energy to the lasing medium through a plurality of electrodes to excite the lasing medium to produce a laser beam; non-waveguiding the laser beam with respect to the first axis; and decreasing power levels of selected modes of the laser beam through interaction of the laser beam with the plurality of electrodes such that a desired mode has the highest power level of any mode present in the laser beam throughout operation of the laser.
CROSS-REFERENCE TO PRIOR APPLICATION
[0001] This application is a continuation-in-part of U.S. Ser. No. 09/472,733, filed Dec. 27, 1999, and allowed Sep. 29, 2000.
Continuation in Parts (1)
|
Number |
Date |
Country |
Parent |
09472733 |
Dec 1999 |
US |
Child |
09766248 |
Jan 2001 |
US |