Rapidly tunable laser assembly

What is claimed is: 1. A laser assembly for emitting an output beam, the laser assembly comprising: a first module assembly that includes (i) a rigid first frame; and (ii) a gain medium coupled to the first frame, the gain medium having a facet, the gain medium generating a beam that exits the facet along a lasing axis when sufficient current is directed to the gain medium; a second module assembly that includes (i) a rigid second frame; (ii) a diffraction grating positioned in the path of the beam exiting the facet to form an external cavity having a cavity length; (iii) an arm assembly that retains the diffraction grating; and (iv) a pivot assembly that secures the arm assembly to the second frame in a fashion that allows the arm assembly and the grating to effectively pivot about a pivot axis; and a module fastener assembly that is moveable between (i) an unlocked position in which the second frame can be selectively moved relative to the first frame to selectively adjust at least one of the cavity length, and the position of the pivot axis relative to the lasing axis; and (ii) a locked position in which the second module assembly is fixedly secured to the first module assembly to inhibit relative movement between the first frame and the second frame. 2. The laser assembly of claim 1 wherein in the unlocked position, the second frame can be selectively moved relative to the first frame to selectively adjust the cavity length. 3. The laser assembly of claim 1 wherein in the unlocked position, the second frame can be selectively moved relative to the first frame to selectively adjust the position of the pivot axis relative to the lasing axis. 4. The laser assembly of claim 1 wherein in the unlocked position, the second frame can be selectively moved relative to the first frame to selectively adjust both the cavity length, and the position of the pivot axis relative to the lasing axis. 5. The laser assembly of claim 1 wherein the arm assembly includes (i) a proximal arm section that is secured to the second frame with the pivot assembly; (ii) a distal arm section that retains the diffraction grating; and (iii) an arm connector assembly that is moveable between an unlocked position in which the distal arm section can be moved relative to the proximal arm section to adjust the plane of a grating face of the diffraction grating relative to the pivot axis; and a locked position in which the distal arm section is fixedly secured to the proximal arm section to inhibit relative movement between the distal arm section and the proximal arm section. 6. The laser assembly of claim 1 wherein the grating can be rotated relative to the arm assembly and subsequently locked to the arm assembly. 7. The laser assembly of claim 1 further comprising a mover that selectively moves the arm assembly and the grating about the pivot axis. 8. The laser assembly of claim 7 wherein the mover is a voice coil motor. 9. The laser assembly of claim 7 wherein the mover is controlled to pivot the arm assembly back and forth in a simple harmonic motion. 10. A method for assembling a laser assembly that emits an output beam, the method comprising: providing a first module assembly that includes (i) a rigid first frame; and (ii) a gain medium coupled to the first frame, the gain medium having a facet, the gain medium generating a beam that exits the facet along a lasing axis when sufficient current is directed to the gain medium; providing a second module assembly that includes (i) a rigid second frame; (ii) a diffraction grating positioned in the path of the beam exiting the facet to form an external cavity having a cavity length; (iii) an arm assembly that retains the diffraction grating; and (iv) a pivot assembly that secures the arm assembly to the second frame in a fashion that allows the arm assembly and the grating to effectively pivot about a pivot axis; and moving the second frame relative to the first frame to selectively adjust at least one of the cavity length, and the position of the pivot axis relative to the lasing axis; and fixedly securing the second module assembly to the first module assembly with a module fastener assembly to inhibit relative movement between the first frame and the second frame. 11. The method of claim 10 wherein the step of moving includes moving the second frame relative to the first frame to selectively adjust the cavity length. 12. The method of claim 10 wherein the step of moving includes moving the second frame relative to the first frame to selectively adjust the position of the pivot axis relative to the lasing axis. 13. The method of claim 10 wherein the step of moving includes moving the second frame relative to the first frame to selectively adjust both the cavity length and the position of the pivot axis relative to the lasing axis. 14. The method of claim 10 wherein the step of providing a second module includes the arm assembly having (i) a proximal arm section that is secured to the second frame with the pivot assembly; and (ii) a distal arm section that retains the diffraction grating; wherein the method includes moving the distal arm section relative to the proximal arm section to adjust the plane of a grating face of the diffraction grating relative to the pivot axis; and fixedly securing the distal arm section to the proximal arm section with an arm connector assembly to inhibit relative movement between the distal arm section and the proximal arm section. 15. The method of claim 10 further comprising rotating the grating relative to the arm assembly and subsequently locking the grating to the arm assembly. 16. A laser assembly for emitting an output beam, the laser assembly comprising: a laser housing; a gain medium coupled to the laser housing, the gain medium having a facet, the gain medium generating a beam that exits the facet along a lasing axis when sufficient current is directed to the gain medium; a diffraction grating positioned in the path of the beam exiting the facet to form an external cavity having a cavity length, the diffraction grating redirecting at least a portion of the beam back to the gain medium, the diffraction grating having a grating face; a pivot assembly that is secured to the laser housing; and an arm assembly that retains the diffraction grating, the arm assembly including (i) a proximal arm section that is secured to the laser housing with the pivot assembly so that the proximal arm section effectively pivots about a pivot axis; (ii) a distal arm section that retains the diffraction grating; and (iii) an arm connector assembly that selectively connects the distal arm section to the proximal arm section, the arm connector assembly being moveable between an unlocked position in which the distal arm section can be moved relative to the proximal arm section independent of the movement with the pivot assembly about the pivot axis to adjust the plane of the grating face relative to the pivot axis and the pivot assembly; and a locked position in which the distal arm section is fixedly secured to the proximal arm section to inhibit relative movement between the distal arm section and the proximal arm section. 17. The laser assembly of claim 16 wherein the grating can be rotated relative to the distal arm section and subsequently locked to the distal arm section. 18. The laser assembly of claim 16 further comprising a mover that selectively moves the arm assembly and the grating about the pivot axis. 19. The laser assembly of claim 18 wherein the mover is controlled to pivot the ar