Laser apparatus

What is claimed is: 1. A laser apparatus comprising: a semiconductor laser element; a wavelength selecting element that performs laser oscillation by forming a resonator between itself and a reflective surface of the semiconductor laser element to output oscillated laser light; and an optical system that is optically coupled to an emission surface of the semiconductor laser element with a coupling efficiency η and inputs to the wavelength selecting element light output from the emission surface, the optical system being arranged such that a coupling distance L between the semiconductor laser element and the optical system has a value that is greater than a first value of the coupling distance L that results in a maximum coupling efficiency η and greater than a second value of the coupling distance L that results in a value of A equal to the value of A when the coupling distance L has the first value, thereby avoiding a peak in the value of A between the first and second values of the coupling distance L, wherein A={I thS 2 ·S.E. M ·η·( M+ 1) −1 ·( N− 1) 2 }/2, M=S.E. M /S.E. S , N=I thM /I thS , I thS represents a single mode oscillation threshold value, I thM represents a multimode oscillation threshold value, S.E. S represents single mode efficiency, and S.E. M represents multimode efficiency. 2. The laser apparatus according to claim 1 , wherein longitudinal multimode oscillation is performed within the linear light output region. 3. The laser apparatus according to claim 1 , wherein the optical system is a lensed fiber that undergoes processing to be lensed on one end thereof and guides the laser light output from the semiconductor laser element to the wavelength selecting element. 4. The laser apparatus according to claim 3 , wherein the lensed fiber is arranged at a position farther from a laser light emission end of the semiconductor laser element than a position that maximizes coupling efficiency with the laser light emission end. 5. The laser apparatus according to claim 3 , wherein a lens curvature radius of the lensed fiber is greater than a curvature radius that maximizes coupling efficiency with a laser light emission end of the semiconductor laser element. 6. The laser apparatus according to claim 3 , wherein one end of the lensed fiber undergoes processing to be lensed in two or more directions. 7. The laser apparatus according to claim 3 , wherein the lensed fiber causes a value B, which is correlated with a minimum light output within a linear light output region in which light output is linear, to be less than the value B occurring when the coupling efficiency η is at a maximum, B =η·( M+ 1) −1 ·( N− 1) 2 }, M=S.E. M /S.E. S , N=I thM /I thS , I thS represents a single mode oscillation threshold value, I thM represents a multimode oscillation threshold value, S.E. S represents single mode efficiency, and S.E. M represents multimode efficiency. 8. The laser apparatus according to claim 1 , wherein the optical system causes the value A to be less than 16 mW·mA. 9. The laser apparatus according to claim 1 , wherein the wavelength selecting element is a fiber Bragg grating. 10. The laser apparatus according to claim 1 , wherein the semiconductor laser element outputs a 980 nm band or a 1480 nm band of laser light. 11. A laser apparatus comprising: a semiconductor laser element; a wavelength selecting element that performs laser oscillation by forming a resonator between itself and a reflective surface of the semiconductor laser element to output oscillated laser light; and a lensed fiber that is optically coupled to an emission surface of the semiconductor laser element with a coupling efficiency η and guides laser light output from the semiconductor laser element to the wavelength selecting element, the lensed fiber being arranged such that a coupling distance L between the semiconductor laser element and the lensed fiber has a value that is greater than a first value of the coupling distance L that results in a maximum coupling efficiency η and greater than a second value of the coupling distance L that results in a value of B equal to the value of B when the coupling distance L has the first value, thereby avoiding a peak in the value of B between the first and second values of the coupling distance L, wherein B =η·( M+ 1) −1 ·( N− 1) 2 }, M=S.E. M /S.E. S , N=I thM /I thS , I thS represents a single mode oscillation threshold value, I thM represents a multimode oscillation threshold value, S.E. S represents single mode efficiency, and S.E. M represents multimode efficiency. 12. The laser apparatus according to claim 11 , wherein longitudinal multimode oscillation is performed within the linear light output region. 13. The laser apparatus according to claim 11 , wherein a lens curvature radius of the lensed fiber is greater than a curvature radius that maximizes coupling efficiency with a laser light emission end of the semiconductor laser element. 14. The laser apparatus according to claim 11 , wherein one end of the lensed fiber undergoes processing to be lensed in two or more directions. 15. The laser apparatus according to claim 11 , wherein the wavelength selecting element is a fiber Bragg grating. 16. The laser apparatus according to claim 11 , wherein the semiconductor laser element outputs a 980 nm band or a 1480 nm band of laser light.