Laser-based systems and methods for fiber-to-ferrule bonding for optical fiber connectors

What is claimed is: 1. A method of securing a bare fiber section within a longitudinal bore of a ferrule having a front end and a back end, wherein the ferrule comprises a ceramic material, and wherein at least a portion of the front end of the ferrule is spaced apart from a back optical surface of a reference optical system by a distance d s in the range 5 μm≦d s ≦15 μm, the method comprising: inserting the bare fiber section into the longitudinal bore of the ferrule from the back end to the front end until an endface of the bare fiber section contacts the back optical surface of the reference optical system such that the bare fiber section protrudes from the front end of the ferrule by the distance d s , the longitudinal bore having a length and an inner wall; introducing a photoactivated adhesive into the longitudinal bore, wherein the photoactivated adhesive occupies at least a portion of a region within the longitudinal bore defined by the inner wall of the longitudinal bore and the bare fiber section disposed therein, and further wherein the photoactivated adhesive is activated when exposed to an activating light; and focusing the activating light at a focus position in front of the front end of the ferrule to form a diverging beam of the activating light that passes through the reference optical system and enters the endface of the bare fiber section while the bare fiber section remains protruding from the front end of the ferrule by the distance d s , wherein the activating light passes out of the bare fiber section in the longitudinal bore and exposes the photoactivated adhesive to bond the bare fiber section to the ceramic material of the ferrule; wherein the activating light is generated by a diode laser with an operating wavelength in the range from 200 nm to 600 nm. 2. The method according to claim 1 , wherein focusing the activating light at the focus position includes passing the activating light through a focusing optical system. 3. The method according to claim 2 , wherein the focusing optical system consists of a single aspheric refractive lens element. 4. The method according to claim 1 , further comprising: incorporating the ferrule and optical fiber bonded therein into an optical fiber connector. 5. The method according to claim 1 , wherein: the photoactive adhesive substantially occupies the annular cylindrical region defined by the inner wall of the longitudinal bore and the outer surface of the bare fiber section; and the activating light that passes out of the bare fiber section in the longitudinal bore exposes the photoactive adhesive over substantially the entire length of the longitudinal bore to bond the bare fiber section within the longitudinal bore. 6. The method according to claim 1 , wherein introducing the photoactivated adhesive into the longitudinal bore includes at least one of: a) dipping the bare fiber section into the photoactivated adhesive and then inserting the bare fiber section and photoactivated adhesive into the longitudinal bore; b) injecting the photoactivated adhesive into the longitudinal bore; and c) passing the bare fiber section through a drop of photoactivated adhesive disposed at the back end of the ferrule at the longitudinal bore. 7. The method according to claim 1 , wherein the optical fiber has a core and the photoactivated adhesive is index-matched to the core. 8. The method according to claim 1 , further comprising: processing the endface of the bare fiber section after the bonding of the bare fiber section within the longitudinal bore. 9. The method according to claim 1 , wherein the focus position is located at a distance d p from the front end of the ferrule, and wherein 0.5 mm≦d p ≦5 mm. 10. The method according to claim 1 , wherein the back optical surface includes a coating that does not substantially bond to the photoactivated adhesive. 11. The method according to claim 1 , wherein the ceramic material of the ferrule comprises zirconia, and wherein the activating light is generated by a visible-wavelength diode laser. 12. A method of bonding a bare section of optical fiber within a longitudinal bore of a ferrule for an optical fiber connector, wherein the ferrule comprises a ceramic material, and wherein at least a portion of a front end of the ferrule is spaced apart from a back optical surface of a reference optical system by a distance d s in the range 5 μm≦d s ≦15 μm, the method comprising: inserting the bare fiber section into the ferrule bore until an endface of the bare fiber section contacts the back optical surface of the reference optical system such that the bare fiber section protrudes from the front end of the ferrule by the distance d s ; introducing a photoactivated adhesive into the ferrule bore, wherein the photoactivated adhesive occupies at least a portion of an annular cylindrical region defined between an inner wall of the ferrule bore and an outer surface of bare fiber section; directing a diverging beam of activating light through the reference optical system and into the endface of the bare fiber section while the bare fiber section remains protruding from the front end of the ferrule by the distance d s , wherein the activating light originates from a diode laser that emits light at a wavelength in the range from 200 nm to 600 nm; and passing the activating light through the bare fiber section to expose the photoactivated adhesive that occupies at least a portion of the annular cylindrical region, thereby bonding the bare fiber section to the ceramic material of the ferrule within the longitudinal bore. 13. The method according to claim 12 , further including incorporating the ferrule and the bare fiber section into an optical fiber connector. 14. The method according to claim 12 , wherein introducing the photoactivated adhesive into the ferrule bore includes at least one of: a) dipping the bare fiber section into the photoactivated adhesive and then inserting the bare fiber section and photoactivated adhesive into the longitudinal bore; b) injecting the photoactivated adhesive into the longitudinal bore; and c) passing the bare fiber section through a drop of photoactivated adhesive disposed at a back end of the ferrule at the longitudinal bore. 15. The method according to claim 12 , further comprising forming the diverging activating light by focusing activating light to a focus position upstream of the endface of the bare fiber section. 16. The method according to claim 12 , wherein the ceramic material of the ferrule comprises zirconia, and wherein the activating light is generated by a visible-wavelength diode laser. 17. The method according to claim 12 , wherein: the ferrule bore is nominally centered on a true center of ferrule; the bare fiber section has a diameter of 125 μm; and the diverging beam of activating light has a divergence angle that is within +/−10% of 45.4 milliradians. 18. A method of securing a bare fiber section within a longitudinal bore of a ferrule having a front end and a back end, wherein at least a portion of the front end of the ferrule is spaced apart from a back optical surface of a reference optical system by a distance d s in the range 5 μm≦d s ≦15 μm, the method comprising: inserting the bare fiber section into the longitudinal bore of the ferrule from the back end to the front end until an endface of the bare fiber section contacts the back optical surface of the reference optical system such that the bare fiber section protrudes from the front end of the ferrule by the distance d s , the longitudinal