Optical couplers for evanescent coupling of polymer clad fibers to optical waveguides using alignment features

What is claimed is: 1. A method of performing evanescent optical coupling, comprising: providing at least one optical fiber having a central axis, a glass core, and a cladding, the cladding comprising an inner cladding made of glass and an outer cladding made of a polymer, and wherein the glass core and the glass inner cladding define a glass portion of the optical fiber; processing the at least one optical fiber to define a stripped portion substantially free of the outer cladding and configured to expose the glass portion, wherein the exposed glass portion defines: i) a first flat surface parallel with the central axis, wherein the core resides at or closely proximate to the first flat surface; and ii) an alignment feature; removing at least a portion of the outer cladding adjacent the exposed glass portion to allow for bending of the at least one optical fiber; bending the at least one optical fiber to define an axial coupling length for the exposed glass portion; operably engaging the alignment feature with an alignment member so that the alignment member operably supports the stripped portion to define an alignment assembly; and using the alignment assembly to bring the glass core sufficiently close to and in relative alignment with a waveguide core of at least one waveguide to establish evanescent coupling between the at least one optical fiber and the at least one waveguide. 2. The method according to claim 1 , wherein the at least one optical fiber comprises multiple optical fibers, and wherein the at least one waveguide comprises multiple waveguides operably supported in respective alignment channels of a photonic device, the method further comprising: inserting the glass portions of the multiple optical fibers into respective ones of the alignment channels. 3. The method according to claim 2 , wherein the inserting of the glass portions of the multiple optical fibers into respective ones of the alignment channels includes inserting the glass portions into respective flared open ends of the alignment channels. 4. The method according to claim 3 , wherein each alignment channel includes first and second opposing sidewalls and is wider than the glass portion, wherein the waveguides each respectively reside closest to the first sidewall, and further comprising: moving the alignment assembly over a motion path that causes the glass portions of each optical fiber to be moved into an aligned position when making contact with the first sidewall. 5. The method according to claim 1 , wherein said removing comprises performing laser ablation. 6. The method according to claim 1 , wherein said bending of the at least one optical fiber comprises pressing the exposed glass portion against a curved surface of a shaping member. 7. The method according to claim 1 , wherein said bending of the at least one optical fiber comprises sandwiching the exposed glass portion between a shaping member and a shaping jig and applying a squeezing force to the shaping member and the shaping jig. 8. The method according to claim 2 , further comprising: supporting the multiple glass portions in respective alignment grooves of an alignment jig, wherein the alignment grooves have a same period Λ as the alignment channels of the photonic device; and using the alignment jig to position the multiple glass portions on the alignment member so that the multiple glass portions define the period Λ. 9. The method according to claim 8 , further including receiving the multiple glass portions on a resilient surface of the alignment member. 10. The method according to claim 1 , wherein the exposed glass portion has a key-shaped profile with a bulbous portion that includes the first flat surface and a dovetail portion that includes the alignment feature, and further comprising: gripping the dovetail portion with gripping elements supported by the alignment member. 11. The method according to claim 10 , wherein the at least one optical fiber comprises multiple optical fibers having a select period Λ, the method further comprising: arranging the exposed glass portions of the multiple optical fibers on the alignment member with optical fiber spacers residing between the exposed glass portions to define paced apart alignment channels having the select period Λ. 12. The method according to claim 1 , further comprising defining the first flat surface and the alignment feature in a preform used draw the at least one optical fiber. 13. A method of performing evanescent optical coupling, comprising: providing at least one optical fiber having a central axis, a glass core, and a cladding, the cladding comprising an inner cladding made of glass and an outer cladding made of a polymer, and wherein the glass core and the glass inner cladding define a glass portion of the optical fiber; processing the at least one optical fiber to define a stripped portion substantially free of the outer cladding and configured to expose the glass portion, wherein the exposed glass portion defines: i) a first flat surface parallel with the central axis, wherein the core resides at or closely proximate to the first flat surface; and ii) an alignment feature; operably engaging the alignment feature with an alignment member so that the alignment member operably supports the stripped portion to define an alignment assembly; and using the alignment assembly to bring the glass core sufficiently close to and in relative alignment with a waveguide core of at least one waveguide to establish evanescent coupling between the at least one optical fiber and the at least one waveguide; wherein the at least one optical fiber comprises multiple optical fibers, and wherein the at least one waveguide comprises multiple waveguides operably supported in respective alignment channels of a photonic device, the method further comprising: supporting the multiple glass portions in respective alignment grooves of an alignment jig, wherein the alignment grooves have a same period Λ as the alignment channels of the photonic device; using the alignment jig to position the multiple glass portions on the alignment member so that the multiple glass portions define the period Λ; and inserting the glass portions of the multiple optical fibers into respective ones of the alignment channels. 14. The method according to claim 13 , further including receiving the multiple glass portions on a resilient surface of the alignment member. 15. A method of performing evanescent optical coupling, comprising: providing at least one optical fiber having a central axis, a glass core, and a cladding, the cladding comprising an inner cladding made of glass and an outer cladding made of a polymer, and wherein the glass core and the glass inner cladding define a glass portion of the optical fiber; processing the at least one optical fiber to define a stripped portion substantially free of the outer cladding and configured to expose the glass portion, wherein the exposed glass portion defines: i) a first flat surface parallel with the central axis, wherein the core resides at or closely proximate to the first flat surface; and ii) an alignment feature; operably engaging the alignment feature with an alignment member so that the alignment member operably supports the stripped portion to define an alignment assembly, wherein the exposed glass portion of the at least one optical fiber has a key-shaped profile with a bulbous portion that includes the first flat surface and a dovetail portion that includes the alignment feature, and wherein operably engaging the alignment feature with the alignment member comprises gripping