Waveguide polarization rotator and method of construction thereof

What is claimed is: 1. A waveguide polarization rotator, comprising: an optical waveguide having an input end and an output end oppositely disposed thereon, the optical waveguide operable to: receive, at the input end, an input optical signal having a mode having an input polarization, and generate, at the output end, an output optical signal having an output polarization orthogonal to the input polarization; and an overlay strip disposed over and non-orthogonally crossing the optical waveguide, and having a first end laterally offset from the optical waveguide by a first offset distance and a second end laterally offset from the optical waveguide by a second offset distance, wherein the optical waveguide has a waveguide width and the overlay strip has an overlay width no greater than the waveguide width. 2. The waveguide polarization rotator of claim 1 wherein the overlay strip comprises polysilicon. 3. The waveguide polarization rotator of claim 1 wherein a fundamental mode of the optical waveguide is equal to a fundamental mode of the waveguide polarization rotator at the first end and at the second end of the overlay strip. 4. The waveguide polarization rotator of claim 1 further comprising a cladding layer disposed between the optical waveguide and the overlay strip. 5. The waveguide polarization rotator of claim 1 wherein the optical waveguide comprises a silicon nanowire waveguide. 6. The waveguide polarization rotator of claim 1 wherein a principal axis of the mode of the input optical signal is parallel to a substrate plane of the waveguide polarization rotator. 7. A method of constructing a waveguide polarization rotator, comprising: forming an optical waveguide having an input end and an output end oppositely disposed thereon; forming a cladding layer over the optical waveguide; registering an overlay strip having a first end and a second end oppositely disposed thereon, wherein: the first end is laterally offset from the optical waveguide by a first offset distance and the second end is laterally offset from the optical waveguide by a second offset distance, and the first end and the second end are oppositely disposed on either side of the optical waveguide; and forming the overlay strip over the cladding layer according to the registering. 8. The method of claim 7 wherein the forming the optical waveguide comprises forming silicon on an insulator substrate. 9. The method of claim 7 wherein the forming the cladding layer comprises forming silica around the optical waveguide. 10. The method of claim 7 wherein the forming the overlay strip comprises forming polysilicon over the cladding layer. 11. The method of claim 7 wherein the first offset distance comprises a tolerance portion determined according to fabrication tolerances for the forming the optical waveguide and the forming the overlay strip. 12. The method of claim 7 wherein the forming the overlay strip comprises: forming a first adiabatic rotation region where the overlay strip begins to cross the optical waveguide nearest the first end of the overlay strip; and forming a second adiabatic rotation region where the overlay strip begins to cross the optical waveguide nearest the second end of the overlay strip. 13. The method of claim 12 wherein the first adiabatic rotation region is operable to rotate a polarization of a mode at least 30 degrees relative to a substrate plane of the optical waveguide. 14. The method of claim 13 wherein the mode is a transverse magnetic (TM) mode. 15. The method of claim 7 wherein the forming the overlay strip comprises forming a polysilicon layer having an overlay width no greater than a waveguide width of the optical waveguide and an overlay length at least long enough to satisfy the first offset distance and the second offset distance. 16. The method of claim 15 wherein the overlay length includes a tolerance to accommodate registration and fabrication errors along an axis of propagation for the optical waveguide. 17. A photonic circuit, comprising: a polarization splitter configured to separate a received optical signal into a first mode and a second mode, wherein the first mode and the second mode are orthogonal with respect to each other; a waveguide polarization rotator having: an optical waveguide having an input end and an output end oppositely disposed thereon, the optical waveguide operable to receive, at the input end coupled to the polarization splitter, the first mode having an input polarization and generate, at the output end, an output optical signal having an output polarization orthogonal to the input polarization, and an overlay strip disposed over and non-orthogonally crossing the optical waveguide, and having a first end laterally offset from the optical waveguide by a first offset distance and a second end laterally offset from the optical waveguide by a second offset distance, wherein the optical waveguide has a waveguide width and the overlay strip has an overlay width no greater than the waveguide width; and a filter coupled to the output end of the waveguide polarization rotator, and configured to apply a transfer function designed for the second mode to the output optical signal from the waveguide polarization rotator. 18. The photonic circuit of claim 17 wherein the first mode is a transverse electric (TE) mode. 19. A waveguide polarization rotator, comprising: an optical waveguide having an input end and an output end oppositely disposed thereon, the optical waveguide operable to: receive, at the input end, an input optical signal having a mode having an input polarization, and generate, at the output end, an output optical signal having an output polarization orthogonal to the input polarization; and an overlay strip disposed over and non-orthogonally crossing the optical waveguide, and having a first end laterally offset from the optical waveguide by a first offset distance and a second end laterally offset from the optical waveguide by a second offset distance, wherein the overlay strip comprises polysilicon. 20. The waveguide polarization rotator of claim 19 , wherein the optical waveguide comprises a silicon nanowire waveguide. 21. The waveguide polarization rotator of claim 19 further comprising a cladding layer disposed between the optical waveguide and the overlay strip. 22. A waveguide polarization rotator, comprising: an optical waveguide having an input end and an output end oppositely disposed thereon, the optical waveguide comprising a silicon nanowire waveguide, and the optical waveguide operable to: receive, at the input end, an input optical signal having a mode having an input polarization, and generate, at the output end, an output optical signal having an output polarization orthogonal to the input polarization; and an overlay strip disposed over and non-orthogonally crossing the optical waveguide, and having a first end laterally offset from the optical waveguide by a first offset distance and a second end laterally offset from the optical waveguide by a second offset distance. 23. The waveguide polarization rotator of claim 22 further comprising a cladding layer disposed between the optical waveguide and the overlay strip.