Optical switches with surface grating couplers and edge couplers

What is claimed is: 1. A photonic integrated circuit (PIC) comprising: an optical switch, wherein the optical switch is a dilated optical switch; a plurality of input edge couplers comprising a first input edge coupler and coupled to the optical switch; a plurality of input surface grating couplers (SGCs) comprising a first input SGC and coupled to the optical switch; a plurality of output edge couplers comprising a first output edge coupler and coupled to the optical switch; and a plurality of output SGCs comprising a first output SGC and coupled to the optical switch. 2. The PIC of claim 1 , further comprising a chip, wherein the chip comprises the optical switch, the input edge couplers, the input SGCs, the output edge couplers, and the output SGCs. 3. The PIC of claim 2 , wherein the chip primarily comprises silicon. 4. The PIC of claim 2 , wherein the chip is a silicon-on-insulator (SOI) chip. 5. The PIC of claim 1 , wherein the optical switch comprises a Benes network. 6. A photonic integrated circuit (PIC) comprising: an optical switch comprising an input cell and an output cell, wherein the input cell comprises a first input and a second input, and wherein the output cell comprises a first output and a second output; a plurality of input edge couplers comprising a first input edge coupler and coupled to the optical switch, wherein the first input is coupled to the first input edge coupler; a plurality of input surface grating couplers (SGCs) comprising a first input SGC and coupled to the optical switch, wherein the second input is coupled to the first input SGC; a plurality of output edge couplers comprising a first output edge coupler and coupled to the optical switch, wherein the first output is coupled to the first output edge coupler; and a plurality of output SGCs comprising a first output SGC and coupled to the optical switch, wherein the second output is coupled to the first output SGC. 7. An apparatus comprising: a plurality of input edge couplers; a plurality of input surface grating couplers (SGCs); a first optical switch coupled to the input edge couplers and the input SGCs and configured to receive from the input edge couplers and the input SGCs first components of input optical signals; a second optical switch coupled to the input edge couplers and the input SGCs and configured to receive from the input edge couplers and the input SGCs second components of the input optical signals; and a plurality of input polarization splitter-rotators (PSRs) coupled to the input edge couplers, the first optical switch, and the second optical switch such that the input PSRs are positioned between the input edge couplers and the first optical switch and between the input edge couplers and the second optical switch. 8. The apparatus of claim 7 , further comprising a plurality of output edge couplers coupled to the first optical switch and the second optical switch and configured to receive the first components from the first optical switch and the second components from the second optical switch. 9. The apparatus of claim 8 , further comprising a plurality of output PSRs coupled to the output edge couplers, the first optical switch, and the second optical switch such that the output PSRs are positioned between the first optical switch and the output edge couplers and between the second optical switch and the output edge couplers. 10. The apparatus of claim 9 , further comprising a plurality of output SGCs coupled to the first optical switch and the second optical switch and configured to receive the first components from the first optical switch and the second components from the second optical switch. 11. The apparatus of claim 10 , wherein the input SGCs and the output SGCs are polarization-splitting SGCs (PSSGCs). 12. An apparatus comprising: a plurality of input edge couplers; a plurality of input surface grating couplers (SGCs); a first optical switch coupled to the input edge couplers and the input SGCs and configured to receive from the input edge couplers and the input SGCs first components of input optical signals, wherein the first components have a transverse electric (TE) polarization upon entering the input edge couplers and the input SGCs; and a second optical switch coupled to the input edge couplers and the input SGCs and configured to receive from the input edge couplers and the input SGCs second components of the input optical signals, wherein the second components have a transverse magnetic (TM) polarization upon entering the input edge couplers and the input SGCs. 13. The apparatus of claim 7 , wherein the first optical switch is a dilated optical switch, the second optical switch is a dilated optical switch, or both the first optical switch and the second optical switch are dilated optical switches. 14. The apparatus of claim 7 , wherein the first optical switch comprises a Benes network, the second optical switch comprises a Benes network, or both the first optical switch and the second optical switch comprise Benes networks. 15. The PIC of claim 1 , wherein the input SGCs and the output SGCs are single-polarization SGCs (SPSGCs). 16. The PIC of claim 1 , wherein the input SGCs and the output SGCs are polarization-splitting SGCs (PSSGCs). 17. The PIC of claim 1 , wherein the input edge couplers, the output edge couplers, or both the input edge couplers and the output edge couplers are configured to couple to optical fibers or other components for testing or implementation purposes. 18. The PIC of claim 1 , wherein the input SGCs, the output SGCs, or both the input SGCs and the output SGCs are configured to couple to optical fibers or other components for testing or implementation purposes. 19. The PIC of claim 1 , wherein the input SGCs and the output SGCs each comprise a grating and a waveguide, and wherein the grating provides scattering centers to couple an optical signal to the waveguide. 20. The PIC of claim 1 , wherein the input SGCs and the output SGCs each comprise a grating, a first waveguide, and a second waveguide, wherein the grating is configured to receive and split an optical signal into a first component and a second component, wherein the first waveguide is configured to focus and output the first component, and wherein the second waveguide is configured to focus and output the second component.