Colorless, directionless, contentionless optical network using MxN wavelength selective switches

What is claimed is: 1. An optical node, comprising: D (D≥2) input ports; D output ports; and D degrees, each degree, of the D degrees, including an inbound M×N (M≥D, N≥2D) wavelength selective switch (WSS) and an outbound M×N WSS, where each inbound M×N WSS includes: an input that connects to a respective input port of the D input ports, D−1 common inputs that connect to D−1 drop outputs, each of a respective inbound M×N WSS of the other degrees, D−1 express outputs that connect to D−1 express inputs, each of a respective outbound M×N WSS of the other degrees, D−1 drop outputs that connect to D−1 common inputs, each of a respective inbound M×N WSS of the other degrees, and at least one local drop port, and where each outbound M×N WSS includes: an output that connects to a respective output port of the D input ports, D−1 common outputs that connect to D−1 add inputs, each of a respective outbound M×N WSS of the other degrees, D−1 express inputs that connect to D−1 express outputs, each of a respective inbound M×N WSS of the other degrees, D−1 add inputs that connect to D−1 common outputs, each of a respective outbound M×N WSS of the other degrees, and at least one local add port. 2. The optical node of claim 1 , where N≥2D+1, and where the optical node further comprises: an expansion inbound WSS comprising: D common inputs that connect to D drop outputs, each of a respective inbound M×N WSS of the D degrees; and at least one local drop port. 3. The optical node of claim 1 , where N≥2D+1, and where the optical node further comprises: an expansion outbound WSS comprising: D common outputs that connect to D add inputs, each of a respective outbound M×N WSS of the D degrees; and at least one local add port. 4. The optical node of claim 1 , where N≥2D+1, and where each degree, of the D degrees, further includes an expansion inbound WSS and an expansion outbound WSS, where each expansion inbound WSS includes: a common input that connects to a drop output of an inbound M×N WSS of a degree associated with the expansion inbound WSS, D−1 common inputs that connect to D−1 drop outputs, each of a respective expansion inbound WSS of the other degrees, D−1 express outputs that connect to D−1 express inputs, each of a respective expansion outbound WSS of the other degrees, D−1 drop outputs that connect to D−1 common inputs, each of a respective expansion inbound WSS of the other degrees, and at least one local drop port, and where each expansion outbound WSS includes: a common output that connects to an add input of an outbound M×N WSS of a degree associated with the expansion outbound WSS, D−1 common outputs that connect to D−1 add inputs, each of a respective expansion outbound WSS of the other degrees, D−1 express inputs that connect to D−1 express outputs, each of a respective expansion inbound WSS of the other degrees, D−1 add inputs that connect to D−1 common outputs, each of a respective expansion outbound WSS of the other degrees, and at least one local add port. 5. The optical node of claim 1 , where an inbound M×N WSS and an outbound M×N WSS, associated with one of the D degrees, are optically independent WSSs arranged in a same physical space. 6. The optical node of claim 1 , where an inbound M×N WSS or an outbound M×N WSS, associated with a degree of the D degrees, includes a 1×N WSS and (D−1) 1×(M−2D+2) WSSs. 7. The optical node of claim 1 , where an inbound M×N WSS or an outbound M×N WSS, associated with a degree of the D degrees, includes a fewer than N M×1 optical switches. 8. An optical node, comprising: D (D≥2), input ports, D output ports, and D degrees, where each degree includes an inbound M×N (M≥D, N≥2D) wavelength selective switch (WSS) associated with a respective input port, and an outbound M×N WSS associated with a respective output port, where each inbound M×N WSS is to: receive optical signals from one input port and from inbound M×N WSSs of other degrees, provide optical signals to the inbound M×N WSSs of the other degrees for local drop at the other degrees, provide optical signals to outbound M×N WSSs of the other degrees, for their respective output ports, and provide optical signals to local drop ports; and where each outbound M×N WSS is to: receive optical signals from the inbound M×N WSSs of the other degrees and from the outbound M×N WSSs of the other degrees for its respective output port, receive optical signals from local add ports for its respective output port, and provide optical signals from local add ports to the outbound M×N WSSs of the other degrees for their respective output ports. 9. The optical node of claim 8 , where N≥2D+1, and where the optical node further comprises an expansion inbound WSS to: receive optical signals from inbound M×N WSSs of each of the D degrees, and provide optical signals to local drop ports of the expansion inbound WSS. 10. The optical node of claim 8 , where N≥2D+1, and where the optical node further comprises an expansion outbound WSS to: receive optical signals from local add ports of the expansion outbound WSS, and provide optical signals to outbound M×N WSSs of each of the D degrees. 11. The optical node of claim 8 , where N≥2D+1, and where each degree, of the D degrees, further includes an expansion inbound WSS and an expansion outbound WSS, where each expansion inbound WSS is to: receive optical signals from an inbound M×N WSS associated with a respective degree, and from expansion inbound M×N WSSs of other degrees, provide optical signals to the expansion inbound M×N WSSs of the other degrees for local drop at the other degrees, provide optical signals to outbound M×N WSSs of the other degrees for their respective outputs to respective outbound M×N WSSs, and provide optical signals to local drop ports of the expansion inbound M×N WSS; and where each expansion outbound WSS is to: receive optical signals from the expansion inbound M×N WSSs of the other degrees and from the expansion outbound M×N WSSs of the other degrees for its respective output to a respective outbound M×N WSS, receive optical signals from local add ports for its respective output to a respective outbound M×N WSS, and provide optical signals from local add ports to the expansion outbound M×N WSSs of the other degrees for their respective outputs to respective outbound M×N WSSs. 12. The optical node of claim 11 , where each expansion inbound M×N WSS is further to: provide optical signals to an additional expansion inbound M×N WSS associated with the respective degree. 13. The optical node of claim 11 , where each expansion outbound M×N WSS is further to: receive optical signals from an additional expansion outbound M×N WSS associated with the respective degree. 14. The optical node of claim 8 , where an inbound M×N WSS and an outbound M×N WSS, associated with one of the D degrees, are optically independent WSSs arranged in a same physical space. 15. The optical node of claim 8 , where an inbound M×N WSS or an outbound M×N WSS, associated with a degree of the D degrees, includes a 1×N WSS and (D−1) 1×(N−2D+2) WSSs. 16. The optical node of claim 8 , where an inbound M×N WSS or an outbound M×N WSS, associated with a degree of the D degrees, includes fewer than N M×1 optical switches. 17. An optical node architecture, comprising: D (D≥2) input ports and D output ports; and D degrees, each including an inbound M×N (M≥D, N≥2D) wavelength selective switch (WSS) and an outbound M×N WSS, where each inbound M×N WSS includes: an input that c