Butterfly optical network with crossing-free switches

What is claimed is: 1. A multi-chip module (MCM), comprising: integrated circuits configured to perform electrical-to-optical conversion based on data to provide modulated optical signals, and configured to receive data in the modulated optical signals by performing optical-to-electrical conversion; optical waveguides, in a first plane, configured to convey the modulated optical signals among the integrated circuits; and a crossing-free optical-butterfly switch, optically coupled to the optical waveguides, configured to dynamically allocate communication bandwidth among the integrated circuits, wherein the optical-butterfly switch comprises optical components in the first plane and a second plane, and optical couplers configured to couple the modulated optical signals to and from the first plane and the second plane, wherein all optical switches in the crossing-free optical-butterfly switch are located in a same plane; and wherein the MCM is configured to communicate the modulated optical signals among the integrated circuits without optical-waveguide crossings in a given plane. 2. The MCM of claim 1 , wherein the optical-butterfly switch comprises a minimum number of optical couplers to avoid optical-waveguide crossings in the given plane. 3. The MCM of claim 1 , wherein the optical-butterfly switch comprises: N first optical switches having M input ports and M output ports, wherein the input ports are in the first plane and the output ports are in the second plane; and M second optical waveguides for the M output ports from each of the N first optical switches. 4. The MCM of claim 3 , wherein a given first optical switch comprises M optical couplers. 5. The MCM of claim 3 , wherein the optical-butterfly switch is configured to receive the modulated optical signals in the first plane and to output the modulated optical signals in the first plane. 6. The MCM of claim 5 , wherein the optical couplers in the optical-butterfly switch are configured to couple the modulated optical signals output by the N first optical switches in the second plane to the first plane. 7. The MCM of claim 3 , wherein a given first optical switch comprises I second optical switches having J input ports and J output ports in the first plane. 8. The MCM of claim 7 , wherein I is 4, J is 2, N is 8 and M is 4 so that the optical-butterfly switch has a total of 16 input ports and 16 output ports. 9. The MCM of claim 7 , wherein inter-switch signaling between adjacent second optical switches in the optical-butterfly switch is conveyed electrically. 10. The MCM of claim 7 , wherein a given second optical switch comprises a Mach-Zehnder interferometer. 11. The MCM of claim 3 , wherein inter-switch signaling among the N first optical switches in the optical-butterfly switch is conveyed optically. 12. The MCM of claim 1 , further comprising control logic to configure the optical-butterfly switch to dynamically allocate communication bandwidth among the integrated circuits. 13. The MCM of claim 1 , wherein the first optical waveguides and the optical-butterfly switch are implemented on a substrate using silicon-on-insulator technology. 14. A system, comprising: a set of light sources configured to output optical signals having carrier wavelengths; and a multi-chip module (MCM) optically coupled to the set of light sources, wherein the MCM comprises: integrated circuits configured to: receive the optical signals, perform electrical-to-optical conversion based on data to provide modulated optical signals, and receive data in the modulated optical signals by performing optical-to-electrical conversion; optical waveguides, in a first plane, configured to convey the modulated optical signals among the integrated circuits; and a crossing-free optical-butterfly switch, optically coupled to the optical waveguides, configured to dynamically allocate communication bandwidth among the integrated circuits, wherein the optical-butterfly switch comprises optical components in the first plane and a second plane, and optical couplers configured to couple the modulated optical signals to and from the first plane and the second plane, wherein all optical switches in the crossing-free optical-butterfly switch are located in a same plane; and wherein the MCM is configured to communicate the modulated optical signals among the integrated circuits without optical-waveguide crossings in a given plane. 15. The system of claim 14 , wherein the optical-butterfly switch comprises: N first optical switches having M input ports and M output ports, wherein the input ports are in the first plane and the output ports are in the second plane, and wherein a given first optical switch comprises M optical couplers; and M second optical waveguides for the M output ports from each of the N first optical switches. 16. The system of claim 15 , wherein the optical couplers in the optical-butterfly switch are configured to couple the modulated optical signals output by the N first optical switches in the second plane to the first plane so that the optical-butterfly switch receives the modulated optical signals in the first plane and outputs the modulated optical signals in the first plane. 17. The system of claim 16 , wherein a given first optical switch comprises I second optical switches having J input ports and J output ports in the first plane. 18. The system of claim 17 , wherein a given second optical switch comprises a Mach-Zehnder interferometer. 19. The system of claim 15 , further comprising control logic to configure the optical-butterfly switch to dynamically allocate communication bandwidth among the integrated circuits. 20. A method for optically communicating information among integrated circuits in an MCM, the method comprising: configuring a crossing-free optical-butterfly switch to dynamically allocate communication bandwidth among the integrated circuits; and routing modulated optical signals that include the information among the integrated circuits using the optical-butterfly switch, wherein the optical-butterfly switch is implemented using optical components in a first plane and a second plane, and optical couplers that couple the modulated optical signals to and from the first plane and the second plane, wherein all optical switches in the crossing-free optical-butterfly switch are located in a same plane; and wherein the modulated optical signals are communicated among the integrated circuits without optical-waveguide crossings in a given plane.