Scalable switch fabric using optical interconnects

What is claimed is: 1. A scalable switch fabric comprising: a plurality of line modules each comprising fabric interface optics supporting a plurality of optical output signals; an optical interconnect optically connected to each of the plurality of line modules via the fabric interface optics; and a plurality of center stage switches, wherein the optical interconnect is adapted to shuffle the plurality of optical output signals from each of the plurality of line modules to the plurality of center stage switches, and wherein the optical interconnect comprises: a first level of shuffle components connected to the one or more line modules, and a second level of shuffle components integrated with the plurality of center stage switches, wherein the first level of shuffle components and the second level of shuffle components utilize one or more cyclic Arrayed Waveguide Grating (AWG) devices, wherein each of the plurality of center stage switches comprises a fabric block forming a part of the second level of shuffle, and wherein expansion of the scalable switch fabric is through addition of the first level of shuffle components and the second level of shuffle components and modification of cabling therebetween. 2. The scalable switch fabric of claim 1 , wherein optical connections in the fabric block remain fixed as the scalable switch fabric grows and optical connections between the first level of shuffle components and the second level of shuffle components are modified as the scalable switch fabric grows. 3. The scalable switch fabric of claim 1 , wherein optical connections between the optical interconnect and the plurality of center stage switches remain partially fixed as the scalable switch fabric grows through addition of more first level of shuffle components and more second level of shuffle components. 4. The scalable switch fabric of claim 1 , wherein the optical interconnect connects to the plurality of line modules via bundled fiber cables each comprising a plurality of optical fibers and a single connector for all of the plurality of optical fibers. 5. The scalable switch fabric of claim 1 , wherein the optical interconnect connects to the plurality of line modules via Dense Wave Division Multiplexing (DWDM) for the plurality of optical output signals from each of the fabric interface optics. 6. The scalable switch fabric of claim 1 , wherein the scalable switch fabric is connected with an existing switch comprising an electrical backplane for expansion thereof. 7. A scalable switch fabric method comprising: providing a plurality of line modules each comprising fabric interface optics supporting a plurality of optical output signals; providing an optical interconnect optically connected to each of the plurality of line modules via the fabric interface optics; and providing a plurality of center stage switches, wherein the optical interconnect is adapted to shuffle the plurality of optical output signals from each of the plurality of line modules to the plurality of center stage switches, and wherein the optical interconnect comprises: a first level of shuffle components connected to the one or more line modules, and a second level of shuffle components integrated with the plurality of center stage switches, wherein the first level of shuffle components and the second level of shuffle components utilize one or more cyclic Arrayed Waveguide Grating (AWG) devices, wherein each of the plurality of center stage switches comprises a fabric block forming a part of the second level of shuffle, and wherein expansion of the scalable switch fabric is through addition of the first level of shuffle components and the second level of shuffle components and modification of cabling therebetween. 8. The scalable switch fabric method of claim 7 , wherein optical connections in the fabric block remain fixed as the scalable switch fabric grows and connectivity between the first level of shuffle components and the second level of shuffle components is modified as the scalable switch fabric grows. 9. The scalable switch fabric method of claim 7 , wherein the optical interconnect connects to the plurality of line modules via bundled fiber cables each comprising a plurality of optical fibers and a single connector for all of the plurality of optical fibers. 10. The scalable switch fabric method of claim 7 , wherein the optical interconnect connects to the plurality of line modules via Dense Wave Division Multiplexing (DWDM) for the plurality of optical output signals from each of the fabric interface optics. 11. The scalable switch fabric method of claim 7 , wherein the scalable switch fabric is connected with an existing switch comprising an electrical backplane for expansion thereof. 12. A switch system with optical interconnections, the switch system comprising: a plurality of line modules each comprising fabric interface optics supporting a plurality of optical output signals; a first level of optical shuffle components connected to each of the fabric interface optics; and a plurality of fabric blocks collectively forming a second level of optical shuffle components connected to the first level of optical shuffle components and a plurality of center stage switches each optically connected to the second level of optical shuffle components in a fixed manner; wherein expansion of the switch system comprises modification of connections between the first level of optical shuffle components and the second level of optical shuffle components with the connections in the one or more fabric blocks in the fixed manner, wherein the first level of optical shuffle components and the second level of optical shuffle components utilize one or more cyclic Arrayed Waveguide Grating (AWG) devices. 13. The switch system of claim 12 , wherein the plurality of line modules are connected to the first level of optical shuffle via bundled fiber cables each comprising a plurality of optical fibers and a single connector for all of the plurality of optical fibers. 14. The switch system of claim 12 , wherein the plurality of line modules are connected to the first level of optical shuffle via Dense Wave Division Multiplexing (DWDM) for the plurality of optical output signals from each of the fabric interface optics.