Transmission device with mode division multiplexing and methods for use therewith

What is claimed is: 1 . A transmission device comprising: at least one transceiver that generates a plurality of electromagnetic signals; and a plurality of couplers that facilitates coupling at least a portion of the plurality of electromagnetic signals to a transmission medium, wherein the plurality of couplers generates a plurality of electromagnetic waves that is bound to a physical interface of the transmission medium via differing ones of a plurality of guided wave modes, wherein the plurality of electromagnetic waves propagates along the physical interface of the transmission medium without requiring an electrical return path, wherein the plurality of guided wave modes includes a first non-fundamental mode and a second non-fundamental mode. 2 . The transmission device of claim 1 , wherein the first non-fundamental mode has a first electromagnetic field pattern that includes a first lobe at a first azimuthal orientation to a longitudinal axis of the transmission medium. 3 . The transmission device of claim 2 , wherein the second non-fundamental mode has a second electromagnetic field pattern that includes a second lobe at a second azimuthal orientation to the longitudinal axis of the transmission medium, and wherein the first azimuthal orientation differs from the second azimuthal orientation. 4 . The transmission device of claim 3 , wherein the first azimuthal orientation corresponds to a local minimum of the second electromagnetic field pattern and wherein the second azimuthal orientation corresponds to a local minimum of the first electromagnetic field pattern. 5 . The transmission device of claim 2 , wherein the first non-fundamental mode has a first electromagnetic field strength that varies helically along a longitudinal axis of the transmission medium and the second non-fundamental mode has a second electromagnetic field strength that varies helically along the longitudinal axis of the transmission medium. 6 . The transmission device of claim 5 , wherein the first electromagnetic field strength varies helically along the longitudinal axis of the transmission medium via a first direction of rotation and wherein the second electromagnetic field strength varies helically along the longitudinal axis of the transmission medium via a second direction of rotation. 7 . The transmission device of claim 1 , wherein the propagation of the plurality of electromagnetic waves facilitates a mode division multiplexing of data conveyed by the plurality of electromagnetic waves. 8 . A method, comprising: generating, by at least one transceiver, a plurality of electromagnetic signals; and coupling, by a plurality of couplers, at least a portion of each of the plurality of electromagnetic signals onto a physical interface of a transmission medium to induce a plurality of electromagnetic waves that propagates, without requiring an electrical return path, along the physical interface of the transmission medium, wherein the plurality of electromagnetic waves propagates via differing ones of a plurality of guided wave modes, wherein the plurality of guided wave modes includes a first non-fundamental mode and a second non-fundamental mode. 9 . The method of claim 8 , wherein the first non-fundamental mode has a first electromagnetic field strength that varies with an azimuthal orientation to a longitudinal axis of the transmission medium. 10 . The method of claim 9 , wherein the second non-fundamental mode has a second electromagnetic field strength that varies with the azimuthal orientation to the longitudinal axis of the transmission medium. 11 . The method of claim 9 , wherein the first non-fundamental mode has a first electromagnetic field pattern that includes a first lobe at a first azimuthal orientation to a longitudinal axis of the transmission medium and the second non-fundamental mode has a second electromagnetic field pattern that includes a second lobe at a second azimuthal orientation to the longitudinal axis of the transmission medium, and wherein the first azimuthal orientation differs from the second azimuthal orientation. 12 . The method of claim 11 , wherein the first azimuthal orientation corresponds to a local minimum of the second electromagnetic field pattern and wherein the second azimuthal orientation corresponds to a local minimum of the first electromagnetic field pattern. 13 . The method of claim 9 , wherein the first non-fundamental mode has a first electromagnetic field strength that varies helically along a longitudinal axis of the transmission medium and the second non-fundamental mode has a second electromagnetic field strength that varies helically along the longitudinal axis of the transmission medium. 14 . The method of claim 13 , wherein the first electromagnetic field strength varies helically along the longitudinal axis of the transmission medium via a first direction of rotation and wherein the second electromagnetic field strength varies helically along the longitudinal axis of the transmission medium via a second direction of rotation. 15 . A transmission device comprising: transceiver means for modulating data to generate a plurality of electromagnetic signals; and coupling means for coupling at least a portion of the plurality of electromagnetic signals onto a physical interface of a transmission medium, wherein the coupling means generates a plurality of mode division multiplexed electromagnetic waves that propagates along the physical of the transmission medium at non-optical frequencies without requiring an electrical return path, and wherein the plurality of mode division multiplexed electromagnetic waves facilitate a mode division multiplexing of the data. 16 . The transmission device of claim 15 , wherein one of the plurality of mode division multiplexed electromagnetic waves propagates along the physical interface of the transmission medium via a first non-fundamental mode and another of the plurality of mode division multiplexed electromagnetic waves propagates along the physical interface of the transmission medium via a second non-fundamental mode. 17 . The transmission device of claim 16 , wherein the first non-fundamental mode has a first electromagnetic field strength that varies with an azimuthal orientation to a longitudinal axis of the transmission medium and the second non-fundamental mode has a second electromagnetic field strength that varies with the azimuthal orientation to the longitudinal axis of the transmission medium. 18 . The transmission device of claim 16 , wherein the first non-fundamental mode has a first electromagnetic field pattern that includes a first lobe at a first azimuthal orientation to a longitudinal axis of the transmission medium and the second non-fundamental mode has a second electromagnetic field pattern that includes a second lobe at a second azimuthal orientation to the longitudinal axis of the transmission medium, and wherein the first azimuthal orientation differs from the second azimuthal orientation. 19 . The transmission device of claim 18 , wherein the first azimuthal orientation corresponds to a local minimum of the second electromagnetic field pattern and wherein the second azimuthal orientation corresponds to a local minimum of the first electromagnetic field pattern. 20 . The transmission device of claim 16 , wherein the first non-fundamental mode has a first electromagnetic field strength that varies helically along a longitudinal axis of the transmission medium and the second non-fundamental mode has