Flat-plate, low sidelobe, two-dimensional, steerable leaky-wave planar array antenna

What is claimed is: 1. An antenna comprising: a composite right- and left-handed (CRLH) metamaterial antenna array configured to radiate a radio-frequency (RF) beam pattern, the CRLH metamaterial antenna array comprising: a plurality of paired first and second rows of unit cells in which one of the first and second rows of unit cells is controllable to operate in a left-hand radiation mode, and the other of the first and second rows of unit cells is controllable to operate in a right-hand radiation mode, the plurality of paired first and second rows of unit cells configured to propagate a radiation pattern along a first axis; and each of the unit cells in the plurality include a volume of liquid crystal having a controllable dielectric value and at least one isolated ground patch configured as a virtual ground connection to enable a potential difference for controlling the dielectric value of the volume of liquid crystal; a plurality of RF input ports disposed in a centralized location; a dual-channel center-feed network structure communicatively coupled to the plurality of paired first and second rows of unit cells and the plurality of RF input ports to form the RF beam pattern, the center feed network structure comprising: a composite right- and left-handed (CRLH) metamaterial, a volume of liquid crystal having a controllable dielectric value, and at least one isolated ground patch configured as a virtual ground connection; and a metallic top enclosure covering a top side of the center feed network structure; wherein, the dual-channel center-feed network structure is configured to supply each of the plurality of RF input ports opposing phase information in a sequential manner, such that the one of the first and second rows of unit cells is controlled to operate in a left-hand radiation mode and the other of the first and second rows of unit cells is controlled to operate in a right-hand radiation mode. 2. The antenna of claim 1 , wherein the plurality of paired first and second rows of unit cells are separated by a distance of one quarter or one half of an operating wavelength. 3. The antenna of claim 1 , wherein each of the plurality of RF input ports are configured to be communicatively coupled to respective sections of the paired first and second rows of unit cells. 4. The antenna of claim 1 , wherein the dual-channel center-feed network structure comprises a first dual-channel center-feed network and a second dual-channel center-feed network, in which each channel of the first and second dual-channel center-feed networks are communicatively coupled to one of the RF input ports. 5. The antenna of claim 4 , wherein each channel of the first and second dual-channel center-feed networks is configured to sequentially supply each of the coupled RF input ports with alternating, opposite phase information. 6. The antenna of claim 1 , wherein the dual-channel center-feed network structure is configured to apply predetermined control voltages to the first and second rows of unit cells to control a direction of the formed RF beam pattern. 7. The antenna of claim 6 , wherein the dual-channel center-feed network structure applies lower level control voltages to the rows of unit cells operating in the right-hand radiation mode to control the formed RF beam pattern along a directional angle. 8. The antenna of claim 6 , wherein the dual-channel center-feed network structure applies higher level control voltages to the rows of unit cells operating in the left-hand radiation mode to control the formed RF beam pattern along a directional angle. 9. A wireless communication device comprising: an antenna for receiving and transmitting wireless signals, the antenna comprising: a composite right- and left-handed (CRLH) metamaterial antenna array configured to radiate a radio-frequency (RF) beam pattern, the CRLH metamaterial antenna array comprising: a plurality of paired first and second rows of unit cells in which one of the first and second rows of unit cells is controllable to operate in a left-hand radiation mode, and the other of the first and second rows of unit cells is controllable to operate in a right-hand radiation mode, the plurality of paired first and second rows of unit cells configured to propagate a radiation pattern along a first axis; and each of the unit cells in the plurality include a volume of liquid crystal having a controllable dielectric value and at least one isolated ground patch configured as a virtual ground connection to enable a potential difference for controlling the dielectric value of the volume of liquid crystal; a plurality of RF input ports disposed in a centralized location; a dual-channel center-feed network structure communicatively coupled to the plurality of paired first and second rows of unit cells and the plurality of RF input ports to form the RF beam pattern, the center feed network structure comprising: a composite right- and left-handed (CRLH) metamaterial, a volume of liquid crystal having a controllable dielectric value, and at least one isolated ground patch configured as a virtual ground connection; and a metallic top enclosure covering a top side of the center feed network structure; wherein, the dual-channel center-feed network structure is configured to supply each of the plurality of RF input ports opposing phase information in a sequential manner, such that the one of the first and second rows of unit cells is controlled to operate in a left-hand radiation mode and the other of the first and second rows of unit cells is controlled to operate in a right-hand radiation mode. 10. The wireless communication device of claim 9 , wherein the plurality of paired first and second rows of unit cells are separated by a distance of one quarter or one half of an operating wavelength. 11. The wireless communication device of claim 9 , wherein each of the plurality of RF input ports are configured to be communicatively coupled to respective sections of the paired first and second rows of unit cells. 12. The wireless communication device of claim 9 , wherein the dual-channel center-feed network structure comprises a first dual-channel center-feed network and a second dual-channel center-feed network, in which each channel of the first and second dual-channel center-feed networks are communicatively coupled to one of the RF input ports. 13. The wireless communication device of claim 12 , wherein each channel of the first and second dual-channel center-feed networks is configured to sequentially supply each of the coupled RF input ports with alternating, opposite phase information. 14. The wireless communication device of claim 9 , wherein the dual-channel center-feed network structure is configured to apply predetermined control voltages to the first and second rows of unit cells to control a direction of the formed RF beam pattern. 15. The wireless communication device of claim 14 , wherein the dual-channel center-feed network structure applies lower level control voltages to the rows of unit cells operating in the right-hand radiation mode to control the formed RF beam pattern along a directional angle. 16. The wireless communication device of claim 14 , wherein the dual-channel center-feed network structure applies higher level control voltages to the rows of unit cells operating in the left-hand radiation mode to control the formed RF beam pattern along a directional angle.