High End Imaging Radar

What is claimed is: 1 . A lens antenna system, comprising: a reconfigurable aperture configured to: receive a source beam; and provide an output beam based on a surface impedance distribution of the reconfigurable aperture and the received source beam; and a control device operatively coupled to the reconfigurable aperture, wherein the control device is configured to control the surface impedance distribution of the reconfigurable aperture to configure and reconfigure a beam pattern of the output beam. 2 . The lens antenna system of claim 1 further comprising a plurality of antenna elements physically positioned proximate the reconfigurable aperture, wherein the plurality of antenna elements are configured to generate the source beam. 3 . The lens antenna system of claim 1 , wherein the control device is configured to control the surface impedance distribution of the reconfigurable aperture to permit at least a portion of the received source beam to propagate the reconfigurable aperture as the output beam. 4 . The lens antenna system of claim 1 , wherein the reconfigurable aperture comprises a plurality of diodes physically positioned on a surface of the reconfigurable aperture and the control device is configured to bias the plurality of diodes to control the surface impedance distribution of the reconfigurable aperture. 5 . The lens antenna system of claim 4 , wherein the plurality of diodes are arranged in a pixelated pattern on the surface of the reconfigurable aperture. 6 . The lens antenna system of claim 4 , wherein each diode of the plurality of diodes are configured to operate in states comprising: a first state that permits at least a portion of the source beam to propagate to a corresponding diode of the plurality of diodes; and a second state that prevents the source beam from propagating to the corresponding diode. 7 . The lens antenna system of claim 6 , wherein the control device is configured to bias each diode of the plurality of diodes to control whether each diode of the plurality of diodes is in the first state or the second state. 8 . The lens antenna system of claim 6 , wherein the first state includes an analog state and the control device is configured to control a level of voltage signals provided to the plurality of diodes to change the surface impedance distribution of the reconfigurable aperture. 9 . The lens antenna system of claim 6 , wherein the first state includes an on-state mode in a forward bias solid-state plasma condition of the corresponding diode of the plurality of diodes; and the second state includes an off-state mode under open bias of the corresponding diode of the plurality of diodes. 10 . The lens antenna system of claim 6 , wherein each diode of the plurality of diodes includes a P region, a N region, and an I region, and the P region and the N region are configured to be biased to control an impedance of the I region and whether the corresponding diode is in the first state or the second state. 11 . The lens antenna system of claim 10 , wherein the I region is physically positioned between the P region and the N region, wherein the I region physically contacts the P region and the N region, wherein a range of impedance values of the impedance of the I region is based on a distance between the P region and the N region. 12 . The lens antenna system of claim 11 , wherein each diode of the plurality of diodes further includes a buried oxide region and the range of impedance values of the impedance of the I region is further based on a thickness of the P region, the N region, and the I region on top of the buried oxide region. 13 . The lens antenna system of claim 6 , wherein the reconfigurable aperture further includes a static portion, the static portion causing the reconfigurable aperture to provide the output beam as at least a minimum beam pattern when the plurality of diodes are in the second state. 14 . The lens antenna system of claim 4 , wherein the plurality of diodes include a plurality of PIN diodes. 15 . The lens antenna system of claim 4 , wherein the control device is configured to control each diode of the plurality of diodes.