Ultra wide band detectors

We claim: 1. A portal for scanning a passenger walking through an inspection region along a longitudinal axis, wherein the passenger is carrying at least one object on the passenger's body, the portal comprising: a funneled entrance comprising a first set of two opposing panels installed at a first angle to the longitudinal axis, each of the first set of two opposing panels comprising a first edge proximal to the center of the portal and a second edge distal to the center of the portal, a distance of the second edge from the longitudinal axis being greater than the distance of the first edge from the longitudinal axis for shaping said entrance as a narrowing funnel and thereby form the first angle, wherein the first angle is in a range of 5 to 85 degrees; a funneled exit comprising a second set of two opposing panels installed at a second angle to the longitudinal axis, each of the second set of two opposing panels comprising a first edge proximal to the center of the portal and a second edge distal to the center of the portal, a distance of the second edge from the longitudinal axis being greater than the distance of the first edge from the longitudinal axis for shaping said exit as an expanding funnel and thereby form the second angle, wherein the second angle is in a range of 5 to 85 degrees; a central portal comprising a third set of two opposing panels positioned parallel to each other and located between said funneled entrance and funneled exit, the funneled entrance and the funneled exit extending beyond the central portal in opposing directions, wherein the first, second and third sets of two opposing panels form the inspection region and comprise a plurality of transmitter elements to project microwave beams on the passenger as said passenger passes through the portal and a plurality of receiver elements to receive scattered microwave beams from the passenger, and wherein more than one transmitter element is active simultaneously and generates a plurality of scans of the inspection region while the passenger passes through the portal; and a plurality of processing blocks associated with said plurality of transmitter and receiver elements to process the scattered microwave beams and output data comprising at least one of a time, phase or frequency domain information, wherein the scattered microwave beams are a result of interactions of the projected microwave beams with an upper surface of the at least one object, a rear surface of the at least one object, and a portion of the passenger adjacent to the upper surface of the at least one object, and wherein said at least one of time, phase or frequency domain information is used to determine a location, shape, size or relative permittivity of the at least one object. 2. The portal of claim 1 , wherein a value of the first and second angles are selected to optimize at least one of an angular divergence of the transmitter and the receiver elements, a maximum allowable width of the portal, and a uniformity of surface coverage of the passenger under inspection, said first and second angles being in a range of 20 to 60 degrees. 3. The portal of claim 1 , wherein each panel of said first, second and third sets of two opposing panels is approximately 2 m tall and has a width ranging between 0.4 m and 1.0 m. 4. The portal of claim 1 , wherein the first, second and third sets of two opposing panels are configured to scan a front surface, a rear surface and a plurality of side surfaces of the passenger. 5. The portal of claim 1 , wherein said plurality of scans are generated at a rate ranging between 5 and 100 frames per second. 6. The portal of claim 1 , wherein said microwave beams have frequencies ranging between 2 GHz and 20 GHz. 7. The portal of claim 1 , wherein an antenna coupled to each of said plurality of transmitter and receiver elements has a diameter ranging between 1 cm and 10 cm. 8. The portal of claim 1 , wherein said plurality of transmitter elements are activated in a sequential raster scan pattern. 9. The portal of claim 1 , wherein said plurality of transmitter elements are activated in a pseudo random scan pattern. 10. The portal of claim 1 , wherein said at least one object is displayed as an icon superimposed on a real-time video image of the passenger. 11. The portal of claim 10 , wherein said icon is colored to indicate a threat status of said at least one object. 12. A method of scanning a passenger walking along a longitudinal axis of an inspection region of a portal, wherein the inspection region is defined by a central portal, an entrance funnel, and an exit funnel, wherein the central portal comprises a right panel and a left panel, said right and left panels opposing each other in a substantially parallel configuration, the entrance funnel and the exit funnel extending beyond the central portal in opposing directions, wherein the entrance funnel comprises a first set of two opposing panels installed at an angle of 5 to 85 degrees relative to the longitudinal axis, each of the first set of two opposing panels comprising a first edge proximal to the center of the portal and a second edge distal to the center of the portal, a distance of the second edge from the longitudinal axis being greater than the distance of the first edge from the longitudinal axis for shaping said entrance as a narrowing funnel, and wherein the exit funnel comprises a second set of two opposing panels installed at an angle of 5 to 85 degrees relative to the longitudinal axis, each of the second set of two opposing panels comprising a first edge proximal to the center of the portal and a second edge distal to the center of the portal, a distance of the second edge from the longitudinal axis being greater than the distance of the first edge from the longitudinal axis for shaping said exit as a narrowing funnel, the method comprising: projecting RF beams on the passenger from a plurality of transmitter elements on each of the panels of said central portal, entrance and exit funnels, wherein more than one transmitter element is active simultaneously and generates a plurality of scans of the inspection region while the passenger transits through the portal; receiving beams, scattered off the passenger, by a plurality of receiver elements on each of the panels of said central portal, entrance and exit funnels, wherein said scattered beams are a result of interactions of the projected RF beams with an upper surface and a rear surface of at least one object located on the passenger and with a surface on the passenger's body adjacent to the upper surface of the at least one object; and processing the scattered beams, using a plurality of processing blocks associated with said plurality of transmitter and receiver elements, to output data comprising at least one of a time, phase or frequency domain information, wherein said at least one of time, phase or frequency domain information is used to determine a location, shape, size, or relative permittivity of the at least one object. 13. The method of claim 12 , wherein the angle of installation of the first and the second set of two opposing panels with respect to the longitudinal axis ranges between 20 to 60 degrees. 14. The method of claim 12 , wherein each panel of said central portal, entrance funnel and exit funnel is approximately 2 m tall and has a width ranging between 0.4 m and 1.0 m. 15. The method of claim 12 , wherein the panels of said central portal, entrance funnel and exit funnel respectively scan a front surface, a rear surface and side surfaces of the passenger. 16. The method of claim 12 , wherein said plur