Reconfigurable radial waveguides with switchable artificial magnetic conductors

The invention claimed is: 1. A switchable artificial magnetic conductor (S-AMC) element comprising: a conductive layer having at least two sides; a conductive patch located on one side of the conductive layer and electrically isolated from the conductive layer; an open stub located on an opposite side of the conductive layer and electrically isolated from the conductive layer; and a switch element configured to selectively open and close an electrical connection between the conductive patch and the open stub in response to a control signal, the conductive patch presenting, when the electrical connection is closed, a high impedance, magnetically conductive surface for radio frequency (RF) signals within a defined frequency band, and the conductive patch presenting, when the electrical connection is open, an electrically conductive surface for RF signals within the defined frequency band. 2. The S-AMC element of claim 1 wherein the open stub and the conductive patch are configured to function as an LC circuit having a resonant frequency that falls within the defined frequency band when the electrical connection is closed. 3. The S-AMC element of claim 1 wherein the switch element is one of a switchable diode and a nano-electromechanical switch (NEMS). 4. The S-AMC element of claim 1 wherein the S-AMC element is formed from a multilayer structure that includes the conductive layer as an intermediate layer sandwiched between first and second dielectric substrate layers, the conductive patch being located on the first dielectric substrate layer and the switch element and open stub being located on the second dielectric substrate layer, the S-AMC element including a conductive element that extends from the conductive patch through the first dielectric layer, the conductive layer and the second dielectric layer to the switch element. 5. A plurality of the S-AMC elements of claim 1 incorporated into a plate of a parallel plate waveguide, the plurality of S-AMC elements being configured to present, when in a first state, a magnetically conductive surface for RF signals within a target frequency band that includes the defined frequency band, and, when in a second state, an electrically conductive surface for the RF signals within the target frequency band, thereby controlling a propagation direction of the RF signals within the parallel plate waveguide. 6. The plurality of S-AMC elements of claim 5 , wherein the parallel plate waveguide is a radial waveguide having an RF feed at a center thereof, and the plurality of S-AMC elements are arranged in a circular array. 7. The plurality of S-AMC elements of claim 5 wherein the defined frequency band is different for at least some of the S-AMC elements, the target frequency band for the plurality of S-AMC elements being larger than the defined frequency bands of individual S-AMC elements. 8. A waveguide comprising: opposed first and second plates defining a radio frequency (RF) signal waveguide region between them, the first plate including an array of switchable artificial magnetic conductor (S-AMC) elements, that can each be switched between a first state in which a waveguide surface of the S-AMC element is electrically conductive within a defined frequency band and a second state in which the waveguide surface is magnetically conductive within the defined frequency band; a radio frequency (RF) probe disposed in the waveguide region for at least one of generating or receiving RF signals; and a control circuit coupled to the S-AMC elements to selectively control the state thereof to control a propagation direction of RF signals within the waveguide region relative to the RF probe. 9. The waveguide of claim 8 wherein the waveguide is a radial waveguide, and the array of S-AMC elements is a circular array surrounding the RF probe. 10. The waveguide of claim 9 wherein the S-AMC elements are arranged in a plurality of rings surrounding the RF probe. 11. The waveguide of claim 9 wherein the S-AMC elements are arranged in a plurality of independently controllable arc section groups of the S-AMC elements surrounding the RF probe. 12. The waveguide of claim 11 wherein at least some of the S-AMC elements within each arc section group have a different defined frequency band than other S-AMC elements within the arc section group. 13. The waveguide of claim 8 wherein each S-AMC element comprises: a conductive layer; a conductive patch that defines the waveguide surface and is located on one side of the conductive layer and electrically isolated from the conductive layer; an open stub located on an opposite side of the conductive layer and electrically isolated from the conductive layer; and a switch element configured to selectively, based on control signals from the control circuit, open an electrical connection between the conductive patch and the open stub to place the S-AMC element in the first state, and close the electrical connection to place the S-AMC element in the second state. 14. The waveguide of claim 13 wherein, for each of the S-AMC elements, the open stub and the conductive patch are configured to function as an LC circuit having a resonant frequency that falls within the defined frequency band when the electrical connection is closed. 15. The waveguide of claim 14 wherein the switch element is one of a switchable diode and a nano-electromechanical switch (NEMS). 16. The waveguide of claim 13 wherein the first plate is a multilayer structure, wherein the conductive layer of the S-AMC elements is an intermediate layer of the first plate sandwiched between first and second dielectric substrate layers, and for each of the S-AMC elements: the conductive patch is located on the first dielectric substrate layer and the switch element and open stub is located on the second dielectric substrate layer, and a conductive element extends from the conductive patch through the first dielectric layer, the conductive layer and the second dielectric layer to the switch element. 17. A method of beam steering radio frequency (RF) signals using a waveguide structure that includes: a waveguide region between opposed first and second surfaces; a RF probe disposed in the waveguide region; an array of switchable artificial magnetic conductor (S-AMC) elements defining the first surface, wherein each of the S-AMC elements can be switched between a first state in which the S-AMC element presents an electrically conductive surface to RF signals in the waveguide region within a defined frequency band and a second state in which the S-AMC elements present a magnetically conductive surface to RF signals in the waveguide region within the defined frequency band; the method comprising, controlling, with a microcontroller, the states of the S-AMC elements to control a propagation direction of the RF signals within the waveguide region. 18. The method of claim 17 wherein the waveguide is a radial waveguide having the RF probe disposed at a center thereof, the array of S-AMC elements being a circular array surrounding the RF probe, wherein controlling the states of the S-AMC elements comprises controlling the states for groups of the S-AMC elements to propagate the RF signals within a selected arc section of the waveguide. 19. The method of claim 18 wherein within a group of the S-AMC elements, at least some the S-AMC elements have different defined frequency bands. 20. The method of claim 18 wherein controlling the states of the S-AMC elements to control the propagation direction of the RF signa