Abstract: Described embodiments provide techniques for controlling a phased array system by a control system including one or more distributed control stations. At least one of the control stations displays a control interface having a status window, a beam window, and a scan window. The control system instructs the phased array system to operate in an operating mode selected from among selectable operating modes displayed in the status window. In the beam window, at least one beam is selected from among selectable beams available to track a target. The control system instructs the phased array system to form the selected beam and assigns the formed beam to (i) track a target detected by the phased array system, or (ii) monitor a selected location. The scan window displays (i) targets tracked by the phased array system, and (ii) beams generated by the phased array system.

Abstract: Described embodiments provide a cupped antenna for transmitting and receiving radio signals. The cupped antenna includes a cup having a rear surface and one or more side surfaces. The rear surface and side surfaces define a cavity having a first radiating element of the cupped antenna disposed within it. The first radiating element is coupled to a first feed circuit. The one or more side surfaces have one or more indentations disposed therein. The one or more indentations are configured to reduce a size and weight of the cup. The one or more indentations also provide an opening within an aperture of the cupped antenna such that an additional antenna can be disposed within the opening.

Abstract: Described embodiments provide an antenna for transmitting and receiving radio frequency (RF) signals. The antenna includes an antenna element and an antenna feed network coupled to the antenna element. The antenna feed network is disposed on a first side of the antenna element. A cavity structure is disposed around the antenna feed network. The cavity structure includes conductive walls defining an antenna element cavity. The walls have a height defining a depth of the cavity. An intracavity wall is disposed within the cavity between feed lines of the antenna feed network. The intra-cavity wall is provided having dimensions selected to reduce cross-coupling within the cavity.

Abstract: A system to configure a conductive pathway and a method of forming a system of configurable conductivity pathways include a photosensitive layer that becomes conductive based on photoexcitation, and a light source layer deposited over the photosensitive layer, the light source layer selectively providing the photoexcitation to the photosensitive layer. The system further includes a controller to control the light source layer, the controller illuminating a portion of the light source layer corresponding with a user input image to photoexcite the photosensitive layer and configure the conductive pathway in the photosensitive layer according to the image.

Abstract: Described embodiments provide a cupped antenna for transmitting and receiving radio signals. The cupped antenna includes a cup having a rear surface and one or more side surfaces. The rear surface and side surfaces define a cavity having a first radiating element of the cupped antenna disposed within it. The first radiating element is coupled to a first feed circuit. The one or more side surfaces have one or more indentations disposed therein. The one or more indentations are configured to reduce a size and weight of the cup. The one or more indentations also provide an opening within an aperture of the cupped antenna such that an additional antenna can be disposed within the opening.

Abstract: A system to configure a conductive pathway and a method of forming a system of configurable conductivity pathways include a photosensitive layer that becomes conductive based on photoexcitation, and a light source layer deposited over the photosensitive layer, the light source layer selectively providing the photoexcitation to the photosensitive layer. The system further includes a controller to control the light source layer, the controller illuminating a portion of the light source layer corresponding with a user input image to photoexcite the photosensitive layer and configure the conductive pathway in the photosensitive layer according to the image.

Abstract: Described embodiments provide techniques for controlling a phased array system by a control system including one or more distributed control stations. At least one of the control stations displays a control interface having a status window, a beam window, and a scan window. The control system instructs the phased array system to operate in an operating mode selected from among selectable operating modes displayed in the status window. In the beam window, at least one beam is selected from among selectable beams available to track a target. The control system instructs the phased array system to form the selected beam and assigns the formed beam to (i) track a target detected by the phased array system, or (ii) monitor a selected location. The scan window displays (i) targets tracked by the phased array system, and (ii) beams generated by the phased array system.

Abstract: A system to configure a conductive pathway and a method of forming a system of configurable conductivity pathways are described. The system includes a photosensitive layer that becomes conductive based on photoexcitation, and a light source layer deposited over the photosensitive layer, the light source layer selectively providing the photoexcitation to the photosensitive layer. The system further includes a controller to control the light source layer, the controller illuminating a portion of the light source layer corresponding with a user input image to photoexcite the photosentive layer and configure the conductive pathway in the photosensitive layer according to the image.

Abstract: Described embodiments provide an antenna for transmitting and receiving radio frequency (RF) signals. The antenna includes an antenna element and an antenna feed network coupled to the antenna element. The antenna feed network is disposed on a first side of the antenna element. A cavity structure is disposed around the antenna feed network. The cavity structure includes conductive walls defining an antenna element cavity. The walls have a height defining a depth of the cavity. An intracavity wall is disposed within the cavity between feed lines of the antenna feed network. The intra-cavity wall is provided having dimensions selected to reduce cross-coupling within the cavity.

Abstract: A system to dynamically configure a conductive pathway and a method of forming a dynamically configurable conductive pathway are described. The system includes a substrate to mechanically support a circuit, and a photosensitive layer disposed on at least a portion of at least one side of the substrate. The system also includes a light source to controllably define the conductive pathway in the photosensitive layer based on photoexcitation of an area of the photosensitive layer corresponding with the conductive pathway, a change in the area photoexcited by the light source facilitating a change in the conductive pathway.

Abstract: A system to configure a planar microwave circuit, a method of forming a configurable planar microwave circuit, and a microwave circuit are described. The system includes a ground plane and a substrate disposed on the ground plane. The system also includes a photosensitive layer disposed on the substrate. A light source controllably changes a pattern of illumination on the photosensitive layer to controllably configure a transmission line in the photosensitive layer.

Abstract: A method of dynamically routing a transmission line in a photosensitive layer including optically switching elements and a system to dynamically route a transmission line are described. The method includes determining dimensions of the transmission line based on a radio frequency signal for transmission through the transmission line. The method also includes controlling a light source to illuminate a portion of the optical switching elements of the photosensitive layer according to the dimensions to route the transmission line.

Abstract: A system to dynamically configure a conductive pathway and a method of forming a dynamically configurable conductive pathway are described. The system includes a substrate to mechanically support a circuit, and a photosensitive layer disposed on at least a portion of at least one side of the substrate. The system also includes a light source to controllably define the conductive pathway in the photosensitive layer based on photoexcitation of an area of the photosensitive layer corresponding with the conductive pathway, a change in the area photoexcited by the light source facilitating a change in the conductive pathway.

Abstract: A method of dynamically routing a transmission line in a photosensitive layer including optically switching elements and a system to dynamically route a transmission line are described. The method includes determining dimensions of the transmission line based on a radio frequency signal for transmission through the transmission line. The method also includes controlling a light source to illuminate a portion of the optical switching elements of the photosensitive layer according to the dimensions to route the transmission line.

Abstract: A system to configure a conductive pathway and a method of forming a system of configurable conductivity pathways are described. The system includes a photosensitive layer that becomes conductive based on photoexcitation, and a light source layer deposited over the photosensitive layer, the light source layer selectively providing the photoexcitation to the photosensitive layer.

Abstract: A system to configure a planar microwave circuit, a method of forming a configurable planar microwave circuit, and a microwave circuit are described. The system includes a ground plane and a substrate disposed on the ground plane. The system also includes a photosensitive layer disposed on the substrate. A light source controllably changes a pattern of illumination on the photosensitive layer to controllably configure a transmission line in the photosensitive layer.