Abstract: A method for forming three-dimensional periodic lattice structures through the use of additive manufacturing to achieve engineered, application specific, effective material properties that differ from that of the bulk host 3d-printable material for radio frequency (RF) applications including radomes and antenna apertures. Such structures remain mechanically robust while offering access to a range of material properties not available otherwise through the engineering of detailed wave-propagation characteristics through such lattice structures.

Abstract: An analog transceiver having low latency for processing a received RF/MW signal and modifying the received RF/MW signal into a modified RF/MW signal prior to transmission of the modified RF/MW signal. The analog transceiver comprises a receiving antenna; a direct conversion receiver, coupled with the receiving antenna, for splitting the received RF/MW signal into an in-phase portion and a quadrature portion; an analog signal processing device, having a plurality of actuatable switches, for modifying the in-phase and quadrature portions and outputting modified signals while only introducing minimal latency during processing; a direct conversion transmitter, for receiving the suitably modified in-phase and quadrature portions and forming the modified RF/MW signal; and a transmitting antenna for receiving the modified RF/MW signal and transmitting the modified RF/MW signal.

Abstract: A system and method for distributing the power of an electromagnetic signal is presented. In one embodiment, a power distribution cavity includes, a planar cavity, input ports and output ports. The planar cavity is formed with a metallic sheet in the shape of a star pattern with a plurality of elongated star arms extending from a round center portion of the metallic sheet. The input ports are attached to the round center portion of the metallic sheet for receiving an input signal. The signals entering the cavity from the input ports creating independent resonant modes within the cavity that combine producing a tapered aperture distribution of signals at the output ports. The output ports are attached near to the outward ends of the elongated star arms. The planar cavity is thus configured to propagate electromagnetic fields at the output ports that were excited within the cavity by the input ports.

Abstract: A system and method for distributing the power of an electromagnetic signal is presented. In one embodiment, a power distribution cavity includes, a planar cavity, input ports and output ports. The planar cavity is formed with a metallic sheet in the shape of a star pattern with a plurality of elongated star arms extending from a round center portion of the metallic sheet. The input ports are attached to the round center portion of the metallic sheet for receiving an input signal. The signals entering the cavity from the input ports creating independent resonant modes within the cavity that combine producing a tapered aperture distribution of signals at the output ports. The output ports are attached near to the outward ends of the elongated star arms. The planar cavity is thus configured to propagate electromagnetic fields at the output ports that were excited within the cavity by the input ports.