The present disclosure provides an antenna and a temperature control system of the antenna. The antenna includes a feed unit layer, a phase shifter layer, an amplifying circuit layer disposed between the feed unit layer and the phase shifter layer, and a temperature control unit layer disposed on a side of the amplifying circuit layer. The amplifying circuit is configured to amplify a microwave signal fed from the feed unit layer and transmit the microwave signal to the phase shifter layer; the phase shifter layer is configured to shift a phase of the microwave signal by a preset phase shift amount; and the temperature control unit layer is configured to adjust a temperature of the amplifying circuit layer to adjust an operating temperature of the antenna.

The present invention provides target devices such as filter units with a plurality of external projection members that project outwardly from the target device and cooperate with apertures in a mounting bracket whereby the target device can be slidably moved from a first position to a second position provided by a lobe of the apertures to couple the target device to a respective support structure using a respective mounting bracket. The mounting bracket can be provided as a plurality of mounting brackets, including a first one attached to the support structure and a first side of a first target device and a second one attached to a second side of the first target device and to a first side of a second target device thereby allowing the first and second target devices to be stacked together to a common support structure.

Technologies directed to binning methods for electronically steered transmit phased arrays with amplitude tapering are described. One communication system includes a first and a second set of power amplifiers. The first set operates with a first peak power level and the second set operates with a second peak power level that is lower than the first peak power level. A digital beamforming (DBF) device sends a first set of signals to the first set of power amplifiers causing the first set of power amplifiers to operate in a first range. The DBF also sends a second set of signals to the second set of power amplifiers causing the second set of power amplifiers to operate in a second range.

The present disclosure relates to a method of making an electronic device comprising a first wafer including at least one trench and a second wafer, the second wafer being bonded, by hybrid bonding, to the first wafer, so as to form, at the level of the trench, at least one enclosed space, empty or gas-filled.

In one example of the present disclosure, a radome assembly for use with an antenna assembly is described. The radome assembly may comprise a radome body portion having a first surface and a second surface, wherein the second surface is opposite the first surface, and wherein the radome body portion defines a portion of a housing for an antenna assembly. The radome assembly may further comprise a radome spacer portion extending from the second surface of the radome body portion, the radome spacer portion defining a plurality of cells that are formed from a plurality of cell walls, wherein at least two cell walls of the plurality of cell walls defining each cell of the plurality of cells are spaced apart from each other.

A method for tuning an antenna may include depositing multiple portions of an antenna structure onto a substrate. The method may further include electrically coupling each of the portions of the antenna structure. The method may also include severing an electrical connection between two of the portions of the antenna structure to tune the antenna structure for use with a transmission device.

A heat sensing system and method for dynamic heat sensing may be implemented in a flight vehicle having a main antenna configured for sending and/or receipt of signals. The system includes an auxiliary antenna system that is arranged within a radome of the flight vehicle for detecting temperatures around the exterior surface of the radome. The auxiliary antenna is configured for receiving and measuring infrared or optical energy. Using the measured energy, the system is configured to determine whether the detected temperature exceeds a predetermined temperature and rotating the vehicle to equalize heat around the vehicle when the current temperature exceeds the predetermined temperature.

An information handling system including a encapsulated antenna may comprise the encapsulated antenna encapsulated in a phase-changing compound to absorb heat, the antenna and the compound enclosed within an outer encapsulated antenna housing a wireless interface device with a 5G radio to generate burst signals to be transmitted via the encapsulated antenna, an information handling system chassis having a skin surface coming into contact with human skin during execution of the information handling system, and a temperature sensor to determine an operable temperature of the antenna reaching a known phase transition point at which the phase-changing compound changes states at least partially from solid to liquid.

Systems and methods for high power microwave combining and switching are provided. In at least one implementation a system includes a plurality of inputs, wherein there are M inputs in the plurality of inputs and a plurality of phase shifters, wherein there are N phase shifters in the plurality of phase shifters and N is a multiple of two times M, wherein a signal received through the plurality of inputs is divided and coupled to N/M phase shifters. The system further includes an N:N Butler matrix coupled between outputs of the N phase shifters in the plurality of phase shifters and a plurality of outputs.

An information handling system (IHS) includes an antenna system. The antenna system includes a smart antenna and a smart antenna control system, the smart antenna control system controlling configuration of a configurable aspect of the smart antenna based upon information regarding the configurable aspect of the smart antenna.