Systems and methods are provided for distortion redirection in phased arrays. In an electronic device configured for transmission and reception of signals and having a two-dimensional phased array, effects of distortion, corresponding to at least one processing function applied during communication of signals, on the communication of signals may be assessed, and based on the effects of distortion, one or more adjustments for mitigating the effects of distortion may be configured and applied during processing of signals. Assessing the effects of distortion may include determining one or more characteristics associated with the communication of the signals, where the one or more characteristics relate and/or are subject to the effects of the distortion, and assessing the effects of distortion based on the one or more characteristics.

In a cellular communication system, particularly in a system using GHz frequencies, communication signals may become blocked by physical objects. As a result, communications may be disrupted or prevented. In a cellular system using beamforming and directional signal beams, a beam is tested prior to its use by sending a discovery signal over the beam, and by detecting any reflections of the discovery signal. A reflection may indicate the presence of a blocking object in the direction of the beam. By repeating this process using different directional beams, it is possible to produce a map of an area surrounding the base station, and to subsequently select or configure a directional beam for communicating with an individual user device. The process may also be used when selecting the antenna position and orientation for a new base station, by testing different alternatives and selecting an alternative that has relatively fewer blocking obstructions.

Systems and methods are provided for improving a reflection signal of a radar antenna assembly. For example, disclosed embodiments are directed to a multiple retrodirective surface mount antenna assembly comprising a plurality of retrodirective antenna arrays, each retrodirective antenna array being angularly offset from at least one other retrodirective antenna array and being configured to reflect a radar signal received from a radar signal source to a radar signal receiver.

One or more input signals are used to generate a Pseudo noise generator and re-inject the signal to obtain a more efficient method of control of a receiver using adaptive antenna array technology. The antenna array automatically adjusts its direction to the optimum using information obtained from the input signal by the receiving antenna elements. The input signals may be stored in memory for retrieval, comparison and then used to optimize reception. The difference between the outputs of the memorized signals and the reference signal is used as an error signal. One or multiple Modal antennas, where the Modal antenna is capable of generating several unique radiation patterns, can implement this optimization technique in a MIMO configuration.

The disclosure relates to suppressing surface waves in a communication device for a wireless communication system. The communication device includes a dielectric layer extending along a plane between a chassis and a glass layer, an antenna element configured to emit a radio wave, and a retroreflective structure extending inside the dielectric layer and being located adjacent to the antenna element, and where the retroreflective structure is configured to reflect the radio wave in an angle non-parallel to the plane. The retroreflective structure hence prevents parasitic channeling of the antenna energy into surface waves in and behind the glass layer and directs the radiation into the desired direction.

The proposed retro-directive quasi-optical system includes at least a lens set and a pixel array. The lens set is positioned on one side of the pixel array and the lens set instantly establishes retro-directive space channels between the pixels in the pixel array and the object(s) distributed in the accessible space defined by the lens set through infinite or finite conjugation. In the pixel array, a number of pixels are arranged as an array and each pixel is composed of at least one pair of transmitter antenna and receiver antenna. To guarantee that the electromagnetic waves transmitted from a pixel into the accessible space may be reflected back to the receiver of the same pixel, the size of each pixel is not larger than the point-spread spot size defined by the lens set, wherein the point-spread spot size can be contributed either from lens diffraction or aberration.

One or more input signals are used to generate a Pseudo noise generator and re-inject the signal to obtain a more efficient method of control of a receiver using adaptive antenna array technology. The antenna array automatically adjusts its direction to the optimum using information obtained from the input signal by the receiving antenna elements. The input signals may be stored in memory for retrieval, comparison and then used to optimize reception. The difference between the outputs of the memorized signals and the reference signal is used as an error signal. One or multiple Modal antennas, where the Modal antenna is capable of generating several unique radiation patterns, can implement this optimization technique in a MIMO configuration.

Radar retroreflective (R3) devices including an electromagnetic absorber are provided. The electromagnetic absorber is disposed on selected areas of the device to reduce specular reflection without substantially reducing retroreflection of the device.

A system for communication comprises an antenna system that includes a reflector having a focus and a feed array positioned at or near the focus and having N feed elements, N being an integer greater than 1. The N feed elements receive N feed signals that result from illumination of the N feed elements by a target signal incident on the reflector from a slow-moving signal source. A first N-to-N Fourier Transform device performs a spatial Fourier Transform on the N feed signals to generate N wavefront signals which are orthogonal to one another. Band-pass filters filter the N wavefront signals and output N filtered wavefront signals. Frequency down-converters down-convert the N filtered wavefront signals to an intermediate frequency or baseband frequency and generate N frequency-down-converted wavefront signals. Analog-to-digital converters digitize the N frequency-down-converted wavefront signals and output N digital wavefront signals. A correlation processor computes a phase slope across the N digital wavefront signals. A direction-of-arrival processor determines a direction of arrival of the target signal based on the phase slope.

One or more input signals are used to generate a Pseudo noise generator and re-inject the signal to obtain a more efficient method of control of a receiver using adaptive antenna array technology. The antenna array automatically adjusts its direction to the optimum using information obtained from the input signal by the receiving antenna elements. The input signals may be stored in memory for retrieval, comparison and then used to optimize reception. The difference between the outputs of the memorized signals and the reference signal is used as an error signal. One or multiple Modal antennas, where the Modal antenna is capable of generating several unique radiation patterns, can implement this optimization technique in a MIMO configuration.