An antenna-in-package (AiP) module is described. The AiP module includes an antenna sub-module. The antenna sub-module is composed of a first package substrate including an antenna side surface having a first group of antennas placed along a first portion of the antenna side surface and a second group of antennas placed along a second portion of the antenna side surface. The first package substrate is composed of a non-linear portion between the first group of antennas and the second group of antennas. The AiP module includes an active circuit sub-module placed on an active side surface of the first package substrate opposite the first group of antennas or the second group of antennas on the antenna side surface of the first package substrate.

A planar array antenna having a low-profile that provides a two dimensional, steerable, high-gain, low-sidelobe radiated RF beam patterns is presented. The antenna includes a metamaterial array of a plurality of first and second rows of unit cells, to propagate a radiation pattern along a first axis. The first rows operate in left-hand mode and the second rows operate in right-hand mode. Each of the unit cells include a volume of liquid crystal and a virtual ground connection capable of generating a potential difference for tuning the dielectric value of the liquid crystal. The antenna further includes a plurality of RF input ports disposed in a centralized location and a dual-channel center-feed network communicatively coupled to the plurality of paired first and second rows of unit cells and the plurality of RF input ports to form and control the direction of the radiated RF beam pattern.

An antenna assembly includes a first interface for receiving a first RF signal, a second interface for receiving a second RF signal, and an antenna array including a first array and a second array that extend vertically. The first array includes a first radiating element and a second radiating element, and the second array includes a third radiating element and a fourth radiating element. A power coupling circuit is provided, which is configured to feed a first sub-component of the first RF signal and a first sub-component of the second RF signal to the first radiating element and/or the third radiating element in a power-reduced coupling manner. A plurality of radiating elements in the first array are electrically connected to the first interface, and a plurality of radiating elements in the second array are electrically connected to the second interface, respectively.

In an embodiment, an antenna unit for an antenna array allows shifting the phase of a radiated or received signal without the need for a phase shifter, and includes an antenna element, switching devices, and signal couplers. The antenna element includes at least one section and signal ports each electrically isolated from each other and from each of the at least one section. The switching devices are each configured to couple a respective one of the signal ports to one of the at least one section in response to a respective control signal, and the signal couplers are each configured to couple a respective one of the signal ports to a respective location of a respective transmission medium.

A combiner network is provided. A combiner network may include a corporate combiner. The corporate combiner may include a first plurality of radiation elements. The corporate combiner may include a first H-plane combiner connected to the first plurality of radiation elements and connected by a U-bend to a first E-plane combiner. The corporate combiner may include a second H-plane combiner connected to the first E-plane combiner. The corporate combiner may further include a first port. A plurality of corporate combiners may be assembled together as a combiner network.

An apparatus is provided that includes a first multi-port antenna that operates with a first radiation pattern when a first port is used and operates with a second radiation pattern, different to the first radiation pattern, when a second port, different to the first port, is used. The apparatus also includes a second multi-port antenna that operates with a third radiation pattern when a third port is used and operates with a fourth radiation pattern, different to the third radiation pattern, when a fourth port, different to the third port, is used. The apparatus further includes at least one switch for selecting one of multiple paths between a node and each port of a pair of ports.

The present invention provides a series of structures that provide a unique electromagnetic signature that can be used as a standalone device or as part of a larger security system. This structure's design method of manufacturing ensures that is resilient to commonly used techniques for reverse engineering electronic components and counterfeiting and is able to be applied to devices or any product before or after fabrication is completed.

An antenna assembly includes a substrate, an antenna radiator and a circuitous transmission line. In various embodiments, a novel antenna radiator, a circuitous transmission line, and assemblies thereof are disclosed. The embodiments provide an antenna module that is optimized for wide band 5GNR frequencies (ex: 600 MHz to 6000 MHz) using a combined feeder extension of a serpentine RF coaxial cable and planar transmission line.

Provided is an antenna for improving an influence of surface waves and increasing a beamwidth, including: a substrate, a first metal ground, a second metal ground, an emitting end and a receiving module. The first metal ground and the second metal ground are disposed on a first surface of the substrate. The second metal ground is completely separated from the first metal ground by a first gap. The emitting end is disposed on the first metal ground and includes a transmission line and a plurality of radiating elements. The receiving module is disposed on the second metal ground and includes a first receiving end and a second receiving end. The first receiving end includes a transmission line and a plurality of radiating elements. The second receiving end includes a transmission line and a plurality of radiating elements. In such a way, the antenna of the present invention can solve mutual interference of electromagnetic waves between the emitting end and the receiving module, and achieve the purpose of improving an influence of surface waves, thereby improving the accuracy in determining the direction of an object by the antenna of the present invention.

According to various embodiments, systems and methods for suppressing grating lobes in a traveling-wave antenna system are disclosed. An apparatus can include a traveling-wave antenna array comprising a plurality of adjacent traveling-wave antennas. The apparatus also can include a phase diversity feed coupled to the traveling-wave antenna array. The phase diversity feed can be configured to provide phase diverse input to two or more of the plurality of adjacent traveling-wave antennas.