Techniques of designing an antenna array or antenna system are described. The antenna system includes a plurality of antenna units structured in a way to form a desired antenna pattern. According to one aspect of the present invention, each of the antenna units includes two antennas disposed orthogonally or in parallel. These antenna units are arranged in a pre-defined geometric pattern to create two substantially similar main beam radiation characteristics for independent polarizations.

An antenna system is provided. The antenna system comprises at least two antenna elements. In this context, the at least two antenna elements are arranged around an inner diameter. In addition to this, each of the at least two antenna elements is configured to be controlled separately from each other. Exemplarily, each of the at least two antenna elements is connected to a corresponding amplifier.

An information handling system (IHS) may include a configuration sensor for sensing a physical configuration of the IHS, a first proximity sensor probe for sensing whether a first biological entity element is proximate to a first antenna, a second proximity sensor probe for sensing whether a second biological entity element is proximate to a second antenna, and a third proximity sensor probe for sensing whether a third biological entity element is proximate to a third antenna. The IHS is adapted to reconfigure use of at least two of the first antenna, the second antenna, and the third antenna in response to the sensing of at least one of the first proximity sensor probe, the second proximity sensor probe, and the third proximity sensor.

Methods and devices for performing dynamic compensation of a phased array RFID reader are disclosed herein. An example method includes configuring an RFID reader having an antenna array to compensate for determined antenna element phase-shift errors. The method includes exciting a reference antenna element of the antenna array, emitting an emitted signal, receiving the emitted signal via a receiver antenna element of the antenna array, and generating a received signal. The method further includes determining, by a processor, a phase shift of the received signal relative to the emitted signal, and determining a phase-shift error. The method then includes configuring the RFID reader to compensate for the determined phase-shift error associated with the receiver antenna element in response to receiving an RFID tag signal.

Provided is a rapid over-the-air (OTA) production line test platform, including a device under test (DUT), an antenna array and two reflecting plates. The DUT has a beamforming function. The antenna array is arranged opposite to the DUT, and emits beams with beamforming. Two reflecting plates are disposed opposite to each other, and are arranged between the DUT and the antenna array. The beam OTA test of the DUT is carried out by propagation of the beams between the antenna array, the DUT and the two reflecting plates. Accordingly, the test time can be greatly shortened and the cost of test can be effectively reduced. In addition to the above-mentioned rapid OTA production line test platform, platforms for performing the OTA production line test by using horn antenna arrays together with bending waveguides and using a 3D elliptic curve are also provided.

An antenna device includes a first antenna group comprising multiple antennas, configured to receive and transmitting signals; a second antenna group comprising multiple antennas, configured to receive and transmitting signals; a processor coupled to the first antenna group by a first electronic switch, coupled to the second antenna group by a second electronic switch, configured to divide radiation pattern of antenna combination of the first antenna group and the second antenna group into a predetermined number of characteristic patterns, and further configured to calculate similarities of the characteristic patterns and the RSSI of each characteristic pattern; wherein when the antenna device is in operation, the processor reads and analyzes RSSI of the signals, and compares with the RSSI of the characteristic patterns, and then determines the matched characteristic pattern group according to results of the comparisons and the similarities of the characteristic patterns.

A high-data-rate antenna assembly includes at least one radiating module and a radio frequency module. The at least one radiating module connected to an electronic device is configured to receive or transmit wireless signals. The radio frequency module is electrically connected to the at least one radiating module and processes the wireless signals. The electronic device transmits or exchanges the processed wireless signals with an external device through the at least one radiating module.

A high-power electromagnetic source for HPEM pulses in a desired radiation direction includes at least three antennas fixed in relation to one another for pulse components, wherein at least two groups of antennas with a respective main direction are present, and a control unit for the activation and phase position of the pulse components for the superimposition for the HPEM pulse, wherein the current radiation direction of said pulse is selectable in an angle range around the main direction. A vehicle with an HPEM source has the antennas mounted in a fixed position or a support for the antennas is pivotably mounted on the vehicle. In a method for emitting the HPEM pulse, all antennas are controlled in order to select the radiation direction in the angle range of less than 360°.

[Problems to be Solved] To provide a radar device that is able to instantly detect a location of an observed object by using an antenna capable of receiving a reflected wave from all directions.

[Solution] A radar device 101 of the present invention includes one or more omni-directional antennae 104 and a controller 102, wherein the controller 102 is able to perform a process of at least the one or more omni-directional antennae 104 transmitting a transmitting wave T; a process of at least the one or more omni-directional antennae 104 receiving a reflected wave R, at least the one or more omni-directional antennae 104 being the same as and/or different from the omni-directional antenna 104 that transmits the transmitting wave T and the reflected wave R being generated by the transmitting wave T illuminating an observed object; and a process of instantly estimating a location of the observed object by using time from transmission of the transmitting wave T to reception of the reflected wave R and/or by using a frequency of the transmitting wave and a frequency of the reflected wave.

A method for a wireless communication device including configuring an antenna including antenna circuitry to receive or transmit wireless signals; feeding a radio frequency signal into the antenna circuitry; providing a housing comprising a plurality of edges, wherein the edges comprise a top edge, a bottom edge, and two side edges, wherein a first edge of the housing comprises a conductive strip, a first slot, and a second slot, and wherein the first edge is the top or bottom edge; providing an input/output port adjacent to the first edge of the housing; and locating the conductive strip, which comprises a portion of the antenna, entirely between the first slot and the second slot, wherein a length of each of the first slot and the second slot extends across the first edge of the housing and is oriented perpendicular to a major axis of the conductive strip.