A radiating system comprises a radiating structure, first and second external ports, and a radiofrequency system. The radiating structure comprises a ground plane layer including a connection point, a single radiation booster including a connection point, and a first internal port defined between the connection points of the single radiation booster and the ground plane layer. The first and second external ports each provide operation in at least one frequency band. The radiofrequency system includes a first port connected to the first internal port of the radiating structure, and second and third ports respectively connected to the first and second external ports.

A communication system is provided, including one or more antennas coupled to multiple RF paths, one or more matching blocks, each block including multiple matching networks, a look-up table including characterization data according to frequency bands and conditions, and a controller configured to control the multiple matching networks by referring to the look-up table to provide optimum impedance for a frequency band selected and a condition detected during a time interval. The matching block may further include switches and adjustment circuits.

A communication system is provided, including one or more antennas coupled to multiple RF paths, one or more matching blocks, each block including multiple matching networks, a look-up table including characterization data according to frequency bands and conditions, and a controller configured to control the multiple matching networks by referring to the look-up table to provide optimum impedance for a frequency band selected and a condition detected during a time interval. The matching block may further include switches and adjustment circuits.

A change in potential at a ground terminal is suppressed. A radio frequency module includes a mount board, a first circuit element, a second circuit element, a signal terminal (an antenna terminal, a signal input terminal, or a signal output terminal) for a radio frequency signal, and a block terminal. The mount board has a first principal surface and a second principal surface facing each other. The first circuit element is mounted on the first principal surface of the mount board. The second circuit element is mounted on the second principal surface of the mount board. The signal terminal (the antenna terminal, the signal input terminal, or the signal output terminal) is disposed on the second principal surface of the mount board. The block terminal is disposed on the second principal surface of the mount board. The block terminal includes a plurality of ground terminals.

System and methods are described herein for providing wireless power to a target device, such as a laptop computer, a mobile phone, a vehicle, robot, or an unmanned aerial vehicle or system (UAV) or (UAS). A tunable multi-element transmitter may transmit electromagnetic radiation (EMR) to the target device using any of a wide variety of frequency bands. A location determination subsystem and/or range determination subsystem may determine a relative location, orientation, and/or rotation of the target device. For a target device within a distance range for which a smallest achievable waist of the Gaussian beam of the EMR at an operational frequency is smaller than the multi-element EMR receiver of the target device, a non-Gaussian beamform may be determined to increase efficiency, decrease overheating, reduce spillover, increase total power output of rectenna receivers on the target device, or achieve another target power delivery goal.

System and methods are described herein for providing wireless power to a target device, such as a laptop computer, a mobile phone, a vehicle, robot, or an unmanned aerial vehicle or system (UAV) or (UAS). A tunable multi-element transmitter may transmit electromagnetic radiation (EMR) to the target device using any of a wide variety of frequency bands. A location determination subsystem and/or range determination subsystem may determine a relative location, orientation, and/or rotation of the target device. For a target device within a distance range for which a smallest achievable waist of the Gaussian beam of the EMR at an operational frequency is smaller than the multi-element EMR receiver of the target device, a non-Gaussian beamform may be determined to increase efficiency, decrease overheating, reduce spillover, increase total power output of rectenna receivers on the target device, or achieve another target power delivery goal.

Certain embodiments of the disclosure relate to a device and a method for increasing the efficiency of an antenna of an electronic device that includes a rollable display. The electronic device may include: a processor; a first housing, in which the processor is disposed, including a first conductive portion; a second housing configured to slide in a first direction from the first housing and including a second conductive portion; a rollable display, at least a portion of which is exposed in a slide-out manner according to movement of the second housing; and a variable element disposed in the second housing and is electrically connected to the second conductive portion. The processor may adjust an electrical characteristic of the variable element in response to sliding of the second housing. The disclosure may further include various other embodiments.

Disclosed herein is a patch antenna that includes a patch conductor and a feed conductor for feeding power to a feed point positioned within a surface of the patch conductor. The patch conductor has a slit around the feed point, the slit being separated from an outer peripheral end of the patch conductor.

Disclosed herein is a patch antenna that includes a patch conductor and a feed conductor for feeding power to a feed point positioned within a surface of the patch conductor. The patch conductor has a slit around the feed point, the slit being separated from an outer peripheral end of the patch conductor.

An antenna is provided for a wearable personal computing device, such as a smartwatch. The antenna has a first radiating element and a second radiating element capacitively coupled to each other. The first radiating element is configured to be tunable to a first set of tuning states operating around a first set of resonant frequencies, and the second radiating element is configured to be tunable to a second set of tuning states operating around a second set of resonant frequencies. The antenna is configured to be tuned such that a tuning state from the first set of tuning states of the first radiating element can be combined with a tuning state from the second set of tuning states of the second radiating element to form a composite tuning state of the antenna. The wearable personal computing device has a housing made of a high permittivity material.