Abstract: Antenna structures and methods of operating the same of a wideband dual-arm antenna of an electronic device are described. One wideband antenna includes a first feeding arm coupled to a radio frequency (RF) feed and a second feeding arm coupled to the RF feed. At least a portion of the second feeding arm is parallel to the first feeding arm. The wideband dual-arm antenna further includes a third arm coupled to the ground plane. The third arm is a parasitic ground element that forms a coupling to the first feeding arm and the second feeding arm. The parasitic element increases a bandwidth of the wideband antenna.

Abstract: This disclosure describes a power unmanned aerial vehicle (UAV) that may generate a current from a magnetic field of an overhead power line. In various implementations, while the power UAV is flying, the power UAV may receive another UAV at a platform. A control element of the power UAV may generate signals to cause the power UAV to fly to a location of a conductor of the power line. The control element may also determine a position of the secondary coil with respect to the power line and generate control signals to adjust the position of the secondary coil based on the determined position of the secondary coil, a determined safety distance, and/or a determined threshold distance for efficient current generation. A shielding substrate may also be provided to shield electronics of the power UAV or other UAVs from magnetic fields.

Abstract: Antenna structures and methods of operating the same are described. One apparatus includes a metal cover having a first corner portion, a second corner portion, and an elongated portion. The elongated portion is physically separated from the first corner portion by a first cutout in the metal cover and the elongated portion is physically separated from the second corner portion by a second cutout in the metal cover. A radio frequency (RF) circuit is coupled to a feeding element that is coupled to the elongated portion. A capacitor is coupled between the feeding element and the first corner portion near the distal end of the feeding element. The RF circuit is operable to cause the feeding element, the elongated portion, and the first corner portion to radiate electromagnetic energy as a first radiator in a first frequency range with dual resonance.

Abstract: An electronic device including a Near Field Communication (NFC) antenna and a slot antenna is described. The slot antenna may be formed by a slot opening in a housing of the electronic device. The slot opening may be shaped as a rectangular slot, a T-shaped slot, or T-shaped slot leading into a circular opening. The slot opening exposes the NFC antenna and allows the NFC antenna to radiate in a first frequency band while the slot antenna radiates at a second frequency band.

Abstract: Technologies described herein are directed to switching between antennas in response to a change in an isolation value identified using a neutralization line. A device may include a first set of antennas including a first antenna, a second antenna, a neutralization line coupled between the first antenna and the second antenna, and a controller. The controller is coupled to the neutralization line. The controller determines a first isolation value between the first antenna and the second antenna using the neutralization line, determines a change in isolation value between the first antenna and the second antenna to a second isolation value, determines that the second isolation value exceeds a threshold, and switches from using the first set of antennas to using a second set of antennas.

Abstract: A user device selects a communication module from a plurality of communication modules of the user device to communicate first data to a first device in a first configuration, selects a first antenna from a plurality of antennas of the user device to communicate the first data in the first configuration, and couples the communication module to the first antenna in the first configuration. The user device additionally selects the communication module to communicate second data to a second device in a second configuration, selects the first antenna and a second antenna from the plurality of antennas to communicate the second data in the second configuration, and couples the communication module to the first antenna and the second antenna in the second configuration.

Abstract: Antenna structures and methods of operating an antenna of an electronic device are described. A system may include an antenna comprising a plurality of physically connected elements. The elements may include a respective electrical switch and may have a respective first electrical path length when the electrical switch is in a non-conductive state and a respective second electrical path length when the electrical switch is in a conductive state. The system may further include an antenna controller to receive information indicative of an operating frequency and to configure the antenna to have a total electrical path length corresponding to the operating frequency by operating the switches.

Abstract: A method and system configures an antenna system to enhance communication signal quality within a wireless communication device. An antenna system controller determines a usage state of the wireless communication device based on received sensor data. In addition, the antenna system controller determines whether the usage state matches a pre-identified reference usage state. If the usage state matches a reference usage state, the antenna system controller configures the antenna system using configuration data mapped to the reference usage state. In addition, the antenna system controller tracks occurrences of usage states to generate usage state statistics and uses the generated usage state statistics to predict a timing of future usage states within the wireless communication device. The antenna system controller configures the wireless communication device for the predicted usage state when an associated trigger event is detected.

Abstract: A capacitive micro-electromechanical switch (MEMS) integrated circuit (IC) comprises a plurality of capacitors, each having a voltage terminal for applying an actuation voltage to the individual capacitor, wherein each capacitor is capable of being individually cycled. The MEMS IC further includes: a high voltage driver having a voltage distribution mechanism that couples to the voltage terminal of each of the plurality of capacitors to enable the high voltage driver to selectively provide a pre-determined voltage input required to actuate and charge a selected one or more of the plurality of capacitors; and control logic communicatively coupled to the high voltage driver and which deterministically applies power cycle times (less than a stiction limit) for an actuation and de-actuation of at least a first capacitor of the plurality of capacitors to substantially reduce an occurrence of stiction within at least the first capacitor during operation of the MEMS device.

Abstract: An antenna system for reception and transmission of radio frequency (RF) signals and a method for tuning the antenna system are provided. The antenna system includes a ground plane, a first element and a second element. The first element includes a driven unbalanced antenna element that resonates within at least one predetermined first frequency band to transmit and receive radio frequency (RF) signals modulated at one or more frequencies within the at least one predetermined first frequency band. The second element is non-resonating within the at least one predetermined first frequency band and is located within an antenna volume of the first element to create a partial loop response within the antenna volume of the first element by capacitively coupling to the first element when connected to the ground plane.

Abstract: A method and system configures an antenna system to enhance communication signal quality within a wireless communication device. An antenna system controller determines a usage state of the wireless communication device based on received sensor data. In addition, the antenna system controller determines whether the usage state matches a pre-identified reference usage state. If the usage state matches a reference usage state, the antenna system controller configures the antenna system using configuration data mapped to the reference usage state. In addition, the antenna system controller tracks occurrences of usage states to generate usage state statistics and uses the generated usage state statistics to predict a timing of future usage states within the wireless communication device. The antenna system controller configures the wireless communication device for the predicted usage state when an associated trigger event is detected.

Abstract: A capacitive micro-electromechanical switch (MEMS) integrated circuit (IC) comprises a plurality of capacitors, each having a voltage terminal for applying an actuation voltage to the individual capacitor, wherein each capacitor is capable of being individually cycled. The MEMS IC further includes: a high voltage driver having a voltage distribution mechanism that couples to the voltage terminal of each of the plurality of capacitors to enable the high voltage driver to selectively provide a pre-determined voltage input required to actuate and charge a selected one or more of the plurality of capacitors; and control logic communicatively coupled to the high voltage driver and which deterministically applies power cycle times (less than a stiction limit) for an actuation and de-actuation of at least a first capacitor of the plurality of capacitors to substantially reduce an occurrence of stiction within at least the first capacitor during operation of the MEMS device.

Abstract: An antenna system for reception and transmission of radio frequency (RF) signals and a method for tuning the antenna system are provided. The antenna system includes a ground plane, a first element and a second element. The first element includes a driven unbalanced antenna element that resonates within at least one predetermined first frequency band to transmit and receive radio frequency (RF) signals modulated at one or more frequencies within the at least one predetermined first frequency band. The second element is non-resonating within the at least one predetermined first frequency band and is located within an antenna volume of the first element to create a partial loop response within the antenna volume of the first element by capacitively coupling to the first element when connected to the ground plane.

Abstract: A method and device for providing impedance tuning to compensate for capacitive loading effects on an antenna which are associated with conductive or physical components in close proximity to the antenna is provided. A dynamic impedance tuning (DIT) controller periodically receives information that indicates that one or more functions of a physical component and/or a particular device operating state are currently active. In response to one or more functions of the physical component being activated, the DIT controller configures the tunable impedance to a pre-set impedance level to compensate for capacitive loading effects on the antenna. In addition, the controller triggers a switch to connect the tunable impedance to the ground signal line to provide antenna tuning corresponding to the preset impedance level. The tunable impedance adjusts the terminal impedance of the ground signal line to minimize capacitive loading effects associated with the signal line.

Abstract: An antenna system for reception and transmission of radio frequency (RF) signals and a method for tuning the antenna system are provided. The antenna system includes a ground plane, a first element and a second element. The first element includes a driven unbalanced antenna element that resonates within at least one predetermined first frequency band to transmit and receive radio frequency (RF) signals modulated at one or more frequencies within the at least one predetermined first frequency band. The second element is non-resonating within the at least one predetermined first frequency band and is located within an antenna volume of the first element to create a partial loop response within the antenna volume of the first element by capacitively coupling to the first element when connected to the ground plane.

Abstract: A hand-held communication device, such as a cellular telephone or a personal digital assistant (PDA), comprises a sensor assembly and an auxiliary input interface. The auxiliary input interface is situated along one or more exterior surfaces of the device and is electrically coupled to processing circuitry within the device. The sensor assembly is removably attached to the one or more exterior surfaces of device and provides signals at the multiple outputs in response to tactile inputs from the user. In one embodiment, an assignment procedure assigns tactile inputs from the user to predefined functions of the device and/or one or more software applications installed in the device. During subsequent operation of the device, each of the specific tactile input executes one or more predefined functions.

Abstract: Embodiments include systems and methods for controlling radiation of radio frequency (RF) energy by a wireless communication device that includes a transmitter, an antenna, a vector field sensor, and a processing system. The transmitter produces an analog RF signal, and the antenna radiates the analog RF signal into an environment. The vector field sensor senses an intensity of a vector field resulting from the analog RF signal radiated by at least the antenna (and possibly other portions of the device). The processing system determines whether a value representing the intensity is greater than a first threshold, and when the value is greater than the first threshold, the processing system causes the radiated RF energy produced by the wireless communication device to be decreased.

Abstract: A method and device for providing impedance tuning to compensate for capacitive loading effects on an antenna which are associated with conductive or physical components in close proximity to the antenna is provided. A dynamic impedance tuning (DIT) controller periodically receives information that indicates that one or more functions of a physical component and/or a particular device operating state are currently active. In response to one or more functions of the physical component being activated, the DIT controller configures the tunable impedance to a pre-set impedance level to compensate for capacitive loading effects on the antenna. In addition, the controller triggers a switch to connect the tunable impedance to the ground signal line to provide antenna tuning corresponding to the preset impedance level. The tunable impedance adjusts the terminal impedance of the ground signal line to minimize capacitive loading effects associated with the signal line.

Abstract: A method (1400) and an RF circuit (100, 400, 700, 1000, 1100, 1200, 1300) for a wireless communication device that mitigates near field radiation generated by the wireless communication device. At least one counterpoise (104, 404, 1304) can be configured to resonate at or near at least one operating frequency of an antenna (102) of the wireless communication device. The antenna can be a component of the RF circuit. The counterpoise can be electromagnetically coupled to the antenna to mitigate near field radiation of the antenna at the at least one operating frequency of the antenna in order to comply with an applicable hearing aid compatibility (HAC) specification.

Abstract: A hand-held communication device, such as a cellular telephone or a personal digital assistant (PDA), comprises a sensor assembly and an auxiliary input interface. The auxiliary input interface is situated along one or more exterior surfaces of the device and is electrically coupled to processing circuitry within the device. The sensor assembly is removably attached to the one or more exterior surfaces of device and provides signals at the multiple outputs in response to tactile inputs from the user. In one embodiment, an assignment procedure assigns tactile inputs from the user to predefined functions of the device and/or one or more software applications installed in the device. During subsequent operation of the device, each of the specific tactile input executes one or more predefined functions.