Abstract: A wireless electronic device includes first and second conductive layers arranged in a face-to-face relationship. The first and second conductive layers are separated from one another by a first dielectric layer. The wireless electronic device includes a first radiating element and a second radiating element. The first conductive layer includes a slot. The second conductive layer includes a stripline. The second radiating element at least partially overlaps the slot. The wireless electronic device is configured to resonate at a resonant frequency corresponding to the first radiating element and/or the second radiating element when excited by a signal transmitted and/or received though the stripline.

Abstract: The present invention relates to a method for operating a base station (21) in a wireless radio network. The base station (21) comprises a plurality of antennas (22) for transmitting radio frequency signals between the base station (21) and a user equipment (UE1, UE2, UE3). According to the method, at each antenna (22) a training signal sent from the user equipment at a first point in time (t1) is received and for each antenna a corresponding first configuration parameter (P1) is determined based on the training signal received at the corresponding antenna at the first point in time (t1). Furthermore, at each antenna (22) a training signal sent from the user equipment at a second point in time (t2), which is different from the first point in time (t1), is received and for each antenna (22) a corresponding secand configuration parameter (P2) is determined based on the training signal received at the second point in time (t2).

Abstract: Embodiments of the invention are directed to systems, methods and computer program products for minimizing data overhead in a cellular network. In some embodiments a method includes receiving, by a base station of the cellular network, location information associated with a mobile device. The method may include determining, by the base station, a location of the mobile device based on the location information; and determining, by the base station, an offload alternative connection point based on the determined location of the mobile device. In some cases, the method includes disconnecting the mobile device from a current connection point; and connecting the mobile device to the offload alternative connection point.

Abstract: Wearable wireless electronic devices are provided. A wearable wireless electronic device may be a wearable first wireless electronic device that may include a user-wearable transmitter. The user-wearable transmitter may include first and second electrodes that are spaced apart from each other. The first and second electrodes may include first and second curved portions, respectively, when the user-wearable transmitter is worn by a user. Moreover, the first and second electrodes may be configured to transmit communications through a human body of the user to a second wireless electronic device on or adjacent the human body of the user.

Abstract: A system including a wireless communication device and a peripheral device communicate with each other using radio frequency (RF) waves that are propagated using a user's own body as a transmission medium. The wireless communication device selectively controls the transmit output power of the peripheral device to cause the peripheral device to transmit data and information in a low-power transmission mode. This minimizes the amount of RF waves that are received at the wireless communication device as reflected RF waves, but helps to ensure that the RF waves that do reach the wireless communication device are transmitted as surface waves along the user's skin. Responsive to the receipt of the surface waves, and based on a validity of the information carried by those surface waves, the wireless communication device transitions from a locked state to an unlocked state.

Abstract: A mobile communications terminal with plural antennas for uplink communications with a network base station in a cell, uses an adaptive antenna selection algorithm to select antennas. A method of operating a mobile communications terminal. The cell operator or base station provides parameters and/or settings to the terminal to determine algorithm behavior in selecting antennas, for example, according to operative characteristics of signals in uplink communications in the network, operation of the terminal, and/or network conditions. A communications method includes sending from a base station one or more parameters and/or settings for a terminal to select which of plural antennas of the terminal to use transmitting signals to the base station. A base station transmits to terminals one or more such parameters and/or settings for use in the adaptive antenna selection algorithm to select antennas for transmitting signals to the base station.

Abstract: A wireless electronic device includes an inverted-F antenna (IFA) having an IFA exciting element, an IFA feed, and a grounding pin. The IFA exciting element is configured to resonate at two different resonant frequencies, when excited by a signal received through the IFA feed. The wireless electronic device includes a highband wave trap having a length defined based on a first resonant frequency of the IFA exciting element. The highband wave trap is electrically coupled to the IFA exciting element through the grounding pin. A ground patch is electrically coupled between the highband wave trap and the ground plane. The wireless electronic device includes a lowband wave trap having a length defined based on a second resonant frequency of the IFA exciting element. The lowband wave trap is electrically coupled to the ground plane through the ground patch.

Abstract: An antenna includes a first radiating element, a second radiating element, a common ground plane between the first radiating element and the second radiating element, and a wavetrap structure coupled to the ground plane and configured to reduce correlation between the first and second radiating elements at first and second RF frequencies.

Abstract: The present invention relates to a charging station for inductive charging of an electrical device having a rechargeable battery and a receiving induction coil. The charging station comprises: a housing comprising a plurality of panels forming an interior volume arranged to host the electrical device; a plurality of primary transmitting induction coils; and a controller arranged to excite the plurality of primary transmitting induction coils with charging current; wherein each of the plurality of primary transmitting induction coils is arranged at a separate panel of the housing.

Abstract: A wireless electronic device includes a printed circuit board (PCB) with first, second, and third conductive layers separated from one another by dielectric layers. A stripline is included in the first conductive layer. Two highband dipole antenna strips are included in the second conductive layer and/or two lowband dipole antenna strips are included in the third conductive layer. The wireless electronic device may be configured to resonate at a lowband resonant frequency corresponding to the two lowband dipole antenna strips and resonate at a highband resonant frequency corresponding to the two highband dipole antenna strips when excited by a signal transmitted and/or received though the stripline.

Abstract: An antenna switching method includes tuning respective signals provided to first and second antennas in a portable electronic device to at least one frequency band. The method may also include connecting the first antenna to an uplink signal path that is for transmissions through the first and second antennas, and performing impedance matching for the first antenna. The method may further include comparing a real-time performance characteristic of the first antenna with a real-time performance characteristic of the second antenna. The method may additionally include, responsive to determining that the second antenna has a stronger real-time performance characteristic than the first antenna while the first antenna is connected to the uplink signal path, switching from the first antenna to the second antenna by connecting the second antenna to the uplink signal path and disconnecting the first antenna from the uplink signal path, and performing impedance matching for the second antenna.

Abstract: A wireless electronic device includes a ground plane including a plurality of slots located along an edge of the ground plane. A dielectric layer is on the ground plane. A stripline on the dielectric layer is opposite the ground plane, positioned to overlap one of the plurality of slots. The stripline is further positioned to not overlap slots adjacent the one of the plurality of slots that the stripline overlaps. The wireless electronic device is configured to resonate at a resonant frequency when excited by a signal transmitted and/or received though the stripline.

Abstract: Network nodes including a non-uniform plurality of array antenna elements coupled to transceiver circuitry configured to provide communications in a cellular or short-range wireless network are provided. Sizes of the non-uniform plurality of array antenna elements, distances between adjacent ones of the non-uniform plurality of array antenna elements, tilt of the non-uniform plurality of array antenna elements, and/or antenna types of the non-uniform plurality of array antenna elements differ among the non-uniform plurality of array antenna elements.

Abstract: A wireless electronic device includes an inverted-F antenna (IFA) having an IFA exciting element, an IFA feed, and a grounding pin. The IFA exciting element is configured to resonate at a resonant frequency when excited by a signal received through the IFA feed. The wireless electronic device includes a choke notch having a length defined based on the resonant frequency of the IFA exciting element. The choke notch is electrically coupled to the IFA exciting element through the grounding pin. A ground patch is electrically coupled between the choke notch and the ground plane.

Abstract: Transparent antennas are described. An antenna apparatus for a radio transceiver of a wireless communication terminal having a housing includes a transparent antenna coupled to the housing around a perimeter of the housing and electrically connected to the transceiver. The transparent antenna has a conductive mesh acting as one or more radiating elements. Light and images may pass through the transparent antenna. The transparent antenna may have a ring shape around the housing of the terminal.

Abstract: An antenna swapping method may include tuning respective signals provided to first and second antennas in a portable electronic device to at least one frequency band. The method may also include connecting the first antenna to an uplink signal path that is for transmissions through the first and second antennas, and performing impedance matching for the first antenna. The method may further include comparing a real-time performance characteristic of the first antenna with a real-time performance characteristic of the second antenna. The method may additionally include, responsive to determining that the second antenna has a stronger real-time performance characteristic than the first antenna while the first antenna is connected to the uplink signal path, swapping from the first antenna to the second antenna by connecting the second antenna to the uplink signal path and disconnecting the first antenna from the uplink signal path, and performing impedance matching for the second antenna.

Abstract: In data transmission between a mobile terminal and a cellular network, a network component, e.g., a base station, establishes a downlink connection from the cellular network to the mobile terminal. The downlink connection uses one or more downlink carriers. Further, the network component identifies multiple uplink carriers which are available for establishing an uplink connection from the mobile terminal to the cellular network. The network component estimates impact of usage of the uplink carriers on power consumption of the mobile terminal. Depending on the estimated impact, the network component selects at least one of the uplink carriers for establishing the uplink connection.

Abstract: Wireless electronic devices may include a ground plane, a double ring antenna and non-cellular antennas integrated within the double ring antenna. The double ring antenna may comprise first and second metal rings around the perimeter of a ground plane to operate as MIMO cellular antennas. At least one non-cellular antenna, such as a MIMO Wi-Fi antenna, may be integrated between the first and second metals rings on one or more sides of the wireless electronic device.

Abstract: A mobile communications terminal with plural antennas for uplink communications with a network base station in a cell, uses an adaptive antenna selection algorithm to select antennas. A method of operating a mobile communications terminal. The cell operator or base station provides parameters and/or settings to the terminal to determine algorithm behavior in selecting antennas, for example, according to operative characteristics of signals in uplink communications in the network, operation of the terminal, and/or network conditions. A communications method includes sending from a base station one or more parameters and/or settings for a terminal to select which of plural antennas of the terminal to use transmitting signals to the base station. A base station transmits to terminals one or more such parameters and/or settings for use in the adaptive antenna selection algorithm to select antennas for transmitting signals to the base station.

Abstract: The invention is directed to systems, methods and computer program products for managing device-to-device (D2D) traffic associated with a terminal. An exemplary method comprises: first determining whether the terminal is handling D2D traffic; second determining whether a human body is located either less than or equal to a predetermined distance from the terminal; third determining whether the terminal is receiving power from an external power source; and fourth determining whether to continue handling D2D traffic based on at least one of the second and third determining steps.