An antenna apparatus for use in a wireless network and method of operating such an antenna apparatus are provided. A wireless network controller provides a configuration of such an antenna apparatus, a method of operating such a wireless network controller, and a resulting wireless network. The antenna apparatus comprises a directional antenna and a uniform circular antenna array. The directional antenna can be rotatably positioned about an axis with respect to a fixed mounting portion of the apparatus in dependence on wireless signals received by the antenna array. The antenna array allows the antenna apparatus to receive wireless signals isotropically and thus to accurately monitor the wireless signal environment in which it finds itself. The antenna apparatus can thus monitor and characterise incoming signals, both from external interference sources and from other network nodes, and the directional antenna can then be positioned in rotation to improve the network throughput.

An electronic device is provided. The electronic device includes a wireless communication circuit including a plurality of radio frequency (RF) modules, a memory configured to store a plurality of reference values for classifying a plurality of areas within a cell to which the electronic device belongs, and a processor, and the processor may be configured to determine, based on at least one of a first broadcasting signal received from a base station in the cell and the plurality of reference values stored in the memory, at least one RF module among the plurality of RF modules to monitor a second broadcasting signal transmitted from the base station and a period of the monitoring, and perform the monitoring by using the determined at least one RF module according to the determined period.

A method includes receiving a first antenna stream from a first feeder link to a first non-terrestrial network payload, wherein the first antenna stream includes signals transmitted by terminal devices that are synchronized in time, receiving a second antenna stream from a second feeder link to a second non-terrestrial network payload, wherein the second antenna stream includes signals transmitted by the terminal devices that are not synchronized in time, storing the first and second antenna streams in buffers, obtaining a first timing advance, obtaining a second timing advance, obtaining an estimation of timing offset based on the timing advances, obtaining the second antenna stream from the second buffer and performing timing offset compensation to the second antenna stream based on the estimation of the timing offset, and obtaining the first antenna stream from the first buffer such that it is synchronized with the second antenna stream.

A system having a platform upon which several phased antenna arrays are mounted and which can communicate with satellites. The system includes a switch that can connect any of the phased array antennas to any of available modems. The system further includes a router that can connect any of the modems to any available computing devices. Based on parameters such as data rates, signal strength, and account information, one or more communication paths are selected for a computing device requesting to communicate with a satellite. Each communication path is established by operating the switch to connect a selected antenna to a selected modem, and operating the router to transfer data between the computing device and the selected modem.

The present invention relates to an electronic device and, more particularly, to an electronic device and a method for transmitting and receiving signals. To this end, the electronic device according to the present invention may comprise: a transceiving unit comprising a first group of power amplifiers (PAs) including at least one PA and a second group of PAs including at least one PA; an antenna unit comprising a first antenna selectively coupled to a PA supporting a first frequency range or a second frequency range of the first group of PAs and the second group of the PAs, and a second antenna selectively coupled to a PA supporting the second frequency range or a third frequency range of the first group of PAs and the second group of the PAs; a power supply unit comprising a first power supply modulator connected to the first group of PAs and a second power supply modulator connected to the second group of PAs; and a communication processor for changing an output voltage at least in part on the basis of transmit power of the PA coupled to at least one of the first power supply modulator and the second power supply modulator, wherein at least one of the first group of PAs and at least one of the second group of PAs are capable of transmitting signals simultaneously.

An electronic device is provided. The electronic device includes a plurality of antennas, a radio frequency (RF) circuit configured to electrically connect with the plurality of antennas, and a processor. The plurality of antennas include a first main antenna, a first sub-antenna, a second main antenna, and a second sub-antenna. The processor controls the RF circuit to operate in a first mode of receiving a signal using the first main antenna and the first sub-antenna. The processor controls the RF circuit to operate in a second mode different from the first mode to receive the signal based on a signal state.

The disclosure relates to a pre-5.sup.th-Generation (5G) or 5G communication system to be provided for supporting higher data rates Beyond 4.sup.th-Generation (4G) communication system such as Long Term Evolution (LTE). An operation method of a communication node in a wireless communication system is provided. The operation method includes generating a default beam pattern, based on a plurality of radio-frequency (RF) paths, by applying beamforming parameters, detecting a path failure associated with at least one RF path among the plurality of RF paths, identifying beamforming parameters based on the default beam pattern in response to the detection, and generating a recovered beam pattern associated with the default beam pattern based on the identified beamforming parameters, wherein the beamforming parameters for generating the recovered beam pattern are determined based on a shape of the default beam pattern.

The invention relates to safety or control systems for a plurality of sensors. In particular, the invention relates to networks for transmitting measured parameters, control or similar signals by modeling signals at carrier frequencies using a wireless electric communication, preferably, using a radio communication.

A method for a radio communication among a plurality of transceivers of a safety or control system comprises broadcasting a radio signal, which comprises at least a preamble and a packet body, and searching for the preamble through a plurality of antennas k1 of one transceiver with an alternate periodical linking of each antenna to search for the preamble followed by evaluating a quality of the radio signal as compared to a given level of the radio signal upon receipt of the preamble and selecting an antenna having a maximum level of the radio signal, through which a synchronization of the transceivers is started to receive the packet body. Therewith, during the broadcasting of the radio signal, a radio frequency is periodically switched among a set of given radio frequencies k2, while during the alternate periodical linking of each antenna to search for the preamble, the radio frequency is periodically switched among the radio frequencies from the set of given radio frequencies k2 for the linked antenna, wherein a minimum duration of the preamble for the broadcasting of the radio signal is determined by a ratio T1=(k1+k2) T, where T1 is a duration of the preamble broadcasting in msec, T is a duration of linking of one antenna of the transceiver at a single radio frequency in msec, wherein upon receipt of the preamble during selecting of the antenna having the maximum level of the radio signal, a frequency, at which the preamble has been received, is assigned as a reference (carrier) frequency followed by synchronization of the transceivers through the selected antenna and the reference frequency. Also, a safety or control system, wherein the described method is implemented, is claimed.

Systems for determining a variability in a state of a medium include one or more transmit elements or antennas and one or more receive elements or antennas which are relatively decoupled from one another. The transmit and receive elements or antennas can be less than 95% coupled to one another. The system also includes a transmit circuit configured to generate a transmit signal to be transmitted, which is in a radio or microwave frequency range of the electromagnetic spectrum. The system also includes a receive circuit configured to receive a response detected by the at least one receive antenna resulting from transmission of the transmit signal into the medium. The system includes a processor configured to determine the variability in the state of the medium based on processing of the response over time. The variability can further be used to direct notifications or automated actions.

Examples disclosed herein relate to a radar system for object identification. The radar system transmitting an azimuth fan beam and incrementing elevation of the beam. The radar system may include a transmit antenna and a receive antenna, each having a plurality of antenna elements arranged in rows and columns. The radar system may include a transceiver coupled to the transmit antenna and the receive antenna, the transceiver configured to control transmit beams having an azimuth fan beam, or an elevation fan beam. The radar system may include a processing unit. In various embodiments, the processing unit may include a digital processing unit; a range Doppler mapping module; and an azimuth detection module coupled to the transceiver. The azimuth detection module may be configured to process received signals and identify an azimuth angle of arrival by correlating signals received at antenna elements in rows of the receive antenna.