A radio communication device includes a plurality of antenna arrays each configured to generate a steerable antenna beam according to a respective beamforming codeword, wherein each of the plurality of antenna arrays is configured to obtain the respective beamforming codeword from a single-antenna-array steering codebook that is reused by each of the plurality of antenna arrays, and a beamforming circuit configured to weight signals for the plurality of antenna arrays to coordinate the steerable antenna beams from a subset of the plurality of antenna arrays to form a combined antenna beam in a first steering direction.

A user terminal for transmitting data to a plurality of access points comprises a pre-processor to pre-process at least one source data stream and a multi-beam antenna. The pre-processor comprises a segmenting device to segment the at least one source data stream into a set of N data sub streams, N being an integer greater than 1; a K-muxing unit to perform a N-to-N K-muxing transform on the N data substreams to generate N K-muxed data streams, each of the N K-muxed data streams being a linear combination of the N data substreams; and a bank of modulators to modulate the N K-muxed data streams to generate N K-muxed signal streams. The multi-beam antenna comprises beam forming networks to transform the N K-muxed signal streams into transmit beams, and an array of antenna elements to transmit the transmit beams to the access points.

A method for alignment of a first node with a second node in a wireless communication network. The method comprises directing a first node first antenna beam at a first pointing angle, using a second node antenna beam for scanning a first volume with objects being able to generate signal reflections/diffraction, detecting a first signal property of reflected/diffracted signals; and saving scan angles resulting in said first signal property exceeding a first threshold level. The method further comprises directing the second node antenna beam at said saved angles, and, for each such angle: using a first node second antenna beam for scanning; and detecting at least a second signal property of reflected/diffracted signals; exchanging information between the nodes comprising first node second antenna beam pointing direction angles resulting in said second signal property exceeding a second threshold level and said saved angles; and selecting angles for communication.

The invention relates to a method, devices and systems, where a first radio connection is formed from a user device to a communication network, and information of a location of the user device is provided to a server system connected to the communication network over the first radio connection. Then, link setup information is formed at the server system and provided from said server system over the first radio connection. The link setup information comprises data for forming a second radio connection from the location of the first user device to a communication network using a beam forming antenna. Utilizing this link setup information, a second radio connection is formed from the first user device to a communication network, and a beam forming antenna operating in a beam forming mode is used in the forming of the radio connection. The second radio link may be a link between the user device mounted in a fixed location, e.g. a wall of a building and a network radio node. The user device may be e.g. a LTE-to-the-home (LTTH) router that provides internet connectivity locally.

An electronic device is provided. The electronic device includes a flexible display comprising a display panel which includes a first portion, a second portion, and a third portion, and is disposed to be at least partially visible in a folded state, an array antenna which is formed on a dielectric sheet disposed on the display panel and includes a first mesh pattern portion disposed at a position corresponding to the first portion, a second mesh pattern portion disposed at a position corresponding to the third portion, and at least one third mesh pattern portion formed at a position spaced apart from the first mesh pattern portion, at a position corresponding to the first portion, a wireless communication circuit configured to transmit and/or receive a wireless signal through the array antenna, and a phase shifting means disposed in an electrical path between the wireless communication circuit and the array antenna.

A communication apparatus having a plurality of antennas uses a predetermined frequency channel to perform communication, adjusts beamforming for transmission/reception by setting a weighting coefficient for each of the plurality of antennas, monitors to detect a radar signal outputted from another communication apparatus by using the predetermined frequency channel in a beamforming state formed in accordance with the weighting coefficients, and determines whether or not a reception level of the radar signal is greater than or equal to a predetermined threshold. When it is determined that the reception level of the radar signal is greater than or equal to the predetermined threshold, the communication apparatus changes the weighting coefficients, and uses the predetermined frequency channel in a beamforming state formed in accordance with the changed weighting coefficients to perform communication.

The present invention relates to a method for beamforming a beam using an active antenna having predetermined aperture data predetermined aperture data comprising M×N dual polarized antenna subarrays within an aperture, each dual polarized antenna subarray comprising a first antenna subarray having a first polarization and a second antenna subarray having a second polarization non-parallel with the first polarization. The method comprises: selecting number of antenna ports, each antenna port being adapted to generate a separate beam using a combination from the first antenna subarray and/or the second antenna subarray; selecting port properties, comprising target beamwidth for each separate beam and desired polarization between beams; and determining port partitioning based upon aperture data and port properties for each antenna port, to adjust an effective length of the aperture over which the beam is created and thereby defining which first antenna subarray(s) and/or second antenna subarray(s) to use for each antenna port.

The apparatus may be a base station. The apparatus processes a plurality of synchronization signals by performing time-division multiplexing (TDM) of at least one of a plurality of first synchronization signals of different types and at least one of the plurality of second synchronization signals of different types, the plurality of synchronization signals including the plurality of first synchronization signals and the plurality of second synchronization signals. The apparatus transmits the processed synchronization signals to a user equipment (UE).

The apparatus may be a base station. The apparatus processes a first group of synchronization signals. The apparatus processes a second group of synchronization signals. The apparatus performs a first transmission by transmitting the processed first group of the synchronization signals in a first synchronization subframe. The apparatus performs a second transmission by transmitting the processed second group of the synchronization signals in a second synchronization subframe.

The apparatus may be a base station. The apparatus sets a first numerology for at least one synchronization signal of one or more synchronization signals to be different from a second numerology for at least one data signal of one or more data signals. The apparatus transmits the one or more synchronization signals to a user equipment (UE) based on the first numerology. The apparatus transmits the one or more data signals to the UE based on the second numerology.