A communication system disposed in a housing includes multiple communication devices each of which performing a wireless communication with one another. The communication devices include a specific communication device disposed on a mounting surface. The specific communication device includes at least one antenna structure, and the at least one antenna structure includes at least one antenna. The at least one antenna structure is disposed between the mounting surface and a predetermined wall surface of the housing. A gap between an outer shell of the at least one antenna structure and the predetermined wall surface of the housing is smaller than a wavelength of a radio wave used in the wireless communication of the communication devices. The at least one antenna of the specific communication device has a directivity in a direction parallel to the mounting surface.

Antennas and methods for using the same are described. In one embodiment, the antenna comprises an aperture having a plurality of radio-frequency (RF) radiating antenna elements, the plurality of RF radiating antenna elements being grouped into three or more sets of RF radiating antenna elements, with each set being separately controlled to generate a beam at a frequency band in a first mode.

Antennas and methods for using the same are described. In one embodiment, the antenna comprises an aperture having a plurality of radio-frequency (RF) radiating antenna elements, the plurality of RF radiating antenna elements being grouped into three or more sets of RF radiating antenna elements, with each set being separately controlled to generate a beam at a frequency band in a first mode.

A microwave distribution network includes stacks of layers, each layer including unit cells. The unit cells have a coaxial input connected to three transmission lines with an angular span of 120°. The layers are configured as a hexagonal lattice formed with replicated unit cells. The coaxial inputs are at the hexagon corners. Each unit cell is connected to three neighbor unit cells. The coaxial inputs of the unit cells and neighbor cells are oriented on a Z-axis of a Cartesian system of axes in which the three transmission lines are on an XY plane, such that the input orientation on the Z-axis is opposite to the former unit cell on the same Z-axis. The distance between coaxial inputs is λ/4, where λ is the wavelength of a microwave distribution network operating frequency. Adjacent layers are interconnected by the coaxial inputs of the unit cells arranged in an opposite direction.

A microwave distribution network includes stacks of layers, each layer including unit cells. The unit cells have a coaxial input connected to three transmission lines with an angular span of 120°. The layers are configured as a hexagonal lattice formed with replicated unit cells. The coaxial inputs are at the hexagon corners. Each unit cell is connected to three neighbor unit cells. The coaxial inputs of the unit cells and neighbor cells are oriented on a Z-axis of a Cartesian system of axes in which the three transmission lines are on an XY plane, such that the input orientation on the Z-axis is opposite to the former unit cell on the same Z-axis. The distance between coaxial inputs is λ/4, where λ is the wavelength of a microwave distribution network operating frequency. Adjacent layers are interconnected by the coaxial inputs of the unit cells arranged in an opposite direction.

A twin beam base station antenna includes a first array that has a plurality of columns of first frequency band radiating elements, the first array configured to form a first antenna beam that provides coverage throughout a first sub-sector of a three-sector base station. The radiating elements in a first of the columns in the first array have a first azimuth boresight pointing direction and the radiating elements in a second of the columns in the first array have a second azimuth boresight pointing direction that is offset from the first azimuth boresight pointing direction by at least 10°. The radiating elements in the second of the columns in the first array are electrically steered.

In some embodiments, a phased array antenna system includes a carrier having a first side and a second side opposite the first side; a first antenna element and a second antenna element coupled to the first side of the carrier, the second antenna element spaced apart from the first antenna element by a space and a signal conditioning module including a support structure having a first side and a second side opposite the first side, one or more signal conditioning elements coupled to the first side of the support structure, and a plurality of coupling elements coupled to the second side of the support structure, wherein at least one of the plurality of coupling elements electrically couples the signal conditioning module to the first antenna element; and at least another of the plurality of coupling elements electrically couples the signal conditioning module to the carrier.

Various aspects of the present disclosure generally relate to wireless communication. In some aspects, a network device may transmit, to a base station, an indication of a capability of a beamforming architecture of the network device. The network device may communicate with the base station based at least in part on the capability of the beamforming architecture of the network device. Numerous other aspects are described.

A wideband bisector antenna has a plurality of antenna elements disposed in horizontal rows, a left beam bi-sector array segment at one section of the antenna comprising a plurality of the horizontal rows of elements, and a right beam bi-sector array segment at one section of the antenna comprising a plurality of the horizontal rows of elements. At least one horizontal row on the antenna is shared in both the left beam bi-sector array segment and the right beam bi-sector array segment.

A low sidelobe beam forming method and dual-beam antenna schematic are disclosed, which may preferably be used for 3-sector and 6-sector cellular communication system. Complete antenna combines 2-, 3- or -4 columns dual-beam sub-arrays (modules) with improved beam-forming network (BFN). The modules may be used as part of an array, or as an independent 2-beam antenna. By integrating different types of modules to form a complete array, the present invention provides an improved dual-beam antenna with improved azimuth sidelobe suppression in a wide frequency band of operation, with improved coverage of a desired cellular sector and with less interference being created with other cells. Advantageously, a better cell efficiency is realized with up to 95% of the radiated power being directed in a desired cellular sector.