Passive reflectors for wireless communication networks and methods of their fabrication are disclosed. In one embodiment, a passive reflector for reflecting a RF beam, the passive reflector includes a dielectric substrate. The passive reflector also includes a reflector includes an array of unit cells, where the reflector array is provided on a surface of the dielectric substrate, each unit cell includes a first conductive loop and a second conductive loop that is orthogonal to the first conductive loop, and each unit cell provides a phased distribution for two different polarizations.

The present disclosure relates to a mounting assembly for an integrated base station antenna and an integrated base station antenna. The integrated base station antenna comprises a 4G antenna module and a 5G antenna module. The mounting assembly comprises at least one mounting frame and two rails located at both sides of the mounting frame, wherein the 5G antenna module of the integrated base station antenna is mounted in the space formed by the mounting frame and the two rails, the mounting frame and the two rails are all made of metal, the two rails are formed to be in mechanical contact with or electrically coupled with a metal component of the 5G antenna module and/or in mechanical contact with or electrically coupled with the mounting frame to form a reflection cavity for reflecting radio frequency signals, and the reflecting cavity is capable of reflecting radio frequency signals transmitted backward by the 4G antenna module of the integrated base station antenna in order to at least reduce the loss of the radio frequency signals transmitted by the 4G antenna module.

The ceiling antenna includes a reflecting bottom plate, wherein the reflecting bottom plate has a via hole; a supporting plate, wherein the supporting plate is fixed to the reflecting bottom plate, and a plane where the supporting plate is located is perpendicular to a plane where the reflecting bottom plate is located; a radiation oscillator, wherein the radiation oscillator is adhered to the supporting plate, the radiation oscillator includes a first radiator, the first radiator has a grid-line-like structure, and a shape of an outer contour of the first radiator is a rectangle having at least one cut corner; and a connector, wherein the connector is located on one side of the reflecting bottom plate that is away from the radiation oscillator, the via hole exposes a part of area of the connector, and the connector is electrically connected to the radiation oscillator through the via hole.

A radio wave control system includes a phase adjustment plate that transmits a radio wave from a second main surface to a first main surface and focuses the radio wave on a focal point; and a reflection plate installed at a position irradiated with the radio wave transmitted through the phase adjustment plate.

An antenna module includes two antennas, a reflecting board, and a plurality of extending plates. The extending plate has a first surface and a second surface. The first surface extends along a first axis and a second axis perpendicular to the first axis. The two antennas are disposed on the first surface and spaced along the first axis. A spacing zone is defined in the reflecting board and located between the two antennas along the first axis. The spacing zone has a shielding portion. A periphery of the shielding portion has a plurality of open grooves. Each open groove penetrates through the first surface and the second surface. The shielding portion has a plurality of side edges, wherein each side edge is adjacent to each open groove. Each extending plate extends towards the second surface. The shielding portion and the extending plates jointly form a shielding cover.