A non-transitory computer-readable recording medium having stored therein a program that, when a processor coupled to a memory and the processor is configured to execute the program, causes the processor configured to: store, in the memory, a design data of a metal member disposed around the patch antenna having a ground conductor and an antenna element having a power feeding point, and a positional relationship between the metal member and the patch antenna; and determine a relative position between the power feeding point and the metal member so that a center point and the power feeding point of the patch antenna in plan view are located on a perpendicular line to a surface of the metal member on the patch antenna side based on the design data of the metal member and the positional relationship stored in the memory.

Base station antennas include a main module that has a first backplane that includes a first reflector. A vertically-extending array of first radiating elements is mounted to extend forwardly from the first reflector, and at least one first RF port is coupled to the vertically-extending array of first radiating elements. These antennas further include a sub-module that is attached to the first backplane. The sub-module includes a second backplane that has a second reflector that is separate from the first reflector. A vertically-extending array of second radiating elements is mounted to extend forwardly from the second reflector and is transversely spaced-apart from the vertically-extending array of first radiating elements. A plurality of second RF ports are coupled to the vertically-extending array of second radiating elements. The vertically-extending array of first radiating elements and the vertically-extending array of second radiating elements are configured to serve a common sector of a base station.

A base station antenna comprises two arrays of radiating elements each configured to emit electromagnetic radiation; two backplanes each configured to reflect respective electromagnetic radiation outwardly, wherein the two backplanes are positioned with a mechanical tilt relative to each other such that the respective electromagnetic radiation are directed in different directions in the azimuth plane; and two plate assemblies each configured to reflect a first portion of received electromagnetic radiation inwardly while allowing a second portion to pass outwardly through the respective plate assembly, where the two plate assemblies are positioned to form two Fabry-Perot cavities with the two backplanes, respectively.

A base station antenna comprises two arrays of radiating elements each configured to emit electromagnetic radiation; two backplanes each configured to reflect respective electromagnetic radiation outwardly, wherein the two backplanes are positioned with a mechanical tilt relative to each other such that the respective electromagnetic radiation are directed in different directions in the azimuth plane; and two plate assemblies each configured to reflect a first portion of received electromagnetic radiation inwardly while allowing a second portion to pass outwardly through the respective plate assembly, where the two plate assemblies are positioned to form two Fabry-Perot cavities with the two backplanes, respectively.

Wireless mesh network (WMN) architectures of network hardware devices organized in a mesh topology is described. One device communicates, using a first radio, first data with a second device via a first wireless link between the device and the second device. The device communicates, using a second radio, second data with a third device via a second wireless link between the device and the third device. The device communicates, using a third radio, third data with a fourth device via a third wireless link between the device and the fourth device. The device communicates, using a fourth radio, fourth data with a server of a content delivery network (CDN) via a point-to-point wireless link between the device and the server. The device is an only ingress point for content files for a mesh network that includes at least the device, the second device, and the third device.

Wireless mesh network (WMN) architectures of network hardware devices organized in a mesh topology is described. One device communicates, using a first radio, first data with a second device via a first wireless link between the device and the second device. The device communicates, using a second radio, second data with a third device via a second wireless link between the device and the third device. The device communicates, using a third radio, third data with a fourth device via a third wireless link between the device and the fourth device. The device communicates, using a fourth radio, fourth data with a server of a content delivery network (CDN) via a point-to-point wireless link between the device and the server. The device is an only ingress point for content files for a mesh network that includes at least the device, the second device, and the third device.

Embodiments of the present disclosure provide method and apparatus for positioning. The method may comprise receiving a first radio signal of a terminal device located in the area from a line of sight (LOS) path between the antenna array and the terminal device; receiving a second radio signal of the terminal device located in the area from at least one path reflected by the reflector; determining respective angles of arrival of the LOS path and the at least one path reflected by the reflector; and determining a location of the terminal device by using triangulation based on the respective angles of arrival.

According to an aspect, there is provided a passive antenna module for an active-passive antenna system. The passive antenna module includes a chassis for detachably mounting onto an active antenna module. The chassis includes an opening or a cavity for extending at least partially over the active antenna module when the chassis is mounted onto the active antenna module. The passive antenna module includes a ground plane layer arranged within or over said opening or cavity and fixed to the chassis. The ground plane layer includes a metallic or metallized grid. The passive antenna module includes a first antenna array including one or more first antenna elements arranged, in part, over said chassis and adjacent to said opening or cavity and, in part, over said opening or cavity. The chassis and the ground plane layer are adapted to act as ground planes for the first antenna array.

A thin antenna includes an antenna element, a first spacer, a second spacer, a first ground plane and a second ground plane. The antenna element is formed in a column shape, and has a top surface and a bottom surface facing each other. The first and second spacers are made of an insulating material. The first ground plane is formed larger than the top surface of the antenna element. The second ground plane is formed larger than the bottom surface of the antenna element. The first ground plane is disposed to face the top surface of the antenna element via the first spacer. The second ground plane is disposed to face the bottom surface of the antenna element via the second spacer. A power is fed at one of the top surface and the bottom surface of the antenna element.

Disclosed are an antenna reflective net and an antenna reflective net mounting structure. Sliding slots are provided on side walls of the antenna reflective net mounting structure respectively. Protrusions of a base of the antenna reflective net slide into the sliding slots, and the size of the sliding slot is adapted to that of the protrusion. The protrusion is fixed in the sliding slot along a direction vertical to the sliding slot. A baffle block is provided at a distal end of the sliding slot. The baffle block restricts the protrusion from sliding along the direction of the distal end. Moreover, a limit part of an elastic pressing member of the antenna reflective net mounting structure restricts the protrusion from sliding along the direction of the entrance end of the sliding slot after the protrusion enters the sliding slot. Therefore, the antenna reflective net is easily mounted in the antenna reflective net mounting structure with high stability.