Aspects of the subject disclosure may include, a communication device having a connection structure that physically connects with a utility structure, where the connection structure has a strut channel. The communication device has a support structure physically connected to the connection structure. The communication device has a group of radio devices secured to the support structure, where the strut channel is configured to enable temporarily locking the support structure to the connection structure via an installation member during an installation process. Other embodiments are disclosed.

Systems and methods for detecting and reducing signal interference affecting wireless communication with a mobile vehicle includes generating an interference signature based on a correlation multiple signal-quality characteristics of a desired target-signal that is received at an antenna assembly attached to the mobile vehicle, and adjusting the orientation of the antenna assembly based on a change or degradation in the interference signature to thereby improve wireless communication with the vehicle.

Systems and methods for detecting and reducing signal interference affecting wireless communication with a mobile vehicle includes generating an interference signature based on a correlation multiple signal-quality characteristics of a desired target-signal that is received at an antenna assembly attached to the mobile vehicle, and adjusting the orientation of the antenna assembly based on a change or degradation in the interference signature to thereby improve wireless communication with the vehicle.

A rotatable antenna apparatus has a fixed unit for attachment of the apparatus to an external structure, and a rotatable unit mounted on the fixed unit for rotation relative to the fixed unit. The rotatable unit comprises both an antenna assembly and processing circuitry coupled to the antenna assembly for performing signal processing operations. The apparatus further includes a thermally conductive shaft connected to the rotatable unit and located for rotation within the fixed unit, and a thermally conductive coupling structure to conduct heat from one or more heat generating components of the processing circuitry into the thermally conductive shaft. A heat sink within the fixed unit is thermally coupled to the thermally conductive shaft to draw heat away from the thermally conductive shaft. This provides an efficient mechanism for removing heat from the rotatable unit, whilst still allowing the rotatable unit to be sealed against external environmental conditions.

A rotatable antenna apparatus has a fixed unit for attachment of the apparatus to an external structure, and a rotatable unit mounted on the fixed unit for rotation relative to the fixed unit. The rotatable unit comprises both an antenna assembly and processing circuitry coupled to the antenna assembly for performing signal processing operations. The apparatus further includes a thermally conductive shaft connected to the rotatable unit and located for rotation within the fixed unit, and a thermally conductive coupling structure to conduct heat from one or more heat generating components of the processing circuitry into the thermally conductive shaft. A heat sink within the fixed unit is thermally coupled to the thermally conductive shaft to draw heat away from the thermally conductive shaft. This provides an efficient mechanism for removing heat from the rotatable unit, whilst still allowing the rotatable unit to be sealed against external environmental conditions.

A self-aiming directional Wi-Fi antenna system includes a directional antenna that is motorized. A motion controller operates the motors to move the antenna position to sources of Wi-Fi radio frequency (RF) transmissions, determines an SSID for each source that satisfies a selection criterion and stores a position data corresponding to each SSID. The directional Wi-Fi antenna is moved to a final position corresponding to the antenna position data for one of the SSIDs stored in memory.

A self-aiming directional Wi-Fi antenna system includes a directional antenna that is motorized. A motion controller operates the motors to move the antenna position to sources of Wi-Fi radio frequency (RF) transmissions, determines an SSID for each source that satisfies a selection criterion and stores a position data corresponding to each SSID. The directional Wi-Fi antenna is moved to a final position corresponding to the antenna position data for one of the SSIDs stored in memory.

The phased array antenna system is described. The phased array antenna system formed on one or more layers of a printed circuit board (PCB). The phased array antenna system be may include a beam forming network to convert between one or more element signals and a beam signal. The phased array antenna system may include one or more control circuits, where each control circuit may receive the element signals for corresponding antenna element. Each of the control circuits may further may establish a control signal path and an element signal path between the antenna elements and the beamforming network, where the signal path may carry multiplexed element and control signals. The control circuits may include a signal adjustment circuit that may adjust the corresponding element signal (e.g., in phase or amplitude) based on the control signal.

One embodiment disclosed herein is related to a device for pointing a radiating element. The device includes an aligned radiating surface; a hinge that is circumferentially mounted to a rear side of the aligned radiating surface, the hinge configured to change azimuth of the aligned radiating surface; and a Tubular Universal joint (TU-joint) having one end coupled to a rear side of the aligned radiating surface and a second end coupled to a base, the TU-joint being configured to change an elevation of the aligned radiating surface. Another embodiment is related to a Tubular Universal-joint (TU-joint). In the embodiment, the TU-joint includes a hollow tube having a first end and a second end; a plurality of slits along the surface of the tube; and a plurality of members between the plurality of slits, each of the plurality of members configured to bear a portion of a load of the TU-joint, wherein the TU-joint is configured to be axially and torsionally stiff while being bendable.

One embodiment disclosed herein is related to a device for pointing a radiating element. The device includes an aligned radiating surface; a hinge that is circumferentially mounted to a rear side of the aligned radiating surface, the hinge configured to change azimuth of the aligned radiating surface; and a Tubular Universal joint (TU-joint) having one end coupled to a rear side of the aligned radiating surface and a second end coupled to a base, the TU-joint being configured to change an elevation of the aligned radiating surface. Another embodiment is related to a Tubular Universal-joint (TU-joint). In the embodiment, the TU-joint includes a hollow tube having a first end and a second end; a plurality of slits along the surface of the tube; and a plurality of members between the plurality of slits, each of the plurality of members configured to bear a portion of a load of the TU-joint, wherein the TU-joint is configured to be axially and torsionally stiff while being bendable.