An inflatable tracking antenna assembly may include an inflatable antenna. The inflatable antenna may be configurable in a packed configuration and a deployed configuration. In the deployed configuration the inflatable antenna may be generally spherical in shape. The assembly may include an antenna support structure. The support structure may include a plurality of support arms that couple with lateral sides of the inflatable antenna. The support structure may include a base that is coupled with each of the plurality of support arms. The base may include an azimuth actuator that adjusts an azimuth position of the inflatable antenna and an elevation actuator that adjusts an elevation angle of the inflatable antenna. The support structure may include a plurality of support legs that extend outward from the base.

The present disclosure describes a telecommunications equipment mount. The mount includes a stabilization frame having a bottom and at least three sides, the bottom and sides defining an open interior cavity, at least one mounting member perpendicular to one of the sides of the stabilization frame and extending outwardly from the side of the stabilization frame a distance, and at least one brace member. The at least one brace member includes a first bracket coupled to one side of the stabilization frame and configured to be secured to the at least one mounting member and a second bracket extending outwardly from the same side of the stabilization frame at an angle. A first end of the second bracket is coupled to a lower end of the first bracket and a second opposing end of the second bracket is configured to be secured to the at least one mounting member at a different location than the first bracket. The stabilization frame is configured to ballast the mount on a mounting structure when telecommunications equipment is secured to the mount. Telecommunications equipment mount assemblies are also described herein.

The present disclosure describes a telecommunications equipment mount. The mount includes a stabilization frame having a bottom and at least three sides, the bottom and sides defining an open interior cavity, at least one mounting member perpendicular to one of the sides of the stabilization frame and extending outwardly from the side of the stabilization frame a distance, and at least one brace member. The at least one brace member includes a first bracket coupled to one side of the stabilization frame and configured to be secured to the at least one mounting member and a second bracket extending outwardly from the same side of the stabilization frame at an angle. A first end of the second bracket is coupled to a lower end of the first bracket and a second opposing end of the second bracket is configured to be secured to the at least one mounting member at a different location than the first bracket. The stabilization frame is configured to ballast the mount on a mounting structure when telecommunications equipment is secured to the mount. Telecommunications equipment mount assemblies are also described herein.

An integrated heatsink and antenna structure that is suitable for inclusion in small and midsized computing devices. The integrated heatsink and antenna structure may include heatsink portions and radio frequency antenna portions. The heatsink portions may provide a path for dissipating thermal energy or heat generated by the components in the device (e.g., printed circuit boards, processors, voltage amplifiers, etc.), and the radio frequency (RF) antenna portions may allow the device to send and receive wireless communications. The integrated heatsink and antenna structure may be formed so that radio frequency antenna portions operate to improve the thermal performance of the heatsink portions and/or so that the heatsink portions operate to improve the antenna properties (e.g., radiation patterns, radiation efficiency, bandwidth, input impedance, polarization, directivity, gain, beam-width, voltage standing wave ratio, etc.) of the radio frequency antenna portions.

The present disclosure describes an antenna mount. The antenna mount may include a base plate having a plurality of mounting apertures configured to secure an antenna thereto, wherein the base plate includes a plurality of arm sections extending radially outwardly therefrom, each arm section comprising an elongated slot, a plurality of fasteners, each fastener configured to slide within a respective slot, and a plurality of brackets, each bracket secured to the base plate by a respective fastener extending through each slot, wherein the position of the brackets are adjustable relative to the base plate by sliding the fasteners within each slot, thereby allowing the antenna mount to be secured to different diameter mounting structures. Antenna mount assemblies are also described herein.

The present disclosure describes an antenna mount. The antenna mount may include a base plate having a plurality of mounting apertures configured to secure an antenna thereto, wherein the base plate includes a plurality of arm sections extending radially outwardly therefrom, each arm section comprising an elongated slot, a plurality of fasteners, each fastener configured to slide within a respective slot, and a plurality of brackets, each bracket secured to the base plate by a respective fastener extending through each slot, wherein the position of the brackets are adjustable relative to the base plate by sliding the fasteners within each slot, thereby allowing the antenna mount to be secured to different diameter mounting structures. Antenna mount assemblies are also described herein.

A communication system comprising a radio device and a gooseneck device. The radio device may be coupled to a first antenna and a second antenna. A feedline gooseneck device may be coupled to the first antenna. The feedline gooseneck device may include a coaxial cable coupled between the mobile device and the first antenna and a ferrite element positioned along the coaxial cable. The ferrite element is configured to reduce EM interaction between the first and the second antenna. The ferrite element may be one of a plurality of ferrite elements and the feedline gooseneck device may further include a plurality of flexible elements positioned adjacent to each of the plurality of ferrite elements. The ferrite element(s) may surround at least 60% of a length of the coaxial cable. The first antenna may be removably coupled to the gooseneck device. The system allows for reduction of an amount of electromagnetic interference between the first antenna coupled to the gooseneck and the second antenna.

An electronic device is provided. The electronic device includes a housing including a conductive part, a device substrate disposed in an inner space of the housing, an antenna structure, disposed in the inner space to form a directional beam and including a substrate, an array antenna including a plurality of antenna elements disposed on the substrate and a support bracket to support the substrate, an electrical connection member connecting the substrate to the device substrate, a conductive contact connecting the electrical connection member to the conductive part, a first wireless communication circuit disposed in the inner space and configured to transmit or receive a first wireless signal in a first frequency band through the antenna structure, and a second wireless communication circuit disposed on the device substrate and configured to transmit or receive a second wireless signal in a second frequency band through the conductive part.

An electronic device is provided. The electronic device includes a housing including a conductive part, a device substrate disposed in an inner space of the housing, an antenna structure, disposed in the inner space to form a directional beam and including a substrate, an array antenna including a plurality of antenna elements disposed on the substrate and a support bracket to support the substrate, an electrical connection member connecting the substrate to the device substrate, a conductive contact connecting the electrical connection member to the conductive part, a first wireless communication circuit disposed in the inner space and configured to transmit or receive a first wireless signal in a first frequency band through the antenna structure, and a second wireless communication circuit disposed on the device substrate and configured to transmit or receive a second wireless signal in a second frequency band through the conductive part.

A communication device includes a wireless communication module, a frame element, and a fixing assembly. The frame element includes a bottom plate and a side plate connected to the bottom plate, and the side plate includes a fixing hole. The fixing assembly includes a first fixing element. The first fixing element includes a first connection portion and a first fixing portion. The first connection portion is adapted to be fixed to the wireless communication module, and the first fixing portion includes a first neck portion and a first protruding portion. The first neck portion is adapted to be in the fixing hole, and the first neck portion is connected between the first connection portion and the first protruding portion. Hence, the fixing component fixes the wireless communication module with the frame element.