A modular communications system having dynamically positionable non-metallic antenna elements and communications devices is disclosed. The system includes an apparel item with a surface and a foam layer positioned therein. Landing pads are each uniquely positioned on the surface. The antenna elements are demountably, intermittingly, and conductively coupled to the landing pads; includes a non-metallic conductive composition; and a unique operational frequency. A hub is positioned on the surface and conductively coupled to each landing pad. Each communications device is demountably affixed to the surface; intermittingly, demountably, and conductively coupled to the hub; and includes a unique operational frequency. The hub intermittingly, demountably, and conductively couples each communications devices to a unique landing pad included in the plurality of landing pads. The foam layer is lined with a conductive material that reflects RF radiation that emanates from the plurality of non-metallic antenna elements.

A wireless access point device includes a main frame, a transmission assembly, an antenna module and a fixing assembly. The main frame includes a casing and a first connection portion connected to the casing. The transmission assembly is disposed in an internal space of the casing and provided with a signal transceiving element. The antenna module includes a waveguide, a second connection portion and a positioning recess. The second connection portion is disposed on the waveguide and detachably connected to the first connection portion to be coupled to the signal transceiving element. The positioning recess is formed on the second connection portion. The fixing assembly is movably disposed on the first connection portion. The antenna module is thereby fixed on the casing, when the second connection portion and the first connection portion are fixed through the fixing assembly removably inserting into the positioning recess.

Methods, systems, and devices for furlable antenna blade components are provided in accordance with various embodiments. For example, some embodiments include a device that may include one or more furlable antenna blade components; each of the one or more furlable antenna blade components may include one or more conductive elements. In some embodiments, each of the one or more furlable antenna blade components include one or more laminate layers. Some embodiments include a method that may include: furling one or more furlable antenna blade components around a central axis; and/or securing the one or more furlable antennae blade components when in a furled state.

A wireless access point device includes a main frame, a transmission assembly, an antenna module and a fixing assembly. The main frame includes a casing and a first connection portion connected to the casing. The transmission assembly is disposed in an internal space of the casing and provided with a signal transceiving element. The antenna module includes a waveguide, a second connection portion and a positioning recess. The second connection portion is disposed on the waveguide and detachably connected to the first connection portion to be coupled to the signal transceiving element. The positioning recess is formed on the second connection portion. The fixing assembly is movably disposed on the first connection portion. The antenna module is thereby fixed on the casing, when the second connection portion and the first connection portion are fixed through the fixing assembly removably inserting into the positioning recess.

A wireless access point device includes a main frame, an antenna module, a signal transceiving element, an unlocking assembly and a fastener. The main frame includes a casing and a first connection portion formed with a fastening recess, connected to the casing and communicates with the internal space. The signal transceiving element is located in the casing. The antenna module includes a waveguide and a second connection portion disposed on one end of the waveguide. The second connection portion is detachably connected to the first connection portion to couple to the signal transceiving element. The unlocking assembly is movably located in the fastening recess. The fastener includes a buckle, and an elastic member that is connected to the second connection portion and the buckle. The antenna module is fixed on the main frame when the buckle is inserted into the fastening recess.

A modular communications systems includes an apparel item with a surface. Landing pads are positioned proximate to the surface with each landing pad uniquely positioned on the surface. Non-metallic antenna elements are each demountably, intermittingly, and conductively coupled to a unique landing pad; includes a non-metallic conductive composition; and a unique operational frequency compared to at least one antenna element. A hub is positioned on the surface and conductively coupled to each landing pad. Each communications device is demountably affixed to the surface; intermittingly, demountably, and conductively coupled to the hub; and includes a unique operational frequency. The hub intermittingly, demountably, and conductively couples each communications devices to a unique landing pad included in the plurality of landing pads.

A mobile device includes a main antenna structure and a detachable antenna structure. The main antenna structure includes a feeding radiation element, a grounding radiation element, a dielectric substrate, and an iron element. The grounding radiation element is adjacent to the feeding radiation element. The feeding radiation element and the grounding radiation element are disposed on the surface of the dielectric substrate. The iron element is coupled to the grounding radiation element. The detachable antenna structure includes a first radiation element, a second radiation element, a third radiation element, and a magnetic element. The third radiation element is coupled between the first radiation element and the second radiation element. The magnetic element is coupled to the third radiation element. When the magnetic element is attracted to the iron element, the detachable antenna structure can enhance the radiation gain of the main antenna structure.

Technologies regarding the wireless interface adapter for the transmission of control protocol in the professional lighting are disclosed. An example wireless interface adapter, includes: an enclosure; an XLR-style connector coupled to the enclosure; a printed circuit board assembly mounted in the enclosure; an RF module mounted on the printed circuit board; user interface indicators mounted on the printed circuit board and protruding out of the enclosure via small holes of the enclosure; user interface buttons or switches mounted on the printed circuit board and protruding out of the enclosure via small holes of the enclosure; a power supply system mounted in the enclosure; a USB connector mounted on the printed circuit board; and an antenna connected to the RF module.

A fin-type planar antenna and a deployable dipole antenna are combined into a probabilistic system as a co-located orthogonal diversity fin antenna to reduce or eliminate cross polarization fades and cancellation dropouts common to wireless audio systems used in theaters, churches and convention centers over coaxial wired connections. Additionally, an optical line may connect the diversity fin antenna to a further circuit. The antenna system features broad bandwidth, resistance to deep nulls or fades caused by cross polarization, resistance to destructive interference, and an air space dielectric covering provides resistance to detuning in the presence of rain, or touching objects.

A mobile device includes a main antenna structure and a detachable antenna structure. The main antenna structure includes a feeding radiation element, a grounding radiation element, a dielectric substrate, and an iron element. The grounding radiation element is adjacent to the feeding radiation element. The feeding radiation element and the grounding radiation element are disposed on the surface of the dielectric substrate. The iron element is coupled to the grounding radiation element. The detachable antenna structure includes a first radiation element, a second radiation element, a third radiation element, and a magnetic element. The third radiation element is coupled between the first radiation element and the second radiation element. The magnetic element is coupled to the third radiation element. When the magnetic element is attracted to the iron element, the detachable antenna structure can enhance the radiation gain of the main antenna structure.