An antenna structure according to an embodiment of the present invention includes a first antenna unit including a first radiator, a first transmission line connected to the first radiator, and a guide pattern disposed around the first transmission line and separated from the first transmission line, a second antenna unit at least partially covered by the guide pattern of the first antenna unit in a plan view, and a dielectric layer interposed between the first antenna unit and the second antenna unit. An antenna structure implementing low-frequency and high-frequency properties with high reliability is provided.

A supporting device for a base station antenna and a base station antenna includes: a first member configured to be mounted to the foundational component; a second member configured to be connected to an end cover at the bottom of the base station antenna; and a plurality of supporting poles that are fixedly connected to the first member and to the second member, include a first section between the first member and the second member and a second section extending from the second member in a direction away from the first member, configured to extend in the longitudinal direction of the base station antenna, are distributed in the circumferential direction of the base station antenna, and are connected to at least one reflecting plate of the base station antenna at the second section, wherein the second section extends over a part of the axial extension of the reflecting plate of the base station antenna.

A supporting device for a base station antenna and a base station antenna includes: a first member configured to be mounted to the foundational component; a second member configured to be connected to an end cover at the bottom of the base station antenna; and a plurality of supporting poles that are fixedly connected to the first member and to the second member, include a first section between the first member and the second member and a second section extending from the second member in a direction away from the first member, configured to extend in the longitudinal direction of the base station antenna, are distributed in the circumferential direction of the base station antenna, and are connected to at least one reflecting plate of the base station antenna at the second section, wherein the second section extends over a part of the axial extension of the reflecting plate of the base station antenna.

A device may include a housing with a plurality of top openings provided in a top portion of the housing and a plurality of bottom openings provided in a bottom portion of the housing. The device may include one or more internal components provided within the housing to provide a wireless service. The device may include a rotation extension connected to the bottom portion of the housing and configured to rotatably attach to a bracket that mounts the device to an object. The device may include a connector connected to the rotation extension and configured to receive a cable that provides communication signals to and from the device.

A device may include a housing with a plurality of top openings provided in a top portion of the housing and a plurality of bottom openings provided in a bottom portion of the housing. The device may include one or more internal components provided within the housing to provide a wireless service. The device may include a rotation extension connected to the bottom portion of the housing and configured to rotatably attach to a bracket that mounts the device to an object. The device may include a connector connected to the rotation extension and configured to receive a cable that provides communication signals to and from the device.

An antenna module includes: an antenna-radio unit comprising an antenna and a radio transceiver in an integrated unit; a foundation plate configured for mounting to a monopole; a bottom plate mounted above the foundation plate to form a first air gap; a support member that extends upwardly from the bottom plate, the antenna-radio unit mounted to the support member; an upper plate mounted to an upper end of the support member; a fan unit mounted to the upper plate; a lower cap mounted above the upper plate; an upper cap mounted above the lower cap to form a second air gap; and a shroud that surrounds and conceals the antenna-radio unit and the support member.

A method for manufacturing a heatable plastic component for a motor vehicle, which includes: providing a planar heating film, which has a first surface and a second surface that faces away from and is opposite the first surface, including at least one heating wire and connecting elements; introducing the planar heating film into an injection mold; mounting a connector housing onto the connecting elements; and back-molding the first surface with a plastic for manufacturing a first partial element of the heatable plastic component in the injection mold. In order to provide an improved method for manufacturing a heatable plastic component, it is proposed that a back-molding of the second surface with a plastic for manufacturing a second partial element of the heatable plastic component in the injection mold takes place such that a composite is formed from the first partial element, the planar heating film and the second partial element.

A vehicle lamp mounted on a vehicle includes: a lamp housing; a lamp cover that covers an opening of the lamp housing; at least one illumination unit disposed in a lamp chamber formed by the lamp housing and the lamp cover; a radar disposed in the lamp chamber and configured to acquire radar data indicating a surrounding environment of the vehicle by emitting a radio wave to an outside of the vehicle; and a dielectric lens disposed in front of the radar and configured to allow the radio wave emitted from the radar to pass therethrough. The dielectric lens is configured to narrow a spread angle of the radio wave emitted from the radar.

The present invention discloses a broadband microstrip patch antenna (106) with U-shaped slot (116) with unequal arms for millimeter wave communications. The electromagnetic coupled type feed is used with microstrip line (103) printed on another substrate layer to minimize feed loss. The dimension of the patch, position and dimension of slots, height of dielectric layer, length, width of the microstrip line and so on are optimized to achieve the desired impedance and gain pattern over the 60 GHz frequency band.

Antenna comprising a fastening body bearing an electrically conductive circuit having at least one signal input segment and one radiating segment, the fastening body comprising two positioning portions defining therebetween a passage dimensioned to receive one edge of a PCB carrier, the input segment being borne by one of the positioning portions in order to extend facing one face of said carrier and the body comprising means for clamping the carrier against one of the positioning portions. Electronic circuit and item of electronic equipment comprising such an antenna.