An antenna device includes a power supply coil coupled to a first power supply circuit operating in a first frequency band, a first conductive member including a first main surface, a second conductive member including a second main surface, a third conductive member, and first connections. The second main surface of the second conductive member is disposed with at least a portion thereof opposing the first main surface. The third conductive member has an area that is smaller than an area of the first conductive member when viewed in a direction perpendicular or substantially perpendicular to the first main surface. The first conductive member, the third conductive member, and the first connections define a loop of a magnetic field antenna in the first frequency band. The power supply coil is closer to the third conductive member than to the first conductive member when viewed in the Z-direction.

A communication system utilizing reconfigurable antenna systems is described where beam steering and null forming techniques are incorporated to limit the region or volume available for communication with client devices. The communication system described restricts communication to defined or desired area and degrades signal strength coverage outside of a prescribed region. An algorithm is used to control the antenna system to monitor and control antenna system performance across the service area. This antenna system technique is applicable for use in communication systems such as a Local Area Network (LAN), cellular communication network, and Machine to Machine (M2M).

A bracket comprises: a bracket body, at least one PCB mounting mechanism and at least one isolation needle mounting mechanism. The PCB mounting mechanism is disposed on the bracket body, for mounting a PCB parasitic unit, and the isolation needle mounting mechanism is disposed on the bracket body, for mounting the isolation needle parasitic unit. The bracket is capable of mounting different types of parasitic units.

A dual-polarized filtering antenna comprising a driven patch, a parasitic stacked patch and a feeding network is disclosed. Two orthogonal H-shaped feeding lines are coupled to the driven patch for realizing dual polarization. The H-shaped feeding line provides a sharp roll-off rate at the lower band-edge, whereas the stacked patch offers a radiation null at the upper stopband. As a result, a quasi-elliptic bandpass response can be achieved for both polarizations.

The present invention relates to energy conversion device which contains one or more collection units (10) suitable for receiving environmental energy as well as a conversion unit (30) in an electrically conducting connection with the collection unit (10) with the help of a cable (20), at least one of the collection units (10) is formed by a set of metal material pipe members (11), while the conversion unit (30) has a condenser part-unit (32) consisting of metal armored plates (32a, 32a′) separated from each other by a gap (T) and located in the cover (31), as well as a frequency-setting part-unit (33) cooperating with the condenser part-unit (32), where the frequency-setting part-unit (33) has a reception space (35) located within the cover (31) of the conversion unit (30) and enclosed by a delimiting shell (34) in the vicinity of the condenser part-unit (32) and a charge (40) located in the reception space (35), and the charge (40) contains an organic component and an inorganic component distributed in a carrier medium (36).

A semiconductor package includes a supporting wiring structure including a first redistribution dielectric layer and a first redistribution conductive structure; a frame on the supporting wiring structure, having a mounting space and a through hole, and including a conductive material; a semiconductor chip in the mounting space and electrically connected to the first redistribution conductive structure; a cover wiring structure on the frame and the semiconductor chip and including a second redistribution dielectric layer and a second redistribution conductive structure; an antenna structure on the cover wiring structure; a connection structure extending in the through hole and electrically connecting the first redistribution conductive structure to the second redistribution conductive structure; and a dielectric filling member between the connection structure in the through hole and the frame and surrounding the semiconductor chip, the frame, and the connection structure.

A radar antenna includes parasitic elements for influencing the radiation characteristics of the radar antenna, the radiation characteristics of the radar antenna being dependent upon the spatial position of the parasitic elements relative to the radar antenna and phase positions (φ1, φ2, φ3) of energies radiated off the radar antenna and the parasitic elements. The radar antenna is designed using microstrip technology.

The present invention discloses a wireless transceiver apparatus and a base station, and pertains to the communications field. The wireless transceiver apparatus includes: a metal carrier and an antenna unit. The antenna unit includes a feeding structure and a radiation patch, where a groove is disposed on the metal carrier, and the antenna unit is disposed in the groove; and the radiation patch is fed by using the feeding structure, and the radiation patch is grounded.

The present disclosure relates to antennas. One example antenna includes a reflective device, at least two radiating arrays whose operating bands are in a first preset frequency band, and a plurality of parasitic radiators. Each radiating array of the at least two radiating arrays includes a plurality of radiating elements. Each radiating array of the at least two radiating arrays is electrically disposed on the reflective device along a length direction of the reflective device, and the plurality of parasitic radiators are disposed between two adjacent radiating arrays in the at least two radiating arrays.

One antenna module includes a first circuit board and a second circuit board connected to the first circuit board. The antenna module includes a first antenna disposed on the first circuit board. The antenna module also includes a second antenna disposed on the second circuit board. The second circuit board has a first side and a second side opposite the first side. The second antenna includes a first parasitic strip and a second parasitic strip. The first parasitic strip is disposed on the first side of the second circuit board, and the second parasitic strip is disposed on the second side of the second circuit board.