A dual band printed antenna that includes a metal substrate, an electrically isolated supporting element and a monopole antenna element. The metal substrate includes a slot. A side of the isolated supporting element is formed on the metal substrate. The monopole antenna element is formed on the other side of the isolated supporting element and corresponding to the position of the slot. The monopole antenna element includes a radiation part that includes a feed point and a ground part separated from the radiation part for a distance. The radiation part resonates with the slot to generate a radiation pattern of a first frequency band. The radiation part resonates itself to generate a radiation pattern of a second frequency band.

A wearable device includes a wearable body that in use is worn on or proximate a skin of a wearer and a wearable antenna embedded in the wearable body and insulated from the wearable body. The wearable antenna includes a microwave dielectric substrate having a first major surface, a second major surface opposed to the first major surface, and a relative permittivity of at least 90. An electrically conductive patch is disposed on the first major surface, a feed line is connected to a feed point of the electrically conductive patch, and an electrically conductive ground plane is disposed on a far side of the second major surface relative to the first major surface.

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.

According to one embodiment, a transmission line includes a substrate; a first transmission conductor on a first surface of the substrate; first conductors penetrating from the first surface of the substrate to a second surface of the substrate on an opposite side from the first surface; second conductors on a side opposite to the first conductors with respect to the first transmission conductor, and penetrating from the first surface to the second surface; a first conductive member forming a first space surrounding the first transmission conductor, and electrically connecting the first conductors and the second conductors; and a second conductive member forming a second space surrounding a region on the second surface of the substrate, the region opposing to the first transmission conductor, and electrically connecting the first conductors and the second conductors.

A microstrip antenna has two feed points. The microstrip antenna includes a feeder circuit which is configured to feed, to the two feed points, electric signals whose phases are different by 90° from each other. The feeder circuit includes a Wilkinson coupler unit and a phase-shift unit each of which is formed as a lumped constant circuit.

A multi-slot patch antenna is provided. The multi-slot patch antenna includes a central patch including cut corners; a plurality of strips of varying widths, the plurality of strips surrounding the central patch; and a plurality of slots of varying widths, the plurality of slots being positioned between each of the plurality of strips, wherein one of the plurality of slots is positioned between a first one of the plurality of strips and the central patch.

A wireless communication device is provided. The wireless communication device includes a millimeter wave antenna comprising a plurality of antenna elements, a radio frequency integrated circuit (RFIC), and a power feeding line, wherein the plurality of antenna elements are dual-type antenna elements configured to excite different polarization modes, and wherein the power feeding line allows a plurality of ports of the RFIC to individually connect to the plurality of dual-type antenna elements to excite the different polarization modes to perform beamforming The wireless communication device and/or electronic device may be diversified according to various embodiments.

Disclosed is an antenna apparatus including a conductive plate on which a main slot, a sub slot, and a slot coupler are formed, a feed line, and a dielectric provided between the conductive plate and the feed line. The main slot, the sub slot, and the slot coupler are formed to penetrate the conductive plate. The slot coupler extends from the sub slot to the vicinity of the main slot. Thereby, the antenna apparatus is able to communicate smoothly with a preceding vehicle and/or a following vehicle.

A device for signal generation including a unit cell. The unit cell contains two oscillators that are coupled in phase. Each oscillator operates at a fundamental frequency. Each oscillator further includes a slot structure, and the slot structures serve as, at a third harmonic of the fundamental frequency, a slot antenna radiating a third harmonic power. If the device contains multiple unit cell, then each unit cell is horizontally coupled out-of-phase and vertically in-phase with adjacent cells at the fundamental frequency in the device. Therefore, coherent radiation and power combining are achieved at the third harmonic.

A low profile array (LPA) includes an antenna element array layer having at least one Faraday wall, and a beamformer circuit layer coupled to the antenna element array layer. The beamformer circuit layer has at least one Faraday wall. The Faraday walls extends between ground planes associated with at least one of the antenna element array layer and the beamformer circuit layer.