Example methods and systems for implementing slotted waveguide array antenna using printed waveguide transmission lines technology are described herein. One example method may include developing a slotted waveguide array antenna may be developed using a plurality of slotted waveguides aligned in an antenna array, in which each slotted waveguide may be developed using printed waveguide transmission lines technology. Components of the slotted waveguide array antenna may be developed using printed circuit board materials, such as Kapton-type laminate and FR4. In addition, through using printed waveguide transmission line technology, a slotted waveguide array antenna may be configured to radiate millimeter electromagnetic waves and may be configured to operate in radar, navigation, or other high frequency systems.

Example methods and systems for implementing slotted waveguide array antenna using printed waveguide transmission lines technology are described herein. One example method may include developing a slotted waveguide array antenna may be developed using a plurality of slotted waveguides aligned in an antenna array, in which each slotted waveguide may be developed using printed waveguide transmission lines technology. Components of the slotted waveguide array antenna may be developed using printed circuit board materials, such as Kapton-type laminate and FR4. In addition, through using printed waveguide transmission line technology, a slotted waveguide array antenna may be configured to radiate millimeter electromagnetic waves and may be configured to operate in radar, navigation, or other high frequency systems.

Provided is an antenna device for a vehicle including an antenna base including a bottom surface portion, a circuit board disposed above the bottom surface portion to face the bottom surface portion, and an antenna element disposed on an outer periphery, and forming a slot antenna with a side end of the antenna base being a facing side of a slot.

Provided is an antenna device for a vehicle including an antenna base including a bottom surface portion, a circuit board disposed above the bottom surface portion to face the bottom surface portion, and an antenna element disposed on an outer periphery, and forming a slot antenna with a side end of the antenna base being a facing side of a slot.

A mobile device includes a metal cavity, a dielectric substrate, and a feeding element. A slot is formed on a side wall of the metal cavity. The dielectric substrate is disposed in the metal cavity. The feeding element is disposed on the dielectric substrate, and is electrically connected to a signal source. A slot antenna structure is formed by the metal cavity, the dielectric substrate, and the feeding element.

A mobile device includes a metal cavity, a dielectric substrate, and a feeding element. A slot is formed on a side wall of the metal cavity. The dielectric substrate is disposed in the metal cavity. The feeding element is disposed on the dielectric substrate, and is electrically connected to a signal source. A slot antenna structure is formed by the metal cavity, the dielectric substrate, and the feeding element.

A low profile temperature transducer has a working surface for placement against a body surface and a first output. The transducer is a flat laminate composed of alternating conductive and dielectric layers. The laminate defines at least one slotline antenna for exposure to the body surface to pick up thermal emissions from the underlying tissue at depth. A feed network having a characteristic impedance is connected to the first output and a slotline-to-stripline transition is connected between the at least one antenna and the feed network, the transition providing a match between the impedance at the at least one antenna and the characteristic impedance. Also, a temperature sensor may be present at the working surface to detect the body surface temperature under the transducer, that surface temperature being used to calculate actual temperature at depth.

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.

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.