Antennas such as flat panel, leaky wave antennas with directional coupler feeds and waveguides are disclosed. In one example, an antenna includes a surface having antenna elements, a guided wave transmission line, and a coupling surface. The guided wave transmission line provides a guided feed wave. The coupling surface is between and separates the guided wave transmission line and the surface having antenna elements. The coupling surface controls coupling of the guided feed wave to the antenna elements. The coupling surface can also spatially filter the guided feed wave to provide a more uniform power density for the antenna elements. The guided feed wave can be a high power density electromagnetic wave or a density radially decaying electromagnetic wave.

An antenna suitable for use in the 5 GHz WLAN/Wi-Fi and DSRC frequency band is integrated with a vehicle window that is includes outer and inner transparent plies bonded together by an interlayer. The inner transparent ply and the interlayer serve as an antenna substrate. A first conductive layer is formed on the inner surface of the outer transparent ply and a second conductive layer that defines a coupling slot is formed on the outer surface of the inner transparent ply. The antenna may be excited by a coaxial cable or a microstrip line that crosses the coupling slot.

A rear glass according to the invention is for attachment to a lift-up backdoor that closes an opening in a rear portion of a vehicle, and includes a glass plate, a defogger disposed in a vicinity of a center of the glass plate in an up-down direction, and a shared antenna installed on the glass plate upward or downward of the defogger, the shared antenna including a power supply unit, an AM antenna connected to the power supply unit, and an FM antenna connected to the power supply unit, and a relationship between an element length L.sub.AM of the AM antenna, a center wavelength λ.sub.FM-C corresponding to a reception frequency band of the FM antenna and a wavelength shortening coefficient α of the glass plate satisfying 0.49×α×λ.sub.FM-C≤L.sub.AM≤0.67×α×λ.sub.FM-C.

Disclosed is an antenna on glass (AOG) device having an air cavity at least partially formed in a photosensitive glass substrate. An air cavity structure is at least partially encloses the air cavity and wherein the air cavity structure at least partially formed from the photosensitive glass substrate. An antenna is formed from portion of a top conductive layer disposed on a top surface of the air cavity structure and at least partially overlapping the air cavity. A metallization structure is provided having a bottom conductive layer disposed on a bottom surface of the air cavity structure, wherein the bottom conductive layer is electrically coupled to the top metal layer by a conductive pillar disposed through the photosensitive glass substrate. In addition, the AOG device may integrate one or more MIM capacitors and/or inductors that allow for RF filtering and impedance matching.

A windshield, vehicle and antenna assembly for the vehicle is disclosed. The antenna assembly includes an antenna and a signal coupler. The antenna is embedded within the windshield of the vehicle. The antenna is configured to receive signals over a first frequency band and a second frequency band separated from the first frequency band. The signal coupler electromagnetically couples to the antenna through the windshield.

A windshield, vehicle and antenna assembly for the vehicle is disclosed. The antenna assembly includes an antenna and a signal coupler. The antenna is embedded within the windshield of the vehicle. The antenna is configured to receive signals over a first frequency band and a second frequency band separated from the first frequency band. The signal coupler electromagnetically couples to the antenna through the windshield.

A light-transmitting antenna includes a substrate, a first and a second conductive pattern. The first and the second conductive pattern is disposed on a first and a second surface of the substrate respectively. The first conductive pattern includes a first feeder unit, a first and a second radiation unit, a first and a second coupling unit and a first parasitic unit. The first feeder unit is connected to the second radiation unit. The first and the second radiation unit are located between the first and the second coupling unit. One side and the other side of the first parasitic unit is connected to the second coupling unit and adjacent to the first coupling unit respectively. The second conductive pattern includes a second feeder unit, a third coupling unit, a second parasitic unit, and a fourth coupling unit.

A non-invasive communication apparatus for a vehicle comprising glass includes a power transfer coupler configured to wirelessly supply vehicle-generated power, via the glass, to an external antenna assembly mounted to the vehicle. The power transfer coupler comprises a substantially transparent transmit coil disposed on an inside surface of the glass and a substantially transparent receive coil disposed on an outside surface of the glass adjacent the transmit coil. One or more information transfer couplers are configured to wirelessly communicate information signals to and/or from the antenna assembly via the glass. Each of the information transfer couplers comprises a substantially transparent first coupler disposed on the inside surface of the glass and a substantially transparent second coupler disposed on the outside surface of the glass adjacent the first coupler.

A window glass for vehicle includes a glass plate; a dielectric body; and a conducting body arranged between the glass plate and the dielectric body. The conducting body includes a pair of feeding units; a first slot having a first open end that opens at an outer periphery of the conducting body, and extending from the first open end and through between the pair of feeding units; a second slot having a second open end that opens at the outer periphery of the conducting body, extending from the second open end, and being connected to the first slot; and a third slot having a non-open end that does not open at the outer periphery of the conducting body, extending from the non-open end, and being connected to the first slot and the second slot.

A window glass for a vehicle includes a glass plate; and a conductor placed on a surface of the glass plate. The conductor includes a conductive film and a strip electrode for applying a DC voltage to the conductive film. The strip electrode is formed to have a gap between the strip electrode and an outer edge of the conductive film, and is positioned between the outer edge of the conductive film and an outer edge of the glass plate in a plan view of the glass plate. The window glass for the vehicle includes a terminal part for electrically connecting the strip electrode to a transmission line.