An access system for a vehicle is provided and includes antennas and an access module. The antennas are configured to each receive a signal transmitted from a portable access device to the vehicle. One of the antennas is a circular polarized antenna. The access module is configured to: downconvert the received signal to generate an in-phase signal and a quadrature phase signal; execute a music algorithm to determine angles of arrival of the received signal as received at the antennas; determine a distance between the portable access device and the vehicle based on the angles of arrival; and permit access to the vehicle based on the distance.

A scanning antenna provided with an array of a plurality of antenna units includes a transmission and/or reception region including the plurality of antenna units, and a non-transmission and/or reception region other than the transmission and/or reception region. The scanning antenna includes a TFT substrate including a first dielectric substrate, a slot substrate including a second dielectric substrate and a slot electrode supported by a first main surface of the second dielectric substrate, a liquid crystal layer provided between the TFT substrate and the slot substrate, and a reflective conductive plate disposed facing a second main surface of the second dielectric substrate opposite to the first main surface with a dielectric layer interposed between the reflective conductive plate and the second main surface. Each of the plurality of antenna units includes a TFT supported by the first dielectric substrate, a patch electrode electrically connected to a drain of the TFT, and a slot formed in the slot electrode corresponding to the patch electrode. The slot substrate further includes a first insulating layer provided between the second dielectric substrate and the slot electrode. The slot electrode has a tensile stress and the first insulating layer has compressive stress. When viewed from a normal direction of the second dielectric substrate, a portion of the slot substrate that does not include the slot electrode includes at least one first region exposing the second dielectric substrate from the first insulating layer and/or at least one second region having a thickness of the first insulating layer that is less than a thickness of a portion of the first insulating layer overlapping the slot electrode. When viewed from the normal direction of the second dielectric substrate, the at least one first region or the at least one second region includes at least a portion of an end of the second dielectric substrate.

A scanning antenna provided with an array of a plurality of antenna units includes a transmission and/or reception region including the plurality of antenna units, and a non-transmission and/or reception region other than the transmission and/or reception region. The scanning antenna includes a TFT substrate including a first dielectric substrate, a slot substrate including a second dielectric substrate and a slot electrode supported by a first main surface of the second dielectric substrate, a liquid crystal layer provided between the TFT substrate and the slot substrate, and a reflective conductive plate disposed facing a second main surface of the second dielectric substrate opposite to the first main surface with a dielectric layer interposed between the reflective conductive plate and the second main surface. Each of the plurality of antenna units includes a TFT supported by the first dielectric substrate, a patch electrode electrically connected to a drain of the TFT, and a slot formed in the slot electrode corresponding to the patch electrode. The slot substrate further includes a first insulating layer provided between the second dielectric substrate and the slot electrode. The slot electrode has a tensile stress and the first insulating layer has compressive stress. When viewed from a normal direction of the second dielectric substrate, a portion of the slot substrate that does not include the slot electrode includes at least one first region exposing the second dielectric substrate from the first insulating layer and/or at least one second region having a thickness of the first insulating layer that is less than a thickness of a portion of the first insulating layer overlapping the slot electrode. When viewed from the normal direction of the second dielectric substrate, the at least one first region or the at least one second region includes at least a portion of an end of the second dielectric substrate.

This document describes a waveguide with radiation slots and parasitic elements for asymmetrical coverage. An apparatus may include a waveguide for providing asymmetrical coverage in an azimuth plane. The waveguide includes a hollow channel containing a dielectric and an array of radiation slots through a surface that is operably connected with the dielectric. The waveguide includes an array of parasitic elements positioned on or in the surface and offset from a longitudinal side of the array of radiation slots. The radiation slots and parasitic elements configure the described waveguide to focus an antenna radiation pattern that provides an asymmetrical coverage to focus on a particular portion within the antenna field-of-view.

Antenna array and phased array system including a first and second antenna group, wherein the first antenna group includes two or more first antennas, and the second antenna group includes two or more second antennas, where in a first plane the one or more first and second antennas point in the same direction, and in a second plane, perpendicular to the first plane the one or more first antennas of the first antenna group are squinted by orientation away from the one or more second antennas of the second antenna group.

Antenna array and phased array system including a first and second antenna group, wherein the first antenna group includes two or more first antennas, and the second antenna group includes two or more second antennas, where in a first plane the one or more first and second antennas point in the same direction, and in a second plane, perpendicular to the first plane the one or more first antennas of the first antenna group are squinted by orientation away from the one or more second antennas of the second antenna group.

Devices for mitigating or stopping noise or surface current on a display are provided. An electronic device including a display may include a display substrate, a mid-support plate that is adjacent to the display substrate, and a lower support plate that is adjacent to the mid-support plate. A space exists between the mid-support plate and the lower support plate. The mid-support plate includes one or more electromagnetic band gap (EBG) structures formed through the mid-support plate, one or more electromagnetic band gap structures mounted onto the mid-support plate, or both. The one or more electromagnetic band gap structures may mitigate or stop surface current flow across the display.

An antenna pane includes an electrically insulating substrate, an electrically conductive functional layer on a surface of the substrate, and an antenna structure, which includes an electrically conductive antenna layer for receiving and/or transmitting high-frequency antenna signals, the antenna layer being galvanically separated from the functional layer, wherein a high-frequency technical resistance between the antenna layer and the functional layer for high-frequency antenna signals is at least 10 ohm, wherein the antenna layer has a first connection region and the functional layer has a second connection region, and an insulating line that electrically divides the functional layer into a first and second functional layer zone that are galvanically separated from one another, but are coupled using high-frequency technology such that a high-frequency technical resistance for high-frequency antenna signals is less than 1 ohm, wherein the second connection region is contained in the second functional layer zone.

An antenna module includes a hollow cylindrical conductor structure. The hollow cylindrical conductor structure includes a cylinder wall, at least one first slot, and a first feed point. The at least one first slot and the first feed point are located on the cylinder wall. The cylinder wall includes a first end edge and a second end edge opposite to each other. The at least one first slot extends from an internal position of the cylinder wall to the first end edge, and forms a first closed path together with the first end edge. The first feed point is located beside the at least one first slot. The antenna module is adapted to excite a first frequency band through the first closed path.

An antenna module includes a hollow cylindrical conductor structure. The hollow cylindrical conductor structure includes a cylinder wall, at least one first slot, and a first feed point. The at least one first slot and the first feed point are located on the cylinder wall. The cylinder wall includes a first end edge and a second end edge opposite to each other. The at least one first slot extends from an internal position of the cylinder wall to the first end edge, and forms a first closed path together with the first end edge. The first feed point is located beside the at least one first slot. The antenna module is adapted to excite a first frequency band through the first closed path.