An assortment of radar sensors in different variant embodiments. Each radar sensor has: a housing terminated by a radome, a circuit board that is equipped on the side facing away from the radome with at least one radio-frequency module, and an antenna structure on the side of the circuit board facing the radome. The housing is realized identically in all variant embodiments. The antenna structure has a planar antenna structure in at least one variant embodiment, and has a hollow conductor structure in at least one variant embodiment.

An assortment of radar sensors in different variant embodiments. Each radar sensor has: a housing terminated by a radome, a circuit board that is equipped on the side facing away from the radome with at least one radio-frequency module, and an antenna structure on the side of the circuit board facing the radome. The housing is realized identically in all variant embodiments. The antenna structure has a planar antenna structure in at least one variant embodiment, and has a hollow conductor structure in at least one variant embodiment.

A radar device comprising: a printed circuit board (120), PCB, comprising a ground plane (1202), a radar sensor chip package (130) mounted on the PCB (120) and comprising a mm Wave radio frequency, RF, integrated circuit (1302) and a planar antenna structure (1304) configured as an antenna-in-package and oriented in a plane parallel to the ground plane (1202), wherein the mmWave RF integrated circuit (1302) is configured to output a mmWave signal (1360) to be transmitted by the planar antenna structure (1304), and a cavity (140), wherein the radar sensor chip package (130) is arranged in the cavity (140), the cavity (140) having an open side (1402), and the cavity (140) being defined by a conductive rear wall surface (1404) opposite the open side (1402), a pair of mutually opposite and conductive sidewall surfaces (1406), a conductive top surface (1408), and a conductive bottom surface (1410), wherein at least a portion of the conductive bottom surface (1410) is formed by at least a portion of the ground plane (1202) of the PCB (120), and wherein the sidewall surfaces, the top surface, and the bottom surfaces (1406, 1408,1410) each extends from the rear wall surface (1404) towards the open side (1402) of the cavity (140).

The disclosure relates to a radar arrangement for a motor vehicle, comprising at least one radar sensor with at least one antenna arrangement, wherein at least two antenna arrangements are arranged at a distance defined in an arrangement direction on a carrier component, which is permeable in particular to radar radiation, of the motor vehicle, and wherein the radar arrangement has a control device for common transmission and reception operation of the at least two antenna arrangements, such that these have the effect of a single virtual antenna arrangement with increased antenna extension in the arrangement direction.

The disclosure relates to a radar arrangement for a motor vehicle, comprising at least one radar sensor with at least one antenna arrangement, wherein at least two antenna arrangements are arranged at a distance defined in an arrangement direction on a carrier component, which is permeable in particular to radar radiation, of the motor vehicle, and wherein the radar arrangement has a control device for common transmission and reception operation of the at least two antenna arrangements, such that these have the effect of a single virtual antenna arrangement with increased antenna extension in the arrangement direction.

An antenna module includes an inner circuit board, an antenna circuit board, an outer circuit board, and at least one chip. The inner circuit board includes at least one inner wiring layer and at least one inner dielectric layer. The antenna circuit board includes at least one antenna structure. The antenna circuit board and the outer circuit board are disposed on opposite sides of the inner circuit board. The inner wiring layer comprises at least one inner pad. At least one first opening passing through the outer circuit board is defined to expose the inner pad. Each chip is received in one first opening and electrically connects to the inner pad. The antenna structure electrically connects to the chip through the inner wiring layer. A method for manufacturing such antenna module is also provided.

An antenna module includes an inner circuit board, an antenna circuit board, an outer circuit board, and at least one chip. The inner circuit board includes at least one inner wiring layer and at least one inner dielectric layer. The antenna circuit board includes at least one antenna structure. The antenna circuit board and the outer circuit board are disposed on opposite sides of the inner circuit board. The inner wiring layer comprises at least one inner pad. At least one first opening passing through the outer circuit board is defined to expose the inner pad. Each chip is received in one first opening and electrically connects to the inner pad. The antenna structure electrically connects to the chip through the inner wiring layer. A method for manufacturing such antenna module is also provided.

Disclosed is an antenna device that includes a capacitor element, a first coil, a second coil, and a capacitor. One end of the first coil is connected to a feeding point and another end of the first coil is connected to the capacitor element. One end of the second coil is connected to the capacitor element. One end of the capacitor is connected to the second coil and another end of the capacitor is connected to a grounding point.

The present disclosure describes strand mounts for small cell radios. The strand mount includes a frame including opposing frame sections, each frame section is configured such that one or more radios and/or antennas can be mounted to an outer surface of the respective frame section and extend outwardly therefrom, an extension member coupled to an end of the frame and configured such that one or more radios and/or antennas can be mounted thereto, the extension member being configured to rotate to a desired angle relative to the frame to achieve a desired azimuth, and one or more mounting clamps coupled to the frame, the one or more mounting clamps being configured to secure the strand mount on a cable strand. Alternative strand mounts and strand mount assemblies are also described.

The present disclosure describes strand mounts for small cell radios. The strand mount includes a frame including opposing frame sections, each frame section is configured such that one or more radios and/or antennas can be mounted to an outer surface of the respective frame section and extend outwardly therefrom, an extension member coupled to an end of the frame and configured such that one or more radios and/or antennas can be mounted thereto, the extension member being configured to rotate to a desired angle relative to the frame to achieve a desired azimuth, and one or more mounting clamps coupled to the frame, the one or more mounting clamps being configured to secure the strand mount on a cable strand. Alternative strand mounts and strand mount assemblies are also described.