A device for detecting an object conveyed through a measuring region comprises a transmission apparatus configured to emit measuring radiation onto the outer contour of the object. The measuring radiation comprises a frequency in a range of one of gigahertz and terahertz. A protective mesh is positioned between the measuring region and at least one of the transmission apparatus and the receiving apparatus. The protective mesh is transparent for the measuring radiation and permeable to as gas.

A concealed radar imaging system includes a visible light mirror, a radar device positioned behind the visible light mirror, and a processing circuit coupled to the radar device. The visible light mirror includes a reflective layer configured to reflect visible light, and allow a radar signal to pass therethrough. The radar device is configured to transmit the radar signal, receive a reflection of the radar signal, and generate reflection data based on the reflected radar signal. The processing circuit is configured to control operation of the radar device, receive the reflection data from the radar device, and generate imaging data based on the transmitted radar signal and the reflection data.

A vehicle, to which a vehicle upper portion structure is applied, has: a peripheral information detecting sensor that is mounted to a vehicle upper portion, and that has a detecting section that obtains peripheral information of the vehicle by detecting a detection medium; and a roof panel that covers the peripheral information detecting sensor from a vehicle upper side, and at which at least a region, that faces the detecting section, is formed of a material that transmits the detection medium therethrough.

The image capture and obstacle detection assembly comprises a support device intended to be mounted on a platform, for example a drone, an image capture unit comprising at least one camera for capturing images and an obstacle detection unit comprising at least one obstacle sensor, the image capture unit and the obstacle detection unit being carried by the support device, the support device being configured such that the image capture unit is rotatable about at least one rotation axis and the obstacle detection unit is rotatable about at least one rotation axis.

Multiple sensing network units are deployed in a venue. Each unit includes an overhead housing, and supports a plurality of electrically-powered sensor modules for sensing targets in the venue, and for generating target data indicative of the targets. Each unit preferably also includes a network communications module. Each module is interchangeably mounted in the housing. A power and data distribution system transmits network control data and electrical power to the sensor modules, and transmits the target data away from the sensor modules.

A vehicle exterior part is configured to be arranged frontward of a millimeter wave radar device with respect to the transmission direction of millimeter waves. The vehicle exterior part includes an ornamental body, a light source that emits light, and a light diffuse reflection member. The light diffuse reflection member is millimeter wave-transmissive and diffuses and reflects light. The ornamental body includes a base and an ornamental layer. The base is millimeter wave-transmissive and diffuses and transmits the light. The ornamental layer is millimeter wave-transmissive and arranged frontward of the base with respect to the transmission direction. The light source, the ornamental body, and the light diffuse reflection member are arranged so that the light emitted from the light source is diffused and reflected by the light diffuse reflection member and directed toward the base.

This technology relates to a system for preventing particle buildup on a sensor housing. The system may include a sensor housing including a first surface, a motor, and a spoiler edge. The motor may be configured to rotate the sensor housing around an axis. The spoiler edge may be positioned adjacent to the first surface and extended away from the first surface perpendicular to the axis of rotation of the sensor housing.

A roof module for forming a vehicle roof on a motor vehicle, the roof module having a panel component whose outer surface at least partially forms the roof skin of the vehicle roof, the roof module having at least one environment sensor configured to send and/or receive electromagnetic signals for detecting the vehicle surroundings. The environment sensor can be disposed below the roof skin formed by the panel component, the roof module having at least one support module, and at least two environment sensors being jointly mounted on the support module.

There is provided a radar apparatus comprising: a substrate; multiple antenna elements mounted on the substrate; and a signal-coupling suppressor disposed between the multiple antenna elements.

A level measurement device for measuring a level (L) of a product, in particular a product contained in a container, comprising: mounting means for mounting said measurement device at a measurement site, an antenna comprising a dielectric antenna element for transmitting microwave signals (S) towards the product and/or for receiving echo signals (R) resulting from reflections of the transmitted microwave signals, and measurement electronics for determining the level (L) of the product based on a transit time needed for the microwave signals to travel to a surface of the product and of their echo signals to return to the device, is described allowing to prevent deposits to build up, which may eventually impair transmission and/or reception of the signals. To this extent, the measurement device according to the invention comprises a cap covering said dielectric antenna element and cleaning means for cleaning said cap are foreseen, which cause said cap to vibrate when they are activated.