Generally, the present disclosure relates to a forward deployed sensor system or, in a specific embodiment, a forward deployed radar (FDR) system. The forward deployed sensor system includes a radar system and may also include other types of sensors such as optical sensors, acoustic sensors including sonar, and electromagnetic sensors. Further, the forward deployed sensor system may also include a communication system such as a full spectrum receiver/transmitter, a ship to ship relay transponder, a satellite communication system, and global positioning system (GPS) capability. The forward deployed sensor system is able to detect objects in the air, on the sea, and underwater, and communicate such detection to a ship, submarine, aircraft, satellite, or other remote location. Such systems may be used to augment the protection of shipping lanes by military or security forces to allow for peaceful commerce and utility of the sea by all nations.

A system including a polarized RF scanning reference source and one or more cavity sensor receivers.

The disclosure relates to a method for processing information based on radar waves, applied to a first terminal. The method includes: a first radar signal sent by a second terminal is received during an event; and identification information of a user to which the second terminal belongs is acquired based on the first radar signal.

A radar device for a vehicle, according to an embodiment of the present invention, comprises: a case; a first printed circuit board (PCB) that is accommodated in the case and has a plurality of antenna arrays and an integrated circuit (IC) chip that are formed thereon, wherein the IC chip is connected to the plurality of antenna arrays; and a radome that is coupled to the case and covers the first printed circuit board, wherein the radome includes: a cover facing the first printed circuit board; a first wall connected to the cover surface; and a second wall connected to the cover and facing the first wall, wherein the internal angle between the cover and the first wall and the internal angle between the cover and the second wall are formed to be greater than 90° and less than 180°.

Embodiments of this application provide a signal processing method and apparatus, and a storage medium, applied to the radar field. One example method includes: performing channel listening based on a first signal and a second signal, and determining, based on a result of the channel listening, a first time-frequency resource for target detection, where the channel listening includes performing channel listening based on a first listening signal in a first time domain range and performing channel listening based on a second listening signal in a second time domain range, and a time domain resource of the first time-frequency resource is the first time domain range.

A radar system that can block false echoes includes: a local oscillator configured to generate a chirp signal comprising a plurality of chirps, each having a corresponding envelope; a transmitter configured to transmit a signal corresponding to the chirp signal; and a modulation circuit configured to modulate the transmitted signal by regulating a magnitude of one or more portions of the chirp envelopes in a predetermined pattern such that the radar system can discern false echoes which do not match the pattern.

A measurement device according to the present disclosure includes a memory and a processor coupled to the memory. The processor is configured to: transmit a distance-detecting radiowave from an antenna; detect a distance between the antenna and a vehicle based on a first reception radiowave received by the antenna, the first reception radiowave being a reception radiowave obtained by the antenna receiving a reflected wave of a distance-detecting radiowave reflected by the vehicle on which a communication system configured to transmit a measurement target radiowave is mounted; perform drive control on at least one of the antenna and the vehicle so that the detected distance reaches a set distance larger than 0; and derive, when the detected distance reaches the set distance, communication performance of the communication system based on a second reception radiowave that is the measurement target radiowave received by the antenna.

A measurement device according to the present disclosure includes a memory and a processor coupled to the memory. The processor is configured to: transmit a distance-detecting radiowave from an antenna; detect a distance between the antenna and a vehicle based on a first reception radiowave received by the antenna, the first reception radiowave being a reception radiowave obtained by the antenna receiving a reflected wave of a distance-detecting radiowave reflected by the vehicle on which a communication system configured to transmit a measurement target radiowave is mounted; perform drive control on at least one of the antenna and the vehicle so that the detected distance reaches a set distance larger than 0; and derive, when the detected distance reaches the set distance, communication performance of the communication system based on a second reception radiowave that is the measurement target radiowave received by the antenna.

A sensor unit for a vehicle includes an external sensor, a cleaning nozzle and a housing. The external sensor is configured to obtain information of an external environment, and to have a sensing area being set forward in a travel direction of the vehicle through an exposed surface exposed to the external environment. The cleaning nozzle has an injection port that is located in front of the exposed surface to inject a cleaning fluid to the exposed surface from above of the exposed surface in a yaw axis direction of the vehicle to clean the exposed surface. The housing is provided to hold the external sensor therein. The housing is configured to define a recess that is recessed toward a rearward in the travel direction from the exposed surface below the exposed surface in the yaw axis direction.

The present disclosure is directed to processing data associated with a non-radar type sensing device to identify data points associated with a radar type sensing device that are likely secondary radar reflections such that a processor of a sensing apparatus can direct processing resources to processing radar data that are associated with primary radar reflections. The receipt of secondary radar reflections may cause a processor of a sensing apparatus to identify that an object is located at a location when there is no object in that location. Because of this, methods and apparatus of the present disclosure identify and avoid processing radar data that are likely to be associated with a object that does not exist. Eliminating false radar data, therefore, can prevent a processor of a sensing apparats from performing unnecessary processing tasks and can help prevent that processor from making false determinations.