A host vehicle is provided with a detection device that detects the behavior of an object in the surroundings of the host vehicle in a non-contact manner. The host vehicle is also provided with the following: a warning device that performs a warning operation pertaining to a warning directed at a following vehicle that is traveling behind the host vehicle; and a control device that controls the warning device on the basis of the result of detection by the detection device. The control device controls the warning device so as to perform the warning operation in a case where the result of detection by the detection device indicates that the behavior of an object in the surroundings of the host vehicle corresponds to an unnatural behavioral pattern.

The misalignment quantity calculating apparatus determines whether a first object detected by a beam sensor is identical to a second object detected by an image sensor. Upon determining that the first object is identical to the second object, the misalignment quantity calculating apparatus calculates, as a misalignment quantity of the beam sensor, an angle between a first line segment and a second line segment; the first line segment connects a predetermined reference point of the misalignment quantity calculating apparatus and a first feature point of the first object, and the second line segment connects the predetermined reference point and a second feature point of the second object.

A platooning control apparatus is provided and includes a processor that separates platooning vehicle groups and creates new platooning vehicle groups when a situation occurs that requires separating the platooning vehicle groups during platooning of a leading vehicle and following vehicles. A storage stores data and algorithms driven by the processor. When an obstacle is detected in the platooning vehicle groups, the process performs in-lane avoidance control by determining whether in-lane avoidance of the following vehicles traveling behind the obstacle is possible.

A vehicle control system and method for operating a host vehicle based on geographic location. The system includes a distance sensor, a location sensor, a user interface, and a controller including an electronic processor and a memory. The controller is communicatively coupled to the distance sensor, the location sensor, the speed control, and the user interface, and is configured to receive a distance signal from the distance sensor indicative of a distance between the host vehicle and another vehicle. The controller receives a location signal from the location sensor indicative of a location of the host vehicle and a control signal from the user interface indicative of a desired mode of operation of the vehicle control system. The controller performs a driver assistance function associated with the desired mode of operation and adjusts a tolerance of the driver assistance function based on the location of the host vehicle.

Embodiments disclosed herein relates to a radar device, and more particularly, to a radar device having a structure that reduces the influence of an internal reflected wave, which is capable of preventing a target sensing performance from being deteriorated by a reflected wave reflected within the radar device, while having a cover structure that is capable of protecting an antenna from the outside.

A method for an overtaking assistant for a vehicle is provided. The vehicle is equipped with environment sensing systems for detecting objects in the own and an adjacent lane on the sides and at the rear of the vehicle. The space in front of the vehicle is preferably detected by environmental sensors as well. Autonomous cutting into an adjacent lane is only initiated if a first vehicle is detected in the adjacent lane. The first vehicle is taken as a reference for a speed of vehicles in the passing lane. It is also assumed that a second vehicle that approaches the first vehicle fast in the same lane has detected the first vehicle and will adjust its speed to the speed of the first vehicle.

A vehicle control apparatus for implementing inter-vehicle distance control of a vehicle carrying the apparatus behind a preceding vehicle. In the apparatus, an offset storage is configured to calculate an offset that is a difference between detected distances to first and second targets, and store the offset associated with the first target forward of the second target. The inter-vehicle distance control may be implemented based on a distance calculated by subtracting the offset from the detected distance to the first target. An offset updater is configured to determine whether or not a relative distance between the first and second targets has increased or decreased, and when the relative distance between the first and second targets has increased or decreased, update the offset stored by the offset storage.

A pre-warning method utilized in a vehicle radar system is disclosed. The vehicle radar system includes a frequency-modulation continuous wave (FMCW) module, a data transceiver module and an antenna module, and the FMCW module and the data transceiver module share the antenna module. The pre-warning method includes the FMCW module utilizing the antenna to transmit and receive beat signals to detect dynamic information of a target corresponding to the vehicle radar system and obtain a first detection result, and receiving and broadcasting data to broadcast the first detection result via the data transceiver module and the antenna module, or receive a detection result broadcasted by another vehicle radar system and combine the detection result with the first detection result to perform real-time target tracking and alarm.

An unloading automation system for unloading of harvested crop from an agricultural vehicle, such as a combine harvester, into a container. The container may be part of a vehicle container combination that is arranged to maneuver next to the agricultural vehicle in the field. The unloading automation system includes a filling degree measurement system and position measurement system, wherein the position measurement is based on UWB technology. This non-optical technology improves measurement results in dusty environments. The filing degree measurement system and the position measurement system have at least one UWB tag or base station in common.

Disclosed aspects relate to transportation vehicle traffic management. A traffic controller detects a first traffic state parameter value for a first lane. In response to detecting the first traffic state parameter value, the traffic controller establishes a first broadcast of a first movement value (e.g., speed, acceleration, direction). The first movement value may indicate a first movement pattern for a first set of vehicles in the first lane. In response to establishing the first broadcast of the first movement value, the traffic controller detects a second traffic state parameter value for the first lane. In response to detecting the second traffic state parameter value the traffic controller modifies the first broadcast of the first movement value. The modified first movement value may indicate a second movement pattern for the first set of vehicles in the first lane.