A vehicle is disclosed that includes a vehicle body and at least one sensor assembly that is supported on the vehicle body. The at least one sensor assembly is configured to detect an external object and includes a housing portion and a sensor that is supported within the housing portion such that the sensor is oriented at a fixed (e.g., downward) angle.

Disclosed is a pedestrian collision determination system including a collision detection sensor and a control unit, the collision detection sensor including a conductive pattern disposed on a front surface of a shock absorber of a vehicle bumper to form an electromagnetic field by an application of alternating current power and a conductive material disposed at a position facing the conductive pattern on an inner surface of a bumper skin of the vehicle bumper, and the control unit determining an occurrence or non-occurrence of a collision of a pedestrian based on a change of a current flowing in the conductive pattern.

A component arrangement includes a carrier element, a first component element connected to the carrier element by a first latching connection, and a second component element connected to the first component element by a second latching connection. The first latching connection includes a first latching hook and the second latching connection includes a second latching hook. The second latching hook engages form-fittingly around the first latching hook to provide the second latching connection.

A sensor installation structure includes: a sensor that has a sensing portion that senses periphery information of a vehicle; an exterior member having an opening portion that exposes the sensing portion, the opening portion being configured so as to allow changes in an angle of the sensing portion; and a cover member that is provided at an outer edge portion of the sensing portion, the cover member covering a gap between the outer edge portion of the sensing portion and a peripheral edge portion of the opening portion such that the gap cannot be seen from an exterior.

A vehicle body front structure has: an object detection device disposed in a vehicle front end section of a vehicle to detect an object ahead of the vehicle; and a pair of bracket members which are spaced apart from each other in a vehicle width direction and which support the object detection device. Each of the pair of bracket members includes: a forwardly extending portion that extends forward from a vehicle body member; and a downwardly extending portion that extends downward from the forwardly extending portion and supports the object detection device. The vehicle body front structure further has a bracket member locking member which couples the forwardly extending portions to each other in the vehicle width direction and to which an exterior member of the vehicle is attached.

A vehicular apron system is provided. The vehicular apron is dimensioned and adapted to extend the length of a door of the vehicle at its outward-most portion, thereby absorbing damage that would otherwise be imparted into the underlying door. The bellow elements have accordion sidewalls which facilitates their movement between a uninflated condition and an expanded condition for absorbing impact. The LIDAR situational awareness functionality is operatively associated with the inflation valves fluidly coupled to the bellow elements, wherein these bellow elements are automatically urged to an expanded condition in response to an object within the vicinity of the vehicle. The LIDAR situational awareness functionality provides video output to be used as evidence in cases of theft or contested accidents.

An object detection apparatus applied to a vehicle having a sensor unit mounted on a predetermined member provided to the vehicle, the sensor unit being provided with an object detection sensor that detects position information of an object present around the vehicle and a tilt sensor that detects a tilt angle as inclination with respect to a predetermined direction, and performing a process of detecting the object based on the position information of the object detected by the object detection sensor, the object detection apparatus comprising a detachment state determination section that determines a detachment state of the predetermined member based on the tilt angle detected by the tilt sensor.

Vehicle sensor systems include modular sensor kits having one or more pods (e.g., sensor roof pods) and/or one or more bumpers (e.g., sensor bumpers). The sensor roof pods are configured to couple to a vehicle. A sensor roof pod may be positioned atop a vehicle proximate a front of the vehicle, proximate a back of the vehicle, or at any position along a top side of the vehicle being coupled, for example, using a mounting shim or a tripod. The sensor roof pods can include sensors (e.g., LIDAR sensors, cameras, ultrasonic sensors, etc.), processing units, control systems (e.g., temperature and/or environmental control systems), and communication devices (e.g., networking and/or wireless devices).

Provided is an energy absorption member including a plate shaped rear wall portion which extends in a vehicle width direction; and an extension wall portion that extends in the vehicle width direction and extends forward from an intermediate part in a height direction of the rear wall portion; wherein the rear wall portion takes on an arch shape that projects forward in a plan view, and the extension wall portion is inclined downward or upward from its rear end part toward its front end part.

An autonomous robot vehicle in accordance with aspects of the present disclosure includes a land vehicle conveyance system, a sensor system configured to capture information including surrounding environment information and/or vehicle subsystem information, a communication system configured to communicate with a remote human operator management system, at least one processor, and a memory storing instructions. The instructions, when executed by the processor(s), cause the autonomous robot land vehicle to, autonomously, determine based on the captured information to request a remote human operator, and communicate a request to the remote human operator management system for a remote human operator to assume control of the land vehicle conveyance system, where the request includes at least a portion of the captured information.