A control system (1) for letting a vehicle travel by automatic steering is a system which includes a vehicle control part (112) which controls the vehicle so that a subject point set for the vehicle passes through a predetermined route, a subject-point selection processing part (113) which selects a subject point, and a subject-point updating processing part (114) which updates the subject point as a control subject as appropriate by setting the subject point newly selected by the subject-point selection processing part (113) as the control subject, and a highly-versatile system capable of automatic steering irrespective of the type of the vehicle or the shape of the route.

When an external detection device detects an obstacle (another vehicle (T)) on either a left or right side of the own vehicle (M), a control device of a steering assistance device for a saddle type vehicle controls an assist torque so that a handle operation to the side opposite to the side on which the obstacle is detected becomes heavier (more difficult to turn) than a case in which the obstacle is not detected. The handle operation to the side on which the obstacle is detected makes a handle relatively light (makes it easier to turn) while steering assist is maintained.

The present application generally relates to a method and apparatus for controlling an autonomous vehicle. In particular, the method and apparatus are operative for detecting, by a sensor, an object within a first vehicle path, generating, by a processor, a second vehicle path in response to either the detection of the object such that the second vehicle path avoids the object, or a user initiated trajectory shift, generating, by the processor, an initial steering torque in response to the second vehicle path, performing, by the processor, an adaptation on the initial steering torque to generate an adapted steering torque in response to the initial steering torque exceeding a torque rate limit, and controlling, by a vehicle controller a host vehicle steering system to follow the second vehicle signal path in response to the adapted steering torque.

A vehicular collision avoidance system includes a forward-viewing camera viewing through the windshield at least forward of the equipped vehicle, a rearward-sensing radar sensor sensing at least rearward of the equipped vehicle, and an electronic control unit. The vehicular collision avoidance system detects vehicles present forward and/or rearward of the equipped vehicle. Responsive to data processing of radar data captured by the rearward-sensing radar sensor, the vehicular collision avoidance system detects another vehicle approaching the equipped vehicle from the rear, determines distance between the equipped vehicle and the other vehicle, and determines speed difference between the equipped vehicle and the other vehicle. Based at least in part on the determined distance between the equipped vehicle and the other vehicle and the determined speed difference between the equipped vehicle and the other vehicle, the vehicular collision avoidance system controls the equipped vehicle to mitigate impact by the other vehicle.

Systems, methods, and other embodiments described herein relate to keeping a vehicle within a safety envelope. In one embodiment, a method includes determining a safety envelope having a boundary, determining a risk level for an environment surrounding the vehicle, and associating a torque value with a location within the safety envelope based on at least one of the risk level, a lateral velocity of the vehicle, and a relationship between the location and the boundary. The method includes, in response to the vehicle being located at the location and a torque being applied to a steering wheel of the vehicle, applying a counter torque of the torque value to the steering wheel.

The present disclosure relates to a steering control apparatus and a method. More specifically, the steering control apparatus according to the present disclosure includes: a receiver that receives first vehicle traveling information and first vehicle vicinity information of a host vehicle from a plurality of sensors and a navigator; and a controller that sets a monitoring range (a region of interest (ROI)) on a traveling path on which the host vehicle is predicted to travel based on the first vehicle traveling information and the first vehicle vicinity information, determines a possibility of a collision between the host vehicle and an object in a case where the object is detected inside the monitoring range, and generates a control signal used for avoiding a collision with the object in a case where the possibility of the collision is a threshold point or higher.

A method for operating a steering system of a vehicle, wherein an actuator is provided for generating a moment at a steering handle of the vehicle, wherein the following steps are carried out: generating the moment up to a maximum moment if the maximum moment is enabled, and up to a lower limited moment if the maximum moment is limited, identifying a vehicle situation of the vehicle, enabling the maximum moment if the vehicle situation is identified as being a boarding and/or deboarding situation in order to brace the steering handle, and limiting the maximum moment if the vehicle situation is identified as being driving operation of the vehicle.

A vehicle control system includes a controller circuit in communication with a steering sensor and one or more perception sensors. The steering sensor is configured to detect a steering torque of a steering wheel of a host vehicle. The one or more perception sensors are configured to detect an environment proximate the host vehicle. The controller circuit is configured to determine when an operator of the host vehicle requests a take-over from fully automated control of the host vehicle based on the steering sensor. The controller circuit classifies the take-over request based on the steering sensor.

A trailer sideswipe avoidance system for a vehicle towing a trailer is disclosed. The trailer sideswipe avoidance system includes a sensor system configured to detect objects in an operating environment of the vehicle. The trailer sideswipe avoidance system may include a controller that processes information received from the sensor system to determine whether the object detected in the operating environment of the vehicle is in the travel path of the towed trailer. A visual display displays a trailer collision alert zone and a trailer collision avoidance zone. The position of the trailer collision avoidance zone on the visual display relative to the position of the trailer collision alert zone on the visual display directionally corresponds with a collision avoidance steering angle of the vehicle relative to a current steering angle of the vehicle when the controller determines that the object is in the travel path of the towed trailer.

Embodiments for assisting steering of a vehicle responsive to detecting an object in a proximity of a vehicle are described. Embodiments described include: receiving an image of a lane indicator corresponding to a lane of travel of the vehicle from an image capturing device; determining, based on the image, reference values corresponding to a position of the lane indicator relative to the vehicle; associating each of the reference values to values used to locate a point within a reference frame related to a direction the vehicle is traveling; receiving position information of an object in an environment external to the vehicle from a radar sensor; determining, based on the values and the position information, an assigned lane of the object; detecting an impending change of the lane of travel of the vehicle to the assigned lane of the object; generating a steering control value based on the impending change.