A system for closest in path vehicle following using surrounding vehicles motion flow is provided and includes a sensor device of a host vehicle generating data related to vehicles upon a drivable surface. The system further includes a navigation controller including a computerized processor operable to monitor the data from the sensor device, define a portion of the plurality of vehicles as a swarm of vehicles, identify one of the plurality of vehicles as a closest in path vehicle to be followed, evaluate the data to determine whether the closest in path vehicle to be followed is exhibiting good behavior in relation to the swarm of vehicles, and, when the closest in path vehicle to be followed is exhibiting the good behavior, generate a breadcrumbing navigation path based upon the data. The system further includes a vehicle controller controlling the host vehicle based upon the breadcrumbing navigation path.

A moving body control apparatus includes a cancel control section performing control to cancel a lane change when a first cancel condition and a second cancel condition for cancelling the lane change are satisfied. When the first cancel condition is satisfied with the grip of an occupant on a manipulator being a prescribed level or greater, if a distance in a vehicle width direction between a moving body and a lane marker is a first distance threshold value or greater, the cancel control section judges that the second cancel condition is satisfied and cancels the lane change, and when the first cancel condition is satisfied with the grip being less than the prescribed level, if the distance is not less than a second distance threshold value greater than the first distance threshold value, the cancel control section judges that the second cancel condition is satisfied and cancels the lane change.

The present invention provides a saddle ride type vehicle including a sensing unit configured to sense a four-wheel vehicle that is present in front of a self-vehicle and is traveling in a travel lane of the self-vehicle, and a control unit configured to, in a case where the four-wheel vehicle is sensed by the sensing unit, perform follow-travel control for causing traveling of the self-vehicle to follow traveling of the four-wheel vehicle, wherein the sensing unit senses a vehicle width of the four-wheel vehicle, and the control unit, in the follow-travel control, controls a travel position in a vehicle width direction of the self-vehicle so that at least a portion of the self-vehicle falls within a region within the vehicle width of the four-wheel vehicle.

A vehicle control method for controlling a vehicle using a vehicle control apparatus includes: a sensor configured to detect a state outside a subject vehicle; and a control device. The vehicle control method includes: executing control of recovering a travel trajectory of the subject vehicle to a target trajectory, as ordinary control, by giving a steering amount in a lateral direction with respect to a travel lane of the subject vehicle; using detection data of the sensor to determine whether or not another vehicle is traveling in an adjacent lane to the travel lane of the subject vehicle; and when determining that the other vehicle is traveling in the adjacent lane ahead of the subject vehicle, increasing a response of the steering amount to a higher response than that in the ordinary control, before the subject vehicle passes the other vehicle.

A first distance d.sub.1 between a vehicle at a first location and an object is determined. A best fit line representing the object is determined from a plurality of sensor data. A distance Δd to move to a second location is specified. A predicted second distance d.sub.p between the vehicle at the second location and the object is determined based on the first distance d.sub.1, the distance Δd, and the best fit line. The vehicle is operated from the first location to the second location based on a center steering wheel angle. A measured second distance d.sub.2 between the vehicle at the second location and object is determined. Then the center steering wheel angle is one of (a) maintained based on the predicted second distance d.sub.p matching the measured second distance d.sub.2, or (b) updated based on the predicted second distance d.sub.p being different than the measured second distance d.sub.2.

The driving support control device is configured to, when a preceding vehicle is detected (S24: YES), be permitted to cause a transition to the preceding vehicle following mode, in response to a manipulation made by the driver to select the preceding vehicle following mode (S27), and then control the vehicle 1 to follow the preceding vehicle, and to, when edges of a traveling road are detected even though no preceding vehicle is detected (S25: YES), be permitted to cause the transition to the preceding vehicle following mode, in response to the manipulation made by the driver to select the preceding vehicle following mode (S26), and then control the vehicle 1 to travel on and along a given target traveling course set based on the edges of the traveling road.

A control unit is provided for an ego vehicle equipped with a transverse guidance actuator which is designed to transversely guide the ego vehicle in an at least partly automated manner during a follow-on drive. The control unit is designed to detect a transverse guidance maneuver of the ego vehicle required for the follow-on drive. The control unit is additionally designed to ascertain driver information with respect to the driver of the ego vehicle, the driver information including at least one indication of how engaged the driver is with monitoring and/or carrying out the transverse guidance of the ego vehicle. The control unit is further designed to set a dynamic of an intervention, which is automatically carried out by the transverse guidance actuator of the ego vehicle, for the transverse guidance maneuver on the basis of the ascertained driver information.

The invention relates to a method for guiding a vehicle (1) during reversing along a desired travelling path (TP), wherein the guiding is based on a lateral offset (y) between a preview point (P) located at a preview distance (Pd) behind the vehicle (1) and the desired travelling path (TP), the method comprising: determining (S1) a curvature of the desired travelling path (TP) behind the vehicle (1); adaptively adjusting (S2) the preview distance (Pd) in dependence on the determined curvature, thereby adaptively adjusting the preview point (P); and guiding (S3) the vehicle (1) along the desired travelling path (TP) by use of the lateral offset (y) between the adjusted preview point (P) and the desired travelling path (TP). The present invention further relates to a control unit (100), to a vehicle (1), to a computer program and to a computer readable medium.

The invention relates to a method for a follower vehicle (2) following a lead vehicle, comprising—determining a position (PL) and a heading (HL) of the lead vehicle (1), —determining a position (PF) and a heading (HF) of the follower vehicle (2), —subsequently establishing a path for the follower vehicle (2) by fitting a curve (C1) to said positions (PL, PF) and said headings (HL, HF), —and controlling the follower vehicle (2) so as to move along the established path.

Techniques for using ball joint sensor data to determine conditions relevant to a vehicle are described in this disclosure. For example, in one example, the ball joint sensor data may be used to determine estimated steering data. The estimated steering data may be directly used to navigate through an environment, such as by the vehicle relying on the estimated steering data when planning, tracking, or executing a driving maneuver. Also, the estimated steering data may be used to verify the reliability of other steering sensor data used to navigate through the environment.