A reference vehicle is identified from data measuring changes in steering wheel angles of a plurality of vehicles. A target vehicle's steering wheel angle deviations is compared to steering wheel angle deviations of the reference vehicle A target vehicle component is actuated upon determining that a difference of the target vehicle's change of steering wheel angle and the reference vehicle's change of steering wheel angle exceeds a predetermined threshold.

An apparatus for assisting driving of a host vehicle provides stable control of the host vehicle by using road conditions including intersections, crosswalks and the like, forward lane markings, and a preceding vehicle. The apparatus includes an image sensor to capture images of an area in front of the host vehicle, and a controller configured to recognize a road section having no lane markings on a drive path, or recognize forward lane markings. The controller performs lateral control of the host vehicle selectively based on the forward lane markings and the recognized preceding vehicle according to whether the road section having no lane markings is recognized.

A driving assist device comprises an electronic control unit configured to: acquire a vehicle present position that is a position at which a vehicle is present; calculate a positional relationship between a lane increase-decrease area and the vehicle, based on the lane increase-decrease area position and a vehicle present position; cause a human machine interface to output information about the lane increase-decrease area when a positional relationship is determined to satisfy a predetermined condition; acquire information about a traveling lane in which the vehicle is traveling; and cause the human machine interface to vary a way to output a information, based on whether or not the lane including the lane increase-decrease area and the traveling lane coincide with each other.

A driving support ECU retains an already-present traveling trajectory of a first vehicle to determine a target traveling line based on the retained already-present traveling trajectory during a specific period. When a specific situation occurs in the specific period, the driving support ECU produces a traveling trajectory of the first vehicle in such a manner that the traveling trajectory of the first vehicle is continuous with the already-present traveling trajectory based on position information of the first vehicle and the retained traveling trajectory to determine the target traveling line based on the produced traveling trajectory.

A driving support apparatus for an own vehicle includes a lane keeping assist control unit. When an interrupting vehicle enters ahead of the own vehicle in (i) a situation in which no preceding vehicle is present ahead of the own vehicle, or (ii) a situation in which a preceding vehicle is present ahead of the own vehicle, while a deviation angle formed between a direction of a traveling trajectory of the interrupting vehicle and a traveling direction of the own vehicle is larger than a threshold, the lane keeping assist control unit is configured not to perform a lane keeping assist control based on the traveling trajectory of the interrupting vehicle, and is configured to discard the traveling trajectory of the interrupting vehicle. On and after the deviation angle becomes equal to or smaller than the threshold, the lane keeping assist control unit is configured to perform the lane keeping assist control based on the traveling trajectory of the interrupting vehicle.

A driving support apparatus for an own vehicle includes a travel trajectory obtaining unit configured to obtain a preceding vehicle trajectory which is a travel trajectory of a preceding vehicle, and a control unit configured to perform a follow-up steering control for changing a steering angle of the own vehicle in such a manner that the vehicle travels along a target traveling line determined based on the preceding vehicle trajectory. The control unit is configured to, when a first distance condition and a manual steering condition are both satisfied while the follow-up steering control is being performed, stop the follow-up steering control.

A vehicular control system includes a camera that captures image data. The system includes an electronic control unit (ECU) for processing image data captured by the camera. The ECU, via processing by an image processor of image data captured by the camera, determines lane information of a traffic lane along a road being traveled by the equipped vehicle. The ECU determines a lane quality value that represents a confidence in the determined lane information. When the lane quality value exceeds a threshold value, and based at least in part on the determined lane information, the ECU provides a steering command to a steering system of the equipped vehicle to adjust a heading of the equipped vehicle to center the equipped vehicle within the traffic lane of the road being traveled by the equipped vehicle.

Systems and methods for a virtually coupled modular transportation system. A first module and a second module, in each for transporting a payload, comprise non-physically coupled vehicle sections. In an embodiment, a controller determines a target orientation between modules. In another embodiment, at least one position detection device determines an actual orientation between modules. A motor in at least one module may receive signals from the controller to position the modules in the target orientation. A plurality of wheels on each module may receive an independent amount of torque to position the modules. In another embodiment, at least one module comprises a rechargeable electric motor.

A vehicle control device includes a storage device configured to store a program, and a hardware processor. The hardware processor executes the program stored in the storage device to recognize a surrounding situation of a vehicle including a road division line and a surrounding vehicle, to control steering and acceleration/deceleration of the vehicle based on at least the road division line without depending on an operation of a driver of the vehicle, and to determine whether occlusion, in which at least a part of the road division line is shielded, has occurred, based on the road division line and a position of the surrounding vehicle present in front of the vehicle.

A system and method for mitigating or avoiding risks due to hazards encountered by platooning vehicles. The system and method involve interrogating, with one or more sensors, a space radially extending from a lead vehicle as the lead vehicle travels over the road surface, perceiving the environment within the space, ascertaining a hazard caused by an object in the space, and causing a following vehicle, operating in a platoon with the lead vehicle, to take a preemptive braking action to avoid or mitigate risks resulting from the hazard caused by the object in the space.