Disclosed embodiments include systems, vehicles, and computer-implemented methods to adjust a threshold level of force to be applied to a steering wheel to disengage an autosteering system. In an illustrative embodiment, a system includes a computing device operably coupled with a vehicle that includes a processor and a computer-readable media configured to store computer-executable instructions configured to cause the processor to: detect that an autosteering system of the vehicle is engaged; detect a level of force applied by an operator to a steering wheel of the vehicle; and disengage the autosteering system when the level of force surpasses a threshold chosen from a default threshold and an adjusted threshold, wherein the adjusted threshold is applied upon detecting a predetermined condition..

A steering control device is configured to control a motor, the motor being a generation source of a driving force that is given to a steering mechanism of a vehicle. The steering control device includes a controller configured to compute a controlled variable depending on a steering state, the controlled variable being used in the control of the motor. The controller is configured to alter a control parameter for the controller, based on a command that is generated by a host control device depending on a purpose of an intervention in a steering control, the host control device being mounted on the vehicle.

Disclosed are a steering control device, a steering control method, and a steering support system including same. Particularly, the steering control device according to the present disclosure comprises: a noise frequency calculation unit for calculating the noise frequency of noise transmitted to a wheel; a noise frequency filtering unit for determining filtering degree on the basis of two or more driving modes, and filtering the noise frequency according to the filtering degree; and a reactive torque calculation unit for calculating reactive torque on the basis of the filtered noise frequency.

Embodiments disclose a system and method to generate smooth steering commands for an autonomous driving vehicle (ADV). According to one embodiment, a system determines a planning steering command based on a driving trajectory of an ADV. The system receives a current steering feedback from a sensor of the ADV for a current planning cycle. The system generates one or more smooth steering commands based on the planning steering command and the current steering feedback over one or more planning cycles. The system controls the ADV based on the one or more smooth steering commands so a change in steering applied to the ADV for any planning cycle is within a predetermined steering change threshold for the ADV. That way, the system applies incremental changes for the steering of the ADV.

During execution of lane keeping control, a vehicle driving support device sets a center line passing through a center of a travelable width of an own vehicle within a current lane as a target traveling line, and autonomously steers the own vehicle such that a reference point of the own vehicle moves along the target traveling line. The vehicle driving support device changes a position of the target traveling line such that the target traveling line is a line located between the center line and the reference point of the own vehicle, when a driver performs a steering operation for steering the own vehicle during the execution of the lane keeping control and a steering operation force of the driver becomes equal to or larger than a target change start threshold value.

An apparatus and method for controlling motor driven power steering system, the apparatus including: a column torque sensor detecting column torque applied to a steering column of a vehicle; an MDPS logic unit deciding a first command current based on the column torque and vehicle speed; a steering angle position control unit outputting a second command current for driving an MDPS motor in an autonomous driving mode, based on a command steering angle and a current steering angle inputted from an autonomous driving system and a steering angle sensor, respectivley; a driver steering intervention determination unit monitoring the column torque of the column torque sensor in an autonomous driving mode, and determining whether a driver has intervened in steering; and an output control unit deciding a final command current by applying the weight decided by the driver steering intervention determination unit to the first and second command currents.

A computer-implemented method, system, and/or computer program product controls a driving mode of a self-driving vehicle (SDV). One or more processors compare a control processor competence level of an on-board SDV control processor in controlling the SDV to a human driver competence level of a human driver in controlling the SDV while the SDV encounters a current roadway condition which is a result of current weather conditions of the roadway on which the SDV is currently traveling. One or more processors then selectively assign control of the SDV to the SDV control processor or to the human driver while the SDV encounters the current roadway condition based on which of the control processor competence level and the human driver competence level is relatively higher to one another.

A motor grader representing a work vehicle includes a steering mechanism and a control unit. The control unit generates a travel path of the motor grader based on a position and an azimuth of the motor grader and a direction of travel of the motor grader and controls the steering mechanism such that the motor grader travels along the generated travel path.

An autonomous driving system configured to perform an autonomous driving of a vehicle includes a lane change determination unit configured to determine a necessity of an operation intervention for a lane change of the vehicle by a driver of the vehicle during the autonomous driving, a lane change request unit configured to request the driver to perform the operation intervention for the lane change of the vehicle when the lane change determination unit determines that it is necessary to perform the operation intervention for the lane change of the vehicle by the driver, and a mode switching unit configured to switch a steering torque mode for a lane keep control in the autonomous driving from a normal steering torque mode to a weak steering torque mode when the driver is requested to perform the operation intervention for the lane change of the vehicle.

A steering system includes a rotary shaft to which an operation member is coupled; a first actuator; a second actuator; a control unit; and a moving unit configured to move the operation member between a normal position and a storage area. The control unit is configured to switch between a manual drive mode and an autonomous drive mode. The control unit is configured to, when moving the operation member from the storage area to the normal position, start synchronous control when the operation member satisfies a predetermined condition before the operation member reaches the normal position, the synchronous control being control in which the control unit controls the first actuator to change a rotation angle of the rotary shaft to an angle corresponding to a steered angle of steered wheels driven by the second actuator.