A driving control device controls traveling of an automatic driving vehicle. The driving control device includes a control unit, and as driving modes, the control unit has at least two driving modes including an automatic driving mode of performing an automatic control of the traveling of the vehicle and a manual driving mode of controlling the traveling of the vehicle in response to an operation by an operator that rides on the vehicle. The control unit sets an upper limit vehicle speed in the manual driving mode to a vehicle speed lower than an upper limit vehicle speed in the automatic driving mode, when the driving mode switches from the automatic driving mode to the manual driving mode.

A vehicle control device disclosed in the present disclosure includes: a first control unit configured to control a speed of the vehicle in accordance with the route distance and the set speed until the detection unit determines that the vehicle has passed through the ETC toll gate, while the vehicle is performing the constant-speed traveling by the cruise control unit; a vehicle frontward detecting unit configured to detect road information about a road frontward of the vehicle; and a second control unit configured to change control content in the cruise control unit on the basis of a detection result from the vehicle frontward detecting unit, when the detection unit determines that the vehicle has passed through the ETC toll gate, while the vehicle is performing the constant-speed traveling by the cruise control unit.

A vehicle control apparatus controls a vehicle-control force of a vehicle that is switchable between traveling under normal traveling control and traveling under cruise control. The apparatus includes a first target-vehicle-control-force determination unit, a second target-vehicle-control-force determination unit, and a vehicle-control-force controlling unit. The first target-vehicle-control-force determination unit determines a target vehicle-control force of the normal traveling control on the basis of an accelerator position, and switches a control mode of the normal traveling control between a normal mode and a one-pedal mode. The second target-vehicle-control-force determination unit determines a target vehicle-control force of the cruise control, and execute override when the accelerator position is greater than a reference accelerator position in the cruise control. The vehicle-control-force controlling unit controls the vehicle-control force on the basis of the target vehicle-control force determined by the first target-vehicle-control-force determination unit or the second target-vehicle-control-force determination unit.

The present invention obtains a controller and a control method capable of securing a driver's comfort during adaptive cruise control for a straddle-type vehicle.

In the controller and the control method according to the present invention, during the adaptive cruise control in which the straddle-type vehicle is made to travel according to a distance from the straddle-type vehicle to a preceding vehicle, motion of the straddle-type vehicle, and a driver's instruction, when a state where a braking force is generated on at least one of wheels of the straddle-type vehicle is switched to a state where a drive wheel is driven using drive power output from a drive source of the straddle-type vehicle, the braking force generated on the at least one of the wheels is controlled such that a reference braking force is generated on the drive wheel at a time point at which the drive wheel starts being driven due to transmission of the drive power output from the drive source to the drive wheel.

A driver assistance system for a vehicle including an autonomous cruise control to autonomously control at least vehicle speed, position data obtaining unit to obtain vehicle position data, ego-vehicle sensor data obtaining unit to obtain ego-vehicle sensor data related to objects in proximity to the vehicle, works data receiving unit to receive works data regarding current roadworks within a predetermined distance of the vehicle, and a processor to determine, based on the ego-vehicle sensor data, the works data, the position data, the vehicle's position and direction of travel relative to one or more roadworks, and when the processor determines the vehicle is approaching one or more roadworks and the vehicle distance to the roadwork is less than a threshold distance, or when the processor determines that the vehicle is already present within a roadwork and the autonomous cruise control is enabled, disable the autonomous cruise control.

A cruise control interlock system detects a current set of conditions for a vehicle, compares the current conditions with cruise control interlock conditions (e.g., an adjustable threshold state of a windshield wiper system), and executes a process to deactivate the cruise control system. The process to deactivate functionality of the cruise control system may include presenting a notification to the operator to alert the operator to an upcoming automatic deactivation or to encourage the operator to deactivate cruise control. The process also may include a vehicle de-rate process (e.g., reducing vehicle speed) to induce the operator to deactivate cruise control. Deactivation of cruise control may be postponed in some situations, such as when the vehicle is ascending an uphill grade or where doing so may deactivate an active downhill speed control function.

A vehicle speed-limit control method is provided. The method includes determining whether a speed-limit control inactivation condition is satisfied by accelerator pedal engaged when speed-limit control is activated. In response to determining that the inactivation condition is satisfied, a candidate value of an accelerator pedal sensor (APS) and a candidate gear shift stage are determined and a speed margin is determined based on the candidate value of the APS, the candidate gear shift stage and a vehicle speed. The speed margin is compared with a predetermined threshold. The candidate gear shift stage is determined as a transition gear shift stage and the candidate value of the APS is determined as a transition value of the APS when the speed margin is equal to or greater than the threshold. The vehicle is operated based on the transition gear shift stage and the transition value of the APS.

A cruise control interlock system detects a current set of conditions for a vehicle, compares the current conditions with cruise control interlock conditions (e.g., an adjustable threshold state of a windshield wiper system), and executes a process to deactivate the cruise control system. The process to deactivate functionality of the cruise control system may include presenting a notification to the operator to alert the operator to an upcoming automatic deactivation or to encourage the operator to deactivate cruise control. The process also may include a vehicle de-rate process (e.g., reducing vehicle speed) to induce the operator to deactivate cruise control. Deactivation of cruise control may be postponed in some situations, such as when the vehicle is ascending an uphill grade or where doing so may deactivate an active downhill speed control function.

A vehicle control apparatus controls a vehicle-control force of a vehicle that is switchable between traveling under normal traveling control and traveling under cruise control. The apparatus includes a first target-vehicle-control-force determination unit, a second target-vehicle-control-force determination unit, and a vehicle-control-force controlling unit. The first target-vehicle-control-force determination unit determines a target vehicle-control force of the normal traveling control on the basis of an accelerator position, and switches a control mode of the normal traveling control between a normal mode and a one-pedal mode. The second target-vehicle-control-force determination unit determines a target vehicle-control force of the cruise control, and execute override when the accelerator position is greater than a reference accelerator position in the cruise control. The vehicle-control-force controlling unit controls the vehicle-control force on the basis of the target vehicle-control force determined by the first target-vehicle-control-force determination unit or the second target-vehicle-control-force determination unit.

A vehicle control device disclosed in the present disclosure includes: a first control unit configured to control a speed of the vehicle in accordance with the route distance and the set speed until the detection unit determines that the vehicle has passed through the ETC toll gate, while the vehicle is performing the constant-speed traveling by the cruise control unit; a vehicle frontward detecting unit configured to detect road information about a road frontward of the vehicle; and a second control unit configured to change control content in the cruise control unit on the basis of a detection result from the vehicle frontward detecting unit, when the detection unit determines that the vehicle has passed through the ETC toll gate, while the vehicle is performing the constant-speed traveling by the cruise control unit.