A controller for a work machine includes a steering control circuit, a memory, and a speed control circuit. The steering control circuit is configured to control a steering of the work machine to change a steering angle based on a travel route. The memory is to store a threshold angle. The speed control circuit is configured to control a speed of the work machine if the steering angle is equal to or larger than the threshold angle and if the steering control circuit does not control the steering.

The present invention provides a braking/driving force control apparatus capable of performing stable braking/driving force control. A braking/driving force control apparatus acquires a target braking/driving force and a target slip ratio for guiding a vehicle to a target route. The target braking/driving force and the target slip ratio are determined by a vehicle control apparatus based on information regarding a running route of the vehicle that is input from an external world recognition sensor and a physical amount regarding a motion state of the vehicle that is input from a vehicle motion state detection sensor. The braking/driving force control apparatus acquires a slip state braking/driving force for achieving the target slip ratio based on a magnitude relationship between a physical amount regarding a wheel speed that is input from a wheel speed sensor configured to detect the physical amount regarding the wheel speed of the vehicle, and information about the acquired target slip ratio, and outputs a braking/driving force control signal based on this slip state braking/driving force and the target braking/driving force to an actuator regarding braking/driving of the vehicle.

A vehicular behavior control apparatus in which a control unit that controls a driving device and a braking device is configured to calculate a target yaw moment and a target deceleration of the vehicle for ensuring stable behavior of the vehicle during non-braking turning, to calculate a first vehicle longitudinal force applied to a turning inner wheel to achieve the target yaw moment and a second vehicle longitudinal force necessary to achieve the target deceleration, to control, when the first vehicle longitudinal force is equal to or less than the second vehicle longitudinal force, the driving device so as to generate a driving force equal to a value obtained by subtracting the second vehicle longitudinal force from a driver-requested driving force and adding the first vehicle longitudinal force, and to apply the first vehicle longitudinal force to the turning inner wheel.

Steering a vehicle may include applying a net brake-steering force to a steered wheel sufficient to affect a steering moment upon the steered wheel sufficient to move the steered wheel away from a zero steering angle, and resisting movement of the steered wheel back toward the zero steering angle.

A brake fluid pressure control device for vehicles with bar handle which is configured to start a holding control of a fluid pressure of a wheel brake according to wheel deceleration calculated based on a wheel speed of the vehicle is provided. In the brake fluid pressure control device, the vehicle includes an acceleration sensor which is configured to detect acceleration in a front-rear direction of the vehicle, acceleration, detected by the acceleration sensor, which occurs in a rearward direction when the vehicle is decelerating is detected as a positive value, and the holding control is started when it is judged that the acceleration detected by the acceleration sensor is larger than or equal to a detection acceleration threshold value and the wheel deceleration is smaller than or equal to a wheel deceleration threshold value.

This driving assist apparatus for a vehicle sets target wheel speed of an inside rear wheel in turning to substantially zero when a state of a center differential apparatus is a locked state in a case where the vehicle is turned in an extremely low speed traveling control. Further, the apparatus sets target wheel speed of each of wheels other than the inside rear wheel in turning such that a mean value of target wheel speeds of front wheels is equal to a mean value of target wheel speeds of rear wheels and the mean value of target wheel speeds of front wheels is equal to target vehicle body speed. Furthermore, the apparatus adjusts driving force and braking force such that wheel speed of each of the wheels becomes equal to the target wheel speed set for each of the wheels.

A vehicle control method for a vehicle (1) comprises the steps: when an output torque of an engine (4) is equal to or greater than a given value, reducing the output torque in accordance with an increase in steering angle of the vehicle; setting, in accordance with a decrease in the steering angle, a first yaw moment instruction value whose direction is reverse to that of a yaw rate being generated in the vehicle; when the output torque is less than the given value, applying a braking force to road wheels, based on the first yaw moment instruction value; and, when the output torque is equal to or greater than the given value, applying a braking force to the road wheels, based on a second yaw moment instruction value smaller than the first yaw moment instruction value.

Disclosed is a vehicle control method which comprises the steps of: determining whether or not a squat of a rear end of a vehicle body is equal to or greater than a given level; determining whether or not turning manipulation of a steering device has been made; and, when the turning manipulation of the steering device is determined to have been made, controlling each part of an engine (4) to reduce an output torque of the engine (4), wherein, in response to the determination that the turning manipulation of the steering device has been made, a reduction amount of the output torque of the engine is increased when the squat of the rear end of the vehicle body is equal to or greater than the given level, as compared to when the squat is less than the given level.

The vehicle attitude control system for controlling the attitude of a vehicle in which a road wheel suspension is configured such that a roll axis of the vehicle inclines downwardly in a forward direction. The vehicle attitude control system includes: a road wheel speed sensor operable to detect a road wheel speed; a brake actuator operable to apply a braking force to each road wheel of the vehicle; and a brake control device operable to cause the brake actuator to generate the braking force, based on a detection signal of the road wheel speed sensor, wherein the brake control device executes vehicle attitude control of applying a first braking force to the inner rear road wheel, based on a difference in road wheel speed between an inner and an outer rear road wheels of the vehicle being turning, during turning of the vehicle.

Disclosed is a vehicle attitude control system for controlling the attitude of a vehicle in which a road wheel suspension is configured such that a roll axis of a vehicle body inclines downwardly in a forward direction. The vehicle attitude control system includes: a lateral acceleration sensor operable to detect a lateral acceleration; a brake actuator operable to apply a braking force; and a brake control device operable, based on a traveling state of the vehicle, to generate the braking force, wherein the brake control device is configured to execute vehicle attitude control of applying, to an inner rear road wheel, a larger braking force when the lateral acceleration of the vehicle is relatively large than when the lateral acceleration is relatively small, thereby suppressing uplift of an inner rear portion of the vehicle body.