A method of controlling a vehicle including providing a system having a plurality of brakes and a curve detecting mechanism. Each brake of the plurality of brakes is configured to slow rotation of a respective wheel. The method further includes detecting a curve in a forward travel path of the vehicle using the curve detecting mechanism. At least two brakes but fewer than all of the plurality of brakes are pre-filled in response to the detection of a curve.

A braking force control device includes an actuator configured to control a braking force generated in vehicle wheels of a vehicle and a control unit configured to output a braking force command value to the actuator. The control unit is configured to perform at least one of the following processes of generating a braking force command value by performing a filter processing on a required braking force based on a braking operation amount using a filter having a smaller damping ratio than a damping ratio of a pitch motion of the vehicle when the required braking force increases, or generating the braking force command value by performing the filter processing on the required braking force based on the braking operation amount using a filter having a greater damping ratio than the damping ratio of the pitch motion of the vehicle when the required braking force decreases.

A method for controlling brakes may comprise receiving, by a controller, a yaw rate from an inertial sensor, calculating, by the controller, a force correction, calculating, by the controller, a pressure correction, and adjusting, by the controller, a pressure command for a brake control device.

A brake control device includes: an object detector; and an ECU configured to (a) determine, based on an output of the object detector, whether a predetermined condition that there is a possibility that the vehicle collides with the object, is satisfied; (b) apply an automatic brake when it is determined that the predetermined condition is satisfied; and (c) stop applying the automatic brake when an operation amount of an accelerator operation unit of the vehicle becomes equal to or larger than a predetermined threshold. The ECU also continues applying the automatic brake when a specified condition including a condition that an operation amount of a brake operation unit of the vehicle is larger than a predetermined amount is satisfied even when it has been determined that the operation amount of the accelerator operation unit becomes equal to or larger than the predetermined threshold.

Disclosed may be a method for controlling counter steering of a vehicle, which, in a counter steering section for controlling over-steer while a vehicle travels a curve, prevents lateral force from being decreased by maintaining a braking pressure according to an operation of an antilock braking system (ABS) for a vehicle wheel (a front axle curve-travelling outer wheel) of a counter steering target at an optimal slip level (before an improvement of a target slip), and improves steering performance by forming a linear yaw rate in a direction for counter steering without a delay in forming the yaw rate.

Disclosed is a method for automatically controlling brakes in a trailer vehicle having antilock control, wherein wheel rotational speeds are continuously monitored and evaluated at wheels having antilock control. According to the method, lateral acceleration and longitudinal acceleration of the trailer vehicle are determined. If a predefined, critical lateral acceleration is exceeded, an automatic braking process occurs. A control unit and trailer vehicle are also disclosed in connection with the inventive method.

A three-wheeled tilting vehicle is disclosed. The vehicle can include an electronic control system that controls the tilting of the vehicle in higher speed turns for increased stability. The vehicle may also include a traction control system to provide additional stability during higher speed turns.

A brake device for a vehicle includes: braking devices provided corresponding to right/left wheels, respectively, the braking devices being configured to generate braking forces by pressing forces according to a depression amount of a pedal; a wheel speed sensor configured to detect rotational speeds of the wheels; a pressing force sensor configured to detect the pressing forces; and a control device configured to control the braking force generating devices. The control device is configured to acquire the rotational speeds and the pressing forces in a state where the braking device is performing braking, specify deceleration, based on the acquired rotational speeds, and specify the loads that are supported by the wheels, based on the specified deceleration and the acquired pressing forces and controls the pressing forces corresponding to the right/left wheels such that a difference in deceleration between the right and left wheels becomes smaller, based on the loads.

A traction saddle disposed on a tractor for connection with a traction pin of a trailer, is provided. The traction saddle includes a base, a gear set, and a damper. A gear carrier of the gear set fixes planetary gears of the gear set, the planetary gears are meshed with an inner ring gear of the gear set, and the inner ring gear is fixed to the base. The gear carrier is used for fixing the traction pin to rotate with the traction pin. The planetary gears are meshed with a sun gear of the gear set to drive the sun gear to rotate, and the damper is connected to the sun gear to apply resistance. In addition, a traction pin, a tractor, a trailer, and a truck are also provided.

A method of adaptively changing brake force distribution in a vehicle may include detecting vehicle parameters during operation of the vehicle, based on the detected vehicle parameters, determining downhill travel of the vehicle while braking and steering inputs are applied to the vehicle as an enabling condition, and responsive to detection of a trigger comprising detection of an understeer condition while the enabling condition is satisfied, executing a brake force distribution modification defining a change in distribution of brake forces between a front axle and a rear axle of the vehicle.