A method of controlling the braking of a vehicle descending a slope. The method includes receiving one or more electrical signals each indicative of a value of a respective vehicle-related parameter. The method further includes detecting that the vehicle is descending a slope based on the value(s) of one or more of the vehicle-related parameters. The method still further includes automatically modifying an amount of brake torque being applied to at least certain of the wheels of the vehicle in response to the detection of the vehicle descending a slope by increasing the amount of brake torque being applied to one or more trailing wheels of the vehicle, and decreasing the amount of brake torque being applied to one or more leading wheels of the vehicle.

The invention relates to a method of controlling a heavy-duty vehicle in a slope when the vehicle has come to a standstill due to service brakes of the vehicle having applied a service brake force, the method comprising determining a total brake force required for maintaining the vehicle at standstill, activating at least one park brake for providing a park brake force, gradually increasing the park brake force, and, while the park brake force is gradually increased, gradually reducing the service brake force while maintaining the sum of the service brake force and the park brake force at least equal to the determined total brake force.

A control device is for controlling an autonomous motor vehicle in order to modify a steering angle of a steered wheel of the autonomous motor vehicle and/or a braking force generated by the brake fitted to a wheel of the autonomous motor vehicle. The control device includes an automatic piloting system, which is configured to generate an automatic driving instruction for automatically driving the vehicle, a primary command chain, which includes a primary controller configured to generate a primary command according to the automatic driving instruction, and at least one primary actuator configured to generate a torque that confers a steering angle to the steered wheel, or configured to actuate the brake based on the primary command obtained directly from the primary controller. A secondary command chain is also included.

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 vehicle is provided with: a main vehicle body having an attachment portion to which a towed vehicle can be attached, and a first onboard unit and a second onboard unit attached to the main vehicle body, the first onboard unit and the second onboard unit being installed so as to be capable of communicating with a roadside device. The first onboard unit has type information relating to the type of the main vehicle body, and is provided at a position at which communication with the roadside device is possible both when the towed vehicle is attached to the attachment portion and when the towed vehicle is not attached to the attachment portion. The second onboard unit is provided at a position at which communication with the roadside device is possible when the towed vehicle is not attached to the attachment portion and at which communication with the roadside device is not possible when the towed vehicle is attached to the attachment portion.

A system includes a controller configured to individually control brake force applied to steered wheels of a vehicle. The controller is configured to release a braking force from a first brake associated with a first steered wheel of the vehicle when the vehicle is stationary, and the controller is further configured to subsequently release a braking force from a second brake of a second steered wheel when the vehicle remains stationary after braking force is released from the first wheel. Methods relate to distributing braking force of a vehicle.

A travel resistance arithmetic device includes: a controller configured to estimate travel resistance which a vehicle receives from a travel road; and a memory configured to store the travel resistance in association with positional information. The controller is configured to: correct, based on difference between a stored value of the travel resistance stored in the memory in association with a predetermined area on the travel road through which the vehicle has already passed and an estimated value of the travel resistance estimated by the controller in the predetermined area, the stored value stored in the memory in association with a correction target area on the travel road and; output the corrected stored value as the travel resistance in the correction target area while the vehicle travels the travel road.

A method for controlling an auto cruise speed of a vehicle includes: determining a feedback torque for correcting a speed error between a target speed set by a driver of the vehicle and a current speed that is a feedback speed detected by a speed sensor of a vehicle; determining a drive resistance according to the target speed by inputting the target speed; determining a first feedforward torque according to the determined drive resistance; determining a second feedforward torque based on a vehicle inertia and a variation of the target speed by inputting the target speed; and outputting a command for generating a wheel required torque that is corrected by adding the first feedforward torque and the second feedforward torque to the feedback torque.

A variable linked braking system controlled by motorcycle lean angle includes a brake master cylinder; a hydraulic pressure proportion variable valve connected to the brake master cylinder; a front brake unit and a rear brake unit, both connected to the hydraulic pressure proportion variable valve; a hydraulic pressure proportion controller for controlling the hydraulic pressure proportion variable valve; a motorcycle lean angle sensor for sensing a motorcycle lean angle and sending a signal thereof to the hydraulic pressure proportion controller; and a brake switch for starting the brake master cylinder and sending a brake signal to the hydraulic pressure proportion controller for controlling the hydraulic pressure proportion variable valve so that the braking force ratio of the front brake unit to the rear brake unit decreases as the motorcycle lean angle increases, thereby enhancing the stability and traction of a motorcycle being braked in a turn.

A method of braking left and right landing gear wheels on respective left and right sides of an aircraft. A desired left braking parameter (L) is received for the left wheel and a desired right braking parameter (R) is received for the right wheel. The left wheel is braked with a reduced left braking parameter (L′) which is less than the desired left braking parameter (L), and the right wheel is braked with a reduced right braking parameter (R′) which is less than the desired right braking parameter (R). A difference between the braking parameters is maintained so that L′−R′=L−R.