The present disclosure relates to a method for autonomously controlling a vehicle performed by a vehicle control system, the vehicle control system comprising a zone control system, a collision prediction system and a braking control system, the method comprising the steps of: defining in the zone control system at least a first zone and a second zone relative to a vehicle position, predicting a collision with an obstacle with the prediction system, autonomously braking the vehicle with the braking control system in a first braking mode if the collision is predicted to occur in the first zone and braking the vehicle with the braking control system in a second braking mode if the collision is predicted to occur in the second zone.

The present embodiments relate to a collision prevention apparatus and method, and a driving support apparatus. The collision prevention apparatus may comprise: a collision risk determiner that determines a collision risk of a vehicle, a driving intervention determiner that determines driving intervention of a driver, and a collision prevention controller that controls a collision risk alert according to a result of determination on a collision risk of the vehicle, and adjusts a braking time point of the vehicle according to a result of determination on driving intervention of the driver.

A method for braking an electric vehicle in which a first axle of an electric vehicle is decelerated by an electric motor of the electric vehicle and/or by a friction brake system of the electric vehicle.

A brake control device for vehicles with bar handle includes: a wheel speed obtaining unit obtaining a speed of a wheel; an estimated vehicle body speed setting unit setting an estimated vehicle body speed; a control unit performing fluid pressure control to raise, reduce or hold a brake fluid pressure; and a bank angle obtaining unit obtaining a bank angle. The estimated vehicle body setting unit sets a limit value of a change amount when the estimated vehicle body speed decreases at a time of braking of the vehicle, and sets the estimated vehicle body speed based on the limit value when a deceleration amount of the speed of the wheel on a braked side is larger than the limit value, and the estimated vehicle body speed setting unit corrects the limit value so that the change amount decreases as the obtained bank angle increases.

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.

The present embodiments relate to a collision prevention apparatus and method, and a driving support apparatus. The collision prevention apparatus may comprise: a collision risk determiner that determines a collision risk of a vehicle, a driving intervention determiner that determines driving intervention of a driver, and a collision prevention controller that controls a collision risk alert according to a result of determination on a collision risk of the vehicle, and adjusts a braking time point of the vehicle according to a result of determination on driving intervention of the driver.

A braking system for a motorcycle may have at least (a) a first brake associated with a front wheel of the motorcycle, at least a first electro-hydraulic or electro-mechanical actuator, operatively connected to the first brake, (b) at least a first manual actuation command, associated with and corresponding to the at least one first brake, to send a braking request from a user, (c) at least a second brake associated with a rear wheel of the motorcycle, (d) at least a second electro-hydraulic or electro-mechanical actuator, operatively connected to the second brake, (e) at least a second manual actuation command, associated with and corresponding to the at least one second brake, to send a brake request from a user, and (f) a control unit operatively connected to the first manual actuation command, to the second manual actuation command and to the first and second electro-hydraulic or electro-mechanical actuators.

A method for controlling deceleration of a vehicle is provided. The vehicle has a braking system having a braking actuation lever, a braking actuator, and at least one braking device. The method involves measuring a current lever position of the braking actuation lever and a current lever speed of the braking actuation lever, dynamically mapping the current lever position and the current lever speed, processing a deceleration curve as a function of the dynamic mapping, and decelerating the vehicle according to the deceleration curve for each current lever position measured in a lever stroke.

A transportation safety apparatus for a vehicle combination, the vehicle combination including a leading vehicle that pulls a trailing vehicle, the apparatus comprising: a plurality of force sensors for measuring pressure on opposite sides of the trailing vehicle; a wheel direction sensor for measuring aim angle at which tires on the leading vehicle aim said leading vehicle; at least one of: a) a plurality of position sensors for measuring angle difference between the leading vehicle and the trailing vehicle; and b) an angle sensor for measuring centerline angle between a leading centerline of the leading vehicle and a trailing centerline of the trailing vehicle; and a processing unit for signaling jack knife risk based on force measured by one of the force sensors, the wheel direction sensor, and at least one of the angle difference and the centerline angle.

A control system (100) for an emergency braking system (200) using at least one transmitter/receiver sensor (210) comprising: means for causing automatic transition, from a first state (310) in which the emergency braking system (200) is inactive to a second state (320) in which the emergency braking system (200) is active, in dependence upon satisfaction of a first condition (412); and means for causing automatic transition from the second state (320) to the first state (310) in dependence upon satisfaction of a second condition (421) different to the first condition (412) wherein transition from the second state (320) to the first state (310) does not occur in dependence upon the first condition (412) no longer being satisfied, and/or transition from the first state (320) to the second state (310) does not occur in dependence upon the second condition (421) no longer being satisfied.