A system for controlling the jerk in an automatic/autonomous vehicle, said system comprising processing means, which comprise a jerk calculation module configured to acquire an electric acceleration signal and calculate a jerk value of said vehicle, and a plurality of operating modules, each configured to acquire an electric braking signal and said jerk value, one of said plurality of operating modules being selected by means of a selection signal, said selected module modifying the electric braking signal as a function of said jerk value and providing a modified electric braking signal to said braking system.

A brake device of the present invention includes: a wheel brake unit for braking a wheel; an electric motor for driving the wheel brake unit; a speed reducer for decelerating rotation of the electric motor; a rotation-linear motion converter for converting a rotational output of the speed reducer into a linear motion; and a braking force transmission member for transmitting the linear motion produced by the rotation-linear motion converter to the wheel brake unit.

A method of controlling braking of a vehicle is provided to minimize heat generation in a brake system at a time of braking the vehicle while securing an appropriate braking force. The method includes determining whether an inclination condition for a road satisfies a preset condition, and when the inclination condition for the road satisfies the preset condition, performing cyclic brake control of alternately braking wheels of two or more different axles of the vehicle.

The present invention obtains a controller and a control method capable of appropriately executing adaptive cruise control of a straddle-type vehicle.

In the controller and the control method according to the present invention, when braking forces are generated on at least one of wheels of the straddle-type vehicle 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 rider's instruction, at a braking start time point at which the braking force starts being generated on at least one of the wheels, braking force distribution between the front and the rear wheel is brought into an initial state where the braking force is generated on the front wheel.

A travel controller including an information acquisition part configured to acquire brake state information of a braking device of a host vehicle and an ACC-ECU configured to perform travel control, wherein the travel control includes constant speed travel control and headway travel control. The constant speed travel control is configured to control the host vehicle to travel at constant speed in accordance with a preset target vehicle speed. The headway travel control is configured to control the host vehicle to travel by following another vehicle travelling ahead so that a predetermined inter-vehicle distance in maintained with the other vehicle and the host vehicle travels in accordance with the target vehicle speed. In the ACC-ECU, when a braking performance index of the host vehicle has a “declined value”, a target acceleration of Example 1 takes a reduced value compared to the target acceleration of Comparative Example for a common distance difference.

A first distance is determined between a location of a host vehicle and a received location of a remote vehicle, the remote vehicle being forward of the host vehicle. A second distance is determined between a target vehicle and the host vehicle. A time to reach is predicted between the target vehicle and the remote vehicle based on the first distance and the second distance. A brake of the host vehicle is pre-charged when the predicted time to reach is below a time threshold. Pre-charging of the brake of the host vehicle is suppressed when the predicted time to reach is above the time threshold.

An electronic device for stopping a vehicle can be activated automatically in the presence of an emergency stopping instruction. A module calculates at least one automatic movement setpoint of the vehicle in order to follow an emergency stopping trajectory comprising a plurality of successive emergency stopping vectors each associated with a separate segment of a portion of the successive segments of the predefined trajectory, from at least for each emergency stopping vector: a stored last actual movement vector of the autonomous vehicle, the predefined movement trajectory of the autonomous vehicle, and a stored last location datum of the autonomous vehicle, and delivered by at least one sensor of the autonomous vehicle. An emergency steering module is capable of steering the vehicle according to said at least one setpoint.

First target braking forces for front and rear wheels are calculated by distributing a target braking force of automatic braking to the front and rear wheels at a first front/rear wheel distribution ratio when braking operation is started by a driver during execution of the automatic braking control, second target braking forces for the front and rear wheels are calculated by distributing the braking force requested by the driver to the front and rear wheels at a second front/rear wheel distribution ratio preset to be different from the first front/rear wheel distribution ratio such that a pitch moment applied to a vehicle body due to braking forces of the front and rear wheels becomes zero, and braking forces of the front and rear wheels are controlled so as to be sums of the first and second target braking forces of the front and rear wheels, respectively.

A bicycle braking system includes a server, a portable device such as a smartphone, a display unit, a control unit, a power supply unit, a rotating electrical machine, and a bicycle. The portable device includes an image display unit, a braking condition transmitting unit, and a braking condition setting unit. The control unit regeneratively brakes the bicycle using the rotating electrical machine in accordance with the braking condition set by the braking condition setting unit. The braking system enables a non-user to set braking conditions for the bicycle and to perform braking based on the conditions set by the non-user.

The disclosure relates to a control device and a corresponding method for operating an electromechanical brake booster of a brake system of a vehicle, comprising an electronics unit that defines a target variable with respect to a target rotational speed of a motor of the electromechanical brake booster, taking into account a brake input signal with respect to a braking request, and that sends at least one control signal to the motor. The electronics unit defines a maximum target variable with respect to a maximum target rotational speed of the motor, taking into account a current intensity of a motor current of the motor and a current angle of rotation of a rotor of the motor, and defines the target variable with respect to the target rotational speed of the motor of the electromechanical brake booster to be at the most equal to the defined maximum target variable.