The present disclosure provides a method of controlling braking of an electric vehicle in which friction braking force generated by a friction braking unit is applied to front wheels and regenerative braking force generated by a motor is applied to rear wheels includes: determining driver's request braking force by a controller based on a driver's braking-input value; detecting driving information and state information of the vehicle by a detection unit; and determining a braking mode of the vehicle that satisfies the driver's request braking force by the controller based on the detected information and information of running state of the vehicle obtained from the detected information. In addition, the present disclosure provides a system of controlling braking of an electric vehicle.

A running control device changes the distribution of engine braking or regenerative braking and the distribution of friction braking in the entire requested braking force according to an operation amount of an operation element, according to whether the behavior of a vehicle during running is in a stable state or an unstable state, or becomes an unstable state in the near future with high probability.

A control device includes: a first braking unit, that applies a first braking force to a steering wheel of a vehicle; a second braking unit, that applies a second braking force to a non-steering wheel of the vehicle; and a control device that controls the first braking unit, and the second braking unit, according to a target braking force, where the control device includes a steering angle information acquiring unit that acquires a steering angle-related value related to a steering angle of the steering wheel, and a distribution changing unit that executes a distribution change control of changing a braking force distribution between the first braking force and the second braking force based on the steering angle-related value when the target braking force is applied.

The invention relates to a 1st power supply arrangement for a rail vehicle. The rail vehicle includes at least one driven car with an intermediate circuit, a brake system and an energy supply system for supplying the brake system with operating energy. In order to improve the framework conditions to ensure reliable electrodynamic braking, the energy supply system contains at least two energy supply units, for the driven car, arranged at the intermediate circuit, for the redundant energy supply to the brake system.

A method for controlling a multitude of braking devices of a vehicle to effect a desired brake function quantified as a desired brake parameter, wherein each of the braking devices is controllable by an actuation parameter to effect at least a portion of said desired brake function, comprising the steps: determine, for each braking device, a brake capability representing a maximum brake function achievable by the braking device; determine, for each braking device, an actuation priority, wherein the actuation priority is determined from at least one predetermined operating parameter of the braking device and/or the vehicle; in order from highest priority to lowest priority of the braking means, allocating, to each braking device, the actuation parameter, wherein the actuation parameter is chosen between the brake capability and the quantity of the desired brake parameter not yet allocated to other braking devices, whichever is lower. Further, a braking system for a vehicle is configured to carry out the method.

A method, carried out in a controller of a motor vehicle having a plurality of wheels, to counteract an undesired influence on the motor vehicle. The method comprises determining, during a braking recuperation process, the undesired influence that is caused by the braking recuperation process and counteracting the determined undesired influence using a vehicle system that affects torques present at one or more wheels of the plurality of vehicle wheels.

The present disclosure relates to a method for controlling an application of regenerative brake torque to a plurality of wheels of at least one of a hybrid electric vehicle or an electric vehicle, to avoid brake instability. The method may involve sensing variables such as an angle of a steering wheel of the vehicle, a speed of the vehicle, a brake pedal rate as an operator engages a brake pedal, and a wheel slip of each of the front and rear wheels. A commanded lateral acceleration may be determined representing a steady state lateral acceleration that the vehicle would reach at an actual vehicle speed and with a presently sensed steering wheel angle. The application of regenerative brake torque can then be controlled based on the sensed wheel slips relative to at least one predetermined wheel slip limit. The predetermined wheel slip limit is determined based at least in part on the determined commanded lateral acceleration.

A vehicle control apparatus includes a controller configured to change a ratio between a regenerative braking force and a frictional braking force, in a specific wheel among wheels, such that the ratio in the specific wheel differs from the ratio between the regenerative braking force and the frictional braking force in each of the other wheels, when a command to generate the require braking force is issued and a vehicle motion control is executed.

A technique provides power-limiting regenerative braking to a utility vehicle. The technique involves detecting that the utility vehicle is moving in a forward direction at a first speed. The technique further involves applying a first regenerative braking power level to the utility vehicle in response to detecting that the utility vehicle is moving in the forward direction at the first speed. The technique further involves detecting that the utility vehicle is moving in the forward direction at a second speed which is less than the first speed. The technique further involves applying a second regenerative braking power level to the utility vehicle in response to detecting that the utility vehicle is moving in the forward direction at the second speed. The second regenerative braking power level is lower than the first regenerative braking power level.

In a vehicle control device, a slip ratio in which front and rear wheels are averaged, and a braking force in which the front and rear wheels are averaged, can be calculated. The vehicle control device is provided with: friction braking devices placed on each wheel; a motor that acts as a regenerative braking mechanism and is placed on the rear wheels; a vehicle slip stiffness calculation unit; a front and rear braking force ratio calculation unit; a vehicle slip stiffness correction unit; and a regenerative braking arithmetic unit. The regenerative braking arithmetic unit operates the friction braking device and the motor so as to make the vehicle slip stiffness reach a vehicle slip stiffness threshold value. Also, the vehicle slip stiffness correction unit corrects the vehicle slip stiffness threshold value in accordance with the ratio of the front wheel braking force and the rear wheel braking force.