The present disclosure in at least one embodiment provides an apparatus for braking a vehicle, including at least one sensor for detecting a braking input of the vehicle, a front-wheel EMB including a front-wheel motor and a front-wheel brake for braking a front wheel(s), a rear-wheel EMB including a rear-wheel motor and a rear-wheel brake for braking a rear wheel(s), a front-wheel ECU for controlling the front-wheel motor for allowing the front-wheel EMB to brake the front wheel, a center ECU for calculating and transmitting, upon receiving the braking input from the at least one sensor, a braking force to the front-wheel ECU, and controlling the rear-wheel motor for allowing the rear-wheel EMB to brake the rear wheel, and a battery for supplying electric power to the front-wheel ECU and the center ECU, wherein the front-wheel EMB is controlled by the front-wheel ECU, and the rear-wheel EMB is controlled by the center ECU.

A method of controlling the vehicle may include predicting, by a controller, a braking situation of the vehicle; performing, by the controller, brake distribution control of front and rear wheels of the vehicle in a response to a predicted sudden braking of the vehicle at a predetermined level; and performing, by the controller, independent braking control of the rear wheel of the vehicle in a response to a predicted general braking of the vehicle at the predetermined level.

A vehicle includes an axle, an electric machine, a first wheel, a second wheel, a first friction brake, a second friction brake, and a controller. The controller is programmed to, in response to and during an anti-locking braking event, generate first and second signals indicative of a braking torque demand at the first and second wheels, respectively, based on a difference between a desired wheel slip ratio and an actual wheel slip ratio of the first and second wheels, respectively, adjust a regenerative braking torque of the electric machine based on a product of the first signal and a regenerative braking weighting coefficient, adjust a first friction braking torque based on a product of the first signal and a friction braking weighting coefficient, and adjust a second friction braking torque based on the second signal and dynamics of the first and second output shafts.

A braking control system and method for a vehicle are configured to calculate a braking force of front and rear wheels using a wheel slip ratio of the front and rear wheels and a road surface friction coefficient and then accurately estimate and calculate a disk temperature of the front and rear wheels using a predetermined estimation formula from the calculated braking force, and control distribution of braking pressure to the front wheels and the rear wheels so as to uniformly wear brake pads based on the calculated temperatures of the disks.

A braking control system and method for a vehicle are configured to calculate a braking force of front and rear wheels using a wheel slip ratio of the front and rear wheels and a road surface friction coefficient and then accurately estimate and calculate a disk temperature of the front and rear wheels using a predetermined estimation formula from the calculated braking force, and control distribution of braking pressure to the front wheels and the rear wheels so as to uniformly wear brake pads based on the calculated temperatures of the disks.

A method for carrying out an autonomous brake application in a two-wheel motor vehicle. In the method, the need for a vehicle deceleration is detected with the aid of a surroundings sensor system; depending thereon, a driver-independent vehicle deceleration is initiated; once the vehicle deceleration has been initiated, a driver readiness variable characterizing the readiness of the driver to control the vehicle deceleration maneuver is ascertained; and the temporal progression of the vehicle deceleration is continued depending on the driver readiness variable.

A regenerative braking control device for an electronic four-wheel drive vehicle, may improve fuel efficiency through a regenerative braking control optimized for the electronic four-wheel drive vehicle.

The present disclosure in at least one embodiment provides a corner module for a vehicle, including a front-wheel corner module configured to drive a front wheel and including a front-wheel inwheel motor installed on the front wheel to generate a driving force and a friction braking device configured to generate a braking force on the front wheel, a rear-wheel corner module configured to drive a rear wheel and including a rear-wheel inwheel motor installed on the rear wheel to generate a driving force, a driving information detector configured to detect driving information of the vehicle, and an electronic control unit configured to control the front-wheel corner module to form a friction braking force by using the driving information and to control the rear-wheel corner module to form a regenerative braking force, wherein the front-wheel corner module uses the front-wheel inwheel motor that is provided with a lower specification than the rear-wheel inwheel motor to save the manufacturing cost, and the rear-wheel corner module has no friction braking device installed so that the rear-wheel inwheel motor is undamaged by heat.

The present invention relates to a control system and components therefor, the invention has particular application in adjusting the brake bias in a vehicle. The control system of the present invention may provide greater usability than existing brake bias control systems due to features such as allowing a display screen to be seen at a glance and the ability to zero the count shown on the display.

The present invention relates to a control system and components therefor, the invention has particular application in adjusting the brake bias in a vehicle. The control system of the present invention may provide greater usability than existing brake bias control systems due to features such as allowing a display screen to be seen at a glance and the ability to zero the count shown on the display.