A regenerative braking control system includes at least one sensor adapted to sense a front tire impact event and transmit a sensor signal responsive to the front tire impact event during vehicle braking and a regenerative powertrain interfacing with the at least one sensor and adapted to reduce regenerative braking torque responsive to receiving the sensor signal from the at least one sensor. A regenerative braking control method is also disclosed.

A braking apparatus and a braking control method for a vehicle, wherein the braking apparatus includes an inlet valve for interrupting a braking hydraulic pressure supplied to a wheel cylinder of the vehicle, a regenerative braking unit for performing the regenerative braking of the vehicle, and a control unit for controlling the braking hydraulic pressure supplied to the wheel cylinder by controlling the inlet valve so that hydraulic braking force determined by subtracting a hydraulic braking force generated by the regenerative braking unit from a demand braking force requested by a driver is generated. The control unit controls the hydraulic braking pressure supplied to the wheel cylinder by controlling the inlet valve on the basis of changes in the vehicle speed and the regenerative braking force of the vehicle.

An electric vehicle according to an example of the present application includes a battery, a regenerative brake, a friction brake, and a controller. The regenerative brake imparts regenerative braking torque to drive wheels. The friction brake imparts frictional braking torque to the drive wheels and non-drive wheels. The controller execute a slip control when the slip of the drive wheels is expected. The controller controls, during the execution of slip control, the regenerative and the friction brakes so that; the total of the frictional and the regenerative braking torque imparted to the drive wheels is less than or equal to upper limit torque set within a range that the drive wheels do not slip; the power of the regenerative power generation is not to exceed an acceptable charging power set according to a state of charge of the battery; and the regenerative braking torque is smaller than the regenerative braking torque before the start of the slip control.

A hill descent system for a vehicle and a control method thereof comprising: wheels; wheel speed sensors used for detecting the speeds of the wheels; motors used for selectively driving or braking the wheels; a motor controllers, for controlling the working states of the motors; resolver sensors for detecting the rotational speeds of the motors; and a vehicle control unit for determining the actual downhill speed of the vehicle and adjusting the working states of the motors to control the descent of the vehicle.

A braking control device for a vehicle includes an anti-lock controller and a resonance controller. The anti-lock controller is configured to perform an anti-lock control that includes making an adjustment to the braking torque command, to cause suppression of one or more wheels from being locked during braking of the vehicle. The resonance controller is configured to correct the braking torque command, to control resonance of a power transmitter. The resonance controller includes a resonance generation processor that is configured to generate the resonance while imposing a limitation on magnitude of the resonance. The resonance controller is configured to suppress the resonance except during the anti-lock control, and allow the resonance generation processor to generate the resonance while imposing the limitation on the magnitude of the resonance during the anti-lock control.

A traction control device and method for a four-wheel drive electric vehicle are disclosed. When the drive wheels of an electric vehicle spin, a drive force of the electric vehicle is controlled so as to restrain the spinning of the drive wheels and to secure the starting performance and acceleration performance of the electric vehicle.

An embodiment method comprises selecting memory zones from a position of instructions of a program, the instructions each occupying one or more memory locations, and the zones comprising, for each memory location, a same number of bits, preferably equal to one or two.

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 vehicle includes an axle, electric machine, friction, brakes, and a controller. The axle has an input shaft to an open differential and output shaft extending out of the open differential. The electric machine is secured to the input shaft and wheels are secured to the output shafts. The controller is programmed to, in response to an anti-locking braking event, generate a signal indicative of a total torque demand to brake the vehicle based on a difference between a desired and an actual wheel slip ratio, adjust a regenerative braking torque of the electric machine based on signal and a regenerative braking weighting coefficient to maintain or drive actual wheel slip toward the desired wheel slip, and adjust a friction braking torque of the friction brakes based on the signal and a friction braking weighting coefficient to drive actual wheel slip at or toward the desired wheel slip.

A system and method for managing braking in a degraded adhesion condition for a vehicle system including at least one vehicle comprising setting a target deceleration value, applying a non-degraded braking force via a braking system of the vehicle system, detecting a presence of a degraded adhesion condition between the vehicle system and a route along which the vehicle system moves. Responsive to the degraded adhesion condition not being detected, maintaining the application of the non-degraded braking force, or responsive to the degraded adhesion condition being detected, applying a degraded braking force, activating recovery means to control deceleration of the vehicle system, determining a compensation deceleration value, and applying at least one of the braking system or recovery means to control the deceleration of the vehicle system.