A system and method for detecting brake judder in a vehicle may include storing information related to determining whether judder was generated when a vehicle was braked, and facilitating easy recognition of a vehicle in which judder was generated, on the basis of stored information without performing methods such as a separate driving reproduction test and a disc thickness measurement test when maintaining later.

A method for detecting undesirable vibrations of an actuator of an electromechanical brake includes the steps of: (1) providing an electrical signal comprising at least one piece of information about a current consumption of the actuator or a parameter correlated with the current consumption; (2) monitoring an operation of the actuator on the basis of the gradient of the electrical signal in such a way that after switching on the actuator and preferably after a subsequent delay time, which includes determining: whether the amount of an initial instantaneous value of the gradient exceeds the amount of a threshold and whether a subsequent second instantaneous value of the gradient has an inverted sign compared to the first instantaneous value; (3) evaluating the results to ensure that an undesirable vibration is assessed as detected the aforementioned conditions are met.

A braking control device for a motor driven vehicle includes a wheel rotation speed sensing part which is disposed on each wheel of the vehicle and detects a detection speed of wheel rotation of the vehicle, a wheel rotation speed estimation part which detects a resolver value of a motor and estimates an estimation speed of wheel rotation using the detected resolver value, a sensor determination part which determines whether the wheel rotation speed sensing part is abnormal using the detection speed of wheel rotation and the estimation speed of wheel rotation, and a wheel rotation speed determination part which determines the estimated estimation speed of wheel rotation to be a wheel rotation speed of the vehicle when the wheel rotation speed sensing part is abnormal.

A braking control device for a motor driven vehicle includes a wheel rotation speed sensing part which is disposed on each wheel of the vehicle and detects a detection speed of wheel rotation of the vehicle, a wheel rotation speed estimation part which detects a resolver value of a motor and estimates an estimation speed of wheel rotation using the detected resolver value, a sensor determination part which determines whether the wheel rotation speed sensing part is abnormal using the detection speed of wheel rotation and the estimation speed of wheel rotation, and a wheel rotation speed determination part which determines the estimated estimation speed of wheel rotation to be a wheel rotation speed of the vehicle when the wheel rotation speed sensing part is abnormal.

In an electrified vehicle, a vibration damping control device performs vibration damping control for canceling or reducing, with the use of regenerative braking, a predetermined vibration component by monitoring the vibration component and controlling a generator control device depending on the vibration component. A system control device determines whether the vibration damping control is performable based on at least a charge status of a battery. An anti-lock braking system control device transmits a request signal to the system control device while performing anti-lock braking system control. The system control device transmits a command signal to the vibration damping control device when the vibration damping control is determined to be performable and the request signal is received from the anti-lock braking system control device. The vibration damping control device performs the vibration damping control when the command signal is received from the system control device.

A controller for a vehicle is provided. One of a prime mover that drives a front wheel and a prime mover that drives a rear wheel is referred to as a first prime mover, and the other one is referred to as a second prime mover. The controller generates, when a required torque required for a drive wheel of the vehicle is a braking torque, the braking torque from the first prime mover. The controller limits, when the required torque changes from the braking torque to a driving torque, an increase in the driving torque generated from the first prime mover during a set period. The controller generates, from the second prime mover that does not generate the braking torque, the driving torque required during execution of the torque limit process.

A method for avoiding false excitations of a slip control system comprises monitoring of a wheel speed signal for a predefined first monitoring time period for the start of a negative half-wave of an oscillation applied to a vehicle wheel, when a brake pressure gradient initiated by a brake start rises above a predetermined threshold. A ruck signal is derived from the wheel speed signal. An acceration signal is derived from the wheel speed signal during a predetermined second monitoring period. The wheel speed signal is monitored for a turning point of the ruck signal and a start of the acceleration signal. The oscillation imposed on the vehicle wheel is identified as a braking-induced vibration, and slip control is not carried out when the turning point of the ruck signal and the re-acceleration of the wheel are detected.

A method for avoiding false excitations of a slip control system comprises monitoring of a wheel speed signal for a predefined first monitoring time period for the start of a negative half-wave of an oscillation applied to a vehicle wheel, when a brake pressure gradient initiated by a brake start rises above a predetermined threshold. A ruck signal is derived from the wheel speed signal. An acceration signal is derived from the wheel speed signal during a predetermined second monitoring period. The wheel speed signal is monitored for a turning point of the ruck signal and a start of the acceleration signal. The oscillation imposed on the vehicle wheel is identified as a braking-induced vibration, and slip control is not carried out when the turning point of the ruck signal and the re-acceleration of the wheel are detected.

A control apparatus includes a controller, a receiver and a discriminator. The receiver, in operation, receives an instruction for controlling a brake of a movable-body apparatus. The discriminator, in operation, determines, in response to the instruction being received by the receiver, whether or not the instruction is fraudulent based on whether or not a speed of the moving body and a distance between the moving body and an obstacle satisfies a predetermined condition for invalidating the instruction.

A control apparatus includes a controller, a receiver and a discriminator. The receiver, in operation, receives an instruction for controlling a brake of a movable-body apparatus. The discriminator, in operation, determines, in response to the instruction being received by the receiver, whether or not the instruction is fraudulent based on whether or not a speed of the moving body and a distance between the moving body and an obstacle satisfies a predetermined condition for invalidating the instruction.