Disclosed herein is an emergency braking system using an electronic parking brake according to the present disclosure, in which the emergency braking system is configured to provide an emergency braking using an electronic parking brake (EPB) in case of total or partial failure of a main braking system, and includes: an EPB actuator configured to apply an emergency braking force to a wheel; a slip detection unit configured to detect a wheel slip on the wheel equipped with the EPB actuator; an EPB control unit configured to determine a road surface condition by calculating a slip ratio through slip information transmitted from the slip detection unit, and to control an operation of the EPB actuator based on the road surface condition.

Disclosed herein is an emergency braking system using an electronic parking brake according to the present disclosure, in which the emergency braking system is configured to provide an emergency braking using an electronic parking brake (EPB) in case of total or partial failure of a main braking system, and includes: an EPB actuator configured to apply an emergency braking force to a wheel; a slip detection unit configured to detect a wheel slip on the wheel equipped with the EPB actuator; an EPB control unit configured to determine a road surface condition by calculating a slip ratio through slip information transmitted from the slip detection unit, and to control an operation of the EPB actuator based on the road surface condition.

In a railway vehicle, a brake control device controlling a first brake device that presses a friction material against a wheel and a second brake device not using the friction material includes: a wheel load estimation unit estimating a wheel load-based on a wheel speed and a brake force applied to the wheel by the friction material; a friction surface state quantity estimation unit estimating a current friction coefficient of the friction material from a state of a friction surface thereof based on the wheel load, the wheel speed, and a brake force command, and outputting a mirror-surfacing signal indicating the friction surface is in a mirror-surfaced state when the friction coefficient is less than a first threshold value; and a brake control unit controlling operations of the first and second brake devices based on the brake force command and presence or absence of the mirror-surfacing signal.

Disclosed are a vehicle control apparatus and a control method thereof. The vehicle control apparatus and the control method thereof include an inputter configured to receive wheel slip values sensed by a sensing apparatus; a calculator configured to receive the wheel slip values and calculate a predicted wheel slip value using slip prediction model information on the basis of a previous wheel slip value and a current wheel slip value among the wheel slip values; a determiner configured to determine whether a current state is a first state of which a vehicle moved from a high friction road to a low friction road on the basis of the calculated predicted wheel slip value, compare the calculated predicted wheel slip value with predicted target slip value ranges when the current state is determined as being the first state, and determine whether to control an electric parking brake (EPB) apparatus in which one state among an apply state, a stop state, and a release state; and a controller configured to transmit at least one command among an apply command corresponding to the apply state, a stop command corresponding to the stop state, and a release command corresponding to the release state to the EPB apparatus when the current state is determined as being the first state.

Disclosed are a vehicle control apparatus and a control method thereof. The vehicle control apparatus and the control method thereof include an inputter configured to receive wheel slip values sensed by a sensing apparatus; a calculator configured to receive the wheel slip values and calculate a predicted wheel slip value using slip prediction model information on the basis of a previous wheel slip value and a current wheel slip value among the wheel slip values; a determiner configured to determine whether a current state is a first state of which a vehicle moved from a high friction road to a low friction road on the basis of the calculated predicted wheel slip value, compare the calculated predicted wheel slip value with predicted target slip value ranges when the current state is determined as being the first state, and determine whether to control an electric parking brake (EPB) apparatus in which one state among an apply state, a stop state, and a release state; and a controller configured to transmit at least one command among an apply command corresponding to the apply state, a stop command corresponding to the stop state, and a release command corresponding to the release state to the EPB apparatus when the current state is determined as being the first state.

A braking system may include a controller, a first wheel and a second wheel. The first wheel may be laterally displaced from the second wheel by a first distance. A first wheel speed sensor may be coupled to the first wheel and a second wheel sensor may be coupled to the second wheel. The controller may be configured to determine at least one of a slip ratio, a coefficient of friction, or a braking pressure of the second wheel in response to failure of the first wheel speed sensor. The controller may be configured to calculate a consistency value of the at least one of the slip ratio, the coefficient of friction, or the braking pressure. The controller may be configured to adjust a braking pressure of the first wheel speed sensor based upon the consistency value and the first distance.

A braking system may include a controller, a first wheel and a second wheel. The first wheel may be laterally displaced from the second wheel by a first distance. A first wheel speed sensor may be coupled to the first wheel and a second wheel sensor may be coupled to the second wheel. The controller may be configured to determine at least one of a slip ratio, a coefficient of friction, or a braking pressure of the second wheel in response to failure of the first wheel speed sensor. The controller may be configured to calculate a consistency value of the at least one of the slip ratio, the coefficient of friction, or the braking pressure. The controller may be configured to adjust a braking pressure of the first wheel speed sensor based upon the consistency value and the first distance.

A system and a method for estimating the coefficient of friction of a hydraulic brake system with axle-individual pressure buildup of a motor vehicle. In addition, a system and to a method for setting the target braking torque of a hydraulic braking system with axle-individual buildup of a motor vehicle in order to obtain a desired actual braking torque.

A system and a method for estimating the coefficient of friction of a hydraulic brake system with axle-individual pressure buildup of a motor vehicle. In addition, a system and to a method for setting the target braking torque of a hydraulic braking system with axle-individual buildup of a motor vehicle in order to obtain a desired actual braking torque.

A road surface condition estimation device extracts a detection signal of a vibration power generation element during a ground contact section to detect a road surface condition. A threshold used for determination of the ground contact section is variable according to a traveling speed of a vehicle. As a result, even if a pulse level of an output voltage of the vibration power generation element changes according to the traveling speed of the vehicle, the threshold corresponding to the change can be set. The ground contact section is determined with the use of the above thresholds, thereby being capable of performing the determination with high accuracy. Therefore, the road surface condition can be detected with high accuracy based on the ground contact section determined with high accuracy.