A vehicle control device, a vehicle control method, and a vehicle control system according to one embodiment of the present invention are configured to acquire a physical quantity relating to a speed of a vehicle and a physical quantity relating to a requested braking force required to decelerate the vehicle and to generate a driving force by a driving device under a state in which a friction braking force is being generated when the vehicle is to be decelerated based on the physical quantity relating to the requested braking force.

A vehicle brake system includes: a brake device configured to apply a braking force to a wheel; and a controller configured to cause the brake device to perform an ABS operation when a slip ratio of the wheel exceeds a threshold. The ABS operation includes a decrease mode in which the braking force is decreased and an increase mode in which the braking force is increased to restore the braking force after the decrease mode. The controller determines a final target braking force that should be attained at an end time point of the ABS operation based on the braking force at a start time point of the ABS operation and determines a cycle time of the ABS operation based on a condition of a road surface on which the vehicle travels. The cycle time is a length of time in which the ABS operation is performed.

An aircraft includes a brake lever for receiving a pilot braking input as a lever travel of the brake lever, a braking wheel operatively coupled with the brake lever to brake the aircraft based on the lever travel, a brake actuator operatively coupled with the braking wheel to apply a braking force in response to a braking pressure provided to the brake actuator, and a brake pressure circuit. The brake pressure circuit is configured for: estimating a maximum braking pressure above which the braking wheel will skid with respect to a ground surface; scaling a lever gain of the brake lever to command the maximum braking pressure at a full travel of the brake lever such that a remaining brake lever travel indicates the amount of braking capability remaining for the aircraft; and braking the braking wheel based on the lever gain and the lever travel.

A road surface detection system, in one example the system includes a hydraulic unit of an anti-lock braking system, the hydraulic unit including a preload adjuster, and a plurality of pressure sensors configured to generate pressure sensor data. The system also includes a controller configured to receive the pressure sensor data from the plurality of pressure sensors, determine a target preload pressure level, compare the pressure sensor data with the target preload pressure level to calculate a pressure differential between the pressure sensor data and the target preload pressure level, determine a road surface based upon the calculated pressure differential, and regulate the preload adjuster to change the pressure within the hydraulic unit based upon the road surface.

Systems and methods are directed to dynamically and automatically adjusting a standard regenerative braking intensity. Roadway data, data from one or more sensors of a vehicle and data including parameter values for operating states of the vehicle regarding a roadway from a route being navigated by the vehicle are received by a processor of a control system of the vehicle. Standard regenerative braking intensity values based on a vehicle's acceleration is retrieved from memory. Adjusted regenerative braking intensity values are calculated based on at least one of the roadway data, the sensor data and the parameter values of the operating states of the vehicle and the standard regenerative braking intensity values. The adjusted regenerative braking intensity values are transmitted to the control system and an acceleration or deacceleration amount is applied to the vehicle based on the adjusted regenerative braking intensity values.

A parking assistance unit comprises: a step determination unit that executes a first determination process for determining whether a step that a vehicle wheel has contacted is a step for stopping the vehicle; and a braking/drive force setting unit that executes a stop request control for requesting stopping of a vehicle by increasing the braking force of the vehicle, when a step has been determined by the first determination process to be a step for stopping the vehicle.

A driving assistance apparatus is provided with: a recognizer configured to recognize a surrounding situation of a host vehicle; a controller programmed to execute a deceleration assistance control of assisting in decelerating a host vehicle when a predetermined condition is satisfied; a determinator configured to determine whether or not the host vehicle is traveling on a roadway on the basis of the recognized surrounding situation; and a restraining device configured to restrain execution of the deceleration assistance control by a controller if it is determined that the host vehicle is not traveling on a roadway, in comparison with a situation in which it is determined that the host vehicle is traveling on a roadway.

An emergency braking control method for a vehicle may include: controlling, by a controller, an ambient information detector to take an image of surroundings of the road on which a vehicle is traveling; controlling, by the controller, a camera recognition fail state detector to analyze the image taken by the ambient information detector, and to determine a severity level of a temporary camera recognition fail state; and controlling, by the controller, an operation of an emergency braking apparatus or setting a control strategy according to the severity level of the temporary camera recognition fail state.

The invention relates to a brake system comprising at least one brake with a frictional surface, a pad carrier with a brake pad, and a control and monitoring unit. According to the invention, the brake system additionally comprises a brake temperature sensor which is connected to the control and monitoring unit that is designed to ascertain brake temperature maintenance values on the basis of the brake effectiveness request, to compare a temperature ascertained by the brake temperature sensor with corresponding brake temperature maintenance values, and to ascertain at least one correction factor on the basis of a deviation. The control and monitoring unit is additionally designed to correct the brake control signal by the at least one correction factor and to actuate the controller using the corrected brake control signal.

A method for determining a slope of a roadway on which a vehicle is located includes imputing image data, supplied by an image sensor, pertaining to surroundings of the vehicle, identifying a defined reference object in the surroundings of the vehicle using the image data, determining an angle relationship between the reference object and the surroundings, estimating a slope of the roadway with reference to the determined angle relationship, and generating a signal indicative of the slope of the roadway. A device for determining a slope of a roadway on which a vehicle is located is configured to execute such a method.