A stroke sensor assembly for a vehicle braking system may include a stroke sensor, a sensor circuit board, and a sensor housing. The stroke sensor may be operable to detect a position of a piston within a hydraulic block. The sensor circuit board may be in communication with the stroke sensor and may be electrically connected to a plurality of terminals. The sensor housing may surround the stroke sensor and the sensor circuit board. The sensor housing may include a single mounting aperture for mounting the sensor housing to the hydraulic block. The sensor housing may include an integrally formed female electrical connector that at least partially houses the terminals. The female electrical connector may include an inlet opening through which a male electrical connector is received for electrical connection with the terminals. The female electrical connector may include one or more ramped surfaces defining the inlet opening.

The vehicle braking device performs a control which makes an actual value of physical quantity associated with a braking force follow a target value thereof when the actual value is outside a dead zone and a control which suppresses a change of the actual value when the actual value is within the dead zone and includes a judging portion which judges whether or not the actual value passes through the dead zone with a value beyond the upper limit threshold value and a setting portion which sets a second upper limit threshold value more closely approximated than a first upper limit threshold value when the actual value is judged not to pass through the dead zone, as the upper limit threshold value, when the actual value is judged to pass through the dead zone by the judging portion.

A method for use with a speed control system of a vehicle is provided. The method comprises receiving readings from one or more vehicle sensors to determine the nature of the terrain over which the vehicle is traveling. The method further comprises gathering information relating to one or more parameters of the vehicle that correspond to the configuration of the vehicle. The method still further comprises determining, based on the nature of the terrain and the gathered information, whether the vehicle is appropriately configured to travel over the terrain. A system comprising an electronic control unit configured to perform the method is also provided.

An active safety control system and method for a vehicle include: a plurality of motors arranged on a plurality of wheels; a plurality of brakes arranged on the plurality of wheels; a hydraulic braking device; a pedal detection device, used for detecting pedal signals of the vehicle; a motor state detection device, used for detecting the states of the plurality of motors; a plurality of wheel speed detection devices, arranged on the plurality of wheels, used for detecting speeds of the wheels and generating wheel speed detection signals; a power battery, connected with the plurality of motors respectively; and a control device, used for obtaining braking torques according to the pedal signals and the wheel speed detection signals, determining a corresponding braking mode according to the states of motors, and controlling the brakes, the motors and the hydraulic braking device according to the braking mode and the braking torques.

In an information providing method for a vehicle, an engine is stopped automatically when a predetermined permission condition is satisfied in a state in which the vehicle is stopped by a brake operation executed by a driver. The permission condition is a brake operation amount of a brake having reached a predetermined brake operation amount. The driver is notified of support information prompting the driver to increase the brake operation amount when the permission condition is not satisfied after a predetermined time has elapsed since the vehicle was stopped. A braking force capable of maintaining a vehicle stop state is generated by a vehicle stop keeping control. The driver is notified of the support information when the brake operation amount decreases before the predetermined time has elapsed in a state in which the vehicle has been stopped by the brake operation and the vehicle stop keeping control is executed.

The invention being presented uses the motors already included in an electric vehicle to charge its batteries while in tow. The charging process provided by the invention is compatible with the charging speed of current battery technology. It will provide an effective way of charging vehicles in theater, when other sources of electrical energy may not be available.

Moreover, the proposed system can actually extend the brake life of the towing vehicle and improve performance boundaries of the overall system.

An improved system for braking an agricultural vehicle propelled by a hydrostatic drive unit is disclosed. An operator provides a desired speed command from a first user interface, such as a joystick. The joystick generates a command responsive to the deflection and communicates the command to a controller. The agricultural vehicle also includes a second user interface, such as a brake pedal. The brake pedal includes a transducer configured to generate a signal corresponding to a deflection of the brake pedal which is also communicated to the controller. If the operator presses the brake pedal when the joystick is commanding motion, the controller reduces the signal from the joystick. The amount the signal is reduced increases as the deflection of the brake pedal increases until the brake pedal overrides any speed command from the joystick.

Methods, systems, and apparatus for controlling the braking of a vehicle. The brake control system includes a first sensor for detecting motion data of the vehicle and an electronic control unit connected to the first sensor. The electronic control unit is configured to determine that the vehicle is not in motion based on the motion data. The electronic control unit is configured to predict a brake application event that requires application of a braking force to prevent the vehicle from moving and cause brakes of the vehicle to apply the braking force to prevent the vehicle from moving based on the brake application event.

An electric brake system and a method for controlling the same are disclosed. The electric brake system includes a hydraulic control device, a sensing unit, and a controller. The hydraulic control device generates hydraulic pressure using a piston operated by an electric signal generated in response to a displacement of a brake pedal. The sensing unit detects driver's braking intention. When an electronic stability control (ESC) of a vehicle operates, the controller calculates a change amount of stroke of the piston needed to output brake pressure corresponding to the driver's braking intention, and acquires the calculated stroke change amount so as to boost pressure of each wheel at a predetermined slope.

A method for output of haptic information to a driver of a motor vehicle via a brake pedal includes ascertaining, based on signals of an environment-sensor system, imminence of a traffic situation that poses a potential risk to the motor vehicle, and modifying, during a driving of the motor vehicle, independent of a driver input, and in response to the ascertained imminence of the traffic situation, a characteristic of the brake pedal of the motor vehicle.