A park brake system and method for corroborated pressure reporting are provided. In one example implementation, primary and redundant park brake controllers read their respecting pressure sensors along an air channel to a parking brake. The controllers exchange the sensor readings, and each controller determines whether or not the sensor readings are in agreement. The controllers provide their determinations to an automated driving system. If the sensor readings are not in agreement, the automated driving system can partially or completely disengage or take some other action. Other implementations are provided.

A method includes collecting first data from a first sensor associated with a vehicle and determining, based on the first data, that an event involving the vehicle may occur. The method includes identifying a second sensor located within a proximity of the vehicle and causing the second sensor to collect second data. The method also includes associating the first data and the second data with a first event associated with the vehicle.

A method for controlling restart of a vehicle is provided. The method includes allowing the vehicle to enter into an ISG state and allowing the vehicle to actuate the Auto Hold. Whether the vehicle fulfills a condition for releasing the Auto Hold is then determined and operation of the Auto Hold is released in response to determining that the vehicle fulfills the condition for releasing the Auto Hold. Additionally, the method includes determining whether the vehicle fulfills a condition for releasing the ISG and releasing the ISG and restarting an engine in response to determining that the vehicle fulfills the condition for releasing the ISG.

An apparatus for activating a pedestrian detection and collision mitigation system (PDCMS) of a vehicle includes: an engine management system (EMS) acquiring speed information of the vehicle in real-time; an image collecting unit recognizing a pedestrian positioned within a driving lane of the vehicle and detecting information of a relative speed or a distance between the pedestrian and the vehicle, when a speed of the vehicle is greater than or equal to a set speed; and an electronic control unit (ECU) activating a PDCMS function based on a mapping table using the speed information of the vehicle and information of a motion or a distance of the pedestrian with respect to the vehicle, and controlling a warning unit to inform a driver of a collision of the pedestrian with the vehicle. The PDCMS function includes activating an operation of an active hood, activating an operation of the warning unit, and activating an operation of a brake regardless of whether the driver operates the brake. The activation of the operation of the warning unit and the activation of the operation of the brake comprise, in order: activating the operation of the warning unit, activating a partial braking of the vehicle, and activating a full braking of the vehicle.

An apparatus for operating a pedestrian detection and collision mitigation system (PDCMS) of a vehicle includes: an engine management system (EMS) acquiring speed information of the vehicle in real time; an image collecting device recognizing a pedestrian positioned within a driving lane of the vehicle and detecting information on a relative speed or a distance between the pedestrian and the vehicle, when a speed of the vehicle is equal to or greater than a set first speed; an electronic control unit (ECU) activating a PDCMS function based on a mapping table using speed information of the vehicle and information on a motion or a distance of the pedestrian with respect to the vehicle; and a warning device operated to inform a driver of a collision of the pedestrian with the vehicle by a control of the ECU.

An apparatus for activating a pedestrian detection and collision mitigation system (PDCMS) of a vehicle includes: a front detection sensor detecting a presence of a pedestrian on a driving lane of the vehicle, gaze information of the pedestrian, and a distance and a relative speed between the pedestrian and the vehicle; a vehicle sensor detecting at least any one of a speed, an acceleration, a steering angle, a steering angular velocity, and a pressure of a master cylinder of the vehicle; an electronic control unit activating a PDCMS function based on information detected by the front detection sensor and the vehicle sensor; and a warning unit operated to inform a driver of a collision of the pedestrian with the vehicle by a control of the electronic control unit.

Methods of estimating a weight of a vehicle and using the information are provided. Kinematic data of the vehicle, including at least one of a velocity or an acceleration of the vehicle, can be measured at a time. This data can be processed to estimate a weight of the vehicle. This data can be used to adjust autonomous driving, confirm a weight of freight carried by the vehicle, transmitted to external devices, or used in other ways.

A method of controlling energy regeneration for a mild hybrid vehicle, the mild hybrid vehicle including a mild hybrid starter generator (MHSG) that includes a rotor having a permanent magnet and an electromagnet, and engine that is connected to the MHSG for power transmission, may include determining whether a difference between an excitation current required to drive the MHSG and a desired amount of generated current is less than a predetermined reference value; and prohibiting regenerative braking when a difference between the excitation current required to drive the MHSG and the desired amount of generated current is less than the predetermined reference value.

A vehicle includes a speed detector detecting a vehicle speed, a brake system and a control system implementing a control mode including determining a threshold speed. The control system further derives an initial brake torque demand proportional to an error between the threshold speed and a vehicle speed exceeding the threshold speed and outputs to the brake system a rate-limited brake torque demand by applying a rate-limit operator based on the error to the initial brake torque demand.

A method of releasing an Automatic Vehicle Hold (AVH) function of an automotive vehicle equipped with a pedal simulator is provided. During operation of the AVH function, either a first mode for releasing the AVH function by an increase of torque of a power train by depressing the accelerator pedal or a second mode for releasing the AVH function by an increase of torque of the power train by depressing the brake pedal again is selected according to driving conditions.