A method of using detection devices for hazard detection when activating a physical closure member of an automobile generates a combined output signal from a first-detection device having a first-operational range and a second-detection device having a second-operational range. The combined output signal is generated for activity detected within a full-operational range, wherein the full-operational range is a mathematical union of the first-operational range and the second-operational range. A cumulative safety threshold is determined for the physical closure member using processing circuitry. Hazard-related data within the combined output signal is analyzed using processing circuitry. If the hazard-related data exceeds the cumulative safety threshold, a current state of the physical closure member is changed. If the hazard-related data does not exceed the cumulative safety threshold, a current state of the physical closure member is maintained.

An indicator is provided in a vehicle for indicating necessity of change of a fuel vapor absorber in a venting line of a vehicle tank, especially a methanol tank for fuel cell vehicles.

An indicator is provided in a vehicle for indicating necessity of change of a fuel vapor absorber in a venting line of a vehicle tank, especially a methanol tank for fuel cell vehicles.

The disclosure provides a steering system for a vehicle. The steering system may include a steering rack and an electronic power steering (EPS) system. The EPS system may include an actuator that assists movement of the steering rack, a torque sensor; an angle sensor; and an EPS system controller. The EPS controller may be configured to determine a steering rack center point indicating a center of the steering rack between opposite maximum steering angles. The EPS controller may be configured to determine a vehicle center zero point. The EPS controller may be configured to store the vehicle center zero point in response to determining that the vehicle center zero point is within a threshold of the steering rack center point.

The disclosure provides a steering system for a vehicle. The steering system may include a steering rack and an electronic power steering (EPS) system. The EPS system may include an actuator that assists movement of the steering rack, a torque sensor; an angle sensor; and an EPS system controller. The EPS controller may be configured to determine a steering rack center point indicating a center of the steering rack between opposite maximum steering angles. The EPS controller may be configured to determine a vehicle center zero point. The EPS controller may be configured to store the vehicle center zero point in response to determining that the vehicle center zero point is within a threshold of the steering rack center point.

A controller for a motor vehicle having an internal combustion engine, and a device for detecting a fire in a fluid conduit, the device having a fluid state sensor for detecting a state variable of a fluid that is conducted in the fluid conduit, are provided. The determination of a fire situation is performed in a manner dependent on a signal of the fluid state sensor.

A controller for a motor vehicle having an internal combustion engine, and a device for detecting a fire in a fluid conduit, the device having a fluid state sensor for detecting a state variable of a fluid that is conducted in the fluid conduit, are provided. The determination of a fire situation is performed in a manner dependent on a signal of the fluid state sensor.

A method and a system of diagnosing a vehicle oil leak are capable of detecting an oil leak state of transmission oil on the basis of logic. The method includes an operating condition determination step of determining, by a controller, whether a minimum operating condition of a vehicle is satisfied. The minimum operating condition is required to normally generate a target line pressure by operating an EOP. The method includes a counting step of counting, by the controller, an operating time of the EOP when the minimum operating condition is satisfied and includes an oil leak diagnosis step of diagnosing, by the controller, an oil leak when the counted continuous operating time of the EOP is a permissible time or more.

A method and a system of diagnosing a vehicle oil leak are capable of detecting an oil leak state of transmission oil on the basis of logic. The method includes an operating condition determination step of determining, by a controller, whether a minimum operating condition of a vehicle is satisfied. The minimum operating condition is required to normally generate a target line pressure by operating an EOP. The method includes a counting step of counting, by the controller, an operating time of the EOP when the minimum operating condition is satisfied and includes an oil leak diagnosis step of diagnosing, by the controller, an oil leak when the counted continuous operating time of the EOP is a permissible time or more.

A vehicular safety system includes a rearward-viewing camera, a forward-viewing camera and an interior-viewing camera configured to be disposed at a vehicle. Image data captured by the forward-viewing camera is processed for (i) headlamp control, (ii) lane departure warning and/or (iii) object detection. Image data captured by the interior-viewing camera is processed for internal cabin surveillance. Responsive at least in part to processing of image data captured by at least one selected from the group consisting of (i) the rearward-viewing camera, (ii) the forward-viewing camera and (iii) the interior-viewing camera, and when reverse gear of the vehicle is not engaged, and responsive to determination of a potential collision involving the vehicle, a safety feature of the vehicle is triggered before actual collision occurs. If actual collision does not occur, the triggered safety feature returns to its condition that existed prior to determination of the potential collision.