A system and method for reducing the risk of road accidents on account of blind spot errors and a vehicle using the system and method includes a visual sensing unit, the visual sensing unit comprising a first camera and a second camera, wherein the first camera looks left and obtains a first image information, the second camera looks to the right and obtains a second image information; a pre-processing unit, the pre-processing unit being coupled with the visual sensing unit, wherein the pre-processing unit processes the first image information and the second image information to generate a single image. An image processing unit generates an obstacle recognition information according to the processed image.

A system and method for reducing the risk of road accidents on account of blind spot errors and a vehicle using the system and method includes a visual sensing unit, the visual sensing unit comprising a first camera and a second camera, wherein the first camera looks left and obtains a first image information, the second camera looks to the right and obtains a second image information; a pre-processing unit, the pre-processing unit being coupled with the visual sensing unit, wherein the pre-processing unit processes the first image information and the second image information to generate a single image. An image processing unit generates an obstacle recognition information according to the processed image.

A car seat includes an actuator capable of changing an orientation of a rest surface of a seat back laterally by turning and moving at least a side portion frame that is part of the car seat frontward and rearward, and a controller configured to exercise control over the actuator. The controller includes a run-time posture support unit configured to execute a run-time posture support control under which when a car makes a turn, the actuator is regulated to cause the rest surface of the seat back to be oriented in a direction of the turn. The run-time posture support unit is configured to regulate the actuator in accordance with a placement of the seat in the car, when the run-time posture support unit executes the run-time posture support control.

An opening switch for a vehicle having a decorative cover assembly, a sensor housing region, and a microelectromechanical (MEMS) sensor mounted in the sensor housing region. The decorative cover assembly has an inner surface, an outer surface, an anchor portion, and a deflection portion. When contact from a vehicle user occurs at the deflection portion in the decorative cover assembly, a microdeflection occurs. The microdeflection has a microdeflection apex, and the microdeflection apex is spaced from other surfaces in the sensor housing region when the contact from the user occurs at the deflection portion in the decorative cover assembly. The MEMS sensor is configured to generate an output signal that is indicative of a force of the contact from the user. The force integrated switch can include haptic feedback and/or backlighting.

An opening switch for a vehicle having a decorative cover assembly, a sensor housing region, and a microelectromechanical (MEMS) sensor mounted in the sensor housing region. The decorative cover assembly has an inner surface, an outer surface, an anchor portion, and a deflection portion. When contact from a vehicle user occurs at the deflection portion in the decorative cover assembly, a microdeflection occurs. The microdeflection has a microdeflection apex, and the microdeflection apex is spaced from other surfaces in the sensor housing region when the contact from the user occurs at the deflection portion in the decorative cover assembly. The MEMS sensor is configured to generate an output signal that is indicative of a force of the contact from the user. The force integrated switch can include haptic feedback and/or backlighting.

A method for alerting a driver includes detecting an object in a spatial environment adjacent to a vehicle and identifying a set of output devices located within a cabin of the vehicle. Each one of the set of output devices may be located at a different location of the cabin. The method also includes selecting an output device of the set of output devices based on a location of the object in relation to the vehicle and generating a notification via the selected output device.

A method for alerting a driver includes detecting an object in a spatial environment adjacent to a vehicle and identifying a set of output devices located within a cabin of the vehicle. Each one of the set of output devices may be located at a different location of the cabin. The method also includes selecting an output device of the set of output devices based on a location of the object in relation to the vehicle and generating a notification via the selected output device.

A vehicular pedal device includes a stroke characteristic control unit that controls a stroke characteristic of the vehicular pedal with respect to a pedaling force of a driver. the stroke characteristic control unit changes the stroke characteristic of the vehicular pedal to a stepped stroke characteristic when the vehicle is under automatic speed control, and the stepped stroke characteristic has a stepping force step corresponding to an override stroke position at which override of automatic speed control is started by operation of the vehicular pedal by the driver.

The present invention obtains a controller and a control method capable of improving safety of adaptive cruise operation in a motorcycle.

In the controller for operation of the motorcycle, to which a surrounding environment detector is mounted, an adaptive cruise operation performing section controls deceleration to be generated by the motorcycle in adaptive cruise operation to be equal to or lower than an upper limit value or to be lower than the upper limit value, determines a collision possibility of the motorcycle on the basis of the upper limit value during the adaptive cruise operation, and performs warning operation that acts on a tactile organ of a rider of the motorcycle when determining that the collision possibility is high.

The present invention obtains a controller and a control method capable of improving safety of adaptive cruise operation in a motorcycle.

In the controller for operation of the motorcycle, to which a surrounding environment detector is mounted, an adaptive cruise operation performing section controls deceleration to be generated by the motorcycle in adaptive cruise operation to be equal to or lower than an upper limit value or to be lower than the upper limit value, determines a collision possibility of the motorcycle on the basis of the upper limit value during the adaptive cruise operation, and performs warning operation that acts on a tactile organ of a rider of the motorcycle when determining that the collision possibility is high.