Disclosed is a rescue device for adjusting the direction of an automobile falling into water through buoyancy. The rescue device comprises an automobile body, wherein storage cavities are formed in the automobile head and the automobile tail of the automobile body, a first high-pressure quick inflation pump is embedded in the inner wall of the storage cavity, a square buoyancy air bag is folded and stored in the storage cavity, an annular storage box body is embedded in a shell of the automobile body, meanwhile, the annular storage box body is located on the side close to the driving position of the automobile body, and an annular buoyancy air bag is folded and stored in the annular storage box body.

In an object detection apparatus, a proximity determination unit determines whether or not a first object and a second object are in close proximity to each other, where the first object is an object detected based on detection information acquired from a radar and the second object is an object detected based on a captured image acquired from a monocular camera. A sameness determination unit determines that the first object and the second object are the same object, if it is determined that the first object and the second object are in close proximity to each other and if a difference between a first collision time with the first object and a second collision time with the second object is less than a reference value.

The misalignment quantity calculating apparatus determines whether a first object detected by a beam sensor is identical to a second object detected by an image sensor. Upon determining that the first object is identical to the second object, the misalignment quantity calculating apparatus calculates, as a misalignment quantity of the beam sensor, an angle between a first line segment and a second line segment; the first line segment connects a predetermined reference point of the misalignment quantity calculating apparatus and a first feature point of the first object, and the second line segment connects the predetermined reference point and a second feature point of the second object.

In an object detection apparatus, a first trajectory estimation unit estimates a trajectory of a first object detected by an electromagnetic wave sensor. An optical flow acquisition unit image-processes a captured image acquired from a camera to acquire movement directions based on optical flows of feature points in the captured image. A movement direction match determination unit determines whether or not a match occurs between a movement direction based on the optical flows and a movement direction based on the trajectory of the first object. If a match occurs between the movement direction based on the optical flows of the plurality of feature points and the movement direction based on the trajectory of the first object, a sameness determination unit determines that a second object identified by the plurality of feature points and the first object are a same object.

An obstacle detection apparatus includes: a transceiver transmitting a transmission wave and receiving an ultrasonic wave; a transmission controller; a receiver circuit detecting a signal level of a receiving wave; a distance calculator sequentially calculating a distance to an object reflecting the transmission wave; a memory storing the distance to the object; an obstacle determinator determining whether the object is an obstacle; and a reception level monitoring device monitoring the signal level of the receiving wave before the transmission wave being transmitted. When the signal level exceeds a predetermined threshold, the obstacle determinator sets a first number of determination data elements to an increased number of determinations for a predetermined period to be used for determining whether the object is the obstacle, as being larger than a second number of determination data elements used when the signal level does not exceed the predetermined threshold.

A damage reduction device according to an embodiment of the present technology includes an input unit, a prediction unit, a recognition unit, and a determination unit. The input unit inputs status data regarding a status in a moving direction of a moving body apparatus. The prediction unit predicts a collision with an object in the moving direction on the basis of the status data. The recognition unit recognizes whether the object includes a person. The determination unit determines, when the collision with the object is predicted and it is recognized that the object includes a person, a steering direction of the moving body apparatus in which a collision with the person is avoidable, on the basis of the status data.

A damage reduction device according to an embodiment of the present technology includes an input unit, a prediction unit, a recognition unit, and a determination unit. The input unit inputs status data regarding a status in a moving direction of a moving body apparatus. The prediction unit predicts a collision with an object in the moving direction on the basis of the status data. The recognition unit recognizes whether the object includes a person. The determination unit determines, when the collision with the object is predicted and it is recognized that the object includes a person, a steering direction of the moving body apparatus in which a collision with the person is avoidable, on the basis of the status data.

There is provided a vehicular component which include an illumination device capable of favorably illuminating the periphery of a host vehicle. There is provided a vehicular component that includes an illumination device (3) installed on a roof part (30) and configured to cover a vehicle interior space from above. The illumination device (4) includes a light source unit (100) and a light emitting unit (300). The light emitting unit (300) configured to emit light by light emitted from the light source unit (100) is provided along an outer peripheral edge (31) of the roof part (30) in a top view of the vehicle (1).

There is provided a vehicular component which include an illumination device capable of favorably illuminating the periphery of a host vehicle. There is provided a vehicular component that includes an illumination device (3) installed on a roof part (30) and configured to cover a vehicle interior space from above. The illumination device (4) includes a light source unit (100) and a light emitting unit (300). The light emitting unit (300) configured to emit light by light emitted from the light source unit (100) is provided along an outer peripheral edge (31) of the roof part (30) in a top view of the vehicle (1).

A lane departure avoidance system includes: a recognition unit that recognizes a road edge of the road, and recognizes an outer line as a dividing line drawn on a road-edge side of a lane closest to the road edge; and an assist implementation unit that provides, within an area including the lane closest to the road edge and extending to the road edge, a forbidden position over which a vehicle is forbidden from going toward the road edge, and implements traveling assistance such that the vehicle does not go over the forbidden position. The system includes a shoulder width calculation unit that calculates, as a shoulder width, a width from the outer line to the road edge. The wider the shoulder width calculated by the shoulder width calculation unit is, the closer the forbidden position is set to the road edge by the assist implementation unit.