An automobile hood 1 has an inner panel 2, an outer panel 3, and a plurality of linear sealer regions A in which joints 21 are arranged. A region which includes the linear sealer region A and in which both ends in a longitudinal direction L of the linear sealer region A reach the outer circumferential edge of the inner panel 2 is defined as an end-to-end region B. Each of three longest linear sealer regions A2, A4 and A3 among the plurality of linear sealer regions A is a length that is 40% or more of the length of an end-to-end region B2, B4 or B3 to which the linear sealer regions A2, A4 or A3 belongs, respectively. These three end-to-end regions B2, B4 and B3 do not intersect with each other within a region surrounded by the outer circumferential edge of the inner panel 2.

An automobile hood 1 has an inner panel 2, an outer panel 3, and a plurality of linear sealer regions A in which joints 21 are arranged. A region which includes the linear sealer region A and in which both ends in a longitudinal direction L of the linear sealer region A reach the outer circumferential edge of the inner panel 2 is defined as an end-to-end region B. Each of three longest linear sealer regions A2, A4 and A3 among the plurality of linear sealer regions A is a length that is 40% or more of the length of an end-to-end region B2, B4 or B3 to which the linear sealer regions A2, A4 or A3 belongs, respectively. These three end-to-end regions B2, B4 and B3 do not intersect with each other within a region surrounded by the outer circumferential edge of the inner panel 2.

Methods and systems for autonomous and semi-autonomous vehicle control, routing, and automatic feature adjustment are disclosed. Sensors associated with autonomous operation features may be utilized to search an area for missing persons, stolen vehicles, or similar persons or items of interest. Sensor data associated with the features may be automatically collected and analyzed to passively search for missing persons or vehicles without vehicle operator involvement. Search criteria may be determined by a remote server and communicated to a plurality of vehicles within a search area. In response to which, sensor data may be collected and analyzed by the vehicles. When sensor data generated by a vehicle matches the search criteria, the vehicle may communicate the information to the remote server.

A vehicle front structure that reduces a shock load applied to immediately under a front grille by using a bumper beam as a support. A vehicle front structure includes a shock absorbing member at an interior of a bumper face on the side near an upper portion thereof which absorbs a load from the diagonally upper front side. The shock absorbing member is at the interior of the bumper face below a front grille, and includes a load receiving portion that receives a load, a locking portion locked to an upper end edge of a bumper beam located behind and below the load receiving portion, at the time of receding of the shock absorbing member, and a connecting portion connecting the load receiving portion and the locking portion. A deformation facilitating portion with respect to a load from the upper front side is thus configured at the connecting portion.

An outside protection apparatus includes: an outside airbag device including an expandable member expandable rearward from a front portion of a body of a vehicle so as to be overlaid on a hood of the body, and an inflator that expands the expandable member; a collision detector that predicts or detects a collision between the body and a outside person outside the vehicle; and a controller that expands the expandable member when the collision detector predicts or detects a collision. The expandable member includes: a front bag portion expandable at the front portion of the body so as to be overlaid on the hood; a rear bag portion expandable in a location closer to rear than the front bag portion; and a tensile member coupled together with the rear bag portion to the body. The rear bag portion is expandable by the tensile member to stand on the hood.

A school bus stop arm with integrated camera system includes a mounting box, an arm-actuating assembly, a stop sign, and a video camera unit. The arm-actuating assembly includes an actuating mechanism, an activation switch, and an elongated arm. The actuating mechanism is mounted within the mounting box so that the elongated arm can moved between a folded position and extended position. A proximal end of the elongated arm is mounted to the actuating mechanism. The stop sign is adjacently mounted to a distal end of the elongated arm. The video camera unit is mounted to the stop sign. The activation switch is operatively coupled with the elongated arm, wherein the activation switch selectively turns the video camera unit on or off based on the positioning of the elongated arm.

A school bus stop arm with integrated camera system includes a mounting box, an arm-actuating assembly, a stop sign, and a video camera unit. The arm-actuating assembly includes an actuating mechanism, an activation switch, and an elongated arm. The actuating mechanism is mounted within the mounting box so that the elongated arm can moved between a folded position and extended position. A proximal end of the elongated arm is mounted to the actuating mechanism. The stop sign is adjacently mounted to a distal end of the elongated arm. The video camera unit is mounted to the stop sign. The activation switch is operatively coupled with the elongated arm, wherein the activation switch selectively turns the video camera unit on or off based on the positioning of the elongated arm.

A vehicle is provided that includes a hood outer panel, hood inner panel, and engine compartment. A fender attachment bracket is disposed within the engine compartment, and a headlight assembly includes an attachment portion that couples the headlight assembly to the fender attachment bracket. The headlight assembly also includes a load block or loading block sized and shaped so that when the hood outer panel and hood inner panel are deformed by the impact of an object, the hood inner panel contacts the load block.

A managing apparatus for positioning rental vehicles includes a memory storing instructions and a processor configured to execute the instructions to cause the managing apparatus to access model information and location information for a plurality of autonomous vehicles, receive a request including a delivery location and a chosen model for renting, select an autonomous vehicle of the chosen model from among the plurality of autonomous vehicles based on the model information, the location information, and the delivery location, instruct the selected autonomous vehicle to fully-autonomously or semi-autonomously travel to the delivery location, and instruct the selected autonomous vehicle to switch to manual operation mode at the delivery location for manual operation by a vehicle rental customer.

A managing apparatus for positioning rental vehicles includes a memory storing instructions and a processor configured to execute the instructions to cause the managing apparatus to access model information and location information for a plurality of autonomous vehicles, receive a request including a delivery location and a chosen model for renting, select an autonomous vehicle of the chosen model from among the plurality of autonomous vehicles based on the model information, the location information, and the delivery location, instruct the selected autonomous vehicle to fully-autonomously or semi-autonomously travel to the delivery location, and instruct the selected autonomous vehicle to switch to manual operation mode at the delivery location for manual operation by a vehicle rental customer.