A vehicle door includes a trim panel coupled to a frame. A single-piece armrest substrate is coupled with the frame. The armrest substrate is a three-dimensionally printed member having interior walls that are printed within the armrest substrate according to a virtual force model generated during a virtual impact scenario. The interior walls define a plurality of voids defined within the armrest substrate.

A vehicle is configured to transport a passenger through autonomous travel. The vehicle includes an in-vehicle camera configured to image the passenger to generate an image, a camera controller configured to control the in-vehicle camera, and a passenger information detection unit configured to detect information about the passenger. The passenger information detection unit measures the number of passengers and the camera controller stops an operation of the in-vehicle camera in a case where the number of passengers is one.

In a collision detection device for a vehicle, the bumper absorber includes general parts and holding parts alternately in a lengthwise direction of the groove portion. In each of the general parts, a predetermined clearance is formed between an inner wall surface of the groove portion on at least one side of vehicle up and down sides, and the detection tube member. Each of the holding parts is in contact with a surface of the detection tube member on at least one side of vehicle up and down sides, and vehicle front and rear sides to hold the detection tube member. A holding part ratio, which is a ratio of a part of the detection tube member held by the holding parts to a unit length of the detection tube member, is set to be smaller than a predetermined value.

An active hinge including a hood bracket for attachment to a vehicle hood and a body bracket for attachment to a vehicle body. A deploy bracket is pivotally attached to the hood bracket and the body bracket. The hood bracket is pivotable relative to the deploy bracket between a non-deployed position and a deployed position. At least one link interconnects, and is pivotally connected to the deploy bracket and the body bracket. A pawl is pivotally mounted to one of the hood bracket, the body bracket, the deploy bracket, and the at least one link. A bolt for engagement by the pawl is connected to another of the hood bracket, the body bracket, the deploy bracket, and the at least one link. An actuator is provided for disengaging the pawl from the bolt to allow the deploy bracket to move relative to the hood bracket and the body bracket.

An occupant protection device includes: an airbag which is deployed and inflated rearward from an accommodation part so that the airbag receives the occupant when inflation gas flows in, the airbag having an inflation completion shape of a loop shape including an upper and lower portions which branch up and down from an inflow opening side and a rear portion which is a mutual connecting part between rear ends of the upper portion and the lower portion as a confluence part on a tip end side. The airbag includes: a bag main body including the upper portion, the lower portion, and the rear portion; and a connecting member having flexibility which is disposed between the upper portion and the lower portion and connects the upper portion and the lower portion so as to regulate a separation distance between the upper portion and the lower portion when inflation is completed.

An object is identified by an on-board camera and a relative speed of the vehicle and the object is acquired. If the object is a two-wheel vehicle and the relative speed is lower than the vehicle speed, the relative speed is set as a collision speed. If the object is an object other than a two-wheel vehicle, the vehicle speed is set as the collision speed. Using the set collision speed, an effective mass is computed and collision determination is executed.

A method includes receiving a first set of images from an image capture device of a vehicle. The method also includes performing a first analysis of movement of biomechanical points of occupants of the vehicle in the first set of images. The method further includes receiving an indication that a traffic incident has occurred. The method also includes receiving a second set of images from the image capture device corresponding to when the traffic incident occurred. The method further includes performing a second analysis of movement of the biomechanical points of the occupants in the second set of images. The method also includes determining a likelihood of injury or a severity of injury to the occupants based on the first analysis of movement and the second analysis of movement.

A laminate film for a vehicle occupant protection device has at least one copolyester barrier layer and at least one copolyester adhesive layer connected to the at least one barrier layer.

A vehicle is configured to transport a passenger through autonomous travel. The vehicle includes an in-vehicle camera configured to image the passenger to generate an image, a camera controller configured to control the in-vehicle camera, and a passenger information detection unit configured to detect information about the passenger. The passenger information detection unit measures the number of passengers and the camera controller stops an operation of the in-vehicle camera in a case where the number of passengers is one.

The present disclosure is directed to a pedestrian protection system that includes a first sensor that generates a first signal indicating a hazard condition in front of a vehicle. The pedestrian protection system may also include an external airbag system that deploys an external airbag outside of the vehicle. In operation, a processor receives the first signal from the first sensor, processes the first signal to detect the hazard condition, and activates the external airbag system in response to the detected hazard condition to protect at least one of a pedestrian and the vehicle.