A system for detecting a vehicular collision (i) receives occupant data from at least one internal sensor; (ii) receives external data from at least one external sensor; (iii) determines positional information for at least one occupant of a vehicle; and (iv) generates a virtual reconstruction of the vehicle collision. The virtual reconstruction indicates a severity of vehicle damage and a severity of injury to the at least one occupant caused by the vehicle collision. The system may also utilized vehicle occupant positional data, and internal and external sensor data to detect potential imminent vehicle collisions, take corrective actions, automatically engage autonomous or semi-autonomous vehicle systems, and/or perform at least one action to reduce a severity of a potential injury.

A vehicle surrounding environment monitoring apparatus includes an imaging device, a memory, a notifier, and a vehicle control processor. The imaging device acquires surrounding person facial information on the surrounding person. The memory stores occupant facial information on an occupant of the vehicle. The notifier issues a notification to one or both of the surrounding person and the occupant. The vehicle control processor performs a determination as to whether the surrounding person is the occupant by comparing the surrounding person facial information with the occupant facial information. The vehicle control processor causes the notifier to issue the notification to one or both of the surrounding person and the occupant when determining that the surrounding person is not the occupant. The vehicle control processor refrains from causing the notifier to issue the notification to the surrounding person when determining that the surrounding person is the occupant.

Methods and apparatus for determining seatbelt status are disclosed. An example system includes a plurality of seats including seatbelts. Each of the seatbelts includes a sensor to detect a position of a respective seatbelt, the position including at least one of a fastened position or an unfastened position, and a transceiver to wirelessly communicate the position of the respective seatbelt. The system includes a remote monitoring unit to receive the positions of the seatbelts. The remote monitoring unit is to determine if one or more seats are occupied and, in response to determining that one or more seats are occupied, the remote monitoring unit is to display an overview the seats and the respective positions of the seatbelts for the one or more occupied seats.

Methods and apparatus for determining seatbelt status are disclosed. An example seatbelt system for a mass transit vehicle includes a first seatbelt of a first seat that includes a first buckle and a first magnetically-responsive switch to detect a first tongue when the first seatbelt is in a fastened position. The example apparatus includes a second seatbelt of a second seat that includes a second buckle and a second magnetically-responsive switch to detect a second tongue when the second seatbelt is in the fastened position. The example apparatus includes a remote monitoring unit to indicate, when the first seat is occupied, if the first seatbelt is in the fastened positioned or an unfastened position. The remote monitoring unit is to indicate, when the second seat is occupied, if the second seatbelt is in the fastened positioned or the unfastened position.

A restraint system includes a side air curtain, a sail panel, and a secondary cushion. The side air curtain is inflatable to an inflated position and has a top edge, a bottom edge, and a forward edge extending from the top edge to the bottom edge. The sail panel extends from the forward edge. The secondary cushion is inflatable to an inflated position and is elongated in a direction away from the bottom edge and the forward edge toward the top edge.

A collision avoidance system for vehicles is presented. The system includes at least one sensor for determining proximity information such as speed, direction and distance of one or more other vehicles in close proximity to a subject vehicle, a computer system for processing the proximity information to determine if collision is imminent between the subject vehicle and one or more of the other vehicles. The subject vehicle and the other vehicles with which collision is imminent have at least one electromagnet that can be activated to prevent or minimize the impending collision. The collision avoidance system may be coupled with the subject vehicle's engine control and the braking control to provide additional collision avoidance protection in addition to the repelling force resulting from activating the electromagnets of the subject vehicle and the one or more of other vehicles per the method of the invention.

A safety system for a motor bike includes an evaluation and control unit which receives crash-relevant information from at least one sensor unit and evaluates it for the purpose of detecting a crash, and in response to a detected crash, the evaluation and control unit activates at least one external safety component and/or at least one internal safety component using a triggering concept. The evaluation and control unit receives presence signals from the at least one external safety component and/or the at least one internal safety component and evaluates the received signals in order to detect the safety components currently available. The evaluation and control unit selects the triggering concept as a function of the detected safety components currently available.

A seat monitoring system for monitoring a state of at least one seat arrangeable in a vehicle's interior and determining the position of the seat in the interior. The monitoring system has a control module, two sending modules signally connected to the control module, and at least one seat module associated with at least one seat and a receiving module. The two sending modules are spaced apart from one another and each have one antenna, the receiving module has two antennas. A first antenna of the receiving module is configured to receive a signal from a first sending module of the sending modules, and a second antenna of the receiving module is configured to receive a signal from a second sending module of the sending modules. The receiving module is configured to determine signal strengths of the signals received by the antennas of the receiving module for position determination.

Methods and systems are provided for transmitting video data associated with a vehicle. In one exemplary embodiment, a vehicle processor determines a vehicle safety event based on one or more safety sensors, activates one or more vehicle cameras that capture video data in response to the determined vehicle safety event, records the video data in a vehicle data storage device, and, if the vehicle processor determines that a suitable connection to a telecommunications network is available when the video data is being captured, then transmits the video data over the telecommunications network in substantially real time.

Among other things, a documentation of a crash involving a vehicle is generated automatically. Telematics data is received that has been produced by one or more sensors associated with a telematics device at the vehicle. Based on the telematics data, a vehicle crash period is determined that begins at a start time and ends at an end time of the vehicle crash. Based on the telematics data, one or more metrics are determined associated with the vehicle during the vehicle crash period. Based on one or more metrics, a human-readable documentation of the vehicle crash is generated automatically.