A vehicle diagnostic and communication system includes a controller with computer executable instructions configured to diagnose operational capability of vehicle operating systems in response to a recognized collision event. The controller is further configured to determine a severity of damage to the vehicle operating systems based on the diagnoses and generate a communication signal based on the determined severity of damage to the vehicle for transmission. The system determines which of a plurality of service providers to send the communication signal based on the severity of damage to the vehicle.

A vehicle diagnostic and communication system and method provides for recognizing a collision event with at least one device associated with a safety system of a vehicle and diagnosing operational capability of vehicle operating systems with an onboard vehicle controller in response to the recognized collision event. The diagnosis provides a determination of a severity of damage to the vehicle operating systems that is used to determine an impact on traffic proximate to the collision and transmit a communication based on the determined impact on traffic to other vehicles and an infrastructure device proximate the collision event.

A communication system for a vehicle includes an accelerometer, and a controller electrically coupled to the accelerometer and configured to respond to a signal indicative of an accident of the vehicle. The controller's response to the signal includes activating an emergency mode, requesting biometric data of occupants of the vehicle, and transmitting data identifying the vehicle, a location of the vehicle and a time of activation, and biometric data.

Event-based connected vehicle control and response systems, methods, and apparatus are disclosed. An example method comprises identifying the occurrence of an event, storing first data corresponding to apparatus operation for a first threshold amount of time prior to the event, during the occurrence of the event, and for a second threshold amount of time after the event, determining whether a responsive object is involved in or near the event, in response to determining that the responsive object is involved in or near the event, transmitting the first data to the responsive object, and receiving, from the responsive object, second data, analyzing the first data and the second data to determine a party at-fault for the event, aggregating the first data and second data into an event report, and causing, automatically, a response to be initiated through an entity associated with the party at-fault.

A motor vehicle with an electric motor, in particular a hybrid or electric vehicle, has a high-voltage vehicle electrical system with a high-voltage stored energy source which supplies electrical energy to the electric motor for driving the motor vehicle, and a low-voltage vehicle electrical system for supplying electricity to a number of consumers in the motor vehicle. An electrical signal path is provided between the low-voltage vehicle electrical system and the high-voltage vehicle electrical system and powered by the voltage from the low-voltage vehicle electrical system. A controller in the motor vehicle is configured to cause a predetermined change of the signal on the signal path from a first signal state to a second signal state, wherein the first signal state indicates normal operation of the motor vehicle and the second signal state indicates an emergency state of operation of the motor vehicle which deviates from normal operation. The high-voltage vehicle electrical system is designed to separate the high-voltage stored energy source from the high-voltage vehicle electrical system in response to the predetermined signal change. The signal path includes a first and a second signal line, wherein the predetermined change of the signal on the signal path includes a change of the signal level on each of the first and second signal lines.

Methods and systems for enhancing the functionality of a semi-autonomous vehicle are described herein. The semi-autonomous vehicle may receive a communication from a fully autonomous vehicle within a threshold distance of the semi-autonomous vehicle. If the vehicles are travelling on the same route or the same portion of a route, the semi-autonomous vehicle may navigate to a location behind the fully autonomous vehicle. Then the semi-autonomous vehicle may operate autonomously by replicating one or more functions performed by the fully autonomous vehicle. The functions and/or maneuvers performed by the fully autonomous vehicle may be detected via sensors in the semi-autonomous vehicle and/or may be identified by communicating with the fully autonomous vehicle to receive indications of upcoming maneuvers. In this manner, the semi-autonomous vehicle may act as a fully autonomous vehicle.

A system for detecting a vehicular collision (i) receives internal data from at least one internal sensor of a vehicle; (ii) receives external data from at least one external sensor; (iii) determines that a vehicle collision is imminent based upon the received external data; (iv) determines positional information for at least one occupant of a vehicle; and (v) automatically engages an autonomous or semi-autonomous vehicle system to mitigate at least one of vehicle damage and occupant injury caused by the vehicle collision. As a result, the potential injury to at least one occupant is reduced. The system may also utilize 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 features, and/or generate virtual reconstructions of the vehicle collision.

A vehicle includes a window and a striker positioned to strike the window. The vehicle includes an actuator positioned to drive the striker. The vehicle includes a temperature sensor in communication with the actuator.

The present invention relates to an intelligent electric vehicle to predict the accident and notify before accident. The present invention identifies the real-time position and the mobile WIFI network connection which is an example of a person being in the car. Through this, the position-detecting vehicle technology, the car also alarms the immediate response team with the fact that a request is being made when a collision is happening and that the victim has been identified using call-based technology. As the crosswalk detection unit senses a pedestrian crossing the road ahead, a stopping system examines the driving behavior of vehicles behind the vehicle to determine whether they are blocking the way, and decides only whether not and stop the vehicle to make way clear for the crossing of the person. The invention also provides process and methods for dynamically defining a safety zone around a user.

Short range wireless location and motion sensing devices and reporting methods are provided herein. An example device includes a housing configured to couple with a power port of a vehicle. The housing includes a wireless interface, a motion sensor that senses at least one of velocity, acceleration, and orientation of the vehicle, a processor and a memory that stores logic that is executed by the processor to receive motion signals from the motion sensor and transmit the motion signals on the wireless interface to a mobile device that is communicatively coupled with the wireless adapter.