In an in-vehicle structure described in the present specification, an electric-power converter is fixed onto a transaxle and positioned in front of a cowl top. The electric-power converter includes a capacitor configured to restrain a high-frequency fluctuation in a voltage of electric power supplied from a battery, and a discharge circuit configured to discharge the capacitor. A connector (a signal connector) to which a wiring harness for communication of a discharge instruction signal to operate the discharge circuit at a time of a collision is connected is provided on a side face of the electric-power converter, the side face of the electric-power converter being facing in a vehicle width direction.

A vehicle includes a first seat and a second seat occupying a vehicle body, a battery pack disposed between the first seat and the second seat, a first inboard airbag, and a second inboard airbag, and optionally a first outboard airbag and a second outboard airbag. The airbags are deployable from a packed position to or between an inflated position. The first inboard airbag is configured to deploy and occupy a space between the first seat and the battery pack, the first outboard airbag is configured to deploy and occupy a space between the first seat and the first side of the vehicle body, the second inboard airbag is configured to deploy and occupy a space between the second seat and the battery pack, and the second outboard airbag is configured to deploy and occupy a space between the second seat and the second side of the vehicle body.

The invention relates to the operation of a motor vehicle having a long-distance driver assistance system comprising at least one sensor which detects the area in front of a vehicle, and a control device which is designed to detect another motor vehicle traveling ahead, in order to drive the motor vehicle relative to the other vehicle traveling ahead when the driver assistance system is activated and operationally ready, wherein the activated driver assistance system can be deactivated from a control or regulating mode by driver activity, wherein upon deactivation, the system may enter into a system standby mode continuously detecting the area in front of the motor vehicle, and can reactivate autonomously once another motor vehicle traveling ahead is detected and a drag deceleration is required to reduce a velocity difference between the operated motor vehicle and the other vehicle traveling ahead.

A vehicle includes a first seat and a second seat occupying a vehicle body, a battery pack disposed between the first seat and the second seat, a first inboard airbag, and a second inboard airbag, and optionally a first outboard airbag and a second outboard airbag. The airbags are deployable from a packed position to or between an inflated position. The first inboard airbag is configured to deploy and occupy a space between the first seat and the battery pack, the first outboard airbag is configured to deploy and occupy a space between the first seat and the first side of the vehicle body, the second inboard airbag is configured to deploy and occupy a space between the second seat and the battery pack, and the second outboard airbag is configured to deploy and occupy a space between the second seat and the second side of the vehicle body.

A method of monitoring a vehicle includes monitoring a precollision fuel level, detecting a collision event, and detecting a vehicle orientation based at least on the precollision fuel level and a postcollision fuel level. The method can be executed by a controller having a processor and a memory storing processor-executable instructions where the processor is programmed to monitor the precollision fuel level, detect the collision event, and detect the vehicle orientation based on at least a precollision fuel level and a postcollision fuel level.

Systems of an electrical vehicle and the operations thereof are provided. In particular, a towing cable and methods for utilizing the same in a towing scenario are described. The towing cable is described to facilitate the transfer of power between vehicles as well as data between vehicles. The data transferred between the vehicles involved in the towing include sensor information of the towed vehicle as well as control signals.

A method of monitoring a vehicle includes monitoring a precollision fuel level, detecting a collision event, and detecting a vehicle orientation based at least on the precollision fuel level and a postcollision fuel level. The method can be executed by a controller having a processor and a memory storing processor-executable instructions where the processor is programmed to monitor the precollision fuel level, detect the collision event, and detect the vehicle orientation based on at least a precollision fuel level and a postcollision fuel level.

The invention relates to a method for operating a motor vehicle (1) having a long-distance driver assistance system (2) comprising at least one sensor (3) which detects the area in front of a vehicle, and a control device (4) which is designed to detect a vehicle traveling ahead as a function of sensor information and to output control or regulating commands to one or more of the vehicle components (5, 6) used for long-distance driving in order to drive the motor vehicle (1) relative to the vehicle ahead when the driver assistance system (2) is activated and operationally ready, wherein the activated and operationally ready driver assistance system (2) can be deactivated from a control or regulating mode by a driver activity and vice versa, wherein, when no vehicle ahead is detected by the activated driver assistance system (2) and the driver assistance system (2) is deactivated by a driver activity, detection of the area in front of the vehicle is continuously carried out and, when a vehicle ahead is detected, either a notification is output to the driver to reactivate the driver assistance system and to place the system in control or regulating mode by means of another driver activity, or the driver assistance system is activated autonomously and switched to the control or regulating mode.

A shift control method of an electronic shift lever may include detecting a collision of a vehicle when the vehicle is in an ignition-on state, detecting a shift range of the electronic shift lever, and preventing shifting by interrupting delivery of a signal for changing the shift range to a transmission, when the signal for changing the shift range is detected within a predetermined time after the detection of the collision.