A system/method using a sensor arrangement in a vehicle interior with an occupant and vehicle systems may comprise a user interface and computing system to process input/signal and data from data sources to facilitate operation and to provide output/signal with connectivity with occupants, vehicle systems, networks, etc. relating to operation, events, conditions, etc. Output may comprise information/interaction at a user interface, to vehicle systems, network communications, etc. The system may use data to provide output comprising enhancement and/or augmentation of input; output may comprise a signal based on data analytics/processing including application of artificial intelligence models and/or augmented reality models. The system may comprise a distributed sensor matrix to obtain data/input from a sensor field within the vehicle; data sources may comprise the sensor matrix, vehicle systems, data storage and/or networks. The sensor/matrix may be for use with an interior component in personal vehicles, commercial/industrial vehicles, autonomous vehicles, etc.

Methods, communication devices, and systems are disclosed for automatically controlling sound producing components of a vehicle. In one embodiment, the method includes receiving an incoming communication and sending a first instruction to one or more vehicle components. The first instruction is configured to cause the one or more vehicle components to be placed in a reduced sound producing operational mode.

Methods, communication devices, and systems are disclosed for automatically controlling sound producing components of a vehicle. In one embodiment, the method includes receiving an incoming communication and sending a first instruction to one or more vehicle components. The first instruction is configured to cause the one or more vehicle components to be placed in a reduced sound producing operational mode.

A desired change of a time derivative of dynamic torque (Tq.sub.fw), provided to an output shaft from an engine in a vehicle, from a current value to a new desired value is determined. A current rotational speed difference (??.sub.pres) is determined between a first end of the powertrain in a vehicle, which rotates with a first rotational speed (?.sub.1), and a second end of the powertrain, which rotates with a second rotational speed. The first rotational speed (?.sub.1) is then controlled on the basis of the desired value of the time derivative for the dynamic torque (Tq.sub.fw), a spring constant (k) related to a torsional compliance in the powertrain, and the determined current rotational speed difference {??.sub.pres). Through control of the first rotational speed, the current value for the time derivative for the dynamic torque is also indirectly controlled towards the desired value.

A parking system adaptively controlling a vehicle during a parking maneuver using a park assist system, for example an active park assist (APA) or trailer backup assist (TBA). Control of the park assist system based on previous speed profiles at a geographic location where the same park assist system was previously activated. The parking system including an activation system that, based on vehicle speed and geographic location, activates the park assist system when preconditions for park assist system operation are met. The activation system may cooperate with the park assist system based on default or previously stored drive history profiles associated with the current geographic location.

A parking system adaptively controlling a vehicle during a parking maneuver using a park assist system, for example an active park assist (APA) or trailer backup assist (TBA). Control of the park assist system based on previous speed profiles at a geographic location where the same park assist system was previously activated. The parking system including an activation system that, based on vehicle speed and geographic location, activates the park assist system when preconditions for park assist system operation are met. The activation system may cooperate with the park assist system based on default or previously stored drive history profiles associated with the current geographic location.

A system includes a processor configured to receive weather data including a plurality of measured data points in an area around a vehicle, from a remote weather server. The processor is also configured to receive a path from a vehicle subsystem. The processor is further configured to combine the data points and path to form a predictive model reflecting expected weather conditions along the path at future times, the model based on predefined parameters defining expected weather behavior and send the model to a requesting vehicle subsystem.

An engine ECU includes a traveling control unit configured to bring a clutch device into a disconnection state to perform inertial traveling of a vehicle according to satisfaction of predetermined inertial traveling implementation conditions and configured to bring the clutch device into a connection state to cancel an inertial traveling state and perform regenerative power generation according to satisfaction of predetermined regenerative power generation implementation conditions during the inertial traveling, and a required power calculation unit configured to calculate required power of the vehicle; and the traveling control unit selectively performs the inertial traveling or the regenerative power generation an ISG based on the required power calculated in a state in which the inertial traveling implementation conditions are satisfied.

Embodiments herein relate to an autonomous vehicle or self-driving vehicle with a vehicle control system. The vehicle control system can determine, prior to and/or during a collision, whether an escape path exits. If an escape path exists, the brakes are disengaged such that at least some of the energy and/or momentum from a colliding vehicle is transferred and a jolt or shock experienced by an occupant is reduced.

Disclosed is an electric vehicle, comprising a chassis (1), a vehicle body and a power battery (71), wherein the chassis (1) comprises a frame system (2), a steering motor damping system (13) mounted on the frame system (2), a wheel system (12) connected to the steering motor damping system (13), a steering system (3) mounted on the frame system (2), and a braking system (4) mounted on the frame system (2); and the wheel system (12) comprises a left front wheel (121) using a hub motor, a left rear wheel (123) using a hub motor, a right front wheel (122) using a hub motor, and a right rear wheel (124) using a hub motor. Driving the wheels (121, 122, 123, 124) with the hub motors can omit a traditional mechanical transmission system, so as to simplify the structure of the chassis (1) and reduce the weight of the chassis (1). Compared with a traditional electric vehicle, the electrical vehicle has a lighter weight, smaller volume, reduced mechanical transmission loss, and improved electrical energy utilization rate.