A vehicle control device has a processor configured to estimate whether or not a driver is attempting to begin vehicle travel after a vehicle has been activated, based on a photographed image of an area near a driving seat, and to control an electrical oil pump to supply a second hydraulic pressure that is lower than a first hydraulic pressure which allows operation of a transmission having a frictional engagement element that can be engaged and disengaged by hydraulic pressure, when it has been estimated that the driver is not attempting to begin vehicle travel, or to control the electrical oil pump to supply the first hydraulic pressure to the transmission, when it has been estimated that the driver is attempting to begin vehicle travel.

A system and method for operating a vehicle having different operating modes affecting emissions include activating, by a vehicle controller, at least one of the different operating modes affecting emissions selected in response to an estimated population density of a designated area associated with a current location or an anticipated future location of the vehicle.

The disclosure includes a system and method for reconfiguring a vehicle based on one or more preferences of a first user without the first user directly providing an input to the vehicle to reconfigure the vehicle. The method may include wirelessly receiving first user profile data at a vehicle. The first user profile data may be associated with a first user. The first user profile data may describe how one or more settings of the vehicle should be configured for the first user. Upon receipt of the first user profile data, the vehicle may be configured in accordance with second user profile data describing how the one or more settings of the vehicle should be configured for a second user. The method may include reconfiguring the one or more settings of the vehicle based on the first user profile data so that the vehicle is reconfigured for the first user.

A method of controlling a change of a travelling mode of a hybrid vehicle is provided. The method includes calculating, by a controller, system required power required by a device mounted within a hybrid vehicle and calculating a reference power. A travelling mode of the hybrid vehicle is then changed from an electric vehicle (EV) mode to a hybrid electric vehicle (HEV) mode by operating an engine clutch to be connected when the system required power is greater than the reference power. The system required power is a value obtained by adding driver required power and power required by an auxiliary load device of the hybrid vehicle, and the reference power is power when a state of charge (SOC) of the battery providing power to the device of the hybrid vehicle is maintained in a normal region.

A control system may include a first electronic control unit programmed to control the engine and a second electronic control unit programmed to control the rotary electric machine. The second electronic control unit may be programmed to output an engine command signal to the first electronic control unit through communication with the first electronic control unit. The first electronic control unit may be programmed to control the engine in accordance with the engine command signal received from the second electronic control unit, when a communication abnormality with the second electronic control unit does not occur; and to execute fixing operation control in which the engine is controlled such that at least one of speed, output power, and output torque of the engine becomes a corresponding fixed value, when the communication abnormality with the second electronic control unit occurs.

An exemplary method includes prompting a user to change an operating mode of an electrified vehicle from a first mode to a second mode that is different than the first mode. The first mode is a default mode. The second mode is a non-default mode.

A battery system includes an electricity storage device including a plurality of battery units. The electronic control device is configured to switch a travel mode of the vehicle between a CD mode and a CS mode. The electronic control device is configured to calculate a vehicle state of charge at a higher value than an average state of charge when the average state of charge is higher than a threshold value, and calculate the vehicle state of charge at a lower value than the average state of charge when the average state of charge is lower than the threshold value. The threshold value is set at a lower value than a center value between an upper limit value and a lower limit value of the vehicle state of charge.

A drive mode hierarchy includes drive mode categories and drive modes belonging to each category. Each drive mode defines values for attributes of the drivetrain and/or suspension of a vehicle. Each drive mode may further have towing and non-towing sub-modes with the towing sub-mode being used when a trailer is detected. An interface is provided for selecting drive modes from the hierarchy and modifying the attributes. The vehicle may define a plurality of trailer profiles including attributes of trailers, such as weight and aerodynamic drag. A user may select among trailer profiles and define the attributes of the trailer profiles. Interfaces displayed by the vehicle may vary according to the selected drive mode and may include a chassis view with interface elements displaying real-time information of components of the vehicle, such as wheels, suspension, and battery. Tiles including real-time information may be displayed according to the selected drive mode.

An electrified fire fighting vehicle includes a chassis, a cab, a body, a front axle, a rear axle, an engine, a battery pack, a pump system including a water pump, an electromagnetic device, and a power divider coupling the engine to the pump system and the electromagnetic device. The electromagnetic device is electrically coupled to the battery pack. The electromagnetic device has (a) an output coupled to at least one of the front axle or the rear axle and (b) a power take-off coupled to the pump system.

An electrified fire fighting vehicle includes a chassis, a cab, a body, a front axle, a rear axle, an engine, a battery pack, a pump system including a water pump, an electromagnetic device electrically coupled to the battery pack and mechanically coupled to at least one of the front axle or the rear axle, and a power divider coupled to the pump system, the engine, and the electromagnetic device.