A method for operating a motor vehicle. At least one electric engine designed for driving the motor vehicle is used to recuperate electric energy. In this case, a travel of the motor vehicle during a period of time lying ahead is taken into account. During the use of at least one electric engine for recuperating the electric energy, it is taken into account whether during a thermal load of the at least one electric engine in the period lying ahead, a reduction of the power that can be output by at least one electric engine is to be expected. The at least one electric engine then recuperates an amount of electric energy during the deceleration of the motor vehicle which is smaller than the amount of electric energy that can be recuperated during the deceleration by the at least one electric engine. The invention relates in addition also to a motor vehicle.

A terminal device is provided to output information about using a transport device for a travel to a destination, a vehicle communicating with the terminal device, a personal mobility device communicating with the terminal device, a method of controlling the terminal device, and a method of controlling the vehicle.

A parking alignment sequence for wirelessly charging an electric vehicle can include determining a location of a charging station by a processing device of a user device based on communication over a cellular network. The charging station can have a transmitter for wirelessly transmitting power to a receiver of the electric vehicle. A first user interface having directions to the charging station from a current location of the user device can be displayed. Alignment data can be wirelessly received via a communication path that is independent of the cellular network in response to the electric vehicle being located within a predetermined distance from the charging station. A second user interface having alignment instructions can be displayed for moving the electric vehicle into alignment based on the alignment data in response to the electric vehicle being located within the predetermined distance from the charging station.

As a control of an inverter, a first pulse width modulation control switches a plurality of switching elements by generating a first pulse width modulation signal of the switching elements, and a second pulse width modulation control switches the switching elements by generating a second pulse width modulation signal of the switching elements based on a voltage modulation rate, a voltage phase, and the number of pulses per unit cycle of an electrical angle of the motor based on the torque command and has a smaller number of switchings of the switching elements than the first pulse width modulation control. The first pulse width modulation control and the second pulse width modulation control are executed in a switched manner. Execution of the second pulse width modulation control as the control of the inverter is restricted when the quietness is needed, compared with when the quietness is not needed.

Systems and methods are provided for suggesting a charging station for an electric vehicle. A partial range of the electric vehicle corresponding to a predetermined percentage of the current state of charge of a battery of the electric vehicle is determined. A location corresponding to the partial range, along a route to a destination, is determined and used to select a suggested charging station based on the location corresponding to the partial range. The suggested charging station is generated for presentation at a display.

A navigation apparatus generates route guidance for an electric vehicle based on information on a battery power state of the electric vehicle. The navigation apparatus includes a driving route generating unit, a battery information acquiring unit, a mileage calculating unit and a driving information setting unit. The driving route generating unit receives destination information and generates a driving route corresponding to the destination information. The battery information acquiring unit obtains information about a minimum remaining amount of a battery of the electric vehicle input by a driver of the electric vehicle. The mileage calculating unit calculates an available driving distance of the electric vehicle based on a current remaining amount of the battery and the minimum remaining amount of the battery. The driving information setting unit sets information related to the driving route based on the available driving distance, and displays the information via a display apparatus.

A method of preconditioning a battery of a vehicle includes determining a baseline preconditioning start time relative to an estimated time of arrival at a charging station. The method further includes analyzing a route of the vehicle to the charging station to determine a route characteristic. The method further includes modifying the baseline preconditioning start time based on the route characteristic to determine a route-based preconditioning start time.

A vehicle determines a current state of charge of the vehicle and a current battery temperature of a battery of the vehicle. The vehicle, based on at least the state of charge and battery temperature, determines a charge acceptance rate for the battery and determines if the acceptance rate meets at least one predefined parameter for charging. The vehicle finds at least one charging station within a predefined proximity for which one or more known charge provision characteristics allow the at least one predefined parameter to be met, responsive to the acceptance rate meeting the at least one predefined parameter, and displays a location of the at least one charging station.

An electric vehicle charging recommendation method is disclosed. The method may include obtaining a vehicle information associated with a vehicle, a driver information, and a vehicle trip information. The vehicle information may include a current state of charge (SOC) of a vehicle battery. The method may further include determining a distance to be travelled by the vehicle from a vehicle current location based on the vehicle trip information. The method may further include determining an expected SOC required to travel the distance from the vehicle current location based on the vehicle information, the driver information and the vehicle trip information. The method may additionally include transmitting a recommendation notification to a user device to charge the vehicle battery when the expected SOC may be greater than the current SOC.

An autonomous driving mode control method includes setting a driving route based on an origin and a destination of a vehicle, comparing an expected state of charge (SOC) value of a battery at the destination with a predetermined SOC value, and controlling travel of the vehicle by determining whether to activate a high-level driving mode in consideration of at least one of whether a dangerous situation occurs, a result of the comparing, or a safety level of the driving route.