A method for operating an electric charging device for an electrically drivable motor vehicle. The electric charging device has a ground unit for positioning in the ground and for generating an alternating magnetic field for an electric charging operation. The method includes sensing a motor vehicle within a predefined perimeter surrounding the ground unit; sensing a driving parameter value of at least one driving parameter of the sensed motor vehicle at at least one respective predefinable point in time; storing the at least one driving parameter value if an electric charging operation is carried out for the detected motor vehicle; determining a driving recommendation on the basis of the at least one sensed and stored driving parameter value; and transmitting the driving recommendation if another motor vehicle is sensed within the predefined perimeter surrounding the ground unit.

Systems and methods are provided herein for controlling the speed on each wheel of a vehicle, possibly operating a vehicle in a speed control mode. In response to receiving input to engage speed control mode and receiving an accelerator pedal input, the system determines a target wheel speed based on the accelerator pedal input, monitors wheel speed of each of a plurality of wheels and determines, for each monitored wheel, a difference based on the monitored wheel speed and the target wheel speed. A torque is provided to each of the plurality of wheels based on the respective difference to achieve the target wheel speed.

A powertrain for an electric vehicle has a driveshaft connected to two or more motors where each motor is connected to a battery pack associated with that motor. A controller is used to select one or more motors to be energized for propulsion or used for regenerative braking to recharge the battery pack to which it is coupled. The controller can optimize the state of charge (SOC) difference of the battery packs and provide for a smooth and efficient powering of the vehicle for acceleration and climbing and optimize the range of the vehicle by management of the relative SOC of the battery packs. The electric vehicle can include two or more fuel cells that individually coupled to a motor.

The present disclosure relates to an energy management system for an energy storage system of a vehicle, a vehicle comprising such an energy management system, an energy management method for an energy storage system of a vehicle and a computer program element for an energy management system of a vehicle.

The energy management system comprises a propulsion sensor unit, a heat sensor unit, an energy storage sensor unit, a navigation unit and a control unit. The propulsion sensor unit is configured to monitor at least one propulsion parameter of the vehicle. The heat sensor unit is configured to monitor at least one thermal parameter of the vehicle. The energy storage sensor unit is configured to monitor at least one state parameter of the energy storage system, wherein the state parameter comprises at least a current capacity of the energy storage system. The control unit is configured to receive navigation data based on a calculation of a route from a current position to a destination of the vehicle by the navigation unit. The control unit is configured to estimate an upcoming energy consumption based on the propulsion parameter, the thermal parameter and/or the navigation data. The control unit is further configured to adjust at least one of the thermal parameter and the propulsion parameter of the vehicle based on the current capacity of the energy storage system to reduce the upcoming energy consumption and/or a trip time of the vehicle to the destination.

A control system for a tiltable vehicle may include a motor controller configured to respond to backward or reverse operation of the vehicle by hindering a responsiveness of the control system (e.g., proportionally) and/or eventually disengaging a drive motor of the vehicle. Accordingly, a user may intuitively and safely dismount the vehicle by selectively commanding reverse operation. In some examples, the backward direction may be user-defined.

A travel information recording system for associating travel information on a vehicle obtained immediately after travel through a branch location with an appropriate road segment includes: travel segment specifying unit for specifying a travel segment that is a road segment in which a vehicle is traveling; and travel information recorder for recording travel information on the vehicle obtained during travel in the travel segment in association with the travel segment in a storage medium. In the case where there occurs a segment variation in which the travel segment is varied from one of several road segments branched off from a branch location, the travel information recorder acquires the travel information to be recorded in association with a post-variation segment, which is the travel segment after the segment variation, on the basis of the travel information obtained before the segment variation.

Proposed are an article transport vehicle with a power operation function, an article transport system, and a method for operation of an article transport vehicle. More particularly, proposed is a technology that controls a traveling state and power operation of an article transport vehicle for each situation according to a traveling condition suitable for an energy storage means selected and mounted according to the requirements of an article transport system, thereby improving the operational efficiency of the entire article transport system.

A powered balancing mobility device that can provide the user the ability to safely navigate expected environments of daily living including the ability to maneuver in confined spaces and to climb curbs, stairs, and other obstacles, and to travel safely and comfortably in vehicles. The mobility device can provide elevated, balanced travel.

A method, apparatus, and system for modifying acceleration characteristics of an electric vehicle is disclosed. A persistent input throttle command signal that starts at a first time instant is received at a vehicle control system of a first vehicle that is a first type vehicle. A transformed throttle command signal is generated based on the persistent input throttle signal and a present time at the vehicle control system. An engine operation of the first vehicle is controlled based on the transformed throttle command signal at the vehicle control system. Controlling the engine operation of the first vehicle based on the transformed throttle command signal causes the engine power output of the first vehicle to be associated with a second acceleration performance curve that is associated with a second type vehicle.

A method for operating a control unit of a light-weight vehicle, especially of a pedal electric cycle or of an electric kick scooter. The method includes: receiving at least one sensor information associated with a sensor of the vehicle; and transmitting, via a communication channel between the control unit and a personal mobile terminal, the at least one sensor information and/or at least an information based thereon.