A vehicle includes a powertrain having an electric machine and a controller. The controller is programmed to, responsive to an accelerator pedal position exceeding a first threshold for a predetermined time period or a lateral acceleration of the vehicle being greater than a second threshold, transition the powertrain from a nominal driving mode to a performance driving mode. The controller is also programmed to, responsive to an increase in a steering wheel angle while in the nominal mode, maintain a power output of the electric machine at a driver demanded power defined by the accelerator pedal position. The controller is further programmed to, responsive to an increase in a steering wheel angle while in the performance driving mode, reduce a power output of the electric machine to less than the driver demanded power.

A system for compensating acceleration of electrical motorbike includes a throttle unit and an electro-mechanic assembly. After the electrical motorbike starts, the throttle unit receives external operation from a rider for generating a series of original throttle signal. An acceleration compensating module calculates a throttle variation rate based on the original throttle signal and variation of a throttle operation magnitude, and calculates a throttle compensating value based on the throttle variation rate when the throttle variation rate is larger than or equal to a correction threshold. A throttle compensating module receives and sums the original throttle signal and the throttle compensating value up for generating a new throttle signal. A torque controller generates a corresponding torque command based on the new throttle signal, and outputs the torque command to the electro-mechanic assembly for operation.

A method for assisting a power-intensive driving maneuver of an ego vehicle propelled by an electric motor fed from an energy-storage device includes predicting a power-intensive driving maneuver of the ego vehicle, ascertaining a peak-power profile that is needed for a complete execution of the predicted driving maneuver, and determining an available propulsive power of the ego vehicle. The method further includes ascertaining whether the available propulsive power is sufficient for the peak-power profile and, if the available propulsive power is sufficient for the peak-power profile, indicating a recommendation for execution of the predicted driving maneuver. If the available power is not sufficient for the peak-power profile, the method further includes ascertaining whether the available propulsive power is sufficient for a restricted peak-power profile that is needed for a restricted execution of the predicted driving maneuver, indicating a recommendation for restricted execution of the predicted driving maneuver if the available propulsive power is sufficient for the restricted peak-power profile, and indicating a recommendation for non-execution of the predicted driving maneuver if the available propulsive power is not sufficient for the restricted peak-power profile.

A battery voltage control device includes a step-up module that steps up a voltage of a battery and applies the voltage to a driving motor, an image analysis processing module that acquires and analyzes a piece of image information of an outside of a vehicle that is obtained through imaging, and driving state forecast module that forecasts a driving state including starting or stopping of the vehicle based on a piece of environment information of the outside of the vehicle that is obtained through analysis of the piece of image information and controls step-up by the step-up module based on the forecast driving state.

A system for dynamic battery loading for electric vehicles includes an electric motor to displace a vehicle. A first battery stores a first electric power charge and a second battery stores a second electric power charge. A controller dynamically loads or couples the first battery or the second battery to deliver the first electric power charge or the second electric power charge, respectively, to the electric motor based at least in part on the power signal, a location of the first battery, or a location of the second battery within the vehicle.

A controlling apparatus is provided for a vehicle including a motor, an inverter, and a battery. The controlling apparatus includes a determiner, an estimator, and a controller. The determiner judges whether a first condition is satisfied or not. The first condition is satisfied if the vehicle is in a coasting state in a regeneration prohibited mode in which a regenerative brake is disabled. The estimator estimates whether a second condition is satisfied or not. The second condition is satisfied if the motor is not to generate a regenerative torque upon a shutdown of the inverter. The controller shuts down the inverter if the determiner judges that the first condition is satisfied and the estimator estimates that the second condition is satisfied.

An electric drive system includes an energy storage system (ESS), a power conversion system, and an alternating current (AC) traction system. The ESS provides or receives electric power. The ESS includes a first energy storage unit and a second energy storage unit. The power conversion system is electrically coupled to the ESS for converting an input power to an output power. The AC traction system is electrically coupled to the power conversion system for converting the output power of the power conversion system to mechanical torques. The AC traction system includes a first AC drive device and a second AC drive device. An energy management system (EMS) is in electrical communication with the ESS, the AC traction system, and the power conversion system for providing control signals.

A driving assistance method for assisting a power-intensive driving maneuver of a subject vehicle includes predicting the power-intensive driving maneuver of the subject vehicle, and determining whether driving maneuver criteria, which comprise at least one energy criterion and at least one traffic criterion, are satisfied for the predicted power-intensive driving maneuver. Determining if the at least one energy criterion is satisfied includes determining a peak power profile required for a full execution of the predicted power-intensive driving maneuver, determining an available drive power of the subject vehicle, and evaluating whether the available drive power is sufficient for the peak power profile, wherein the at least one energy criterion is satisfied if the available drive power is sufficient for the peak power profile. Determining if the at least one traffic criterion is satisfied includes detecting a traffic situation, which comprises at least one traffic condition and/or a route topology, in the surroundings of the subject vehicle, and evaluating whether the predicted power-intensive driving maneuver can be fully executed in the detected traffic situation, wherein the traffic criterion is satisfied if the predicted driving maneuver can be fully executed in detected traffic situation. The method further includes displaying a result of determining whether the driving maneuver criteria are satisfied for the predicted power-intensive driving maneuver.

A method controls an electrified powertrain having an electric traction motor and a traction power inverter module (TPIM). A controller determines a current component capability and use case of the electrified powertrain. In response to the current component capability being less than a capability threshold and the use case matching a predetermined approved use case, the controller determines whether a predetermined margin exists in the component capability for operating the electrified powertrain in a maximum performance mode (MPM) for a full duration of a boosted driving maneuver. When the predetermined margin exists, the controller temporarily applies an extended inverter limit (EIL) of the TPIM to enable the MPM. The EIL allows operation of the traction motor to occur above default torque and speed operating limits for the full duration of the boosted driving maneuver. MPM/EIL availability is communicated to the operator.

A power delivery system for an electric vehicle provides efficient power management for either continuous or intermittent high-performance operation, using a boost stage and an on-board charging circuit. A main battery, configured as a high-capacity power source, supplies power to the electric motor under normal load conditions. An auxiliary boost battery assists the main battery in supplying a high-level current at a higher discharge rate thereby causing the motor to operate in a high-performance drive mode. A charging circuit recharges the boost battery from the main battery during operation of the motor. The charging circuit also maintains a charge balance between the boost battery and the main battery when the two batteries have different chemistries. In one embodiment, participation of the boost battery in powering the electric motor can be controlled automatically according to sensed changes in the load. In another embodiment, power management can be based on timed intervals.