In a hybrid vehicle including: a step-up converter for stepping-up the voltage from a battery and supplying power to the front motor for driving front wheels; as well as a paddle switch for setting regenerative braking torque stepwisely, and a hybrid control unit for calculating a regenerative braking force based on a selection stage set by the paddle switch, the hybrid control unit decreases the regenerative braking force to be less than the regenerative braking force while the maximum input/output power of the step-up converter is not limited, when a selection stage in which regenerative braking force is more than that in a D range is selected while the maximum input/output power of the step-up converter is limited.

An electronic control unit performs a control process including a step of setting a second learning time shorter than a first learning time when a Charge Sustaining mode is not selected, a step of setting enlarged values as upper and lower limit values of a feedback value, a step of switching an engine stop prohibition flag to an ON state when a learning start condition is satisfied, a step of performing learning control, a step of performing an update process when the set learning time elapses, and a step of turning off the engine stop prohibition flag.

An electronic control unit performs a control process including a step of setting a second learning time shorter than a first learning time when a Charge Sustaining mode is not selected, a step of setting enlarged values as upper and lower limit values of a feedback value, a step of switching an engine stop prohibition flag to an ON state when a learning start condition is satisfied, a step of performing learning control, a step of performing an update process when the set learning time elapses, and a step of turning off the engine stop prohibition flag.

A permanent magnet synchronous motor includes at least two series-connected windings for each phase, and is configured to be driven by selecting the windings using a multi-inverter driving device configured to switch between an inverter for low-speed drive and an inverter for high-speed drive. A ratio of an induced voltage constant of at least one group of windings constituting the windings for the high-speed drive and a d-axis inductance is larger than a ratio of an induced voltage constant of all the series-connected windings to the d-axis inductance.

A permanent magnet synchronous motor includes at least two series-connected windings for each phase, and is configured to be driven by selecting the windings using a multi-inverter driving device configured to switch between an inverter for low-speed drive and an inverter for high-speed drive. A ratio of an induced voltage constant of at least one group of windings constituting the windings for the high-speed drive and a d-axis inductance is larger than a ratio of an induced voltage constant of all the series-connected windings to the d-axis inductance.

A method for controlling a hybrid electric powertrain includes, in response to a request to increase a powertrain braking force on at least one of a plurality of traction wheels, (i) commanding at least one clutch to increase a gear ratio of a transmission, and (ii) during clutch stroke, commanding an electric machine to act as a generator such that the electric machine applies a braking force to at least one of the traction wheels.

An information provision apparatus including: a provision control unit (40, 30) configured to provide a vehicle passenger with energy replenishment information relating to energy replenishment of a vehicle-driving energy supply source (20) that is capable of storing regenerative energy regenerated from rotational energy of a vehicle wheel, when a remaining energy amount of the energy supply source (20) falls below a determination reference value; and a modification unit (40) configured to modify a provision condition that is a condition on which the provision control unit (40, 30) provides the energy replenishment information, so that after the energy replenishment information is once provided when the remaining energy amount falls below the determination reference value, the energy replenishment information is less likely to be provided than before the energy replenishment information is once provided.

An information provision apparatus including: a provision control unit (40, 30) configured to provide a vehicle passenger with energy replenishment information relating to energy replenishment of a vehicle-driving energy supply source (20) that is capable of storing regenerative energy regenerated from rotational energy of a vehicle wheel, when a remaining energy amount of the energy supply source (20) falls below a determination reference value; and a modification unit (40) configured to modify a provision condition that is a condition on which the provision control unit (40, 30) provides the energy replenishment information, so that after the energy replenishment information is once provided when the remaining energy amount falls below the determination reference value, the energy replenishment information is less likely to be provided than before the energy replenishment information is once provided.

A vehicle brake control system includes an inverter configured to convert direct current (DC) into an alternating current (AC) for a motor of a vehicle. The inverter includes switches configured to convert the DC to the AC, as well as a resistor and a bypass switch disposed in series with each other. A controller is communicatively coupled with the inverter switches and the bypass switch. The controller opens the bypass switch so that the DC is conducted through and converted into the AC for the motor during a motoring mode. The controller closes the bypass switch so that regenerated current from the motor is conducted through the resistor of the inverter for partial dissipation of the regenerated current during a dynamic braking mode.

A vehicle brake control system includes an inverter configured to convert direct current (DC) into an alternating current (AC) for a motor of a vehicle. The inverter includes switches configured to convert the DC to the AC, as well as a resistor and a bypass switch disposed in series with each other. A controller is communicatively coupled with the inverter switches and the bypass switch. The controller opens the bypass switch so that the DC is conducted through and converted into the AC for the motor during a motoring mode. The controller closes the bypass switch so that regenerated current from the motor is conducted through the resistor of the inverter for partial dissipation of the regenerated current during a dynamic braking mode.