Abstract: The drive control process of the invention sets minimum and maximum control rotation speeds Necmin and Necmax to a minimum engine speed Nemin and a maximum engine speed Ncmax of an engine. When output of a torque demand Tr* to a driveshaft is attainable, the drive control process performs the control to ensure output of the torque demand Tr* to the driveshaft in the range of the minimum control rotation speed Necmin and the maximum control rotation speed Necmax. When the output of the preset torque demand Tr* to the driveshaft is unattainable, the drive control process sets a performance-based minimum rotation speed Nmin and a performance-based maximum rotation speed Nrnax to the minimum engine speed Nemin and the maximum engine speed Nemax of the engine and repeats the series of control.

Abstract: On condition that a motor temperature is lower than a preset reference temperature and that a vehicle speed is lower than a preset reference speed, a booster circuit is controlled to adjust the voltage level of a high voltage system to be not higher than a certain low voltage. On condition that the motor temperature is lower than the preset reference temperature and that the vehicle speed is not lower than the preset reference speed, the booster circuit is controlled to adjust the voltage level of the high voltage system to be not higher than a maximum input voltage. On condition that the motor temperature is not lower than the preset reference temperature, the booster circuit is controlled to adjust the voltage level of the high voltage system to be not higher than the maximum input voltage, irrespective of the vehicle speed.

Abstract: During a standstill, a prescribed rotation speed N3, which is lower than a prescribed rotation speed N2 used during a travel at a low vehicle speed, is set as a minimum rotation speed Nemin (S410), and when a demand for an idle operation has been made (S490), the minimum rotation speed Nemin is set as a target rotation speed Ne* and the value 0 is set as a target torque Te* (S500), whereby an engine is controlled. As a result of this, it is possible to improve the fuel consumption of a vehicle when the engine is operated at idle at standstill compared to a case where the engine is operated at idle at the minimum rotation speed Nemin for which the prescribed rotation speed N2 is set regardless of whether or not the vehicle is at a standstill.

Abstract: A vehicle includes a converter for stepping up power provided from a power storage device, and an inverter for converting the power output from converter and outputting it to an alternating-current motor for driving the vehicle. In the vehicle, a rectangular voltage control unit controls the inverter by means of rectangular wave voltage control that is based on a torque command value and the like, so as to control an output torque of the alternating-current motor. A system voltage control unit controls a system voltage, which is an output voltage of the converter. The system voltage control unit lifts a restriction on a system voltage command value based on an accelerator pedal position and the like, and then increases it. When increasing the system voltage command value during the rectangular wave voltage control for the inverter, a cooperative control unit increases the system voltage command value and the torque command value in a cooperative manner.

Abstract: A vehicle control device (10) comprises a driving device (20) including an engine (22) and a rotary electric machine (24), a power circuit (30) connected to the rotary electric machine (24), a control part (50), and an ecoswitch (42). The CPU (52) of the control part (50) comprises a low fuel consumption travel instruction judgment module (60) for judging on or off of the ecoswitch (42), an operation condition switch module (62) for switching the operation condition of the rotary electric machine on the basis of the on or off of the ecoswitch (42), an engine state judgment module (64) for judging whether or not the engine (22) is in a started state or a stopped state, and a damping control module (68) for carrying out damping control when the engine (22) is stalled or stopped.

Abstract: On condition that a motor temperature is lower than a preset reference temperature and that a vehicle speed is lower than a preset reference speed, a booster circuit is controlled to adjust the voltage level of a high voltage system to be not higher than a certain low voltage. On condition that the motor temperature is lower than the preset reference temperature and that the vehicle speed is not lower than the preset reference speed, the booster circuit is controlled to adjust the voltage level of the high voltage system to be not higher than a maximum input voltage. On condition that the motor temperature is not lower than the preset reference temperature, the booster circuit is controlled to adjust the voltage level of the high voltage system to be not higher than the maximum input voltage, irrespective of the vehicle speed.

Abstract: The drive control process of the invention sets minimum and maximum control rotation speeds Necmin and Necmax, which are based on an output limit Wout and an input limit Win of a battery, to a minimum engine speed Nemin and a maximum engine speed Nemax of an engine (step S120). When output of a torque demand Tr* to a driveshaft is attainable through input and output of energies from and to a rotation system including the engine in the range of the input limit Win and the output limit Wout of the battery with limitation of a rotation speed Ne of the engine to the range of the minimum control rotation speed Necmin and the maximum control rotation speed Necmax, the drive control process performs the control to ensure output of the torque demand Tr* to the driveshaft in the range of the minimum control rotation speed Necmin and the maximum control rotation speed Necmax (steps S130 to S200).

Abstract: During execution of an auto cruise function, in response to selection of a power mode, when an measured accelerator opening Acc is less than a preset opening Accref, a hybrid vehicle of the invention sets a power mode cancellation flag Fpmc to 1 and a power mode enabling flag Fpm to 0 (steps S540 and S550). This prohibits the use of an accelerator opening setting map in the power mode for execution of the auto cruise function. In the power mode, in response to an instruction for enabling the auto cruise function, the hybrid vehicle keeps the power mode enabling flag Fpm to the setting of 1 (step S560) as long as the measured accelerator opening Acc is not less than the preset opening Accref. This allows the use of the accelerator opening setting map in the power mode for execution of the auto cruise function.

Abstract: During a standstill, a prescribed rotation speed N3, which is lower than a prescribed rotation speed N2 used during a travel at a low vehicle speed, is set as a minimum rotation speed Nemin (S410), and when a demand for an idle operation has been made (S490), the minimum rotation speed Nemin is set as a target rotation speed Ne* and the value 0 is set as a target torque Te* (S500), whereby an engine is controlled. As a result of this, it is possible to improve the fuel consumption of a vehicle when the engine is operated at idle at standstill compared to a case where the engine is operated at idle at the minimum rotation speed Nemin for which the prescribed rotation speed N2 is set regardless of whether or not the vehicle is at a standstill.