A control apparatus of a powertrain with a centrifugal pendulum absorber, includes an engine formed with a plurality of cylinders, a drive force transmission shaft for receiving an engine output torque, a centrifugal pendulum absorber for reducing a variation in the output torque, a connect-disconnect mechanism, an engine controlling module for shifting an engine operating state between an all-cylinder operation and a reduced-cylinder operation, and a connection controlling module. The connection controlling module shifts a connecting state of the connect-disconnect mechanism to a first state when the engine is in the all-cylinder operation, and shifts the connecting state to a second state in which the connection is tighter than the first state when the engine is in the reduced-cylinder operation. In response to issued requests to shift the engine operating state, the connection controlling module shifts the connecting state, and the engine controlling module shifts the engine operating state.

A control apparatus for a vehicle that includes a first power transmission path, a second power transmission path, a clutch mechanism, a clutch controller, a supply current controller, a self-shut unit, and an electric power generating mode controller. The self-shut unit holds a conducting state of a second electric power supply line over a set time, in response to a change in a state of a first electric power supply line from a conducting state to a non-conducting state. The electric power generating mode controller executes an electric power generating mode that drives an electric motor to generate electric power upon a stop of a vehicle in which the clutch mechanism is disengaged. The supply current controller increases a supply current supplied to the clutch controller, in response to the change in the state of the first electric power supply line during the electric power generating mode.

A running control device of a vehicle includes an engine, a clutch separating the engine and wheels, and a torque converter with a lockup clutch transmitting power of the engine toward the wheels, the running control device of a vehicle is configured to execute a neutral inertia running mode that is an inertia running mode performed while the engine and the wheels are separated and a cylinder resting inertia running mode performed by stopping operation in at least some of cylinders of the engine while the engine and the wheels are coupled, the lockup clutch has a weak engagement force while the neutral inertia running mode is performed as compared to while the cylinder resting inertia running mode is performed.

A driving control method for a hybrid vehicle is provided to overcome a slip of the vehicle by a conversion of an EV mode into an HEV mode. The driving control method includes: determining by a controller whether the hybrid vehicle is insufficiently driven backward only by power of a motor when the vehicle is driven backward on an uphill road by driving the motor backward; starting an engine and engaging a backward stage gear; releasing a first clutch and at the same time requesting a brake operation signal to the hybrid vehicle while the motor is converted into forward driving; and then engaging a second clutch and requesting a brake release signal to the hybrid vehicle while an engine clutch is engaged to control the hybrid vehicle to be started by the power of the motor and the engine.

A method for controlling a hybrid electric vehicle includes: connecting a first motor directly connected to an engine to a second motor directly connected to a transmission input terminal through a dual mass flywheel; determining a target angular acceleration of the first motor according to a gear shifting progress rate so that an angular acceleration of the first motor follows a target angular acceleration of the transmission input terminal when a gearshift is performed in the transmission; and controlling a torque of the first motor based on the target angular acceleration of the first motor.

A control apparatus for a hybrid electrically-operated vehicle that includes an engine, a rotating machine, a transmission apparatus and an engine connection/disconnection device which is to be engaged to connect a power transmission between the engine and the transmission apparatus and which is to be released to disconnect the power transmission between the engine and the transmission apparatus. The control apparatus executes a vibration suppression control by using a first vibration model in which the engine connection/disconnection device is engaged and a second vibration model in which the engine connection/disconnection device is released, such that the vibration suppression control is executed also during a switch control for switching between an engine driving mode and a motor driving mode, by using one of the first and second vibration models which is used in execution of the vibration suppression control before start of the execution of the switch control.

A clutch disposed between an engine and an automatic transmission and including a first engagement element connected to the engine and a second engagement element connected to the automatic transmission. The electronic control unit is configured to, when a predetermined condition is satisfied, execute predetermined control in which the engine is stopped, the clutch is disengaged, and the vehicle is caused to travel. The electronic control unit is configured to start the engine when the predetermined condition is not satisfied during execution of the predetermined control, and execute downshift of the automatic transmission such that the rotational speed of the second engagement element becomes equal to or higher than a predetermined rotational speed when the predetermined condition is not satisfied during the execution of the predetermined control and the rotational speed of the second engagement element is lower than the predetermined rotational speed, and then engage the clutch.

A hydraulic control system for vehicle includes: an engine; an oil pump driven by the engine; a clutch device brought into engagement to enable power transmission between the engine and drive wheels by delivering a pressurized fluid thereto, and brought into disengagement to interrupt the power transmission between the engine and the drive wheels by discharging the fluid therefrom; and an accumulator storing the fluid delivered to the clutch device. The hydraulic control system is configured to control the hydraulic pressure applied to the clutch device, to stop the engine while bringing the clutch device into disengagement upon satisfaction of a predetermined stopping condition, and to restart the engine while bringing the clutch device into engagement upon satisfaction of a predetermined restarting condition. In the hydraulic control system, a hydraulic circuit increases flow rate of the fluid flowing between the accumulator and the clutch device when the engine is stopped.