An engine control method for preventing an engine of a vehicle from stalling on a sloped road includes steps of: detecting whether a shifting lever is in a neutral stage (N-stage); measuring a vehicle speed and a slope angle of the sloped road, and calculating a load acting on a vehicle body on the sloped road; accelerating an engine a first time to increase an engine RPM so that an engine torque is larger than the load; and accelerating the engine a second time to move the vehicle when the shifting lever enters into a driving gear stage (D-stage).

Method and apparatus are disclosed for secure idle for a vehicle generator. An example vehicle includes an outlet external to the vehicle, a power inverter dedicated to supplying AC power to the outlet, and a powertrain control module. The powertrain control module controls the power inverter to supply first power level when a switch is in a first position and a second power level when the switch is in a second position. Additionally, the powertrain control module, after entering a secure mode, controls an engine to remain idling when an ignition switch is off.

A vehicle includes an engine, a transmission mechanism, and an electronic control unit. The electronic control unit performs first switching control when there is a request for switching from a low mode to a high mode. The first switching control is to release a first engagement mechanism, and switch a second engagement mechanism to an engaged state when a difference between input and output rotational speeds of the second engagement mechanism becomes equal to or smaller than a permissible value.

A method of controlling the operating mode of a motor vehicle includes transitioning between driving and coasting modes and vice-versa automatically in response to a driver trigger. The method controls an engine of the motor vehicle to bring a driveline driven by the engine via an electronically controlled clutch into a lash state before engaging or disengaging the electronically controlled clutch thereby preventing driveline disturbances from being produced by the transition.

A vehicle includes an engine, motor, powertrain, and controller. The engine and the motor are each configured generate power within the powertrain. The controller is programmed to, in response to full depression of accelerator and brake pedals while the vehicle is stopped and the powertrain is in drive, increase engine power to a maximum power output capacity and increase a motor torque to a predetermined torque output that is less than a maximum torque capacity.

Methods of operating internal combustion engines are provided. A controller detects a coasting event while an associated vehicle is in motion. In response to the coasting event, the controller directs at least a portion of an exhaust gas output by an exhaust system of an internal combustion engine of the vehicle into an intake system of the internal combustion engine.

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 fail-safe control method for a hybrid electric vehicle is carried out based on a power transmission system of an engine, which is used to control the speed of the engine. When one of a plurality of motor-generators of the power transmission system malfunctions, the vehicle is controlled to be driven in a limp-home mode, thereby ensuring vehicle driving reliability and preventing the vehicle from becoming inoperable.

The purpose of the present invention is to improve fuel efficiency during coasting by calculating, with high accuracy, travel resistance during coasting. This vehicle control device comprises: a first travel resistance acquisition unit that acquires a first travel resistance, which is determined on the basis of road information or external information; and a second travel resistance acquisition unit that acquires a second travel resistance, which is determined on the basis of the result of actual traveling of the vehicle. This vehicle control device determines the content of coasting travel control during traveling of the vehicle on the basis of the result of a comparison of the first travel resistance and the second travel resistance in a predetermined zone where the vehicle has actually traveled.

A pre-stoppage ignition control unit defines, as a stoppage transition air amount, an intake air amount of the engine with which the engine torque becomes the stoppage transition torque in a state in which an ignition timing of the engine is set to a predetermined self-sustaining operation ignition timing, defines, as an intermediate timing, a predetermined timing earlier than timing at which the intake air amount converges to the stoppage transition air amount during an execution period of the pre-stoppage self-sustaining operation control, sets the ignition timing of the engine in a period from the start of the pre-stoppage self-sustaining operation control to the intermediate timing to timing earlier than the self-sustaining operation ignition timing, and sets the ignition timing of the engine in the period after the intermediate timing to the self-sustaining operation ignition timing.