Methods and systems are provided for reduction of VDE harmonics and improvement in the phase alignment of powertrain sensor signals that are asynchronously tasked. In one example, torque converter slip control is improved in a variable displacement engine by processing a raw torque converter turbine speed signal with a moving average filtered engine speed signal. By determining an actual delay between the sampled signals and adjusting a downstream filter parameter, a desired delay can be provided between the samples to align the phases and reduce the signal harmonics.

A boost regulator for a supercharger is responsive to one or more vehicle operation parameter inputs to determine limits of boost applied to an internal combustion engine. In one configuration, the boost regulator limits the amount of movement of a conventional dashpot boost control valve actuator based on various vehicle and sensor input data. In another configuration, the boost regulator adjusts the amount of boost output during supercharger operation in response to the vehicle and sensor input data.

An in-vehicle controller includes processing circuitry. The processing circuitry stops injection of fuel under a preset fuel cutoff condition including a lockup clutch being in an engagement state. A request for raising heating performance of a heater core is a heater actuation request, and an amount of particulate matter deposited on a filter is a deposition amount. The processing circuitry controls the lockup clutch in a disengagement state when a heater actuation request is generated and the deposition amount is less than a preset deposition amount threshold. The processing circuitry controls the lockup clutch in the engagement state when the heater actuation request is generated and the deposition amount is greater than or equal to the preset deposition amount threshold.

A hybrid vehicle for anti-rollover through active control of an engine and an anti-rollover control method for the same, may include detecting a roll angle of the vehicle, and when the detected roll angle is equal to or greater than a threshold roll angle, accelerating or decelerating, by a controller, the engine in a state in which the engine clutch is released depending on a direction of the roll angle.

A smart driveline disconnect assembly having a torque coupling assembly, an actuator, at least one sensor and a controller is provided. The torque coupling assembly is configured to selectively couple torque between a transmission and a final drive assembly. The actuator is configured to activate the torque coupling assembly. The at least one sensor is used to generate sensor information. The controller is configured to control the actuator based at least in part on the sensor information. The controller is further configured to determine at least a thermal energy level associated with the torque coupling assembly based on the sensor information and at least in part control the actuator based on the determined estimated thermal energy level.

Methods and systems are provided for reduction of VDE harmonics and improvement in the phase alignment of powertrain sensor signals that are asynchronously tasked. In one example, torque converter slip control is improved in a variable displacement engine by processing a raw torque converter turbine speed signal with a moving average filtered engine speed signal. By determining an actual delay between the sampled signals and adjusting a downstream filter parameter, a desired delay can be provided between the samples to align the phases and reduce the signal harmonics.

A control method for an internal combustion engine in which a driving force is transmitted through a clutch to a driving wheel of a vehicle, the control method includes: when the internal combustion engine which is automatically stopped in a state where the clutch is disengaged is restarted, performing a torque down control to decrease a target torque of the internal combustion engine when the clutch is engaged; and setting a target torque in the torque down control, to a predetermined torque lower limit value determined in accordance with a driving state, the torque lower limit value including at least one of a predetermined full open value set when an accelerator opening degree is full open, and a predetermined full close value set when the accelerator opening degree is full close.

A control apparatus for a vehicle that includes an engine includes an electric generator, a throttle valve, an electric generator control unit, and a throttle control unit. The electric generator is configured to be coupled to the engine. The throttle valve is configured to control an amount of intake air of the engine. The electric generator control unit is configured to allow the electric generator to perform regenerative power-generation on decelerated travel of the vehicle. The throttle control unit is configured to control the throttle valve openwise on the decelerated travel. The electric generator control unit is configured to cause an increase in power-generation torque of the electric generator, upon a switchover of the engine from a fuel cut state to a fuel injection state on the decelerated travel.

An engine air-fuel ratio control device is configured to be used in a vehicle including a power transmission device configured to transmit power between an output shaft of an engine and an input shaft of a transmission and to execute a lean-burn control that puts an air-fuel ratio of the engine into a lean state. An engine controller executes a fuel injection feedback control such that the air-fuel ratio becomes a lean target value after the power transmission device is released during a deceleration of the vehicle. An engine stall predictor predicts a stall of the engine on a basis of a deceleration indicator that is correlated with a deceleration degree of the vehicle in a state in which the power transmission device is released. A lean-burn control canceler cancels the lean-burn control in a case in which the engine is predicted to stall.

Methods for determining an irregular fuel request (IFR) for vehicle engines coupled to driveshafts via clutched transmissions are provided and include: determining an idle condition of the engine, generating one or more fuel requests during the idle condition, and determining an IFR based on a clutch control parameter and a fuel request generated during the idle condition. The idle condition of the engine is determined based on a vehicle speed and an engine speed if the vehicle speed and engine speed are below respective thresholds. An IFR is determined if a fuel request falls outside a range, and/or if the clutch control parameter is such that the clutch does not substantially impart load to the engine. The idle fuel request range is determined based on a combustion mode of the engine and/or a gear state of the transmission. The method further includes implementing a control action after determining an IFR.