A control device for an internal combustion engine includes an air-fuel ratio controller to execute a stoichiometric operation in which an air-fuel ratio of an air-fuel mixture in a combustion chamber of the internal combustion engine is set to a stoichiometric air-fuel ratio and a lean operation in which the air-fuel ratio is set to an air-fuel ratio leaner than the stoichiometric air-fuel ratio. A ignition timing controller is to calculate at least one ignition timing control parameter based on a laminar combustion velocity and to control an ignition plug provided in the combustion chamber to ignite based on the at least one ignition timing control parameter in a transitional state between the stoichiometric operation and the lean operation.

Provided is an engine control device for controlling an opening degree of a valve adjusting a flow rate of an air-fuel mixture of an engine, wherein the opening degree is corrected based on an exhaust temperature deviation which is a deviation between a reference value and a current value of an exhaust temperature when controlling the opening degree.

A system and method of inducing an operational response change in an operating direct-injection internal combustion engine is provided such that the engine includes a cylinder into which liquid fuel injection is directly performed. The method starts by operating the direct-injection engine using a start of injection (SOI) protocol. At some point during operation, it is determined that a change is desired for a first parameter of engine operation that is at least partially a function of a charge provided to the cylinder (such as the torque output). In response an operational response in the engine is induced by altering the SOI protocol via a first SOI alteration that alters the volumetric efficiency of the cylinder and changes the first parameter.

Provided are a control device for an internal combustion engine, wherein the internal combustion engine is provided with a crank mechanism for converting a reciprocating motion of a piston into a rotating motion of a crankshaft, a cylinder accommodating the piston, and an intake valve capable of opening and closing an inlet for sucking gas into the cylinder, and the control device is provided with: a volumetric efficiency calculating unit for calculating a volumetric efficiency representing a suction efficiency when gas is sucked into the cylinder, on the basis of a cylinder capacity when the intake valve is closed; a gas suction amount calculating unit for calculating a gas suction amount sucked into the cylinder, by means of a predetermined formula, on the basis of the calculated volumetric efficiency; and a control unit for controlling the internal combustion engine on the basis of the calculated gas suction amount.

A homogenous charge electromagnetic volumetric ignition (HCEMVI) internal combustion engine (ICE) and its ignition method are disclosed in the present invention. The HCEMVI ICE includes a control module of the engine, an electromagnetic wave source, an electromagnetic wave coupling module and the cylinders of the ICE. Its ignition method is stated as: the control module of the engine controls the electromagnetic wave generation and, when the piston of a cylinder containing an air-fuel mixture moves to the preset ignition advance angle, the electromagnetic wave source is commanded to generate an electromagnetic wave at a frequency in accordance with the resonant frequency of the cylinder head at the advance angle. The electromagnetic wave is transmitted into the cylinder by the coupling module to create a strong electric field through electromagnetic resonance in the cylinder head and initiate volumetric ignition and bulk combustion of the air-fuel mixture inside the cylinder of the engine.

A control device for an internal combustion engine, which can set a VVT (variable valve timing) phase angle so that a reduction in the output of the engine can be suppressed even on a high ground, while ensuring sufficient output, is provided. The control device has a VVT mechanism which changes the opening or closing timing of one or both of an intake valve and an exhaust valve, and comprises: a processor device; a memory device for storing a control program for controlling the processor device; a first sensor for detecting atmospheric pressure; and a second sensor for detecting the amount of air flowing through an intake air flow path. The control program calculates a charging efficiency based on the amount of air detected by the second sensor, calculates a volumetric efficiency from the amount of air and the atmospheric pressure detected by the first sensor, calculates the charging efficiency valve opening timing of the intake valve based on the charging efficiency, calculates the volumetric efficiency valve opening timing of the intake valve based on the volumetric efficiency, and sets the valve opening timing(s) of one or both of the intake valve and the exhaust valve by the variable valve timing mechanism based on one of the charging efficiency valve opening timing and the volumetric efficiency valve opening timing.

A control device for an engine includes a variable valve timing mechanism for changing an open and close timing for at least one of an intake valve and an exhaust valve to adjust an intake and exhaust overlap amount. The control device includes a detector for detecting an atmospheric pressure; a first calculator for calculating a target torque of the engine, an increasing device for calculating the overlap amount based on the target torque and increasing the overlap amount under a low pressure environment, a second calculator for calculating an increase limitation amount for limiting an increase in the overlap amount under the low pressure environment, a limiter for limiting an increase in the overlap amount increased by the increasing device, based on the increase limitation amount, and a drive controller for controllably driving the variable valve timing mechanism to achieve the limited overlap amount.

Techniques for setting a boost target for a turbocharged engine comprise (i) operating the engine in a scavenging mode such that opening of intake and exhaust valves of cylinders of the engine overlap and (ii) while transitioning the engine in/out of the scavenging mode: determining an engine torque request, creating a torque reserve by setting independent targets for throttle inlet pressure (TIP) and intake manifold absolute pressure (MAP), determining a target TIP based on a target total air charge, engine speed, and a previously-determined target engine volumetric efficiency (VE), controlling a wastegate valve based on the target TIP, determining a target MAP based on the engine torque request, and controlling a throttle valve based on the target MAP. During steady-state scavenging operation, the controller calculates a conventional target TIP based on the engine torque request and controls the wastegate valve based on the conventionally calculated target TIP.

A system and an approach for determining various flows in an internal combustion engine, such as an amount of recirculation exhaust gas flow through a controlled valve and a fresh air mass flow to an intake of an engine. Also, among the sensors accommodated in the system, is an inexpensive but slow-responding lambda sensor in the exhaust stream.

An air-bypass valve control device is disposed in an engine. The engine includes an intake passage, a compressor, a throttle valve, an air-bypass passage and the air-bypass valve. The air-bypass valve control device includes an intake air amount detector, a controller. The intake air amount detector detects an intake air amount of the engine. The controller configured to temporarily bring the air-bypass valve into an opened state in the case where the intake air amount of the engine immediately before a decrease in an opening degree of the throttle valve is equal to or larger than a predetermined value when the opening degree of the throttle valve decreases at a predetermined speed or higher.