Abstract: When an injection sharing ratio r is neither 0 nor 1, an engine ECU executes a program including a step of calculating a purge reduction amount of an in-cylinder injector as fpg×r and calculating a purge reduction amount of an intake manifold injector as fpg×(1?r) when performing purge processing according to a current fuel injection sharing ratio of the injectors, and a step of calculating a correction fuel injection amount of the in-cylinder injector by raising the fuel injection amount to a minimum fuel injection amount, and calculating a correction fuel injection amount of the intake manifold injector by subtracting the raised amount from the fuel injection amount of the intake manifold injector when the fuel injection amount of the in-cylinder injector calculated by using the purge reduction amount is lower than the minimum injection amount.

Abstract: Avoiding inconvenience during purge processing execution of fuel vapor in an internal combustion engine including an in-cylinder injector and an intake manifold injector. An engine ECU 300 executes a program including the steps of: when the purge control execution flag is ON (YES at S400), the step (S410) of calculating injection ratio (DI ratio) r; the step (420) of calculating the basic injection amounts of the in-cylinder injector and the intake manifold injector; when the injection ratio r is not 0 (NO at S430) and the injection ratio r is not 1 (NO at S460), the step (S480) of substituting 0 for purge reduction calculation value fpgd at the in-cylinder injector side, and substituting fpg for purge reduction calculation value fpgp of the intake manifold injector side; and the step (490) of calculating the final injection amounts of the in-cylinder injector and the intake manifold injector.

Abstract: When an injection sharing ratio r is neither 0 nor 1, an engine ECU executes a program including a step of calculating a purge reduction amount of an in-cylinder injector as fpg×r and calculating a purge reduction amount of an intake manifold injector as fpg×(1-r) when performing purge processing according to a current fuel injection sharing ratio of the injectors, and a step of calculating a correction fuel injection amount of the in-cylinder injector by raising the fuel injection amount to a minimum fuel injection amount, and calculating a correction fuel injection amount of the intake manifold injector by subtracting the raised amount from the fuel injection amount of the intake manifold injector when the fuel injection amount of the in-cylinder injector calculated by using the purge reduction amount is lower than the minimum injection amount.

Abstract: An engine ECU executes a program including the steps of: determining presence of abnormality in a high-pressure fuel system; when abnormality is sensed in the high-pressure fuel system, and not in an in-cylinder injector, injecting fuel from the in-cylinder injector at the feed pressure; selecting criteria (1) that is the restriction standard for a more gentle output restriction of the engine; when abnormality is sensed in the high-pressure fuel system and in the in-cylinder injector, ceasing the in-cylinder injector; selecting criteria (2) that is the restriction standard for a stricter output restriction of the engine; increasing the VVT overlap; retarding the ignition timing; and restricting the throttle opening according to the selected criteria.

Abstract: An engine ECU executes a program including the step of closing a current control valve in all regions when there is abnormality in a high-pressure system fuel system (YES at S100), the step of setting the VVT overlap to 0, the step of injecting fuel from only an intake manifold injector, the step of corresponding to an ignition timing when the current control valve is closed, and the step of correcting the increased quantity of fuel.

Abstract: An engine ECU executes a program including the steps of: determining presence of abnormality in a low-pressure fuel system; ceasing an intake manifold injector when determination is made of abnormality in the low-pressure fuel system; increasing the target purge rate when the engine operation state attains an injection partaking state between an in-cylinder injector and an intake manifold injector; reducing the VVT overlap; and retarding the ignition timing.

Abstract: An engine ECU executes a program including the steps of: determining presence of abnormality in a high-pressure fuel system; when abnormality is sensed in the high-pressure fuel system, and not in an in-cylinder injector, injecting fuel from the in-cylinder injector at the feed pressure; selecting criteria (1) that is the restriction standard for a more gentle output restriction of the engine; when abnormality is sensed in the high-pressure fuel system and in the in-cylinder injector, ceasing the in-cylinder injector; selecting criteria (2) that is the restriction standard for a stricter output restriction of the engine; increasing the VVT overlap; retarding the ignition timing; and restricting the throttle opening according to the selected criteria.

Abstract: An engine ECU executes a program including the step of closing a current control valve in all regions when there is abnormality in a high-pressure system fuel system (YES at S100), the step of setting the VVT overlap to 0, the step of injecting fuel from only an intake manifold injector, the step of corresponding to an ignition timing when the current control valve is closed, and the step of correcting the increased quantity of fuel.

Abstract: A fuel injection controller for an engine having a direct injector for injecting fuel into a cylinder and an intake injector for injecting fuel into an intake passage. When the engine is idling, the controller reduces a target engine speed while preventing the engine from stalling. The fuel injection controller supplies fuel to the engine through the direct injector and the intake injector when the engine is idling. The electronic control unit determines if there is a possibility of the engine stalling when the engine is idling. When having determined that there is such a possibility, the electronic control unit selectively increases the fuel injection amount of the direct injector.

Abstract: An engine ECU executes a program including the steps of: determining presence of abnormality in a low-pressure fuel system; ceasing an intake manifold injector when determination is made of abnormality in the low-pressure fuel system; increasing the target purge rate when the engine operation state attains an injection partaking state between an in-cylinder injector and an intake manifold injector; reducing the VVT overlap; and retarding the ignition timing.

Abstract: When an injection sharing ratio r is neither 0 nor 1, an engine ECU executes a program including a step of calculating a purge reduction amount of an in-cylinder injector as fpg×r and calculating a purge reduction amount of an intake manifold injector as fpg×(1-r) when performing purge processing according to a current fuel injection sharing ratio of the injectors, and a step of calculating a correction fuel injection amount of the in-cylinder injector by raising the fuel injection amount to a minimum fuel injection amount, and calculating a correction fuel injection amount of the intake manifold injector by subtracting the raised amount from the fuel injection amount of the intake manifold injector when the fuel injection amount of the in-cylinder injector calculated by using the purge reduction amount is lower than the minimum injection amount.

Abstract: A clutch controlling device switches the degree of engagement of a clutch according to at least one of the running state of a vehicle, the running state of an engine, or the manipulation state of a gearbox. A detecting device detects the temperature of an emission control catalyst. When a clutch controlling device decreases the degree of engagement of the clutch, the clutch controlling device increases the degree of engagement of the clutch if the temperature of the catalyst detected by the detecting device is less than a reference temperature. Accordingly, the temperature of the catalyst is increased.

Abstract: A fuel injection controller for an engine having a direct injector for injecting fuel into a cylinder and an intake injector for injecting fuel into an intake passage. When the engine is idling, the controller reduces a target engine speed while preventing the engine from stalling. The fuel injection controller supplies fuel to the engine through the direct injector and the intake injector when the engine is idling. The electronic control unit determines if there is a possibility of the engine stalling when the engine is idling. When having determined that there is such a possibility, the electronic control unit increases the fuel injection amount of the direct injector.

Abstract: A clutch controlling device switches the degree of engagement of a clutch according to at least one of the running state of a vehicle, the running state of an engine, or the manipulation state of a gearbox. A detecting device detects the temperature of an emission control catalyst. When a clutch controlling device decreases the degree of engagement of the clutch, the clutch controlling device increases the degree of engagement of the clutch if the temperature of the catalyst detected by the detecting device is less than a reference temperature. Accordingly, the temperature of the catalyst is increased.

Abstract: A target homogeneous mode throttle opening TA1 that is suitable for homogeneous stoichiometric combustion without EGR is computed regardless of the current combustion mode. During homogeneous stoichiometric combustion without EGR, the opening of a throttle valve is controlled based on the target opening TA1. During homogeneous stoichiometric combustion with EGR, an opening adjustment value TAo is added to the target opening TA1 and the resultant is set as a target EGR throttle opening TA2. The opening of the throttle valve is controlled based on the target opening TA2. During stratified lean combustion, the fuel injection amount is controlled based on a hypothetical throttle opening TA1, which corresponds to the target opening TA1. In either combustion mode, the engine torque is adjusted based on a common control value, which is the target opening TA1. Therefore, the engine torque is not abruptly changed when the combustion mode is switched.

Abstract: A target homogeneous mode throttle opening TA1 that is suitable for homogeneous stoichiometric combustion without EGR is computed regardless of the current combustion mode. During homogeneous stoichiometric combustion without EGR, the opening of a throttle valve is controlled based on the target opening TA1. During homogeneous stoichiometric combustion with EGR, an opening adjustment value TAo is added to the target opening TA1 and the resultant is set as a target EGR throttle opening TA2. The opening of the throttle valve is controlled based on the target opening TA2. During stratified lean combustion, the fuel injection amount is controlled based on a hypothetical throttle opening TA1, which corresponds to the target opening TA1. In either combustion mode, the engine torque is adjusted based on a common control value, which is the target opening TA1. Therefore, the engine torque is not abruptly changed when the combustion mode is switched.

Abstract: An engine in which an elapsed time Ta(i) of 30° crank angle near top dead center of the compression stroke and an elapsed time Tb(i) of 30° crank angle near 90° after top dead center of the compression stroke are found. The difference DTa(i) of the elapsed times Ta(i) in a 720° crank angle range is found for the first cylinder and the second cylinder where combustion is performed after the first cylinder. The assumed elapsed time Tb′(i) assuming that there is no torque fluctuation is calculated from the difference of elapsed times DTa(i) of the first cylinder and the second cylinder and the assumed elapsed time Tb′(i) is used to calculate the amount of torque fluctuation.

Abstract: The elapsed time Ta(i) of 30.degree. crank angle near top dead center of compression and the elapsed time Tb(i) of 30.degree. crank angle near 90.degree. after top dead center of compression are found. The difference DTa(i) of the elapsed times Ta(i) between 720.degree. crank angle for a first cylinder and a second cylinder performing combustion after the first cylinder is found. The assumed elapsed time when assuming that there is no torque fluctuation is calculated from the difference DTa(i) of the elapsed time of the first cylinder and the elapsed time of the second cylinder is calculated and the assumed elapsed time is used to calculate the amount of torque fluctuation. It is judged if the vehicle is driving over a rough road from the amplitude and cycle of fluctuation of the vehicle speed. When it is judged that the vehicle is driving over a rough road, correction of the air-fuel ratio based on the amount of torque fluctuation is prohibited.

Abstract: The elapsed time Ta(i) of 30.degree. crank angle near top dead center of compression and the elapsed time Tb(i) of 30.degree. crank angle near 90.degree. after top dead center of compression are found. The difference DTa(i) of the elapsed times Ta(i) between 720.degree. crank angle for a first cylinder and a second cylinder performing combustion after the first cylinder is found. The assumed elapsed time when assuming that there is no torque fluctuation is calculated from the difference DTa(i) of the elapsed time of the first cylinder and the elapsed time of the second cylinder is calculated and the assumed elapsed time is used to calculate the amount of torque fluctuation. It is judged if the vehicle is driving over a rough road from the amplitude and cycle of fluctuation of the vehicle speed. When it is judged that the vehicle is driving over a rough road, correction of the air-fuel ratio based on the amount of torque fluctuation is prohibited.