Abstract: A manufacturing error and a mounting error of a position sensor used for detection of a rotation angle of a rotary shaft are appropriately calibrated to improve detection accuracy of the rotation angle.

Abstract: Failure in ignition of a fuel by an ignition plug is reduced, and, at the same time, wearing of electrodes of the ignition plug in an internal combustion engine is suppressed. A control device 1 for an internal combustion engine includes an ignition control unit that controls energization of an ignition coil 300 that supplies electric energy to an ignition plug 200 that discharges in a cylinder 150 of the internal combustion engine 100 to ignite fuel. The ignition control unit controls the energization of the ignition coil 300 such that first electric energy is released from the ignition coil 300 and second electric energy is released in superposition with the first electric energy. At this time, the energization of the ignition coil 300 is controlled such that releasing of the second electric energy is stopped at a timing that depends on a state of gas around the ignition plug 200 so that the discharge of the ignition plug 200 is stopped.

Abstract: Provided is a fuel injection control device that controls a fuel injection amount at higher accuracy. The fuel injection control device includes: a base waveform acquisition section 823 that generates a control current S9 for controlling a fuel injector 400; an A/D converter 824 that acquires a drive current P for the fuel injector 400 (controlled based on the control current S9) at each of measurement timings t1 to t6 based on a counter cycle; and an arithmetic operation section 821 that, based on a drive current P1 at a first measurement timing t1 and a drive current P2 at a second measurement timing t2 later than the first measurement timing t1, both acquired by the base waveform acquisition section 823, predicts a drive current P3 at a third measurement timing t3 later than the second measurement timing.

Abstract: Provided is an internal-combustion-engine control device that minimizes a detection error of a cylinder pressure sensor used in a control of an internal combustion engine. The internal-combustion-engine control device is an electronic control unit (ECU) 1 for an internal combustion engine 100 that includes a cylinder pressure sensor 140 for detecting cylinder pressure in a combustion chamber. The ECU 1 includes an overall controller 81 configured to correct an output signal S2 transmitted from the cylinder pressure sensor 140 in a cylinder 150. The overall controller 81 corrects the output signal S2 from the cylinder pressure sensor 140 in accordance with a correction period calculated based on drive of components of the internal combustion engine 100, such as a fuel injector 400.

Abstract: A manufacturing error and a mounting error of a position sensor used for detection of a rotation angle of a rotary shaft are appropriately calibrated to improve detection accuracy of the rotation angle.

Abstract: Provided is an internal-combustion-engine control device that minimizes a detection error of a cylinder pressure sensor used in a control of an internal combustion engine. The internal-combustion-engine control device is an electronic control unit (ECU) 1 for an internal combustion engine 100 that includes a cylinder pressure sensor 140 for detecting cylinder pressure in a combustion chamber. The ECU 1 includes an overall controller 81 configured to correct an output signal S2 transmitted from the cylinder pressure sensor 140 in a cylinder 150. The overall controller 81 corrects the output signal S2 from the cylinder pressure sensor 140 in accordance with a correction period calculated based on drive of components of the internal combustion engine 100, such as a fuel injector 400.

Abstract: Provided is a fuel injection control device that controls a fuel injection amount at higher accuracy. The fuel injection control device includes: a base waveform acquisition section 823 that generates a control current S9 for controlling a fuel injector 400; an A/D converter 824 that acquires a drive current P for the fuel injector 400 (controlled based on the control current S9) at each of measurement timings t1 to t6 based on a counter cycle; and an arithmetic operation section 821 that, based on a drive current P1 at a first measurement timing t1 and a drive current P2 at a second measurement timing t2 later than the first measurement timing t1, both acquired by the base waveform acquisition section 823, predicts a drive current P3 at a third measurement timing t3 later than the second measurement timing.

Abstract: A method for correcting an output characteristic of an in-cylinder pressure sensor has a problem of insufficient correction precision because the measurement range required for the detection of a peak in-cylinder pressure and an ignition timing resides in a high-pressure region of an in-cylinder combustion cycle, whereas a reference pressure used for correction is measured while leaving an intake valve and an exhaust valve open, so that the reference pressure is out of the required measurement range. An apparatus for measuring an in-cylinder pressure includes: exhaust pressure detection means disposed in an exhaust port of an internal combustion engine to measure an exhaust pressure in the exhaust port; exhaust pressure recording means that records time history of the measured exhaust pressure; and peak exhaust pressure detection means that detects a peak value for each pulsation cycle of the exhaust pressure on the basis of the recorded time history of the exhaust pressure.

Abstract: A method for correcting an output characteristic of an in-cylinder pressure sensor has a problem of insufficient correction precision because the measurement range required for the detection of a peak in-cylinder pressure and an ignition timing resides in a high-pressure region of an in-cylinder combustion cycle, whereas a reference pressure used for correction is measured while leaving an intake valve and an exhaust valve open, so that the reference pressure is out of the required measurement range. An apparatus for measuring an in-cylinder pressure includes: exhaust pressure detection means disposed in an exhaust port of an internal combustion engine to measure an exhaust pressure in the exhaust port; exhaust pressure recording means that records time history of the measured exhaust pressure; and peak exhaust pressure detection means that detects a peak value for each pulsation cycle of the exhaust pressure on the basis of the recorded time history of the exhaust pressure.

Abstract: A control apparatus of an EGR control valve has an EGR control valve has an exhaust gas recirculation passage to circulate exhaust gas of an combustion engine from an exhaust gas passage to an intake air passage. A measurement unit measures a flow rate of EGR gas flowing in the exhaust gas recirculation passage, and a controller receives an input from the measurement unit and closes the EGR control valve if the EGR-gas flow rate is smaller than a predetermined threshold value when the EGR gas is flowing from the exhaust side to the intake side of the internal combustion engine.

Abstract: The present invention prevents an EGR sensor installed in an engine's EGR path from being soiled by soiling substances in exhaust. A catalyst is positioned upstream of the EGR sensor to purify the soiling substances in EGR gas. The status of the EGR sensor is properly controlled in accordance with the conditions of the catalyst. This ensures the EGR sensor is less likely to be affected by the soiling substances in the exhaust under any circumstances of the EGR path and allows the EGR sensor to avoid a decrease in the accuracy of EGR gas detection. An alternative configuration may be employed such that the EGR gas recirculates from the downstream side of a catalyst installed in a main exhaust path.

Abstract: A conventional technique performs valve close control of an EGR valve after an EGR-gas back flow is detected. Therefore, the conventional technique has a subject that, if an EGR-gas flow direction changes from forward flow to back flow, a back flow condition will last not only for a response delay time of a detector but also for the judgment time by calculation processing and the actuation time of the EGR control valve.

Abstract: In measurement methods and a measuring equipment for flow of exhaust gas re-circulation, in order to prevent performances of exhaust, fuel efficiency, and power output from deteriorating due to reasons such as large loss in pressure and time, a control delay during an excessive operation, and reduction in an exhaust gas re-circulation gas flow rate upon measuring an exhaust gas re-circulation gas flow rate, an exhaust gas re-circulation gas flow rate is measured by a plurality of measurement methods on the basis of an intake air flow rate and pressure before and after a heat exchanger installed at an exhaust gas re-circulation passage and the measurement methods are carried out by performing a mutual comparison of the measurement flow rates. Accordingly, it is possible to measure the exhaust gas re-circulation gas flow rate with high precise in a short response time without increasing loss in pressure, and thus to improve performances of exhaust, fuel efficiency, and power output.

Abstract: The present invention prevents an EGR sensor installed in an engine's EGR path from being soiled by soiling substances in exhaust. A catalyst is positioned upstream of the EGR sensor to purify the soiling substances in EGR gas. The status of the EGR sensor is properly controlled in accordance with the conditions of the catalyst. This ensures the EGR sensor is less likely to be affected by the soiling substances in the exhaust under any circumstances of the EGR path and allows the EGR sensor to avoid a decrease in the accuracy of EGR gas detection. An alternative configuration may be employed such that the EGR gas recirculates from the downstream side of a catalyst installed in a main exhaust path.