Abstract: An apparatus is for a process machine having a process-status switch and a process-control element. The apparatus includes a sensor input signal conditioning circuit, a logic circuit and a power output circuit. The sensor input signal conditioning circuit is configured to provide a logic-converted status signal representing a process-status signal associated with the process-status switch of the process machine. The logic circuit is configured to provide a latched output signal converted from the logic-converted status signal provided by the sensor input signal conditioning circuit. The latched output signal has any one of a first latched state and a second latched state. The power output circuit is configured to execute any one of maintaining and disconnecting a voltage being applied to the process-control element depending on the state of the latched output signal.

Abstract: A control device of an internal combustion engine that can accurately estimate an NOx concentration in exhaust gas by using a cylinder internal pressure as basic data. A cylinder internal pressure sensor provided to the internal combustion engine detects a cylinder internal pressure P?. An internal energy correlation value (?V·dP?/d?·??) having correlation with internal energy consumed in the cylinder is calculated based on the cylinder internal pressure P? and an in-cylinder volume V? (? represents a crank angle). The internal energy correlation value is standardized by a load ratio KL, then corrected by a function f(kl) as for a load factor KL so as to calculate an NOx concentration estimated value [NOx]={(?V·dP?/d?·??)/KL}×f(kl).

Abstract: Knocking control is performed using a data group of serial segments each including a predetermined number of values obtained by A/D-converting a signal that appears within a knocking detection window and a data group consisting of serial segments each including the predetermined number of values. The starting timing is shifted and a time-frequency analysis is applied to the data groups in a plurality of frequency bandwidths. Peak values and integration values of spectrums, within the knocking detection window, outputted after the time-frequency analysis in each of the frequency bandwidths are calculated. A P/H method is performed based on the peak value in each of the frequency bandwidths and an integration method is performed based on the integration value in each of the frequency bandwidths for a knocking determination. If knocking is detected through at least one of the methods, the ignition timing is delayed in order to avoid the knocking.

Abstract: A method for determining a point in time of a start of combustion in a cylinder of an internal combustion engine includes: providing a base compression pressure model which gives a curve of a compression pressure in the cylinder as a function of the operating point; adjusting the base compression pressure model using measured cylinder pressures of at least one operating state of the internal combustion engine at points in time at which no combustion is taking place in the cylinder, in order to obtain an adjusted compression pressure model; and determining a point in time of a start of combustion with the aid of a pressure curve determined by the adjusted compression pressure model.

Abstract: A method for determining one or more cylinder pressure features for setting the combustion position in an internal combustion engine includes ascertaining a curve of a cylinder pressure or a curve of a cylinder pressure gradient with respect to a crankshaft angle, filtering the curve of the cylinder pressure or the curve of the cylinder pressure gradient using a filter, in order to eliminate a component of a pressure fluctuation brought about by the piston movement in the combustion chamber, and determining at least one cylinder pressure feature from the filtered curve.

Abstract: The start of the combustion (CRK) of a mixture in a combustion chamber of an internal combustion engine is determined in accordance with a pressure (pc) that is measured in the combustion chamber.

Abstract: A control system for an internal combustion engine having a fuel injector located in a combustion chamber of the engine for injecting fuel into the combustion chamber. The fuel injection timing stored in a fuel injection timing map is retrieved according to the detected engine operating condition to determine the fuel injection timing. An actual ignition timing of the fuel injected into the combustion chamber is detected. An ignition delay of the actual ignition timing with respect to the target ignition timing, which is set according to the engine operating condition and a fuel injection timing correction amount, is calculated according to the calculated ignition delay. The fuel injection timing is corrected with the fuel injection timing correction amount, and the fuel injection is executed according to the corrected fuel injection timing.

Abstract: An ignition timing control system for internal combustion engines, which is capable of preventing occurrence of variation in engine speed and vibrations which can be caused due to variation in combustion state between the cylinders, to thereby improve drivability. The ECU 2 of the ignition timing control system 1 calculates a statistically processed value Pmi_ls#i according to the in-cylinder pressure Pcyl#i, and calculates an averaging target value Piav_cmd by weighted averaging of a minimum value Pmi_ls_min1 and a second minimum value Pmi_ls_min2 within a predetermined range of the statistically processed value.

Abstract: The present invention provides a system and method for controlling the retard limit of an engine having one or more cylinders in which combustion occurs. A sensor is employed to detect the ionization of the combustion process in the cylinders. The ionization is related to a retard limit feedback, and the sensor further transmits a signal associated with the retard limit feedback. A controller relates the retard limit feedback signal to a metric, monitors the stochastic behavior of the metric, and adjusts the ignition timing of the engine in response to the stochastic behavior to operate the engine below a retard limit target.

Abstract: A method eliminates detonation in an internal combustion engine (10) by identifying conditions that identify the imminence thereof. The method centers about the pressure inside the cylinder (16) of the internal combustion engine (10). The method tracks the pressure and when small rapid changes or fluctuations (38) in the pressure occur, the ignition timing is advanced for that particular cylinder (16). An alternative method utilizes a model of pressure based on an array of inputs and how the pressure should act based thereon. The method may also be used to maximize performance of the output of each cylinder (16) by retarding the ignition timing until the small fluctuations (38) appear. The ignition timing could immediately be advanced to prevent a detonation thus identifying a maximized output performance without reaching a detonation condition.

Abstract: A method and an apparatus for controlling an internal combustion engine are described. At least one sensor serves to detect a first variable that characterizes the pressure in the combustion chamber of at least one cylinder. A second variable, which characterizes the maximum value of the change and/or the location of the maximum value of the change, is determined on the basis of this first variable. This second variable serves to control operating parameters of the internal combustion engine in an open-loop and/or a closed-loop manner.

Abstract: A method eliminates detonation in an internal combustion engine (10) by identifying conditions that identify the imminence thereof. The method centers about the pressure inside the cylinder (16) of the internal combustion engine (10). The method tracks the pressure and when small rapid changes or fluctuations (38) in the pressure occur, the ignition timing is advanced for that particular cylinder (16). An alternative method utilizes a model of pressure based on an array of inputs and how the pressure should act based thereon. The method may also be used to maximize performance of the output of each cylinder (16) by retarding the ignition timing until the small fluctuations (38) appear. The ignition timing could immediately be advanced to prevent a detonation thus identifying a maximized output performance without reaching a detonation condition.

Abstract: Maximum braking torque timing in an internal combustion engine can be determined by calculating the net pressure change in an engine cylinder during combustion. The second derivative of the net pressure change is then calculated. The spark timing of the engine is then varied until the maximum acceleration point of the net pressure change is aligned with top dead center.

Abstract: Maximum braking torque timing in an internal combustion engine can be determined by calculating the net pressure change in an engine cylinder during combustion. The second derivative of the net pressure change is then calculated. The spark timing of the engine is then varied until the maximum acceleration point of the net pressure change is aligned with top dead center.

Abstract: A method of controlling detonation in an internal combustion engine is provided with the steps of: combusting a fuel and air mixture within a combustion cylinder; sensing a plurality of pressures at discrete points in time within the combustion cylinder; determining a pressure profile of the plurality of pressures; detecting detonation within the combustion cylinder; and acting upon the detonation, dependent upon where said detonation occurs on the pressure profile.

Abstract: A valve timing system and method 10 is provided which automatically compensates for variations in the compression ratios of cylinders 12 of an internal combustion engine 30. Valve timing system 10 includes a controller 24 and actuators 26, 28 which selectively actuate valves 14, 16 in response to signals received from controller 24. In one embodiment, controller 24 is effective to cause each of the cylinders 12 to have a substantially uniform susceptibility to knock.