The invention provides a method and a system for sensing position of a moving object. A relatively long stroke of a moving object is divided into multiple areas. A sensing element is disposed in each area to sense a magnetic field signal when a magnet apparatus moves along with a moving object and passes through each area, and to generate a sensed signal of each area. A microcontrol unit receives sensed signals of segments and performs temperature compensation and correction on the sensed signals, then combines the sensed signal according to time and a stroke sequence to form a continuous moving-object movement signal that reflects the entire stroke. The invention also provides a clutch piston position sensing system with a sleep function, having a magnet apparatus disposed on the piston and moving along with the piston in the stroke; a sleep control circuit having a sleep sensing element and configured to sense a position of the magnet apparatus and generate a sleep control signal to control the clutch piston position sensing system to be in a started or sleep mode; and a microcontrol unit for receiving the sleep control signal and control the clutch piston position sensing system to be in a sleep or started state.

The invention provides a method and a system for sensing position of a moving object. A relatively long stroke of a moving object is divided into multiple areas. A sensing element is disposed in each area to sense a magnetic field signal when a magnet apparatus moves along with a moving object and passes through each area, and to generate a sensed signal of each area. A microcontrol unit receives sensed signals of segments and performs temperature compensation and correction on the sensed signals, then combines the sensed signal according to time and a stroke sequence to form a continuous moving-object movement signal that reflects the entire stroke. The invention also provides a clutch piston position sensing system with a sleep function, having a magnet apparatus disposed on the piston and moving along with the piston in the stroke; a sleep control circuit having a sleep sensing element and configured to sense a position of the magnet apparatus and generate a sleep control signal to control the clutch piston position sensing system to be in a started or sleep mode; and a microcontrol unit for receiving the sleep control signal and control the clutch piston position sensing system to be in a sleep or started state.

The control device for an internal combustion engine disclosed in the present application is a control device that determines the presence or absence of misfire based on an angle detection cycle calculated from an output signal of an angle sensor, the control device includes an arithmetic processing device and a storage device, the control device is configured so that the storage device stores the angle detection cycle calculated in a misfire detection threshold value comparison section after the reference angle section as a threshold value comparison target cycle and is configured such that the arithmetic processing device determines the presence or absence of misfire based on the misfire detection threshold value cycle calculated based on the reference detection cycle and the threshold value comparison target cycle, thereby it becomes possible to accurately determine the presence or absence of misfire in the control device for the internal combustion engine.

The control device for an internal combustion engine disclosed in the present application is a control device that determines the presence or absence of misfire based on an angle detection cycle calculated from an output signal of an angle sensor, the control device includes an arithmetic processing device and a storage device, the control device is configured so that the storage device stores the angle detection cycle calculated in a misfire detection threshold value comparison section after the reference angle section as a threshold value comparison target cycle and is configured such that the arithmetic processing device determines the presence or absence of misfire based on the misfire detection threshold value cycle calculated based on the reference detection cycle and the threshold value comparison target cycle, thereby it becomes possible to accurately determine the presence or absence of misfire in the control device for the internal combustion engine.

A powertrain engine control method may include: acquiring period information based on tooth information of an engine crank target wheel by using a timer (T); subdividing the period information by a division rate value (R) by using a timer (D) so as to enable the timer (D) to operate R times; carrying out synchronization with the timer (D) and carrying out counting by using a timer (A) from a zero (0) to 720 degrees for a four-stroke engine operation cycle; and correcting, by using a timer (V), an angle counter which is not generated at the time of deceleration of a vehicle.

A powertrain engine control method may include: acquiring period information based on tooth information of an engine crank target wheel by using a timer (T); subdividing the period information by a division rate value (R) by using a timer (D) so as to enable the timer (D) to operate R times; carrying out synchronization with the timer (D) and carrying out counting by using a timer (A) from a zero (0) to 720 degrees for a four-stroke engine operation cycle; and correcting, by using a timer (V), an angle counter which is not generated at the time of deceleration of a vehicle.

A method of determining the instantaneous acceleration of an internal combustion engine comprising one or more cylinders, with respect to a combustion event, n, comprising: a) providing a signal indicative of crankshaft speed, said signal comprising a series of minima and maxima with respect to each successive combustion event; b) determining the accelerations based on: the initial speed value of the minima, Min(n) just before the combustion event, n, and the subsequent speed value of the maximum immediately subsequent to the combustion event, Max (n), as well as the speed of the minima for the subsequent combustion event, Min (n+1).

A method of determining the instantaneous acceleration of an internal combustion engine comprising one or more cylinders, with respect to a combustion event, n, comprising: a) providing a signal indicative of crankshaft speed, said signal comprising a series of minima and maxima with respect to each successive combustion event; b) determining the accelerations based on: the initial speed value of the minima, Min(n) just before the combustion event, n, and the subsequent speed value of the maximum immediately subsequent to the combustion event, Max (n), as well as the speed of the minima for the subsequent combustion event, Min (n+1).

A misfire detection device for an internal combustion engine is provided. A mapping takes time series data of instantaneous speed parameters as inputs. Each instantaneous speed parameter corresponds to one of a plurality of successive second intervals in a first interval. The instantaneous speed parameters correspond to the rotational speed of the crankshaft. The first interval is a rotational angular interval of the crankshaft in which compression top dead center occurs. The second interval is smaller than an interval between compression top dead center positions. The mapping outputs a probability that a misfire has occurred in at least one cylinder that reaches compression top dead center in the first interval. The mapping data defining the mapping has been learned by machine learning.

A misfire detection device for an internal combustion engine is provided. A mapping takes time series data of instantaneous speed parameters as inputs. Each instantaneous speed parameter corresponds to one of a plurality of successive second intervals in a first interval. The instantaneous speed parameters correspond to the rotational speed of the crankshaft. The first interval is a rotational angular interval of the crankshaft in which compression top dead center occurs. The second interval is smaller than an interval between compression top dead center positions. The mapping outputs a probability that a misfire has occurred in at least one cylinder that reaches compression top dead center in the first interval. The mapping data defining the mapping has been learned by machine learning.