An engine virtual test environment system may include at least one memory and at least one processor configured to perform a virtual engine test and generate a virtual engine to which a physics-based model and a data-driven model are applied to replace an engine. The at least one memory may be configured to store a physics-based model representing the actual structure of an engine by any one of simulation, phenomenological relationship expression, physical characteristic change of constituent elements, a combust model, an ECU model, and an engine model, and a data-driven model representing the actual operation of the engine by any one of a test model, a mathematical model, modeling, engine DoE techniques, mathematical and statistical techniques, a driving range.

A vehicle comprises an aftertreatment system configured to reduce constituents of an exhaust gas. The vehicle also includes a controller configured to determine a predicted load on the vehicle during a route, and adjust at least one of a temperature of the aftertreatment system or an amount of a reductant inserted into the aftertreatment system based on the predicted load.

In a method for determining an optimized fuel injection profile in an internal combustion engine, a setpoint combustion profile is firstly defined. Furthermore, at least one influential parameter which influences the setpoint combustion profile is determined. With the influential parameter, a corrected fuel injection profile is determined in a closed-loop control process. This method is preferably repeated iteratively.

A method of providing stable communication between subsystems in a co-simulation system, including providing a signal S.sub.1 describing an output angular velocity of a rotating body of the first physical system; filtering the signal S.sub.1 using a continuous moving average, CMA, filter; and forming a time discrete first output signal S.sub.1*. In a second subsystem the signal S.sub.1* is received and the angular velocity described by S.sub.1* is applied to the second physical system. A response signal S.sub.2* describes a torque generated by the second subsystem. The response signal S.sub.2* is received by the first subsystem where a time discrete feedback signal S.sub.F* is formed based on the difference between the response signal S.sub.2* and a time discrete damping signal S.sub.D*.

An apparatus for controlling an EGR valve, includes: a measurement unit to measure at least one operation condition of an engine system; a fresh air amount setting unit to set a target amount of fresh air based on the operation condition; a fresh air amount sensor to measure a current amount of fresh air introduced through an intake line; a control calculation unit to set a signal for controlling an opening degree of the EGR valve so that the current amount of fresh air follows the target amount of fresh air; and an identifier to simulate an input and an output of the engine system, and output engine system input-output sensitivity which is a ratio of a change rate of the current amount of fresh air to a change rate of the opening degree of the EGR valve.

A control device of an internal combustion engine using a neural network, wherein an output value obtained by experiments is made training data for a value of an operating parameter of the engine in a presumed usable range, while an output value obtained by prediction without relying on experiments is made training data for a value of the operating parameter of the engine outside of the presumed usable range. The training data obtained by experiments and the training data obtained by prediction are used to learn the weights and the biases of the neural network so that an output value which changes in accordance with a value of an operating parameter of the engine matches the training data, and thereby even outside of the presumed usable range of the operating parameter, the output value can be suitably estimated.

A method for control and co-simulation in a system having multiple subsystems, each representing a physical system, includes, in a first subsystem simulating a first physical system, providing a first time continuous output signal representing a property of the first physical system, and filtering the output signal using a continuous moving average (CMA) filter as an anti-aliasing filter to form a filtered time continuous signal. Filtering the output signal includes integrating the time continuous signal to form an integrated signal, sampling the integrated signal, for each sample, forming an average value from the current sample and a previous sample, and forming a filtered time continuous signal from the average values. The method also includes providing the filtered time continuous signal to a second subsystem simulating a second physical system. A system for performing the method is also provided.

The present invention provides a process for reducing abnormal combustion within a combustion chamber of the engine. The process can include simulation of the piston-driven internal combustion engine with oil droplets from the crankcase entering into the combustion chamber. In addition, the oil drops entering into the combustion chamber can be simulated as hot spots, as can simulation of fuel combustion within the combustion chamber. A probability of pre-ignition for at least a portion of the simulated hot spots as a function of the simulated fuel combustion and the simulated hot spots within the combustion chamber can be calculated and based on the calculation a combustion chamber parameter can be altered such that pre-ignition within the combustion chamber is reduced.

A system for project planning for an engine for determining an operating behavior of the engine to be expected under defined operating conditions of the engine includes: a plurality of sensors configured to measure respective ones of the defined operating conditions of the engine; and a knocking intensity prediction tool configured to determine the knocking intensity of the engine to be expected under the defined operating conditions of the engine.

The present disclosure relates to internal combustion engines in general. The teachings may be embodied in methods and devices for operating an internal combustion engine having one or more cylinders which are each assigned gas inlet valves. The method may include: in a first operating state, determining a model temperature of a gas in the intake tract cyclically for a present point in time using a predefined intake pipe model without reference to a present temperature measurement value of the gas; determining a cylinder air mass situated in a respective cylinder after closing the gas exchange valves based at least in part on the model temperature determined for the present point in time; and metering fuel into the respective cylinder based at least in part on the determined cylinder air mass. The model temperature for the present point in time depends at least in part on a model temperature determined for a preceding point in time.