Control-Oriented Model for Camless Intake Process—Part I1

Ashhab, Moh’d Sami; Stefanopoulou, Anna G.; Cook, J.A.; Levin, Michael

doi:10.1115/1.482447

Cited by 24 publications

(12 citation statements)

References 12 publications

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“…The thermodynamic equations that describe the intake process of internal combustion engines including the 12-cyliner camless engine are based on the principles of the conservation of mass and the ideal gas law [3]. More specifically, the following relations hold for the engine cylinders .…”

Section: Intake Process Analysismentioning

confidence: 99%

“…A simulation model in Matlab software was built for the engine based on Equations (1) and (2) and implementing the implicit relations of the terms within the equations [3]. The various implicit relations include parameters that needs to be selected by comparison with real experimental engine data available from the dynamometer test at an automotive company.…”

Section: Intake Process Analysismentioning

confidence: 99%

“…The camless engine model was initiated in [3] as a result of collaboration between academia and industry. Furthermore, the basic control system of such an engine was designed in [1].…”

Section: Introductionmentioning

confidence: 99%

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Control of 12-Cylinder Camless Engine with Neural Networks

Ashhab

2017

MATEC Web Conf.

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Abstract. The 12-cyliner camless engine breathing process is modeled with artificial neural networks (ANN's). The inputs to the net are the intake valve lift (IVL) and intake valve closing timing (IVC) whereas the output of the net is the cylinder air charge (CAC). The ANN is trained with data collected from an engine simulation model which is based on thermodynamics principles and calibrated against real engine data. A method for adapting single-output feed-forward neural networks is proposed and applied to the camless engine ANN model. As a consequence the overall 12-cyliner camless engine feedback controller is upgraded and the necessary changes are implemented in order to contain the adaptive neural network with the objective of tracking the cylinder air charge (driver's torque demand) while minimizing the pumping losses (increasing engine efficiency). All the needed measurements are extracted only from the two conventional and inexpensive sensors, namely, the mass air flow through the throttle body (MAF) and the intake manifold absolute pressure (MAP) sensors. The feedback controller's capability is demonstrated through computer simulation.

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Section: Intake Process Analysismentioning

confidence: 99%

Section: Intake Process Analysismentioning

confidence: 99%

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Control of 12-Cylinder Camless Engine with Neural Networks

Ashhab

2017

MATEC Web Conf.

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“…From t to t # t, the valve moves with constant acceleration, hence, t controls the peak lift of the valve. By simplifying the trapezoidal valve pro"le with an ideal rectangular pro"le, it is clear that the intake valve duration is controlled by the di!erence in the pulse timing v"t !t # t. The cylinder air charge is more sensitive to the duration rather than the lift, especially, if the lift is above 3 mm [6]. For this reason, we choose IVD as the e!ective control signal of the camless breathing process.…”

Section: Camless Actuation Dynamicsmentioning

confidence: 99%

Inherent limitations and control design for camless engine idle speed dynamics

Wang

Stefanopoulou

Smith

2001

Intl J Robust & Nonlinear

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SUMMARYThe idle speed control problem of a spark-ignited engine equipped with a camless valvetrain is considered. The camless valvetrain allows control of the individual intake and exhaust valves of each cylinder and can be used to achieve unthrottled operation, and consequently, optimize the engine performance. We formulate the speed control problem for this engine and show that it exhibits unstable open-loop behaviour with a signi"cant delay in the feedback loop. The instability is intrinsic to the unthrottled operation and speci"c to the camless actuation used to achieve the unthrottled operation. The delay is caused by the discrete combustion process and the sensor/computer/actuator interface. We demonstrate the inherent system limitations associated with the unstable dynamics and the delay and provide insight on the structural (plant) design that can alleviate these limitations. Finally, stabilizing controllers using classical and modern robust design techniques are presented and tested on a nonlinear simulation model.

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“…al.. 2001), and a dynamic characterization based on a Helmholtz resonator intake runner pressure model, (Moraal, 1994, Ashhab, et. al., 2000.…”

Section: Introductionmentioning

confidence: 99%

Modeling positive intake value overlap air charge response in camless engines

Gibson

Kolmanovsky

Proceedings of the 2003 American Control Conference, 2003.

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Camless engines are capable of maximizing torque and fuel efficiency over a broad range of engine speeds by independently controlling the engine valves. The valve timing and operating mode changes that are required to achieve these benefits can potentially generate significant steady state and transient variations in the air charge and burned gas fraction. An unthrottled camless engine air charge model is developed that is capable of simulating the steady state and transient air charge behavior. Simulation results are used to demonstrate the impact of valve timing and engine speed variations on the air charge and burned gas response and to motivate the use of such models in the camless engine control development process.

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Control-Oriented Model for Camless Intake Process—Part I1

Cited by 24 publications

References 12 publications

Control of 12-Cylinder Camless Engine with Neural Networks

Control of 12-Cylinder Camless Engine with Neural Networks

Inherent limitations and control design for camless engine idle speed dynamics

Modeling positive intake value overlap air charge response in camless engines

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