High-Degree-of-Freedom Engine Modelling for Control Design Using a Crank-Angle-Resolved Flame Propagation Simulation and Artificial Neural Network Surrogate Models

Abstract

Non-linearity of the engine system creates a challenge in building a reliable control-oriented model (COM). The main source of non-linearity is the complex nature of the combustion process. Modern engine system configurations are increasingly complex and predicting their transient response poses additional difficulty. In the present paper, a COM is developed to address the challenges and capture the behaviour of a high-degree-of-freedom engine system. Engine combustion models are created by utilizing the high-fidelity engine cycle simulation to characterize the effects of main parameters, such as turbulence, air—fuel ratio, and residual fraction, and subsequently capturing the interrelationships with artificial neural networks. Then, system dynamics are accounted for by adding manifold and actuator dynamics models. The capabilities of the proposed COM are demonstrated using a spark-ignition engine with a dual-independent cam phasing as a test case. The results indicate the model's ability to accurately predict engine responses to an arbitrary schedule of engine control inputs over the feasible operating range.

Keywords

control-oriented model engine simulation control combustion model artificial neural network

Get full access to this article

View all access options for this article.

References

Guzzella

Onder

C. H.

Introduction to modeling and control of internal combustion engine system (Springer, Berlin).

Stefanopoulou

A. G.

Cook

J. A.

Freudenberg

J. S.

Grizzle

J. W.

Control-oriented model of a dual equal variable cam timing spark ignition engine. ASME J. Dyn. Syst. Meas. Contr. 1998, 120(2), 257–266.

Stefanopoulou

A. G.

Modeling and control of advanced technology engines PhD Dissertation, Department of Electrical Engineering and Computer Sciense, University of Michigan, 1996.

Lin

Development and validation of a mean value engine model for integrated engine and control system simulation. SAE technical paper 2007-01-1304.

Cook

J. A.

Powell

B. K.

Modelling of an internal combustion engine for control analysis. IEEE Contr. Syst. Mag. 1988, 8(4), 20–26.

Hendricks

Sorenson

S. C.

Mean value modeling of spark ignition engines. SAE technical paper 900616, 1990.

Livshiz

Kao

Will

Validation and calibration process of powertrain model for engine torque control development. SAE technical paper 2004-01-0902, 2004.

Filipi

Z. S.

Assanis

Kramer

D. M.

Ohl

G. L.

Prucka

M. J.

Prucka

DiValentin, Using artificial neural networks for representing the air flow rate through a 2.4liter VVT engine. SAE technical paper 2004-01-3054, 2004.

Stefanopoulou

A. G.

Freudenberg

J. S.

Grizzle

J. W.

Variable camshaft timing engine control. IEEE Trans. Contr. Syst. Technol. , 2000, 8(1), 23–34.

10.

Hsieh

S. C.

Freudenberg

J. S.

Stefanopoulou

A. G.

Multivariable controller structure in a variable cam timing engine with electronic throttle and torque feedback. In Proceedings of the 1999 Conference on Control Applications, Kohala Coast, HI, 22–27 August 1999, pp. 465–470.

11.

Mianzo

Peng

Modeling and control of a variable valve timing engine. In Proceedings of the American Control Conference, Chicago, IL., 2000, pp. 554–558.

12.

Krämmer

Liebl

Krug

Munk

Reuss

H.-C.

Real-time engine models. SAE technical paper 2003-01-1050, 2003.

13.

Krug

Liebl

Munk

Krämmer

Reuss

Physical modelling and use of modern system identification for real-time simulation of spark ignition engines in all phases of engine development. SAE technical paper 2004-01-0421, 2004.

14.

Wiebe

I. I.

The combustion speed in internal combustion piston engines. In Collected works of piston engine research, 1956 (Laboratory of Engines, Academy of Science, Moscow). Translated into English by Kiisa

, 1993 (KTA, Stockholm).

15.

Lee

T.-K.

Filipi

Z. S.

Improving the predictiveness of the quasi-D combustion model for spark ignition engines with flexible intake system. Int. J. Automot. Technol. 2010 (in press).

16.

Tabaczynski

R. J.

Ferguson

C. R.

Radhakrishnan

A turbulent entrainment model for spark-ignition engine combustion. SAE technical paper 770647, 1977.

17.

Tabaczynski

R. J.

Trinker

F. H.

Shannon

B. A.

Further refinement and validation of a turbulent flame propagation model for spark-ignition engines. Combust. Flame , 1980, 39(2), 111–121.

18.

Ricardo, Inc, WAVE V8 engine reference manual 2008 (Ricardo Software, Ricardo, Inc.).

19.

Poulos

S. G.

Heywood

J. B.

The effect of chamber geometry on spark-ignition engine combustion. SAE technical paper 830334, 1983.

20.

Filipi

Z. S.

Assanis

D. N.

Quasi-dimensional computer simulation of the turbocharged spark-ignition engine and its use for 2- and 4-valve engine matching studies. SAE technical paper 910075, 1991.

21.

Filipi

Z. S.

Investigation of variable valve area strategies for a turbocharged SI-engine. In IMechE 1994-6, Proceedings of the 5th International Conference on Turbocharging and turbochargers, London, 7–9 June 1994, pp. 93–102 (Mechanical Engineering Publications Limited, London and Bury St. Edmunds, UK).

22.

Filipi

Z. S.

Assanis

D. N.

The effect of stroke-to-bore ratio on combustion, heat transfer and performance of a homogeneous-charge spark-ignited engine of given displacement. Int. J. Engine Res. , 2001, 1(2), 191–208. DOI: 10.1243/1468087001545137.