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Abstract

This paper proposes a radial basis function (RBF) based approach for the fuel injection control problem. In the past, neural controllers for this problem have centred on using a cerebellar model articulation controller (CMAC) type network with some success. The current production engine control units also use look-up tables in their fuel injection controllers, and if adaptation is permitted to these look-up tables the overall effect closely mimics the CMAC network. Here it is shown that an RBF network with significantly fewer nodes than a CMAC network is capable of delivering superior control performance on a mean value engine model simulation. The proposed approach requires no a priori knowledge of the engine systems, and on-line learning is achieved using gradient descent updates. The RBF network is then implemented on a four-cylinder engine and, after a minor modification, outperforms a production engine control unit.

Keywords

Gaussian networks air-fuel ratio control radial basis functions

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References

Draft air quality improvement plan. In EPA Publication 707, 2000 (Environmental Protection Authority, Port Phillip Region).

Majors

Stori

Cho

Neural network control of automotive fuel-injection systems. IEEE Control Sys., 1994, 31–36.

Onder

Geering

Model-based multivariable speed and air-to-fuel ratio control of an SI engine. SAE paper 930859, 1993.

Inagaki

Ohata

Inoue

An adaptive fuel injection control with internal model in automotive engines. IEEE Proc., 1990, 78–83.

Amstutz

Fekete

N. P.

Powell

J. D.

Model based air-fuel ratio control in SI engines with a switch type EGO sensor. SAE paper 940972, 1994.

Dingli

Watson

Palaniswami

Milkins

Adaptive control of air-fuel ratio for optimizing the fuel efficiency of a lean burn natural gas engine. SAE paper 945750, 1994.

Shiriashi

Ipri

Cho

CMAC neural network for fuel-injection control. Presented at American Control Conference 1993, 1993.

Park

Sandberg

I. W.

Universal approximation using radial basis function networks. Neural Computation, 1991, 3, 246–257.

Girosi

Poggio

Networks and the best approximation property. Biological Cybernetics, 1990, 63, 169–176.

10.

McDowell

D. M.

Irwin

G. W.

Lightbody

McConnell

Hybrid neural adaptive control for bank-to-turn missiles. IEEE Control Syst. Technol., 1997, 297–308.

11.

Ziauddin

Zalzala

A. M.

Model-based compensation and comparison of neural network controllers for uncertainties of robotic arms. Presented at IEE Control Theory Applications, 1995.

12.

Gorinevsky

Kapitanovsky

Goldenberg

Neural network architecture for trajectory generation and control of automated car parking. IEEE Control Syst. Technol., 1996, 50–56.

13.

Cho

Hedrick

J. K.

Automotive powertrain modelling for control. Trans. ASME, 1989, 568–576.

14.

Won

Choi

S.-B.

Hedrick

J. K.

Air-to-fuel ratio control of spark ignition engines using Gaussian network sliding control. IEEE Control Syst. Technol., 1998, 678–687.

15.

Hendricks

Vesterholm

Kaidantzis

Rasmussen

Jensen

Nonlinear transient fuel film compensation. SAE paper 930767, 1993.

16.

Aquino

Transient A/F control characteristics of the 5 liter central fuel injection engine. SAE paper 810494, 1981.

17.

Albus

J. S.

A new approach to manipulator control: The cerebellar model articulation controller (CMAC). Trans. ASME, 1975, 220–227.

18.

Shiriashi

Ipri

Cho

CMAC neural network controller for fuel-injection systems. IEEE Control Syst. Technol., 1995, 32–37.

19.

Falk

C. D.

Mooney

J. J.

Three-way conversion catalysts: effect of closed loop feed-back control and other parameters on catalyst efficiency. SAE paper 800462, 1980.

Gaussian networks for fuel injection control

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