Abstract
In a modern small gasoline engine fuel injection system, the load of the engine is estimated based on the measurement of the manifold absolute pressure (MAP) sensor, which took place in the intake manifold. This paper present a more economical approach on estimating the MAP by using only the measurements of the throttle position and engine speed, resulting in lower implementation cost. The estimation was done via two-stage multilayer feed-forward neural network by combining Levenberg-Marquardt (LM) algorithm, Bayesian Regularization (BR) algorithm and Particle Swarm Optimization (PSO) algorithm. Based on the results found in 20 runs, the second variant of the hybrid algorithm yields a better network performance than the first variant of hybrid algorithm, LM, LM with BR and PSO by estimating the MAP closely to the simulated MAP values. By using a valid experimental training data, the estimator network that trained with the second variant of the hybrid algorithm showed the best performance among other algorithms when used in an actual retrofit fuel injection system (RFIS). The performance of the estimator was also validated in steady-state and transient condition by showing a closer MAP estimation to the actual value.
Highlights
Electronic fuel injection (EFI) system is expected to be one of the most promising technologies on improving the fuel economy and reducing harmful emissions [1]
Due to the different test mean squared error (MSE) produced by different sets of network weights, the networks were trained multiple of times
The average test MSE were recorded for detailed analysis
Summary
Electronic fuel injection (EFI) system is expected to be one of the most promising technologies on improving the fuel economy and reducing harmful emissions [1]. A different approach in estimating the manifold absolute pressure of a small engine were introduced by using a feedforward neural network with hybrid training algorithm.
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