Abstract

In this paper, a nonlinear active disturbance rejection control (NLADRC) strategy based on nonlinear extended state observer (NLESO) is proposed to solve the unmodeled dynamics, coupling and disturbance due to change of working point in the variable geometry turbine (VGT) and exhaust gas recirculation (EGR) system, so as to achieve accurate control of intake manifold pressure and mass air flow in a diesel engine. To achieve decoupling, the double-input double-output (DIDO) VGT-EGR system is decomposed into two single-input single-output (SISO) subsystems, and each subsystem has a separate nonlinear active disturbance rejection controller. At the same time, the convergence proof of the designed NLESO is also given theoretically. Finally, the NLADRC controller is compared with linear active disturbance rejection controller and proportional–integral–derivative (PID) controller. Through simulation, it is indicated that the proposed NLADRC controller has better transient response performance, resistance to external disturbance and robustness to the change of engine operating point.

Highlights

  • As one of the main power sources of trucks and ships, diesel engines have the characteristics of strong power performance, good fuel economy and long service life

  • The nonlinear, uncertain and time-varying process dynamics and the external disturbance are uniformly treated as a total disturbance, which is estimated and compensated by extended state observer (ESO) and eliminated in the control input, achieving the purpose of controlling the intake manifold pressure and air quality flow rate of diesel engines by linear active disturbance rejection control (LADRC) controller

  • tracking differentiator (TD) was mentioned earlier when we introduced the structure of the nonlinear active disturbance rejection control (NLADRC)

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Summary

Introduction

As one of the main power sources of trucks and ships, diesel engines have the characteristics of strong power performance, good fuel economy and long service life. To achieve the required emission level and safe operation of the engine and turbocharger, Wahlström et al [4] proposed a proportional–integral–derivative (PID) structure that controls the air/fuel ratio λ and the intake manifold EGR fraction xegr. The nonlinear, uncertain and time-varying process dynamics and the external disturbance are uniformly treated as a total disturbance, which is estimated and compensated by extended state observer (ESO) and eliminated in the control input, achieving the purpose of controlling the intake manifold pressure and air quality flow rate of diesel engines by LADRC controller. Based on the work of Song and Xie [24,25] on the LADRC controller in diesel engines, we designed the NLADRC controller for VGT-EGR system in order to improve the control accuracy.

System Dynamics
NLESO Design
Convergence Analysis of NLESO for the Intake Manifold Pressure
NLADRC Controller Design and Simulation Results
Disturbance Rejection
Robustness
Conclusions

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