Litcius/Paper detail

Optimization of PID control parameters for marine dual-fuel engine using improved particle swarm algorithm

Zhuo Hu, Weihao Guo, Kege Zhou, Lei Wang, Fu Wang, Jinliang Yuan

2024Scientific Reports17 citationsDOIOpen Access PDF

Abstract

This study presents a comprehensive investigation into the optimization of PID control parameters for marine dual-fuel engines using an improved particle swarm algorithm. Through the development of a Matlab/Simulink simulation model, the thermodynamic behavior of the engine and the functionality of its control system are analyzed. The PID control parameters for air-fuel ratio control and mode switching control systems are fine-tuned utilizing the improved particle swarm algorithm (PSO). Simulation results demonstrate that the proposed improved PID-PSO approach outperforms traditional PID and traditional PSO-PID control methods in terms of reduced overshoot, minimized steady-state error, faster response times, and improved stability across various operating conditions and response modes. In comparison to traditional PID and PSO-PID controllers, the improved PSO-PID controller reduces the response time by 0.47 s and 0.21 s, the maximum overshoot by 98.43% and 96.05%, and decreases the absolute errors by 87.42% and 90.55%, respectively, in air-fuel ratio control using the step response method. The study's findings offer valuable insights into enhancing the performance and efficiency of marine dual-fuel engines through advanced control strategies.

Topics & Concepts

PID controllerOvershoot (microwave communication)Particle swarm optimizationControl theory (sociology)MATLABStep responseComputer scienceController (irrigation)Rise timeControl engineeringAlgorithmTemperature controlEngineeringControl (management)VoltageArtificial intelligenceBiologyOperating systemAgronomyElectrical engineeringTelecommunicationsAdvanced Control Systems OptimizationAdvanced Control Systems DesignAdvanced Combustion Engine Technologies