Simulating Optimal Control of an Inertial Platform Stabilization Loop Using Genetic Algorithms

Author

Ke Deng ; Fei Long ; Su Wang

Author_Institution

Dalian Naval Acad., Dalian, China

fYear

2013

fDate

3-4 Dec. 2013

Firstpage

177

Lastpage

181

Abstract

Inertial platform stabilization loop is required with good quickness, high steady precision, strong anti-jamming capability, etc. at the same time, and the traditional PID control is difficult to meet index requirements of the good control performance. Stabilization loop of inertial navigation system platform is treated as a study object, and the mathematical model is built with dynamic loop according to the position of PID controller. Based on the self-adaptive online genetic algorithm tuning, PID control strategy is proposed, and the PID parameters are optimized, and loop model is simulated with MATLAB software. The result of simulation shows that since PID controller is adopted after the genetic algorithm optimization, system control precision, stability and response speed have been improved, enhancing the robustness.

Keywords

genetic algorithms; inertial navigation; optimal control; robust control; self-adjusting systems; three-term control; velocity control; MATLAB software; PID control; PID parameters; antijamming capability; dynamic loop; genetic algorithm optimization; inertial navigation system platform; inertial platform stabilization loop; loop model; mathematical model; optimal control; response speed; robustness; self-adaptive online genetic algorithm tuning; stability; system control precision; DC motors; Encoding; Genetic algorithms; Mathematical model; Optimization; PD control; Torque; PID control; genetic algorithm; inertial stabilization loop;

fLanguage

English

Publisher

ieee

Conference_Titel

Intelligent Systems (GCIS), 2013 Fourth Global Congress on

Conference_Location

Hong Kong

Print_ISBN

978-1-4799-2885-9

Type

conf

DOI

10.1109/GCIS.2013.34

Filename

6805931