Optimal design of an adaptive robust proportional-integral-derivative controller based upon sliding surfaces for under-actuated dynamical systems

Abstract: This paper presents a novel adaptive robust proportional-integralderivative (PID) controller for under-actuated dynamical systems via employing the advantages of the PID control and sliding surfaces. The related control gains as adjustable parameters are computed during the control process using gradient descent techniques and the chain derivative rule. Based on the design of control rules, the genetic algorithm optimization is utilized in order to find the optimal values of the learning rates and initial cond… Show more

A New Hybrid Load Frequency Control Strategy Combining Fuzzy Sets and Differential Evolution

A New Hybrid Load Frequency Control Strategy Combining Fuzzy Sets and Differential Evolution

Barrier function-based nonsingular prescribed performance terminal sliding mode tracker for under-actuated nonlinear systems: Experimental study

A novel adaptive PID controller with new seesaw algorithms using alternative derivatives