Model and robust gain‐scheduled PID control of a bio‐inspired morphing UAV based on LPV method

In this paper, for the nonlinear influencing factors such as uncertainty and external disturbance existing in the actual driving process of the car‐like mobile robot (CLMR), a data‐driven generalized predictive control (GPC) method based on interval type‐2 T‐S fuzzy neural network (IT2TSFNN) is proposed for the trajectory tracking of CLMR. The controlled auto‐regressive integrated moving average (CARIMA) model of the mobile robot is established by analyzing data samples and using IT2TSFNN. Then, a generalized predictive controller is designed for the CARIMA model. Also, the global convergence of IT2TSFNN is verified by the Stone‐Weirstrass theorem. Unlike most previous results, the proposed method does not rely on the mathematical model of the mobile robot but only on the historical data of its operation. Finally, the simulation results show that the proposed method can avoid repeatedly debugging parameters, deal with the influence of uncertain factors, and obtain higher tracking accuracy.

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Data‐driven generalized predictive control for car‐like mobile robots using interval type‐2 T‐S fuzzy neural network

Shui

Zhao

Dian

et al. 2021

“…The proportional‐integral‐derivative (PID) family is still a commonly used controller in the industry due to its simplicity in implementation and ability to provide satisfying results. This includes its application in the solar steam turbines [1], hydro turbine governing system [2], the bio‐inspired morphing wing of the unmanned aerial vehicle (UAV) [3] and robotics [4]. The Proportional‐Integral (PI) controller is able to eliminate errors or disturbance in a system but could be subjected to oscillation in their response, large overshoot, and prolonged settling time due to the coupled tuning gains, where the gain affects each other and oppose the response characteristics carried by individual tuning gain.…”

Section: Introductionmentioning

confidence: 99%

Study of anti‐windup pi controllers with different coupling–decoupling tuning gains in motor speed

Chiah

Hoo

Chung³

2021

Proportional‐integral (PI) controller is still a widely used closed‐loop controller in industrial applications due to its simplicity. PI controllers experience difficulty in having both non‐overshoot with short rise time. Such unfavorable response is due to its coupled tuning‐gains and the integral windup, which eventually leads to system instability. Various anti‐windup techniques have been proposed. However, similar to the conventional PI controllers, most of these techniques have coupled proportional and integral tuning gains that affect one another. The controllers contain adaptive switching between the conventional and its designated integral control depending on the saturation state. This paper proposes a robust non‐switching anti‐windup PI controller with semi‐decoupling tuning gain. Speed control simulation and experimental testing are conducted to investigate the impact of the various tuning gain dependency. The proposed controller shows a fast response with no overshoot as compared to the conventional and other non‐switching anti‐windup PI controllers with coupling and decoupling tuning gain at certain loading conditions.

“…Gain‐scheduling PID controller design based on quadratic stability and special technique to simplify the corresponding BMI solution is presented in [26]. In [27], an improved modeling method which combines partial linearization and function substitution is proposed to build an LPV model for a nonlinear unmanned aerial vehicle. Then a robust gain‐scheduling PID controller is designed based on bounded real lemma.…”

Section: Introductionmentioning

confidence: 99%

Novel robust gain scheduled PID controller design usingD_Rregions

Rosinová

Veselý

Hypiusova

2021

This paper develops a new design procedure for robust output feedback gain scheduled and switched PID controller design for a linear parameter varying discrete‐time system with polytopic uncertainties. The proposed approach is based on DR regions for robust pole placement and allows to consider also other performance indices. The design procedure aims to design a robust PID gain scheduled and switched controller for polytopic gain scheduled and switched plant model such that the closed‐loop eigenvalues for fixed gain scheduled parameters are in the prescribed DR region and the corresponding quadratic performance has the minimal value. The obtained design procedure can be also used to design a robust discrete‐time switched controller with arbitrarily switching law.