Optimized Controller Structured to Solve Aircraft Pitch Control Problem

In this paper, a comparative assessment is made based on time domain specifications and erro r criteria between various types of controllers like conventional PID, and heuristic approaches like FA, P SO and BFO based PID and I-PD structured controllers. The dynamic modelling of pitch control system i s considered on the design of an auto pilot that controls the pitch angle. To study the effectiveness of the c ontrollers, PID controller, FA, PSO and BFO based PID and I-PD controllers are developed for controllin g the pitch angle of an aircraft. Simulation results for the response of pitch controller are presented in ste p response. Finally the performances of pitch control systems are investigated and analyzed based on com mon criteria of step’s response in order to identify which control strategy delivers better performance wit h respect to the desired pitch angle. The results are obtained and finally a comparative study of the error indices and time domain specifications are made between all the controllers. This experimental study conf irms that, IPD structure offers enhanced result for the reference tracking problem compared with the PI D structure. FA based PID controller has least settling time and least IAE and ISE. Keywords-Flight pitch control, Heuristic approach, PID controller, I-PD controller, Performance eva luation. 1.INTRODUCTION Present research work approves that: heuristic approach optimization is developed as a prominent practice to determine the best solutions for a class of engineering optimization issues. In the paper, number of heuristic proc edures are implemented and executed for PID and I-PD structures by the authors for a class of process models [1 ,2]. Selection of soft computing technique for a chosen problem relies on the following constrains: (i) Engineeri ng problem to be resolved, (ii) Search space dimension, (iii) Value of cost function (single or multiple), (iv) Ada ptability of the algorithm and its parameters, (v) Simplicity in execution, (vi) Optimization accuracy and (vii) Fl exibility. In this paper, conventional controllers, such as PI and PID are tuned using the Ziegler-Nichols, Tyreus-Luyb en and relay auto tuning methods [8] and are compared with heuristic approaches like, Particle Swarm Optimiz ation (PSO), Bacterial Foraging Optimization (BFO) and Firefly Algorithm (FA) based controllers for the aircra ft pitch control problem. The heuristic approaches like BFO, PSO and FA are adopted to determine the optimal values of Kp, Ki and Kd for PID and I-PD structures. The performance of the conventional and soft computing approach based controllers is assessed based on the well known time domain specifications and error criteria. Proposed work determines the best possibly tuned con troller parameters for aircraft pitch system. In this paper, the aircraft pitch control issue is addressed using the co nventional PID controllers and heuristic approaches based PID and I-PD structures. The remaining part of the paper is as follows; section 2 outlines the description of aircraft pitch system, sectio n 3 discusses about the chosen heuristic algorithms, section 4 presents the experimental results and discussions. Finally the conclusion of the present research work is discussed in section 5. I. DESCRIPTION OF SYSTEM The movement of aircraft during flight is three dimensional and it can be represented by three principal axes-r oll, pitch and yaw .Roll is the rotation around the front to back axis. Pitch is the rotation around side to side axis. Pitch motion is the movement of the nose of the aircraft upwards and downwards. Pitch motion is responsible f or the change in altitude during flight. Pitch control movement is a critical parameter during take off as well as d uring steady flight. If pitch of an aircraft is not calibrated properly then the aircraft can be stalled. Pitch moveme ISSN (Print) : 2319-8613 ISSN (Online) : 0975-4024 R. Monica et al. / International Journal of Engineering and Technology (IJET) DOI: 10.21817/ijet/2017/v9i2/170902281 Vol 9 No 2 Apr-May 2017 1155 nt of aircraft is categorized under longitudinal stability and the other two parameters roll and yaw are categorize d under lateral stability. An elevator is used to control pitch and it is present on the horizontal tail surface. An el evator tilts the nose of the aircraft upwards and downwards. If the elevator rotates up, lift force on the tail decrea ses which causes the tail to lower and the nose to rise. If the elevator rotates downwards, lift force on the tail inc reases which causes the tail to rise and the nose to lower. Yaw is the rotation around the vertical axis .The move ment of aircraft is non-linear and complex to stabilize and control. Aircraft pitch varies when any of the other tw o parameters yaw or roll are varied. The forward speed of the aircraft increases when the aircraft’s nose lowers a nd the forward speed decreases as the aircraft’s nose rises. Hence it is required to stabilize the pitch of an aircraf t in order to maintain the altitude during flight. Here the authors have proposed design of conventional PI and PI D controllers using Ziegler–Nichols method, Tyreus-Luyben and relay auto-tuning methods [1] and other heuris tic approaches such as PSO, BFO and FA for stabilizing and controlling the aircraft pitch. The mathematical equations of an aircraft are a set of six coupled non-linear differential equations. Under cert ain assumptions these equations can be decoupled and linearized using lateral and longitudinal dynamics. Longit udinal dynamics are used to govern aircraft pitch In this paper an auto pilot is designed to control the pitch of an aircraft. Let us assume the aircraft is steady at constant altitude and velocity; hence the forces thrust, drag, weight and lift balance each other in x and y directions. .Let us assume that changing the pitch angle does not change the sp eed of an aircraft under any circumstance. Under these assumptions, the longitudinal equations are written as: ( = μΩ [−( + ) + 1/(μ − ) − ( sinγ) + ] (1) = μ [[ − ( + )] + [ + (1 − μ )] + ( )] (2) = Ω (3) In this system, the input is the elevator angle and pitch angle is the output of the aircraft. Let us assume some numerical values to simplify the modeling equations: = −0.313 + 56.7 = 0.232 (4) = -0.0139α -0.426q + 0.0203 (5) P = 56.7q (6) The above values are obtained from the data of one of the Boeing’s commercial aircraft. Normally, the pitch angle of an aircraft is controlled byvarying the angle and the lift force of the rear elevator. During this situation, it is necessary to account the aerodynamic forces (lift and drug) and aircraft’s inertia. As p er the literature, the mathematical model of this system is a third order equation, after linearising the nonlinear d ynamics around an operating point. In this paper, the well known models existing in the literature are chosen for the study. Example 1: This model is obtained from [10,11]. This is a third order equation with a zero dead time. Eqn. (7) depicts the transfer function model and eqn. (2) shows the state-space model. s 921 . 0 s 739 . 0 s 1774 . 0 s 151 . 1 ) s ( ) s ( 2 3 e + + + = δ Δ θ Δ (7)