Proportional-derivative linear quadratic regulator controller design for improved longitudinal motion control of unmanned aerial vehicles

With the purpose of overcoming the defect that unmanned air vehicles (UAVs) are easily disturbed by air current and tend to be unstable, an augmented-stability controller was developed for a certain UAV’s longitudinal motion. According to requirements of short-period damping ratio and control anticipation parameter (CAP) in flight quality specifications of GJB185-86 and C*, linear quadratic regulator (LQR) theory was used in the augmented-stability controller’s design. The simulation results show that the augmented-stability controller not only improves the UAV’s stability and dynamic characteristics but also enhances the UAV’s robustness.

Download Full-text

Gain scheduling LQI controller design for LPV descriptor systems and motion control of two-link flexible joint robot manipulator

An International Journal of Optimization and Control Theories & Applications (IJOCTA) ◽

10.11121/ijocta.01.2018.00564 ◽

2018 ◽

Vol 8 (2) ◽

pp. 201-207 ◽

Cited By ~ 1

Author(s):

Yusuf Altun

Keyword(s):

State Space ◽

Motion Control ◽

Controller Design ◽

Linear Quadratic Regulator ◽

Robotic Manipulator ◽

Gain Scheduling ◽

Descriptor Systems ◽

Natural State ◽

Linear Quadratic ◽

Flexible Joint

This paper proposes a gain scheduling linear quadratic integral (LQI) servo controller design, which is derived from linear quadratic regulator (LQR) optimal control, for non-singular linear parameter varying (LPV) descriptor systems. It is assumed that state space matrices are non-singular since many mechanical systems do not have any non-singular matrices such as the natural state space forms of robotic manipulator, pendulum and suspension systems. A controller design is difficult for the systems due to rational LPV case. Therefore, the proposed gain scheduling controller is designed without the difficulty. Accordingly, the motion control design is implemented for two-link flexible joint robotic manipulator. Finally, the control system simulation is performed to prove the applicability and performance.

Download Full-text

Flight control law of unmanned aerial vehicles based on robust servo linear quadratic regulator and Kalman filtering

International Journal of Advanced Robotic Systems ◽

10.1177/1729881416686952 ◽

2017 ◽

Vol 14 (1) ◽

pp. 172988141668695 ◽

Cited By ~ 3

Author(s):

Yongfeng Zhi ◽

Gaoshang Li ◽

Qun Song ◽

Ke Yu ◽

Jun Zhang

Keyword(s):

Unmanned Aerial Vehicles ◽

Kalman Filtering ◽

Flight Control ◽

Pitch Angle ◽

Linear Quadratic Regulator ◽

Control Law ◽

Linear Quadratic ◽

Aerial Vehicles ◽

Simulation Results ◽

Influence Of Noise

A new flight control law for unmanned aerial vehicles based on robust servo linear quadratic regulator control and Kalman filtering is proposed. This flight control law has a simple structure with high dependability in engineering. The pitch angle controller, which is designed based on the robust servo linear quadratic regulator control, is given to show the flight control law. Simulation results show that the pitch angle controller works well under noise-free conditions. Finally, Kalman filtering is applied to the pitch angle controller under noisy conditions, and the simulation results show that the proposed method reduces the influence of noise.

Download Full-text

Simulation of a Steam Injected Gas Turbine Plant Control System

ASME 1997 Turbo Asia Conference ◽

10.1115/97-aa-129 ◽

1997 ◽

Author(s):

Shusheng Zang ◽

Jaqiang Pan

Keyword(s):

Gas Turbine ◽

Flow Rate ◽

Controller Design ◽

Dynamic Performance ◽

Linear Quadratic Regulator ◽

Linear Quadratic ◽

Turbine Plant ◽

Fuel Flow ◽

Lqr Controller ◽

Gas Turbine Plant

The design of a modern Linear Quadratic Regulator (LQR) is described for a test steam injected gas turbine (STIG) unit. The LQR controller is obtained by using the fuel flow rate and the injected steam flow rate as the output parameters. To meet the goal of the shaft speed control, a classical Proportional Differential (PD) controller is compared to the LQR controller design. The control performance of the dynamic response of the STIG plant in the case of rejection of load is evaluated. The results of the computer simulation show a remarkable improvement on the dynamic performance of the STIG unit.

Download Full-text

Design and flight-stability analysis of a closed fixed-wing unmanned aerial vehicle formation controller

Proceedings of the Institution of Mechanical Engineers Part I Journal of Systems and Control Engineering ◽

10.1177/0959651818821448 ◽

2018 ◽

Vol 233 (8) ◽

pp. 1045-1054 ◽

Cited By ~ 2

Author(s):

Jialong Zhang ◽

Bing Xiao ◽

Maolong Lv ◽

Qiang Zhang

Keyword(s):

Unmanned Aerial Vehicles ◽

Collision Avoidance ◽

High Speed ◽

Physical Simulation ◽

Controller Design ◽

Formation Flight ◽

External Factors ◽

Flight Stability ◽

Aerial Vehicles ◽

Closed Formation

This article addresses a flight-stability problem for the multiple unmanned aerial vehicles cooperative formation flight in the process of the closed and high-speed flight. The main objective is to design a cooperative formation controller with known external factors, and this controller can keep the consensus of attitude and position and reduce the communication delay between any two unmanned aerial vehicles and increase unmanned aerial vehicles formation cruise time under the known external factors. Known external factors are taken into consideration, and longitude maneuvers using nonlinear thrust vectors were employed with unsteady aerodynamic models, according to the attitude and position of unmanned aerial vehicles, which were employed as corresponding input signals for studying the dynamic characteristics of unmanned aerial vehicles formation flight. In addition, the relative distance between any two unmanned aerial vehicles was not allowed to exceed their safe distance so that the controller could perform collision avoidance. An analysis of formation flight distance error shows that it converged to a fixed value that well ensured unmanned aerial vehicles formation flight stability. The experimental results show that the controller can improve the speed of a closed formation effectively and maintain the stability of formation flight, which provides a method for closed formation flight controller design and collision avoidance for any two unmanned aerial vehicles. Meanwhile, the effectiveness of proposed controller is fully proved by semi-physical simulation platform.

Download Full-text

Cross Regulation Reduced Optimal Multivariable Controller Design for Single Inductor DC-DC Converters

Energies ◽

10.3390/en12030477 ◽

2019 ◽

Vol 12 (3) ◽

pp. 477 ◽

Cited By ~ 1

Author(s):

S. Augusti Lindiya ◽

N. Subashini ◽

K. Vijayarekha

Keyword(s):

Pid Controller ◽

Controller Design ◽

Multiple Input Multiple Output ◽

Linear Quadratic Regulator ◽

Prototype Model ◽

Linear Quadratic ◽

Load Current ◽

Practical Applications ◽

Input Multiple Output ◽

Single Input

Single Inductor (SI) converters with the advantage of using one inductor for any number of inputs/outputs find wide applications in portable electronic gadgets and electrical vehicles. SI converters can be used in Single Input Multiple Output (SIMO) and Multiple Input Multiple Output (MIMO) configurations but they need controllers to achieve good transient and steady state responses, to improve the stability against load and line disturbances and to reduce cross regulation. Cross regulation is the change in an output voltage due to change in the load current at another output and it is an added constraint in SI converters. In this paper, Single Input Dual Output (SIDO) and Dual Input Dual Output (DIDO) converters with applications capable of handling high load current working in Continuous Conduction Mode (CCM) of operation are taken under study. Conventional multivariable PID and optimal Linear Quadratic Regulator (LQR) controllers are developed and their performances are compared for the above configurations to meet the desired objectives. Generalized mathematical models for SIMO and MIMO are developed and a Genetic Algorithm (GA) is used to find the parameters of a multivariable PID controller and the weighting matrices of optimal LQR where the objective function includes cross regulation as a constraint. The simulated responses reveal that LQR controller performs well for both the systems over multivariable PID controller and they are validated by hardware prototype model with the help of DT9834® Data Acquisition Module (DAQ). The methodologies used here generate a fresh dimension for the case of such converters in practical applications.

Download Full-text

Backstepping Controller Design for a 5 DOF Spherical Inverted Pendulum

International Journal of Engineering Research in Africa ◽

10.4028/www.scientific.net/jera.41.37 ◽

2019 ◽

Vol 41 ◽

pp. 37-50 ◽

Cited By ~ 2

Author(s):

Soukaina Krafes ◽

Zakaria Chalh ◽

Abdelmjid Saka

Keyword(s):

Degrees Of Freedom ◽

Inverted Pendulum ◽

Controller Design ◽

Linear Quadratic Regulator ◽

Performance Comparison ◽

Virtual Reality Environment ◽

Linear Quadratic ◽

Control Scheme ◽

Linearized System ◽

Backstepping Controller

This paper presents a Backstepping controller for five degrees of freedom Spherical Inverted Pendulum. Since the system is nonlinear, unstable, underactuated and MIMO and has a nonsquare form, the classic control design cannot be applied to control it. In order to remedy this problem, we propose in this paper a new method based on hierarchical steps of the Backstepping controller taking into a count the nonlinearities that cannot be neglected. Furthermore, a Linear Quadratic Regulator controller and LQR + PID based on the linearized system model are also designed for performance comparison. Finally, a simulation study is carried out to prove the effectiveness of proposed control scheme and is validated using the virtual reality environment that proves the performance of the Backstepping controller over the linear ones where it brings the pendulum from any initial condition in the upper hemisphere while the base is brought to the origin of the coordinates.

Download Full-text

Novel Method on Using Evolutionary Algorithms for PD Optimal Tuning

Applied Mechanics and Materials ◽

10.4028/www.scientific.net/amm.110-116.4977 ◽

2011 ◽

Vol 110-116 ◽

pp. 4977-4984 ◽

Cited By ~ 3

Author(s):

R.A. Khoshrooz ◽

M.A.D. Vahid ◽

M. Mirshams ◽

M.R. Homaeinezhad ◽

A.H. Ahadi

Keyword(s):

Attitude Control ◽

Controller Design ◽

Linear Quadratic Regulator ◽

Initial Guess ◽

Pd Controller ◽

Linear Quadratic ◽

Optimal Tuning ◽

Heavy Burden ◽

Novel Method

This paper presents a method to solve the Evolutionary Algorithm (EA) problems for optimal tuning of the Proportional-Deferential (PD) controller parameters. The major efficiency of the proposed method is the Genetic Algorithm (GA) stuck avoidance as well an appropriate estimation for GA lower and upper bounds. Also by this method for the Particle Swarm Optimization (PSO) methodology the initial choice of the controller parameters can be fulfilled to achieve the acceptable performance accuracies. For both GA and PSO methods, the Linear Quadratic Regulator (LQR) obtained trend is used as the reference for the determination of the aforementioned bounds and initial guess. The presented algorithm was applied to regulate a PD controller for the attitude control of a virtual satellite and also with Hardware-in-the-loop (HIL) reaction wheels. Heavy burden trying and error was eliminated from the PD controller design which can be mentioned as the important merit of the presented study.

Download Full-text

Flight Control System Design for Propulsion-Controlled Aircraft

Proceedings of the Institution of Mechanical Engineers Part G Journal of Aerospace Engineering ◽

10.1243/095441005x30289 ◽

2005 ◽

Vol 219 (4) ◽

pp. 329-340 ◽

Cited By ~ 3

Author(s):

Y Ochi

Keyword(s):

Flight Control ◽

Linear Models ◽

Control Method ◽

Linear Quadratic Regulator ◽

State Feedback Control ◽

Longitudinal Motion ◽

Linear Quadratic ◽

Engine Thrust ◽

Model Following Control ◽

Flight Controls

The loss of an aircraft's primary flight controls can lead to a fatal accident. However, if the engine thrust is available, controllability and safety can be retained. This article describes flight control using engine thrust only when an aircraft has lost all primary flight controls. This is a kind of flight control reconfiguration. For safe return, the aircraft must first descend to a landing area, decelerate to a landing speed, and then be capable of precise flight control for approach and landing. For these purposes, two kinds of controllers are required: a controller for descent and deceleration and a controller for approach and landing. The former controller is designed for longitudinal motion using a model-following control method, based on a linear quadratic regulator. The latter is designed by an H∞ state-feedback control method for both longitudinal and lateral-directional motions. Computer simulation is conducted using linear models of the Boeing 747. The results indicate that flight path control, including approach and landing, is possible using thrust only; however, speed control proves more difficult. However, if the horizontal stabilizer is available, the airspeed can be reduced to a safe landing speed.

Download Full-text

Actuator Placement for Active Surge Control in a Multi-Stage Axial Compressor

Volume 1: Turbomachinery ◽

10.1115/96-gt-241 ◽

1996 ◽

Cited By ~ 1

Author(s):

M. Montazeri-Gh. ◽

D. J. Allerton ◽

R. L. Elder

Keyword(s):

Cost Function ◽

Mass Flow ◽

Controller Design ◽

Axial Compressor ◽

Minimum Cost ◽

Linear Quadratic Regulator ◽

Algebraic Riccati Equation ◽

Linear Quadratic ◽

Non Linear ◽

Actuator Placement

This paper describes an actuator placement methodology for the active control of purely one-dimensional instabilities of a seven-stage axial compressor using an air bleeding strategy. In this theoretical study, using stage-by-stage non-linear modelling based on the conservation equations of mass, momentum, and energy, a scheduling LQR (Linear Quadratic Regulator) controller is designed for several actuator locations in a compressor from the first stage to the plenum. In this controller design, the LQR weighting matrices are selected so that the associated cost function includes only air bleeding mass flow leading to the minimisation of the air bleed. The LQR cost function represents a measure of the consumption of air bleeding and can be calculated analytically using the solution of an Algebraic Riccati Equation. From analysis of the cost at different compressor stages, the location of an air bleeding actuator is selected at the stage with the minimum cost. Finally, using an ACSL simulation program, the scheduling controller has been integrated with a non-linear. stage-by-stage model and the time response of the air bleeding mass flow at different locations has been obtained to confirm the results from the analytical approach. Results are presented to show actively stabilised compressor flow beyond the surge point where the air bleed is minimised. These results also indicate the preferred location of the actuator at the compressor downstream stages for both low and high compressor speeds.

Download Full-text