LATERAL FLIGHT CONTROL
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Transcript of LATERAL FLIGHT CONTROL
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M O U L O U D B O U R A S
P H I L I P P E S E J E A N
R A G H A V E N D R A P E N D Y A L A
LATERAL FLIGHT CONTROLMECH 6091
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Project overview
Introduction
Equations of Motion
Non-Linear and Linear Modeling
Autopilot design and Simulink Demonstration
Results and Discussion
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Introduction
Objective:
Design a control system for an existing aircraft for lateral
motion. Matlab/Simulink software is used to implement design and test for the designed autopilot control system.
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Introduction
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Introduction
STOL transport data was used from R.Nelson Flight Stability and Automatic Control textbook to test the control system.
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Assumptions
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Equations of Motion
Equations of motion are found applying Newton’s second law:
The forces considered for lateral motion are:
Fa: Aerodynamic forces acting on the vertical tail.
T : Thrust pushes forward along the length of the aircraft
D : Drag pulls back along the length of the aircraft
W : Weight
The Moments considered for lateral motion are:
Rolling moment L about the C.G.
Yawing moment N about the C.G.
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Equations of Motion
Dynamic equations:
Kinematic equations:
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Nonlinear Model
The above Equations are derived from the dynamic and kinematic equations based
On the following assumptions:
Angle of attack (α) is small and constant.
Pitch angle (θ) and the rate of the change of pitch angle (Q) are zeros.
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Linear Model
For the linearization the Jacobian matrix is used and the states and inputs control of the model is specified as:
However the controller should keep the constant the velocity, the thrust is not included as input control since it is assumed enough to get constant velocity and all initial conditions are zeros.
State space representation of the linear model as this form
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Linear Model
A and B are Jacobian Matrices
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Linear Model
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LQR Controller
Linear-quadratic Regular LQR controller was used for the lateral control system.
Linear quadratic Regulator Controller is the best controller signal to bring the system from an initial state to the steady state . As we know the choosing of weighting matrix (Q and R) are very important and to minimize the cost function according to this function:
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Simulink Model
The block contains the nonlinear aircraft dynamics
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Simulink Model
Subsystem produces the Moments N,L
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Simulink Model
NonLinear simulink model of the Autopilot system
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Simulink Model
Linear simulink model of the Autopilot system
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Time Response: linear vs nonlinear
Linearized model time reponse for y0=10
Non-Linear model time reponse for y0=10
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Linear System Results
For y0=1 and δa=0.005
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Non-Linear System Results
For y0=1 and δa=0.005
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linear vs nonlinear control
0 500 1000 1500 2000 25000
2
4
6
8
10
12
x-position
y-p
ositio
n
nonlinear model
linear model
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Conclusion
The general equations of motion were developed for the lateral motion of an aircraft.
The equations were linearized.
Simulink models were built for both linear and non-linear models of the autopilot control system.
Comparing the response of the reference input y for both linear and non-linear has shown that the controller works well for both systems.
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REFERENCES
[1] Youmin. Zhang, Lecture Notes on Flight Control system, Concordia University, 2010.
[2]B.L. Stevens, F.L. Lewis. Aircraft Control and Simulation, 2nd
edition
[3] R. Nelson. Flight Stability and Automatic Control, 2nd edition
[4] http://en.wikipedia.org/wiki/Stability_derivatives.
[5] http://en.wikipedia.org/wiki/Linear-quadratic_regulator