dc.description.abstract |
A successful Guidance, Navigation, and Control (GNC) system for ballistics
defence system is critical to a target tracking scenario's success. This thesis applies a
GNC system and compares it to state-of-the-art systems that are extensively used
today. The work contains an autopilot, guiding law, target tracking law, and a
dependable inertial navigation system capable of precisely operating an agile vehicle
such as a UAV, missile, or other vehicle utilizing available sensor data. The GNC
system is simulated using a non-linear generic missile model in a
MATLAB/Simulink environment.
The control system is the first component of the GNC system to be examined.
Two types of autopilots are contemplated: The commonly used three-loop autopilot
is the initial design. The autopilot determines the ideal missile fin deflections to
travel towards a target based on the guidance system's intended acceleration
directives. The second configuration utilizes two decoupled autopilots for lateral and
longitudinal control, with course and flight-path-angle serving as reference
commands. Fin deflections are generated to achieve the required missile orientation
using a Linear-Quadratic Regulator (LQR) based on the linearized generic missile
model. By incorporating extra input from sideslip and angle-of-attack derivatives,
performance and resilience features are increased.
The navigation system is the second component of the GNC system to be
explored. Without trustworthy sensors and filters, other control loop subsystems will
lose track of the vehicle's Position, Velocity, and Attitude (PVA). To achieve vehicle
state convergence, a Multiplicative Extended Kalman Filter (MEKF) supported by
Global Navigation Satellite Systems (GNSS) and gyro and acceleration biases is
generated. The MEKF is distinguished from the regular Extended Kalman Filter
(EKF) by the fact that it updates the Inertial Navigation System (INS) attitude
calculations through quaternion multiplication, resulting in the inclusion of the
vi
multiplicative property. When calculating guiding instructions in a target-tracking
situation, it is critical to have information about the target's location, velocity, and, in
certain circumstances, acceleration. Along with the INS-provided estimated missile
states, a target-tracking Kalman Filter (KF) is used to monitor the relative states of
the target and missile.
Finally, two guideline laws are compared to finalize the GNC design. The well known Proportional Navigation (PN) rule is compared to a Line-Of-Sight (LOS)
system with a course and flightpath-angle controlled autopilot. By assuming
independent control of the horizontal and vertical planes, LOS guidance aims to steer
the missile toward a vector connecting the launch platform and the predicted point of
interception between the missile and target.
Simulink simulations of the GNC system provide encouraging results in both
reference tracking for the autopilot and state estimation utilizing both KF designs.
Figure 1 Organization of thesis, including the primary content Guidance, Navigation
and Control (GNC |
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