ENGINE FAILURE COMPENSATION USING CONTROL ALLOCATION FOR AIRCRAFT WITH DISTRIBUTED ELECTRIC PROPULSION
The current development in electric aircraft to achieve a greener and cleaner aviation sector has opened many technology advancements. One of the attractive technology is the Distributed Electric Propulsion (DEP) which distributes many motor arrays on the wing leading edge. One of the major issue...
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| Format: | Final Project |
| Language: | Indonesia |
| Online Access: | https://digilib.itb.ac.id/gdl/view/69006 |
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| Institution: | Institut Teknologi Bandung |
| Language: | Indonesia |
| Summary: | The current development in electric aircraft to achieve a greener and
cleaner aviation sector has opened many technology advancements. One of
the attractive technology is the Distributed Electric Propulsion (DEP) which
distributes many motor arrays on the wing leading edge. One of the major issue
encountered by multi engine aircraft is engine failure case. With this challenge,
for aircraft with DEP, compensating and re-distributing the thrust command
accordingly and simultaneously, so the yawing moment is in balance to fly
symmetrically, become a concern. Such that not only the aircraft can fly in
symmetric fashion, but the automatic controller for speed and altitude can also
be operated normally. The goals of this undergraduate thesis are to distribute
thrust command on the DEP aircraft and evaluate the controller performance,
especially when an engine failure(s) exists in a numerical longitudinal flight
simulation. The proposed method for thrust command management is using
the control allocation method based on linear programming (LP) and quadratic
programming (QP). To perform speed and altitude tracking, a speed hold
controller and altitude hold controller are developed using a PID controller.
The numerical flight simulation is built based on ATR72-200 longitudinal model
using Simulink. The thrust management and engine failure compensation are
successfully conducted using LP and QP-based control allocation. Both LP and
QP can achieve the scenarios’ goal and compensate the engine failure effectively
based on the numerical simulation results while maintaining zero engine yawing
moment. The QP-based CA tends to use more balanced effectors, which may
be desirable for DEP aircraft. LP tends to use minimal actuators to the fullest
first (one by one). When engine failure(s) exists, some tracking performance
is degraded due to lower attainable thrust, contributed by failed engine and
control allocation limiting action to maintain zero engine yawing moment. |
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