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Online system identification for fault tolerant control of unmanned aerial vehicles

Thesis (MScEng)--Stellenbosch University, 2013. / ENGLISH ABSTRACT: In this thesis the strategy for performing System Identification on an aircraft is presented. The
ultimate aim of this document is to outline the steps required for successful aircraft parameter
estimation within a Fault Tolerant Control Framework.
A brief derivation of the classical 6 degree-of-freedom aircraft model is firstly presented. The
derivation gives insight into the aircraft dynamics that are to be used to estimate the aircraft
parameters, and provides a basis for the methods provided in this thesis.
Different techniques of System Identification were evaluated, resulting in the choice of the
Regression method to be used. This method, based on the Least-Squares method, is chosen
because of its simplicity of use and because it does not require as much computational time as
the other methods presented. Regression methods, including a recursive algorithm, are then
applied to aircraft parameter estimation and practical considerations such as Identifiability and
corrupted measurements are highlighted.
The determination of unknown measurements required for System Identification of aircraft
parameters is then discussed. Methods for both estimating and measuring the Angle-of-Attack
(AoA) and angular accelerations are presented. The design and calibration of an AoA probe
for AoA measurements, as well as a novel method that uses distributed sensors to determine
the angular accelerations is also presented.
The techniques presented in this thesis are then tested on a non-linear aircraft model. Through
simulation it was shown that for the given sensor setup, the methods do not provide
sufficiently accurate parameter estimates. When using the Regression method, obtaining
measurements of the angle-of-attack solely through estimation causes problems in the
estimation of the aerodynamic lift coefficients.
Flight tests were performed and the data was analyzed. Similar issues as experienced with
estimation done on the non-linear aircraft simulation, was found. Recommendations with
regards to how to conduct future flight tests for system identification is proposed and possible sources of errors are highlighted. / AFRIKAANSE OPSOMMING: In hierdie tesis word die strategie vir die uitvoering van Stelsel Identifikasie op 'n vliegtuig
aangebied. Die uiteindelike doel van hierdie document is om die stappe wat nodig is vir 'n
suksesvolle vliegtuig parameter beraming, binne 'n Fout Tolerante Beheer Raamwerk, uit
eente sit.
'n Kort afleiding van die klassieke 6 graad-van-vryheid vliegtuig model word eerstens
aangebied. Die afleiding gee insig in die vliegtuig dinamika wat gebruik moet word om die
vliegtuig parameters te beraam, en bied 'n basis vir die metodes wat in hierdie tesis verskyn.
Verskillende tegnieke van Stelsel Identifikasie is geëvalueer, wat lei tot gebruik van die
regressie-metode. Hierdie metode is gekies as gevolg van sy eenvoudigheid en omdat dit nie
soveel berekening tyd as die ander metodes vereis nie. Regressie metodes, insluitend 'n
rekursiewe algoritme, word dan toegepas op vliegtuig parameter beraming en praktiese
orwegings soos identifiseerbaarheid en korrupte metings word uitgelig.
Die bepaling van onbekende afmetings wat benodig is, word vir Stelsel Identifisering van die
vliegtuig parameters bespreek. Metodes om die invalshoek en hoekige versnellings te meet en
beraam, word aangebied. Die ontwerp en kalibrasie van 'n invalshoek sensor vir invalshoek
metings, sowel as 'n nuwe metode wat gebruik maak van verspreide sensore om die
hoekversnellings te bepaal, word ook aangebied.
Die tegnieke wat in hierdie tesis aangebied is, word dan op 'n nie-lineêre vliegtuig model
getoets. Deur simulasie is dit getoon dat die metodes vir die gegewe sensor opstelling nie
voldoende akkurate parameters beraam nie. Dit is ook bewys dat met die gebruik van die
Regressie metode, die vekryging van metings van die invalshoek slegs deur skatting,
probleme in die beraming van die aerodinamiese lug koëffisiente veroorsaak.
Die tegnieke wat in hierdie tesis verskyn, word dan op werklike vlug data toegepas.Vlugtoetse
is uitgevoer en die data is ontleed. Aanbeveling met betrekking tot hoe om toekomstige vlug
toetse vir Stelsel Identifikasiete word voorgestel, en moontlike bronne van foute word uitgelig.

Identiferoai:union.ndltd.org:netd.ac.za/oai:union.ndltd.org:sun/oai:scholar.sun.ac.za:10019.1/80125
Date03 1900
CreatorsAppel, Jean-Paul
ContributorsPeddle, I. K., Stellenbosch University. Faculty of Engineering. Dept. of Electrical and Electronic Engineering.
PublisherStellenbosch : Stellenbosch University
Source SetsSouth African National ETD Portal
Languageen_ZA
Detected LanguageUnknown
TypeThesis
Format163 p. : ill.
RightsStellenbosch University

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