عنوان
پدید آورنده
موضوع
رده
کتابخانه
محل استقرار
NATIONAL BIBLIOGRAPHY NUMBER
Number
TLpq2519810843
LANGUAGE OF THE ITEM
.Language of Text, Soundtrack etc
انگلیسی
TITLE AND STATEMENT OF RESPONSIBILITY
Title Proper
A Dynamic Mode Decomposition Based Deep Learning Technique for Prognostics
General Material Designation
[Thesis]
First Statement of Responsibility
Akkad, Khaled Mohammad A.
Subsequent Statement of Responsibility
He, David
.PUBLICATION, DISTRIBUTION, ETC
Name of Publisher, Distributor, etc.
University of Illinois at Chicago
Date of Publication, Distribution, etc.
2020
PHYSICAL DESCRIPTION
Specific Material Designation and Extent of Item
116
DISSERTATION (THESIS) NOTE
Dissertation or thesis details and type of degree
Ph.D.
Body granting the degree
University of Illinois at Chicago
Text preceding or following the note
2020
SUMMARY OR ABSTRACT
Text of Note
Remaining useful life is one of the key indicators for mechanical equipment health and condition-based maintenance requirements. The field of prognostics and health management heavily relies on remaining useful life estimation. Due to the magnitude of monetary costs associated with failure of mechanical equipment, remaining useful life prediction has become one of the pillars of the prognostics and health management field. The availability of industrial big data enabled remarkable research efforts in prognostics. Much of this effort is directed at the development and improvement of deep learning based prognostic techniques by means of creating hybrid models, hyperparameter optimization, and other approaches. This dissertation aims to improve the remaining useful estimation capabilities of deep learning prognostic techniques by integrating a physics based approach into deep learning schemes. This physics based approach is the Koopman operator which produces infinitely linear representations of nonlinear systems with known equations. These infinite representations need to be approximated via a data driven approach for the purposes of obtaining health indicators useful for predicting the remaining useful of industrial machines and equipment. Dynamic mode decomposition is a data driven approach for approximating the modes of the Koopman operator. In this dissertation, dynamic mode decomposition is incorporated into a variety of deep learning prognostic schemes to enhance the performance of the remaining useful estimation. Two industrial applications are utilized to validate the proposed approach. The first application is the NASA spiral bevel gear vibration data. The second application is the NASA commercial modular aero-propulsion system simulated vibration data of turbofan engines. The proposed approach demonstrates an increase in accuracy of remaining useful estimation in both applications and across all datasets therein when the dynamic mode decomposition is in incorporated into the deep learning prognostic schemes.
TOPICAL NAME USED AS SUBJECT
Industrial engineering
PERSONAL NAME - PRIMARY RESPONSIBILITY
Akkad, Khaled Mohammad A.
He, David
ELECTRONIC LOCATION AND ACCESS
Electronic name
مطالعه متن کتاب p
[Thesis]
276903
a
Y
