System Reliability-Based Design and Multiresolution Topology Optimization

Nguyen, Tam H.

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https://hdl.handle.net/2142/18408 Copy

Description

Title

System Reliability-Based Design and Multiresolution Topology Optimization

Author(s)

Nguyen, Tam H.

Issue Date

2011-01-14T22:49:32Z

Director of Research (if dissertation) or Advisor (if thesis)

• Paulino, Glaucio H.
• Song, Junho

Doctoral Committee Chair(s)

Paulino, Glaucio H.

Committee Member(s)

• Song, Junho
• Hajjar, Jerome F.
• Duarte, C. Armando
• Penmetsa, Ravi C.
• Sutradhar, Alok
• Baker, William F.
• Beghini, Alessandro

Department of Study

Civil & Environmental Eng

Discipline

Civil Engineering

Degree Granting Institution

University of Illinois at Urbana-Champaign

Degree Name

Ph.D.

Degree Level

Dissertation

Date of Ingest

2011-01-14T22:49:32Z

Keyword(s)

• topology optimization
• design optimization
• multiresolution
• high resolution
• reliability
• finite element method
• multiresolution topology optimization (MTOP)
• reliability-based design optimization (RBDO)
• reliability-based topology optimization (RBTO)
• first-order reliability method (FORM)
• second-order reliability method (SORM)
• component reliability-based topology optimization (CRBTO)
• component reliability-based design optimization (CRBDO)
• system reliability-based topology optimization (SRBTO)
• system reliability-based design optimization (SRBDO)
• reliability index approach (RIA)
• performance measure approach (PMA)
• Adaptive Mesh Refinement (AMR)
• matrix-based system reliability (MSR)
• reliability index approach
• performance measure approach
• component probability
• system probability
• single-loop
• double-loop
• first-order reliability method
• second-order reliability method
• density method
• projection
• density filter
• reliability-based design optimization
• reliability-based topology optimization
• reliability index
• optimal design
• topology
• risk
• computational cost
• uncertainty
• design variable
• density element
• displacement element
• Adaptive
• efficient approach
• large-scale
• matrix-based

Abstract

Structural optimization methods have been developed and applied to a variety of engineering practices. This study aims to overcome technical challenges in applying design and topology optimization techniques to large-scale structural systems with uncertainties. The specific goals of this dissertation are: (1) to develop an efficient scheme for topology optimization; (2) to introduce an efficient and accurate system reliability-based design optimization (SRBDO) procedure; and (3) to investigate the reliability-based topology optimization (RBTO) problem. First, it is noted that the material distribution method often requires a large number of design variables, especially in three-dimensional applications, which makes topology optimization computationally expensive. A multiresolution topology optimization (MTOP) scheme is thus developed to obtain high-resolution optimal topologies with relatively low computational cost by introducing distinct resolution levels to displacement, density and design variable fields: the finite element analysis is performed on a relatively coarse mesh; the optimization is performed on a moderately fine mesh for design variables; and the density is defined on a relatively fine mesh for material distribution. Second, it is challenging to deal with system events in reliability-based design optimization (RBDO) due to the complexity of system reliability analysis. A new single-loop system RBDO approach is developed by using the matrix-based system reliability (MSR) method. The SRBDO/MSR approach utilizes matrix calculations to evaluate the system failure probability and its parameter sensitivities accurately and efficiently. The approach is applicable to general system events consisting of statistically dependent component events. Third, existing RBDO approaches employing first-order reliability method (FORM) can induce significant error for highly nonlinear problems. To enhance the accuracy of component and system RBDO approaches, algorithms based on the second-order reliability method (SORM), termed as SORM-based RBDO, are proposed. These technical advances enable us to perform RBTO of large-scale structures efficiently. The proposed algorithms and approaches are tested and demonstrated by various numerical examples. The efficient and accurate approaches developed for design and topology optimization can be applied to large-scale problems in engineering design practices.

Graduation Semester

2010-12

Permalink

http://hdl.handle.net/2142/18408

Copyright and License Information

Copyright 2010 Tam Hong Nguyen

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