Machine-learning-based measurement, modeling, and control of spatial variability in advanced manufacturing
Yang, Yuhang
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https://hdl.handle.net/2142/115503
Description
Title
Machine-learning-based measurement, modeling, and control of spatial variability in advanced manufacturing
Author(s)
Yang, Yuhang
Issue Date
2022-02-08
Director of Research (if dissertation) or Advisor (if thesis)
Shao, Chenhui
Doctoral Committee Chair(s)
Shao, Chenhui
Committee Member(s)
Ferreira, Placid M
King, William P
Wang, Pingfeng
Department of Study
Mechanical Sci & Engineering
Discipline
Mechanical Engineering
Degree Granting Institution
University of Illinois at Urbana-Champaign
Degree Name
Ph.D.
Degree Level
Dissertation
Keyword(s)
Machine learning
Spatial process
Spatiotemporal process
Gaussian process
Surface measurement
Sampling design
Measurement strategy
Big data analytics
Data fusion
Smart manufacturing
Advanced manufacturing
Additive manufacturing
Quality control
Hierarchical modeling
Data-efficient learning
Intelligent metrology
Abstract
Spatial and spatiotemporal variabilities commonly exist in many advanced manufacturing processes and systems. High-performance characterization, modeling, and control of such variabilities are crucial for enabling next-generation smart decision-making in quality inspection, process control, machine health monitoring and prognostics, etc. However, fundamental challenges exist in these decision-making tasks. Although the recent development in measurement technologies has made it possible to acquire spatial and spatiotemporal data at different scales, it is generally expensive and time-consuming to use such technologies in real-world production settings. Additionally, there is a lack of effective and data-efficient methods for analyzing high-dimensional, heterogeneous spatial and spatiotemporal data in manufacturing. This dissertation presents novel machine-learning-based approaches for the measurement, modeling, and control of spatial and spatiotemporal variabilities. The effectiveness of these approaches is demonstrated using real-world data collected from different manufacturing processes and systems at different length scales including ultrasonic metal welding, additive manufacturing, and two-photon lithography.
A hierarchical measurement strategy is developed to cost-effectively acquire spatiotemporal data by optimally allocating the measurement efforts in both spatial and temporal domains. Determining the observation times and measurement locations is formulated as a two-level decision-making problem. To expedite the solution search process, hierarchical genetic algorithm is adopted and implemented using high-performance computing.
A hybrid multi-task-learning approach is created for accurate and cost-effective response surface modeling. This approach recognizes the differences and similarities between multiple manufacturing processes and accordingly constructs physics-informed self-learning and multi-task-learning models. Data efficiency and learning performance are thus improved through the transfer of information across processes.
A hybrid hierarchical modeling method is developed to data-efficiently predict the feature-level geometric accuracy of parts produced by multiple identical additive manufacturing machines. The modeling method decomposes the geometric variability into a large-scale part-level trend and a small-scale feature-level term, which are characterized by a hierarchical Bayesian linear model and a Gaussian process model, respectively.
A geometric compliance improvement framework for two-photon lithography is established to quantify the spatial variation in the geometric accuracy of 3D structures and generate compensation designs to improve geometric compliance. It is revealed for the first time that both systematic and random geometric errors exist in 3D structures fabricated by two-photon lithography.
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