Xixiang Jia

Topic

Lightweight Deep Learning Model for Nondestructive Evaluation of Crack Defects

Department of Electrical and Computer Engineering

Date & location

• Wednesday, August 21, 2024

• 12:00 P.M.

• Virtual Defence

Reviewers

Supervisory Committee

• Dr. Daler Rakhmatov, Department of Electrical and Computer Engineering, University of Victoria (Supervisor)

• Dr. Stephen Neville, Department of Electrical and Computer Engineering, UVic (Member) 

External Examiner

• Dr. Alex Thomo, Department of Computer Science, UVic 

Chair of Oral Examination

• Dr. Farouk Nathoo, Department of Mathematics and Statistics, UVic 

Abstract

Ultrasonic nondestructive evaluation (NDE) is an essential tool in various industries, including aerospace, energy, and civil engineering, for assessing the structural integrity of manufactured products without damaging them. This thesis is focused on the automated analysis of ultrasonic NDE data by means of low-cost machine learning (ML) techniques, particularly in the context of inline pipeline inspection. We propose two lightweight neural network architectures for efficient multi-attribute classification to characterize surface-breaking crack defects in terms of their location, size, and tilt. Our networks have under 2M parameters and incorporate novel design elements inspired by the latest MobileNet models. Their computational footprint is also small, not exceeding 100M floating-point operations (FLOPs) per data sample. The proposed models process raw channel data acquired by a transducer array, as opposed to multi-view beamformed image patches utilized in related works, thus eliminating the computational burden associated with image reconstruction.

Our evaluation results, based on a public-domain NDE dataset, demonstrate that our networks offer a balanced combination of their competitively high classification performance and low cost. These findings highlight the potential of lightweight deep learning models in ultrasonic NDE data analysis, which contributes to the development of more advanced and intelligent inspection systems. Our future research will focus on refining the proposed models to enhance their spatio-temporal feature learning, interpretability, generalization capability, and applicability to other fields, such as biomedical imaging and computer vision.