Your search keyword '"Yun-Lai Zhou"' showing total 6 results

1. Mono-Component Feature Extraction for Condition Assessment in Civil Structures Using Empirical Wavelet Transform

Author

Yun-Xia Xia and Yun-Lai Zhou

Subjects

signal processing, empirical wavelet transform, structural health monitoring, feature extraction, civil structures, Chemical technology, TP1-1185

Abstract

This paper proposes a methodology to process and interpret the complex signals acquired from the health monitoring of civil structures via scale-space empirical wavelet transform (EWT). The FREEVIB method, a widely used instantaneous modal parameters identification method, determines the structural characteristics from the individual components separated by EWT first. The scale-space EWT turns the detecting of the frequency boundaries into the scale-space representation of the Fourier spectrum. As well, to find meaningful modes becomes a clustering problem on the length of minima scale-space curves. The Otsu’s algorithm is employed to determine the threshold for the clustering analysis. To retain the time-varying features, the EWT-extracted mono-components are analyzed by the FREEVIB method to obtain the instantaneous modal parameters and the linearity characteristics of the structures. Both simulated and real SHM signals from civil structures are used to validate the effectiveness of the present method. The results demonstrate that the proposed methodology is capable of separating the signal components, even those closely spaced ones in frequency domain, with high accuracy, and extracting the structural features reliably.

Published

2019

2. Vibration Mitigation Effect Investigation of a New Slab Track Plate Design

Author

Linya Liu, Xuan Wang, Yun-Lai Zhou, and Jialiang Qin

Subjects

slab track plate, urban rail transit, optimal design, vibration mitigation, modal testing, Chemical technology, TP1-1185

Abstract

This study proposed a novel vibration mitigation slab track plate design to mitigate the vibration induced in urban rail transit operations. The optimal recipe for the newly designed slab track plate is obtained by a series of laboratory tests, and both newly designed vibration mitigation slab track plates and normal slab track plates are fabricated and hereinafter tested. The newly designed slab track plate was examined with a series of laboratory tests in comparison with the normal slab track plate. The PolyMAX method is then adopted for extracting the modal properties, including resonant frequencies, and damping ratios are also determined for both the designed slab and normal slab track plates. A vibration mitigation level (Ls) is defined to address the vibration mitigation performance taking the acceleration response of the normal slab track plate as reference. The newly designed slab track plate demonstrated better dynamic and damping characteristics in comparison with the normal slab track plate. Under the same excitation force, the newly designed slab track plate can mitigate 8.9 dB on average in the frequency range [20, 400] Hz, expressing the feasibility of effective vibration mitigation capacity.

Published

2019

3. Degradation of the In-plane Shear Modulus of Structural BFRP Laminates Due to High Temperature

Author

Yu-Jia Hu, Cheng Jiang, Wei Liu, Qian-Qian Yu, and Yun-Lai Zhou

Subjects

basalt fiber reinforced polymer (BFRP), digital image correlation (DIC) sensor, in-plane shear modulus, high-temperature test, thermal behavior, Chemical technology, TP1-1185

Abstract

The behavior of fiber reinforced polymer (FRP) composites at high temperature is a critical issue that needs to be clearly understood for their structural uses in civil engineering. However, due to technical difficulties during testing at high temperature, limited experimental investigations have been conducted regarding the thermal behavior of basalt fiber reinforced polymer (BFRP) composites, especially for the in-plane shear modulus of BFRP laminates. To this end, both an analytical derivation and an experimental program were carried out in this work to study the in-plane shear modulus of BFRP laminates. After the analytical derivation, the in-plane shear modulus was investigated as a function of the elastic modulus in different directions (0°, 45° and 90° of the load-to-fiber angle) and Poisson’s ratio in the fiber direction. To obtain the in-plane shear modulus, the four parameters were tested at different temperatures from 20 to 250 °C. A novel non-contacting digital image correlation (DIC) sensing system was adopted in the high-temperature tests to measure the local strain field on the FRP samples. Based on the test results, it was found that the elastic moduli in different directions were reduced to a very low level (less than 20%) from 20 to 250 °C. Furthermore, the in-plane shear modulus of BFRP at 250 °C was only 3% of that at 20 °C.

Published

2018

4. Dynamic Model Updating for Bridge Structures Using the Kriging Model and PSO Algorithm Ensemble with Higher Vibration Modes

Author

Shiqiang Qin, Yazhou Zhang, Yun-Lai Zhou, and Juntao Kang

Subjects

dynamic model updating, kriging model, particle swarm optimization, higher modes, bridge structure, Chemical technology, TP1-1185

Abstract

This study applied the kriging model and particle swarm optimization (PSO) algorithm for the dynamic model updating of bridge structures using the higher vibration modes under large-amplitude initial conditions. After addressing the higher mode identification theory using time-domain operational modal analysis, the kriging model is then established based on Latin hypercube sampling and regression analysis. The kriging model performs as a surrogate model for a complex finite element model in order to predict analytical responses. An objective function is established to express the relative difference between analytically predicted responses and experimentally measured ones, and the initial finite element (FE) model is hereinafter updated using the PSO algorithm. The Jalón viaduct—a concrete continuous railway bridge—is applied to verify the proposed approach. The results show that the kriging model can accurately predict the responses and reduce computational time as well.

Published

2018

5. Dynamic Model Updating for Bridge Structures Using the Kriging Model and PSO Algorithm Ensemble with Higher Vibration Modes

Author

Kang Juntao, Qin Shiqiang, Yun-Lai Zhou, and Zhang Yazhou

Subjects

Computer science, 0211 other engineering and technologies, 020101 civil engineering, 02 engineering and technology, lcsh:Chemical technology, Biochemistry, Article, 0201 civil engineering, Analytical Chemistry, Surrogate model, Normal mode, Kriging, 021105 building & construction, lcsh:TP1-1185, Electrical and Electronic Engineering, Instrumentation, particle swarm optimization, kriging model, Mode (statistics), Particle swarm optimization, Regression analysis, bridge structure, Atomic and Molecular Physics, and Optics, Finite element method, Operational Modal Analysis, Latin hypercube sampling, dynamic model updating, higher modes, Algorithm

Abstract

This study applied the kriging model and particle swarm optimization (PSO) algorithm for the dynamic model updating of bridge structures using the higher vibration modes under large-amplitude initial conditions. After addressing the higher mode identification theory using time-domain operational modal analysis, the kriging model is then established based on Latin hypercube sampling and regression analysis. The kriging model performs as a surrogate model for a complex finite element model in order to predict analytical responses. An objective function is established to express the relative difference between analytically predicted responses and experimentally measured ones, and the initial finite element (FE) model is hereinafter updated using the PSO algorithm. The Jal&oacute, n viaduct&mdash, a concrete continuous railway bridge&mdash, is applied to verify the proposed approach. The results show that the kriging model can accurately predict the responses and reduce computational time as well.

Published

2018

6. Output-Based Structural Damage Detection by Using Correlation Analysis Together with Transmissibility

Author

Hongyou Cao, Quanmin Liu, Magd Abdel Wahab, and Yun-Lai Zhou

Subjects

Engineering, Damage detection, Technology and Engineering, Cantilever, correlation analysis, 02 engineering and technology, lcsh:Technology, 01 natural sciences, Article, damage detection, 0203 mechanical engineering, 0103 physical sciences, transmissibility, General Materials Science, lcsh:Microscopy, 010301 acoustics, lcsh:QC120-168.85, lcsh:QH201-278.5, dynamic analysis, lcsh:T, business.industry, Engineering structures, Structural engineering, Transmissibility (vibration), Reliability engineering, 020303 mechanical engineering & transports, lcsh:TA1-2040, Correlation analysis, Benchmark (computing), lcsh:Descriptive and experimental mechanics, lcsh:Electrical engineering. Electronics. Nuclear engineering, Structural health monitoring, lcsh:Engineering (General). Civil engineering (General), business, lcsh:TK1-9971

Abstract

Output-based structural damage detection is becoming increasingly appealing due to its potential in real engineering applications without any restriction regarding excitation measurements. A new transmissibility-based damage detection approach is presented in this study by combining transmissibility with correlation analysis in order to strengthen its performance in discriminating damaged from undamaged scenarios. From this perspective, damage detection strategies are hereafter established by constructing damage-sensitive indicators from a derived transmissibility. A cantilever beam is numerically analyzed to verify the feasibility of the proposed damage detection procedure, and an ASCE (American Society of Civil Engineers) benchmark is henceforth used in the validation for its application in engineering structures. The results of both studies reveal a good performance of the proposed methodology in identifying damaged states from intact states. The comparison between the proposed indicator and the existing indicator also affirms its applicability in damage detection, which might be adopted in further structural health monitoring systems as a discrimination criterion. This study contributed an alternative criterion for transmissibility-based damage detection in addition to the conventional ones.

Published

2017