Professor Wang Lei
Ph.D. Supervisor
Email: wanglei33@xmu.edu.cn
Address: Room 291, Aerospace Building, Xiamen University
Education
September 2004 – June 2007, Hefei University of Technology, School of Information Science and Technology, Department of Electronics, Ph.D.
September 1999 – June 2002, Xiamen University, College of Physics and Mechanical & Electrical Engineering, Department of Mechanical and Electrical Engineering, M.Sc.
September 1993 – July 1997, Xiamen University, Department of Scientific Instruments and Precision Mechanics, B.Eng.
Work Experience
-August 2021 – Present, Xiamen University, School of Aerospace, Department of Mechanical and Electrical Engineering, Professor
-July 2007 – August 2021, Xiamen University, College of Physics and Mechanical & Electrical Engineering, Department of Mechanical and Electrical Engineering, Associate Professor
June 2014 – December 2014, University of Heidelberg, Visiting Scholar
September 2006 – December 2006, University of Heidelberg, Visiting Scholar
September 2005 – December 2005, University of Heidelberg, Visiting Scholar
August 2002 – June 2007, Xiamen University, College of Physics and Mechanical & Electrical Engineering, Department of Mechanical and Electrical Engineering, Lecturer
Research Interests
Machine Vision
Intelligent Manufacturing and Inspection
Optical Measurement
Intelligent Spectroscopic Instruments
Intelligent Signal Processing
Teaching Positions
Research Projects
1. National Natural Science Foundation of China, Artificial Intelligence-driven Rapid Raman Imaging System and its Application in Apoptosis Research (22174120), 2022-2025, 600,000 CNY, Principal Investigator.
2. Sub-project of the Ministry of Science and Technology's Key Research and Development Plan, Development of a 3D Defect Detection System for Chip Packaging, 2020-2022, 600,000 CNY, Principal Investigator.
3. Xiamen City Achievement Transformation Project, Intelligent Vision Inspection System for Flat Panel Displays, 2020-2022, 1,000,000 CNY, Principal Investigator.
4. Enterprise-commissioned Project, Appearance Defect Detection System for Flexible Circuit Boards, 2020-2022, 1,600,000 CNY, Principal Investigator.
5. Key Project of the National Natural Science Foundation of China, In-situ Nano-Spatial Resolution Study of the Relationship between Electrochemical Tip-enhanced Raman Spectroscopy Method and Catalyst Interface Structure-Performance, 2016-2021, 3,000,000 CNY, Participant.
6. National Natural Science Foundation of China, 21373173, Angle-resolved spectral measurement system and its application in optical characterization of two-dimensional nanostructures, January 2014-December 2017, 800,000 CNY, Completed, Principal Investigator.
7. National Natural Science Foundation of China, Basic Research on Scientific Instruments, 21227004, Development and Application Research of an In-situ Electrochemical Micro-Raman Spectrometer Suitable for High Spatiotemporal Resolution, January 2013-December 2016, 3,200,000 CNY, Completed, Participant.
Selected Publications
The relevant research results have been published in more than thirty papers in domestic and international journals such as Advanced Materials, Analytical Chemistry, Acta Electronica Sinica, and Optics and Precision Engineering. Twelve Chinese invention patents have been authorized, four utility model patents, and three software copyrights have been authorized. Recent publications include:
1. Speeding up the Topography Imaging of Atomic Force Microscopy by Convolutional Neural Network, Analytical Chemistry, 94, 12, 5041-5047, 2022-03-16
2. Collaborative Low-Rank Matrix Approximation-Assisted Fast Hyperspectral Raman Imaging and Tip-Enhanced Raman Spectroscopic Imaging, Analytical Chemistry, 93, 44, 14609–14617, 2021-10-25
3. Deep Learning for Bio-spectroscopy and Bio-spectral Imaging: State-of-the-Art and Perspectives, Analytical Chemistry, 93, 8, 3653-3665, 2021-01-01
4. Automated weak signal extraction of hyperspectral Raman imaging data by adaptive low-rank matrix approximation, Journal of Raman Spectroscopy, 51, 12, 2552-2561, 2020-12-02
5. Speeding Up the Line-Scan Raman Imaging of Living Cells by Deep Convolutional Neural Network, Analytical Chemistry, 2019, 91, 7070-7077, 2019-06-04
6. Electrochemical Reflective Absorption Microscopy for Probing the Local Diffusion Behavior in the Electrochemical Interface, Analytical Chemistry, 91, 4, 2831-2837, 2019-02-19
7. A Plasmonic Sensor Array with Ultrahigh Figures of Merit and Resonance Linewidths down to 3 nm, Advanced Materials, 30, 1, 1706031, 2018-03-22
8. Dynamic Raman imaging system with high spatial and temporal resolution, Review of Scientific Instruments, 88, 9, 095-110, 2017-09-01
9. Electrochemical fabrication of silver tips for tip-enhanced Raman spectroscopy assisted by a machine vision system, Journal of Raman Spectroscopy, 47, 7, 808-812, 2016-07-01
10. Efficient Platform for Flexible Engineering of Super-radiant, Fano-Type, and Sub-radiant Resonances, ACS Photonics, 2, 12, 1725-1731, 2015-12-16
11. Surface-enhanced Raman spectroscopy identification of common drug traces in urine, Analytical Chemistry, 43, 1, 33-39, January 19, 2015.
12. SERS spectral identification of Malachite Green in aquaculture water bodies, Spectroscopy and Spectral Analysis, 34, 5, 134-138, May 15, 2014.
13. Design and implementation of a portable rapid detection device based on plasmonic-enhanced Raman spectroscopy, Spectroscopy and Spectral Analysis, 37, 12, 3730-3735, December 1, 2017.
14. Angle-resolved spectral measurement system based on coaxial rotating arm, Acta Optica Sinica, 26, 12, 1224001-7, December 10, 2016.
15. Uncertainty in visual measurement of the external diameter of a mini-milling cutter, Optics and Precision Engineering, 20, 4, 202-209, April 1, 2012.
