Junbao Hu, Ph.D.

Qualified Associate Professor

Department of Optoelectronic Engineering

School of Microelectronics &Data Science

Anhui University of Technology

Research Interests

l Optical field control based on orbital angular momentum

l Optical image and information processing

l Computational optical imaging and detection

 

Teaching Courses

l Optoelectronic image processing

 

Grants

l 2023.07-2026.06, Research on mode recognition and detection of orbital angular momentum beam and its application in optical communication, Anhui University of Technology Talent Introduction Project, QD202306; (leading)

l 2020.11-2022.10, Deep learning-enabled optical orbital angular momentum mode demodulation and data transmission research, Shenzhen University Excellent Doctoral Program Funding, 2050493003; (leading)

l 2022.01-2025.12, Research on all fiber photon orbital angular momentum routing detection device, National Science Foundation of China, 62175162 (participating).

 

Selected Publications

1. Feng, F^†., Hu, J^†., Wang, Y., Guo, Z., Li, N., Zhao, B., Yuan, X*., & Somekh, M*. “Deep-learning enabled simultaneous detection of phase and polarization singularities of CVVBs and its application to image transmission.” Optics & Laser Technology, 2024, 168: 109890.

2. Hu, J., Guo, Z., Fu, Y., Gan, J., Chen, P., Chen, G., Min, C., Yuan, X*., & Feng, F*. “How convolutional-neural-network detects optical vortex scattering fields.” Optics and Lasers in Engineering, 2023, 160: 107246.

3. Feng, F^†., Hu, J^†., Guo, Z., Gan, J., Chen, P., Chen, G., Min, C*., Yuan, X*., & Somekh, M*. “Deep Learning-Enabled Orbital Angular Momentum-Based Information Encryption Transmission.” ACS Photonics, 2022, 9: 820–829.

4. Hu, J., Wu, L*., & Li, N. “High dynamic range imaging with short- and long-exposures based on artificial remapping using multiscale exposure fusion.” Journal of Visual Communication and Image Representation, 2022, 87:103585.

5. Hu, J., Wu, L*., & Li, N. “High dynamic range imaging by a pseudo exposure fusion method based on artificial remapping.” Optik, 2022, 260: 169132.

6. Wu, L., Hu, J*., Yuan, C., & Shao, Z. “Details-preserving multi-exposure image fusion based on dual-pyramid using improved exposure evaluation.” Results in Optics,2021, 2: 100046.

7. Hu, J., Wei, Q., Kong, Y., Jiang, Z., Xue, L., Liu, F., Kim, D., Liu, C*., & Wang, S*. “Higher Order Transport of Intensity Equation Methods: Comparisons and Their Hybrid Application for Noise Adaptive Phase Imaging.” IEEE Photonics Journal, 2019, 11(3): 4200214.

8. Hu, J., Kong, Y., Jiang, Z., Xue, L., Liu, F., Liu, C*., & Wang, S*. “Adaptive Dual-Exposure Fusion based Transport of Intensity Phase Microscopy.” Applied Optics, 2018, 57(25): 7249-7258.

9. Hu, J., Meng, X., Wei, Q., Kong, Y., Jiang, Z., Xue, L., Liu, F., Liu, C*., & Wang, S*. “Numerical tilting compensation in microscopy based on wavefront sensing using transport of intensity equation method.” Journal of Optics, 2018, 20(3): 035301.