Dr. Yi Weng
My Social Links

Dr. Yi Weng

Product Engineer
Finisar, United State of America

Highest Degree
Ph.D. in Electrical Engineering from University of Louisville, Louisville, Kentucky, USA

Share this Profile

Area of Interest:

Engineering
100%
Electrical Engineering
62%
Astronomy
90%
Optical Communication
75%
Computational Intelligence
55%

Research Publications in Numbers

Books
0
Chapters
0
Articles
0
Abstracts
0

Selected Publications

  1. Weng, Y., J. Wang, X. He and Z. Pan, 2018. A rigorous analysis of digital pre-emphasis and DAC resolution for interleaved DAC Nyquist-WDM signal generation in high-speed coherent optical transmission systems. Opt. Commun., 409: 77-85.
  2. He, X., Y. Weng, J. Wang and Z. Pan, 2018. Fast convergent frequency-domain MIMO equalizer for few-mode fiber communication systems. Opt. Commun., 490: 131-136.
    CrossRef  |  Direct Link  |  
  3. Weng, Y., X. He, W. Yao, M.C. Pacheco, J. Wang and Z. Pan, 2017. Investigation of adaptive filtering and MDL mitigation based on space-time block-coding for spatial division multiplexed coherent receivers. Opt. Fiber Technol., 36: 231-236.
    CrossRef  |  Direct Link  |  
  4. Weng, Y., X. He and Z. Pan, 2017. Space division multiplexing optical communication using few-mode fibers. Opt. Fiber Technol., 36: 155-180.
    CrossRef  |  Direct Link  |  
  5. Weng, Y., T. Wang and Z. Pan, 2017. Multi-functional fiber optic sensors based on mode division multiplexing. Opt. Mater. Exp., 7: 1917-1933.
    CrossRef  |  Direct Link  |  
  6. Weng, Y., E. Ip, Z. Pan and T. Wang, 2016. Advanced spatial-division multiplexed measurement systems propositions-from telecommunication to sensing applications: A review. Sensors, Vol. 16. .
    Direct Link  |  
  7. Wang, J., Y. Weng and Z. Pan, 2016. Digital Signal Processing for Nyquist-WDM Optical Fiber Systems. In: Optical Communication Systems: Fundamentals, Techniques and Applications, Matthew, N., O. Sadiku and S.M. Musa (Eds.)., Nova Science Publishers, Inc., USA.
  8. Pan, Z., Y. Weng and J. Wang, 2016. Investigation of nonlinear effects in few-mode fibers. Phot. Network Commun., 31: 305-315.
    CrossRef  |  Direct Link  |  
  9. Weng, Y., X. He, J. Wang and Z. Pan, 2015. All-optical ultrafast wavelength and mode converter based on inter-modal four-wave mixing in few-mode fibers. Opt. Commun., 348: 7-12.
    CrossRef  |  Direct Link  |  
  10. Weng, Y., E. Ip, Z. Pan and T. Wang, 2015. Single-end simultaneous temperature and strain sensing techniques based on Brillouin optical time domain reflectometry in few-mode fibers. Opt. Exp., 23: 9024-9039.
    CrossRef  |  Direct Link  |  
  11. Pan, Z., J. Wang and Y. Weng, 2015. Digital signal processing techniques in Nyquist-WDM transmission systems. Phot. Network Commun., 32: 236-245.
  12. Wang, J., X. Jiang, X. He, Y. Weng and Z. Pan, 2013. Chromatic dispersion estimation methods using polynomial fitting in PDM-QPSK or other multilevel-format coherent optical systems. Opt. Fiber Technol., 19: 162-168.
    CrossRef  |  Direct Link  |  
  13. Jiang, K., C.J. Brignac, Y. Weng, M.B. Kim, H. Lee and J.P. Dowling, 2012. Strategies for choosing path-entangled number states for optimal robust quantum-optical metrology in the presence of loss. Phys. Rev. A, Vol. 86. .
    Direct Link  |