Analysis of Physics of Novel Light-Emitting Diode for Holographic Imaging

Analysis of Physics of Novel Light-Emitting Diode for Holographic Imaging

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DOI:

https://doi.org/10.56741/jnest.v3i02.566

Keywords:

Holographic Imaging, Novel Light Emitting Diode,, Physics of Semiconductor

Abstract

The paper focuses on the analysis of the physics of a novel light-emitting diode for holographic imaging. The research problems in this study are based on the specific challenges that were discussed in the introduction. The solution for this research problem is accomplished with two approaches such as (i) device modeling, physics of LEDs, and characteristics of LEDs under the theoretical analysis and (ii) fabrication of LEDs, PL and FTIR measurement, performance check, and performance comparison under the experimental studies. The specific objectives of this research are to advance the LED design for optical transmission in 5G communication systems, to recognize the semiconductor material for LED structure, and to approach theoretical and numerical calculations for LED. In these analyses, there are two main approaches for solving the performance of the novel light-emitting diodes. The first one is to develop the effective structure for light emitting diode and the other is to develop the energy diagram design of III-V and II-VI compound-based LED. The simulation analyses were carried out with the help of MATLAB language. The results confirm that the numerical analyses of these two developments could be supported to estimate the outcomes of experimental studies without using real equipment in the laboratory.

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Author Biographies

Thae Nu Wah, Yangon Technological University

received her B.E. (Electronics) from Technological University (Mawlamyinw) in 2009, M.E. (Electronics) Degree from Technological University (Thanlyin), Myanmar in 2018, respectively. She joined Technological University (Mawlamyine), Myanmar as a tutor at the Department of Electronic Engineering in 2003. She is now a PhD candidate at the Department of Electronic Engineering of Yangon Technological University, Myanmar. (email: mathaenuwah.ytu@gmail.com).  

Thanda Win, Yangon Technological University


is a Professor at the Department of Electronic Engineering of Yangon Technological University, Myanmar. (email: mathandawin.ytu@gmail.com).

Lei Lei Yin Win, Yangon Technological University


is a Professor of the Department of Electronic Engineering at Yangon Technological University, Myanmar. (email: maleileiyinwin.ytu@gmail.com).

Hla Myo Tun, Yangon Technological University


is a Leading Pro-Rector for Research and Engineering Higher Education at Yangon Technological University (YTU), Myanmar. He specializes in professional training for Engineering Higher Education leaders, heads of departments, and faculty members. He also directs Research and Development programs and workshops and has worked as a certified Quality Assurance Evaluator of the Myanmar Engineering Council (MEngC) since 2019. (email: kohlamyotun.ytu@gmail.com).  

Devasis Pradhan, Acharya Institute of Technology

is working as an Assistant Professor in Grade 1 and Dean of Research and Development at Acharya Institute of Technology, Bengaluru, Karnataka, from 2017 onwards. His current research includes the effectiveness of 5G Green Communications, mmWave antenna design, UWB antennas, and its implementation. With 16+ years of experience in the Academic and Research field, he has published 76 research papers and eight papers submitted to IEEE Access and Reputed Book and 4 Authored Books and 3 Edited Books (CRC, ISTE, Bentham Science) with a reputed publishing house. (email: devasispradhan@acharya.ac.in).

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Published

2024-04-20

How to Cite

Wah, T. N., Win, T., Win, L. L. Y., Hla Myo Tun, & Pradhan, D. (2024). Analysis of Physics of Novel Light-Emitting Diode for Holographic Imaging. Journal of Novel Engineering Science and Technology, 3(02), 46–53. https://doi.org/10.56741/jnest.v3i02.566

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Vol. 3 No. 02 (2024): Forthcoming Issue - Journal of Novel Engineering Science and Technology

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