Doojin Lee | Electrical Engineering | Best Researcher Award

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Prof. Dr. Doojin Lee | Electrical Engineering | Best Researcher Award

Changwon National University, South Korea

Dr. Doojin Lee is an Assistant Professor in the Department of Electronic Engineering at Changwon National University (CWNU), South Korea. His work bridges theoretical and applied aspects of antenna design, ultra-wideband (UWB) radar systems, electromagnetic cloaking, and advanced signal processing. With postdoctoral and research experience at globally recognized institutions — including The Ohio State University, University of Waterloo, University of Mississippi, and South Korea’s Agency for Defense Development — Dr. Lee has established himself as a rising expert in his field. His research includes contributions to NASA projects, military radar systems, biomedical sensing, and wearable imaging technologies. Dr. Lee’s expertise spans hardware and software, covering antenna simulation, fabrication, electromagnetic measurements, and radar algorithm development. Beyond research, he contributes actively as a reviewer for prestigious journals such as IEEE Transactions on Antennas and Propagation, IEEE Access, and IET Electronics Letters, reflecting his international reputation. He is also a long-standing member of the Korean Institute of Electromagnetic Engineering and Science. Dr. Lee’s professional trajectory is marked by steady academic growth, international collaborations, and technical excellence, making him a promising candidate for research recognition. He continues to push the boundaries of radar and antenna technologies, with a vision to develop next-generation electromagnetic sensing systems for diverse applications.

Professional Profile

Education

Dr. Doojin Lee completed his integrated M.S./Ph.D. program at the Gwangju Institute of Science and Technology (GIST), South Korea, earning his doctorate in Biomedical and Electronic Engineering in 2017. His dissertation focused on ultra-wideband electromagnetic sensors, particularly resistively loaded dipole antennas for skull imaging applications, setting the stage for his specialization in biomedical and radar sensing technologies. Before his graduate studies, he earned his B.S. in Electronic Engineering from Changwon National University (CWNU) in 2012, where his foundation in mechatronics and electronics developed. Post-Ph.D., Dr. Lee pursued advanced research as a postdoctoral fellow at the University of Waterloo, Canada, where he worked on UWB pulsed radar sensors for UAV applications and electromagnetic remote sensing. He continued as a postdoctoral fellow at The Ohio State University, focusing on GNSS receiver design and ground-penetrating radar antennas in collaboration with NASA. Later, as a research associate at the University of Mississippi, he explored electromagnetic cloaking using mantle metasurfaces. This diverse international educational and research background has shaped Dr. Lee’s multidisciplinary approach, blending antenna design, signal processing, and sensing technologies. His formal education and postdoctoral training reflect a consistent focus on cutting-edge electromagnetic research.

Professional Experience

Dr. Doojin Lee’s professional experience spans both academic and applied research settings, reflecting a balance of theoretical innovation and practical development. Since October 2022, he has served as an Assistant Professor in the School of Electrical, Electronic, and Control Engineering at Changwon National University (CWNU), South Korea, where he focuses on ultrawideband (UWB) antenna design and electromagnetic cloaking theories. Prior to this, Dr. Lee worked as a senior researcher at the Agency for Defense Development (ADD) in South Korea from 2020 to 2022, contributing to the analysis of electromagnetic interference on integrated masts for advanced naval combat systems under the KDDX project. Earlier, he gained international research experience at leading institutions: at the University of Mississippi, he worked on metasurface-based electromagnetic cloaking; at The Ohio State University’s ElectroScience Laboratory, he collaborated with NASA on GNSS receivers and non-contact GPR antennas; and at the University of Waterloo, he developed UWB radar sensors for UAVs and military surveillance. These roles demonstrate his broad expertise in antenna design, radar systems, electromagnetic sensing, and applied defense technologies. His career path highlights a progressive blend of academic leadership, government-funded research, and cross-national collaborations in cutting-edge electromagnetic engineering.

Research Interests

Dr. Doojin Lee’s research interests center on the design, development, and verification of advanced electromagnetic and radar systems. His work on ultra-wideband (UWB) impulse radar sensors addresses critical applications such as ground-penetrating radar, foliage-penetration radar, and through-wall radar imaging, making significant contributions to both civilian and military sectors. He is particularly interested in antenna innovations, including the design of small, planar, resistive, wrapped, and bowtie antennas, as well as the development of multi-input multi-output (MIMO) antenna arrays and packaging techniques. Another major focus area is electromagnetic cloaking, where Dr. Lee explores mantle metasurfaces to decouple closely spaced or overlapping phased antenna arrays, aiming to minimize electromagnetic interference and improve system efficiency. Additionally, his work on GNSS antenna receiver design advances the field of precise global navigation technologies, which are critical for aerospace and geospatial applications. He also has strong interests in physics-based and radar image signal processing, where algorithm development complements his hardware innovations. Overall, Dr. Lee’s research integrates electromagnetic theory, materials, hardware design, and signal processing, creating a comprehensive portfolio that addresses both fundamental scientific challenges and real-world sensing and communication problems.

Research Skills

Dr. Doojin Lee possesses a wide range of advanced research skills that span simulation, fabrication, measurement, and analysis. He is proficient in using leading electromagnetic simulation software such as HFSS, CST, FEKO, ADS, AutoCAD, and OrCAD, which allow him to design and optimize complex antenna structures and radar systems. His programming and data analysis capabilities are supported by strong MATLAB skills, essential for algorithm development and signal processing tasks. In hardware, Dr. Lee is experienced in photolithography and chemical etching techniques for precise PCB fabrication, enabling the creation of experimental prototypes for antenna and radar testing. His measurement expertise includes operating vector network analyzers, conducting far-field and near-field antenna measurements, and analyzing electromagnetic interference, ensuring accurate experimental validation of designs. Additionally, Dr. Lee is skilled in using LaTeX for scientific publishing, reflecting his experience in preparing high-quality technical reports and journal articles. These combined technical competencies allow him to bridge the full cycle of research and development, from theoretical design and simulation to prototype fabrication, experimental testing, and performance optimization across a broad range of electromagnetic applications.

Awards and Honors

While specific named awards or honors are not detailed in the available records, Dr. Doojin Lee’s professional recognition is evidenced by his continuous role as a reviewer for top-tier international journals, including IEEE Transactions on Antennas and Propagation, IEEE Access, and IET Electronics Letters. Serving as a reviewer for these journals since 2017–2018 demonstrates that his expertise is trusted and valued by the global scientific community, an acknowledgment that often parallels formal academic honors. Additionally, Dr. Lee’s selection as a research collaborator on NASA-supported projects and national defense research programs such as the KDDX initiative reflects a level of professional respect and trust awarded only to highly competent and reliable experts. His early-career achievements, including publication highlights and a featured interview in Electronics Letters, further underscore his growing recognition in the field of electromagnetic engineering. While expanding his portfolio with formal awards, fellowships, or competitive research grants would further boost his profile, his current standing as a respected contributor and international collaborator already places him among promising researchers with a steadily rising reputation.

Conclusion

In conclusion, Dr. Doojin Lee presents himself as a highly capable, technically skilled researcher with a clear focus on advancing antenna and radar system technologies. His academic and professional journey demonstrates a consistent commitment to both foundational and applied research, with projects that span biomedical sensing, aerospace communication, ground-penetrating radar, and electromagnetic cloaking. His technical mastery across simulation, fabrication, measurement, and signal processing enables him to contribute meaningfully to complex, multidisciplinary projects. Dr. Lee’s reputation as a regular reviewer for top international journals and his history of collaboration with prestigious organizations like NASA and national defense agencies position him as an emerging leader in his field. To maximize his competitiveness for high-level research awards, he may benefit from increasing his formal leadership in large-scale projects, expanding his independent research funding, and documenting high-impact contributions such as patents, innovations, or societal applications. Overall, Dr. Lee’s research excellence, international collaborations, and specialized expertise make him a strong candidate for recognition through a Best Researcher Award, reflecting both his current accomplishments and his significant potential for future contributions.

Publications Top Notes

  1. Design of Multi-Time Programmable Intellectual Property with Built-In Error Correction Code Function Based on Bipolar–CMOS–DMOS Process

    • Authors: L. Li, S. Kwon, D. Kim, D. Lee, Y. Kim

    • Year: 2025

  2. Investigation of Dual-Mode Cloaked Cylindrical Slot Antennas with a Pulsed Radar Signal Processing

    • Authors: D. Lee, A.B. Yakovlev

    • Year: 2024

  3. Design and Investigation on Antipodal Vivaldi Antenna Emitting a Pulse-Like Waveform for Imaging Close-Range Objects

    • Authors: D. Lee, S. Raman, R. Augustine

    • Year: 2024

    • Citations: 1

 

Mohammad Maalandish | Power Electronics | Best Researcher Award

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Dr. Mohammad Maalandish | Power Electronics | Best Researcher Award

Assistant Professor from Gdansk University of Technoloy, Iran

Mohammad Maalandish is an emerging researcher in the field of power electronics, currently pursuing a Ph.D. at the University of Tabriz, Iran. With a focused and impactful academic trajectory, he has contributed significantly to the advancement of energy conversion systems, particularly in designing and controlling high-performance DC-DC and DC-AC power converters. Born in 1990 in Marand, Iran, he completed his B.Sc. in Electrical Engineering from Azarbaijan Shahid Madani University and his M.Sc. in Power Electronics from the University of Tabriz. Mohammad has published over 40 journal and conference papers, many of which appear in high-ranking international journals. His work has been recognized nationally and internationally through prestigious awards and inclusion in Stanford’s World’s Top 2% Scientists list for several consecutive years. Apart from research, he is actively involved in teaching and laboratory activities, demonstrating a commitment to academic mentorship. His international exposure through a research visit to Aarhus University in Denmark further strengthens his global research outlook. Equipped with a range of technical skills and a collaborative mindset, Mohammad exemplifies a new generation of dedicated scholars whose contributions are shaping the future of energy systems and electronic applications.

Professional Profile

Education

Mohammad Maalandish’s educational background demonstrates a strong and focused progression in the field of electrical and power engineering. He began his academic journey at Azarbaijan Shahid Madani University in Tabriz, Iran, where he earned his B.Sc. in Electrical Engineering in 2013. Motivated to specialize further, he pursued his M.Sc. in Power Electronics at the University of Tabriz, completing it in 2016. His postgraduate studies centered on advanced topics in power electronics, laying a solid foundation for research in power conversion and control systems. Currently, he is a Ph.D. candidate at the Faculty of Electrical and Computer Engineering, Power Engineering Department at the University of Tabriz. His doctoral research continues to explore complex areas such as multi-input multi-output (MIMO) converters and model predictive control (MPC) for electric vehicle and renewable energy applications. The continuity and depth of his education reflect a well-planned academic pathway, reinforced by a strong theoretical and practical understanding of electrical engineering principles. His education has been instrumental in enabling him to conduct high-level research and publish extensively in reputable international journals, making him a valuable contributor to the global scientific community.

Professional Experience

Mohammad Maalandish’s professional experience encompasses a combination of academic, research, and technical roles that enhance his profile as a well-rounded researcher. Since 2014, he has been affiliated with the University of Tabriz in various capacities. He served as a teaching assistant from 2014 to 2016 and again from 2018 to 2024, supporting instruction in power electronics and electrical engineering fundamentals. He also worked as a laboratory assistant at the Power Electronics Laboratory from 2019 to 2024, actively contributing to experimental research and mentoring undergraduate and graduate students. Notably, Mohammad expanded his academic exposure internationally through a research visiting position at Aarhus University in Denmark between March 2022 and August 2023. This experience allowed him to collaborate with European researchers and contribute to international projects. He has also provided consulting services as a senior advisor at VIET Company, demonstrating an ability to bridge academic knowledge with industry applications. Through these roles, he has acquired valuable experience in teaching, research supervision, and applied engineering, which collectively support his academic growth and research productivity.

Research Interest

Mohammad Maalandish’s research interests are deeply rooted in modern power electronics and its applications in renewable energy and electric transportation. His work primarily focuses on the development and optimization of power conversion systems, including DC-DC and DC-AC converters. He is particularly interested in designing high step-up converters with advanced control strategies to enhance efficiency and stability. Another key area of his research is Multi-Input Multi-Output (MIMO) converter architecture, which offers improved flexibility and control for complex energy systems. His investigations also extend to Model Predictive Control (MPC), a robust technique for controlling converters in real-time applications, especially in electric vehicle power systems. Additionally, he explores methods for eliminating leakage current in converter systems to ensure operational safety and efficiency. Renewable energy integration, especially through innovative converter topologies, is another cornerstone of his research. His contributions are aimed at improving power density, minimizing losses, and promoting sustainable energy solutions. By addressing both theoretical and applied aspects, his research is well-positioned to make a meaningful impact on the fields of energy conversion and smart grid technologies.

Research Skills

Mohammad Maalandish possesses a wide array of research and technical skills that equip him to tackle complex problems in electrical and power engineering. He is proficient in simulation and modeling tools such as MATLAB, PSCAD/EMTDC, and PSIM, which are essential for designing and analyzing power electronic systems. His expertise also includes hardware programming and embedded system design using platforms such as Arduino and Code Vision AVR. For circuit design and PCB layout, he is skilled in using Altium Designer. He is capable of conducting both theoretical analysis and experimental validation, having extensive experience in laboratory setups and prototype development. Mohammad’s familiarity with MIMO systems, soft switching techniques, and high step-up converter design demonstrates his capacity to innovate in high-efficiency energy systems. His technical competence is matched by his ability to document and disseminate research through high-impact publications. Furthermore, his experience as a teaching and lab assistant has refined his skills in research mentoring and technical communication. Collectively, his skill set reflects a balanced combination of analytical thinking, hands-on experimentation, and technological fluency essential for advanced research in power electronics.

Awards and Honors

Mohammad Maalandish has received multiple awards and distinctions that reflect his exceptional performance and recognition in the academic and scientific communities. From 2018 to 2021, he was consecutively awarded the Research Prize by the National Elites Foundation of Iran for being a top student. In 2022 and 2023, he was honored as the top student at the University of Tabriz, further underscoring his consistent academic excellence. A particularly prestigious recognition came in the form of the Alborz Prize in 2022, awarded to national top students in Iran. Perhaps most notably, he has been listed among the World’s Top 2% Scientists by Stanford University and Elsevier from 2021 to 2024. This global distinction highlights the impact and citation strength of his scientific work on an international scale. These accolades not only affirm his research capabilities but also demonstrate his dedication to scholarly excellence. They position him as a leader among early-career researchers in the field of electrical and power engineering. These repeated and diverse recognitions are a testament to his sustained contribution and future potential in academia.

Conclusion

In conclusion, Mohammad Maalandish stands out as a highly promising researcher with an exceptional record of academic achievement and scientific contribution. His focused research in power electronics addresses critical global needs in energy conversion and renewable integration. With over 40 publications in top-tier journals and conferences, multiple national and international honors, and hands-on technical expertise, he exemplifies the qualities of a next-generation leader in engineering research. His educational and professional background, combined with international research exposure and active academic involvement, reflect a well-rounded and impactful profile. His ability to bridge theory with practical application, particularly in converter design and electric vehicle systems, places him at the forefront of innovation in the power electronics domain. Recognitions such as the Alborz Prize and his inclusion in the World’s Top 2% Scientists affirm both the quality and impact of his work. With continued emphasis on research leadership, interdisciplinary collaboration, and broader industrial engagement, Mohammad is well-positioned to contribute significantly to both academic and practical advancements in his field. He is a worthy candidate for the Best Researcher Award and an asset to the scientific community.

Publications Top Notes

  • Robust optical-levitation-based metrology of nanoparticle’s position and mass
    Authors: Y. Zheng, L.M. Zhou, Y. Dong, C.W. Qiu, X.D. Chen, G.C. Guo, F.W. Sun
    Journal: Physical Review Letters, 124(22), 223603
    Year: 2020
    Citations: 83

  • Non-Markovianity-assisted high-fidelity Deutsch–Jozsa algorithm in diamond
    Authors: Y. Dong, Y. Zheng, S. Li, C.C. Li, X.D. Chen, G.C. Guo, F.W. Sun
    Journal: npj Quantum Information, 4(1), 3
    Year: 2018
    Citations: 59

  • Coherent dynamics of multi-spin V center in hexagonal boron nitride
    Authors: W. Liu, V. Ivády, Z.P. Li, Y.Z. Yang, S. Yu, Y. Meng, Z.A. Wang, N.J. Guo, F.F. Yan, …
    Journal: Nature Communications, 13(1), 5713
    Year: 2022
    Citations: 55

  • Temperature dependent energy gap shifts of single color center in diamond based on modified Varshni equation
    Authors: C.C. Li, M. Gong, X.D. Chen, S. Li, B.W. Zhao, Y. Dong, G.C. Guo, F.W. Sun
    Journal: Diamond and Related Materials, 74, 119–124
    Year: 2017
    Citations: 53

  • A robust fiber-based quantum thermometer coupled with nitrogen-vacancy centers
    Authors: S.C. Zhang, Y. Dong, B. Du, H.B. Lin, S. Li, W. Zhu, G.Z. Wang, X.D. Chen, …
    Journal: Review of Scientific Instruments, 92(4)
    Year: 2021
    Citations: 44

  • Near-infrared-enhanced charge-state conversion for low-power optical nanoscopy with nitrogen-vacancy centers in diamond
    Authors: X.D. Chen, S. Li, A. Shen, Y. Dong, C.H. Dong, G.C. Guo, F.W. Sun
    Journal: Physical Review Applied, 7(1), 014008
    Year: 2017
    Citations: 35

  • Quantum imaging of the reconfigurable VO₂ synaptic electronics for neuromorphic computing
    Authors: C. Feng, B.W. Li, Y. Dong, X.D. Chen, Y. Zheng, Z.H. Wang, H.B. Lin, W. Jiang, …
    Journal: Science Advances, 9(40), eadg9376
    Year: 2023
    Citations: 28

  • Focusing the electromagnetic field to 10⁻⁶λ for ultra-high enhancement of field-matter interaction
    Authors: X.D. Chen, E.H. Wang, L.K. Shan, C. Feng, Y. Zheng, Y. Dong, G.C. Guo, …
    Journal: Nature Communications, 12(1), 6389
    Year: 2021
    Citations: 28

  • Quantum enhanced radio detection and ranging with solid spins
    Authors: X.D. Chen, E.H. Wang, L.K. Shan, S.C. Zhang, C. Feng, Y. Zheng, Y. Dong, …
    Journal: Nature Communications, 14(1), 1288
    Year: 2023
    Citations: 27

  • Experimental implementation of universal holonomic quantum computation on solid-state spins with optimal control
    Authors: Y. Dong, S.C. Zhang, Y. Zheng, H.B. Lin, L.K. Shan, X.D. Chen, W. Zhu, …
    Journal: Physical Review Applied, 16(2), 024060
    Year: 2021
    Citations: 26