Taehyoun Oh | Digital Architecture | Best Researcher Award

Published on by Architecture Engineers

Prof. Dr. Taehyoun Oh | Digital Architecture | Best Researcher Award

Professor | Kwangwoon University | South Korea

Taehyoun Oh is an Associate Professor at Kwangwoon University specializing in high-speed I/O circuit design and advanced mixed-signal integrated systems. He brings extensive experience from both academia and industry, contributing to high-performance SerDes development, MIMO channel equalization, and signal-integrity innovation through impactful roles in major semiconductor organizations. His research focuses on high-speed chip-to-chip communication, MIMO crosstalk cancellation, low-power equalization architectures, and multichannel I/O design, leading to significant advancements in CMOS-based receiver architectures, adaptive calibration algorithms, and prototype implementations. He has authored influential journal papers, contributed to prominent conferences, and published a specialized book on high-speed I/O circuits, demonstrating consistent leadership in circuit innovation. His work has been recognized through best-paper distinctions, competitive research awards, and collaborative contributions across internationally respected research laboratories and design teams. His technical expertise, scholarly output, and continued commitment to advancing high-speed interface technologies position him as a leading contributor in the field. His research impact includes 115 citations, 26 publications, and an h-index of 5.

Profiles: Scopus | ORCID | Google Scholar

Featured Publications

1. Cho K.U., Gil J., Park C., Cho K.J., Shin J.W., Kim E.S., Eo Y.S., Harjani R., et al. A 3.5–4.7 GHz Fractional-N ADPLL with a low-power time-interleaved GRO-TDC of 6.2 ps resolution in 65 nm CMOS process. IEEE Access, 2024, 2.

2. Chung G., Cho K., Oh T. 2 Lanes × 2.65–6.4 Gb/s scalable IO transceiver with delay compensation technique in 65 nm CMOS process. J. Semicond. Technol. Sci., 2024, 24(3), 184–190.

3. Ahn J., Kim S., Kwon K., Park M., Gil J., Choi H., Kim N.Y., Kim E.S., Jung Y., et al. A 5.3–6.2 GHz Fractional-N frequency synthesizer with variable-gain automatic frequency calibration using cycle slips in 65 nm CMOS. Electronics, 2024, 14(22), 4368.

4. Oh T., Harjani R. A 12 Gb/s multichannel I/O using MIMO crosstalk cancellation and signal reutilization in 65 nm CMOS. IEEE J. Solid-State Circuits, 2013, 48(6), 1383–1397.

5. Oh T., Harjani R. A 6 Gb/s MIMO crosstalk cancellation scheme for high-speed I/Os. IEEE J. Solid-State Circuits, 2011, 46(8), 1843–1856.

Taehyoun Oh’s work advances the future of high-speed electronic systems by enabling faster, more reliable, and energy-efficient chip-to-chip communication essential for next-generation computing and data-driven technologies. His innovations in MIMO equalization, crosstalk cancellation, and high-speed I/O architecture contribute directly to enhancing semiconductor performance and strengthening the global electronics industry. His vision is to pioneer intelligent, scalable interface solutions that shape the backbone of future digital infrastructure.

Hussien M.Hassan | AI and Automation in Architecture | Best Researcher Award

Published on by Architecture Engineers

Dr. Hussien M.Hassan | AI and Automation in Architecture | Best Researcher Award

Associate Professor | Port Said University | Egypt

Dr. Hussien M. Hassan is an Associate Professor at the Faculty of Engineering, Port Said University, specializing in Naval Architecture and Marine Hydrodynamics. With a Ph.D. in Ship Hydrodynamics, he has developed extensive expertise in Computational Fluid Dynamics (CFD), artificial intelligence applications in ship design, and green marine technologies. His research primarily focuses on hydrodynamic optimization, sustainable ship geometry, marine bio-mimetics, and the integration of AI for energy-efficient maritime systems. Dr. Hassan has led and contributed to numerous funded research projects, including initiatives on smart solar desalination and innovative ventilation systems for climate resilience. His scholarly output includes several high-impact publications in international journals such as Marine Systems & Ocean Technology and Journal of Ocean Engineering and Marine Energy. Beyond academia, he has demonstrated entrepreneurial leadership as CEO of multiple marine and engineering ventures. He is also the author of a technical book on Artcam software and has delivered seminars on emerging maritime technologies. Recognized for his contributions to marine innovation and education, Dr. Hassan actively engages with global research communities, serving as a reviewer and collaborator in multidisciplinary engineering forums. His research impact includes 5 citations, 3 publications, and an h-index of 2.

Profiles: Scopus | Google Scholar

Featured Publications

1. Hassan H.M., Elsakka M.M., Refaat A., Zhang H., Yin Z., Ahmed A., A comparative study on the hydrodynamic performance of traditional and closed-loop marine propellers. Marine Systems & Ocean Technology, 2025, 20(3), 34.

2. Mosaad M.A., Gafaary M.M., Yehia W., Hassan H.M., On the design of X-bow for ship energy efficiency. Influence of EEDI on Ship Design & Operation, London, UK, 2017, 22(11).

3. Hassan H.M., Elsakka M.M., Refaat A., Amer A.E., Rizk R.Y., Optimal design of container ships geometry based on artificial intelligence techniques to reduce greenhouse gases emissions. International Work-Conference on Bioinformatics and Biomedical Engineering, 2023, 3.

4. Hassan H.M., Elsakka M.M., Moustafa M.M., On the comparative hydrodynamic analysis of conventional and innovative closed-loop marine propellers, 2024, 2.

5. Mosaad M., Improving ship wave resistance by optimal bulb configuration. SYLWAN, 2020, 164(11), 1–14.

Dr. Hussien M. Hassan’s work advances sustainable maritime innovation by integrating artificial intelligence and hydrodynamic optimization to enhance ship energy efficiency and reduce environmental impact. His research contributes to the global shift toward greener marine technologies, fostering progress in both academic and industrial applications of smart ship design.