Prof. Hwa Yaw Tam | Engineering | Best Researcher Award

Posted on 10/07/202510/07/2025 by Physicist Particle

Prof. Hwa Yaw Tam | Engineering | Best Researcher Award

Prof. Hwa Yaw Tam at The Hong Kong Polytechnic University , Hong Kong

Prof. Hwa Yaw TAM 🎓🔬, IEEE Life Fellow and OPTICA Fellow, is a visionary in photonics and optical fibre sensing. Currently Chair Professor of Photonics at The Hong Kong Polytechnic University 🇭🇰, he has spearheaded groundbreaking innovations in fibre-optic sensor systems for transportation 🚄, energy ⚡, and medical 👂 applications. With over 800 publications 📚 and 20 patents 🔖, he stands as the second most cited expert in fibre-optic sensing, boasting an H-index of 73. His trailblazing contributions span continents, from Hong Kong’s MTR to the Netherlands and Australia 🌍. A laureate of the Berthold Leibinger Innovationspreis 🏆 and multiple Geneva Invention awards, Prof. Tam’s legacy bridges academia, industry, and public safety. His work has also spun off seven photonics companies 🚀. With unwavering passion and pioneering spirit, Prof. Tam continues to illuminate the future of smart sensing and laser technologies 🔭.

Professional Profile

🎓 Education

Prof. Hwa Yaw TAM embarked on his academic voyage at The University of Manchester, UK 🇬🇧, earning both his B.Eng in 1985 and Ph.D. in 1989 🎓. His early educational foundations laid the groundwork for a lifelong commitment to photonics and optical engineering. Specializing in electrical and electronic engineering, his doctoral studies fused rigorous theory with hands-on research in laser systems and fibre technologies 🔍. This dual emphasis cultivated a mindset driven by innovation and precision. The UK academic environment, rich in historical scientific achievement, greatly influenced his research ethos 🌐. Prof. Tam’s education not only equipped him with cutting-edge technical knowledge but also instilled in him a vision to translate science into impactful, real-world applications. Today, that foundation continues to echo through his advanced fibre-optic sensor innovations 🔬, standing as a beacon for future generations of engineers and scientists 📘💡.

🏛️ Professional Experience

Prof. Tam’s professional journey spans academia and industry in equal brilliance 🌠. He began his research career at GEC-Marconi Ltd. (London) between 1989–1993, delving into erbium-doped fibre amplifiers and laser systems 💡. He then joined The Hong Kong Polytechnic University in 1993, rising through the ranks from Lecturer to Chair Professor of Photonics. He also served as Head of the Electrical Engineering Department and was the Founding Director of the Photonics Research Centre (2000–2022) 🏫. Presently, he is Associate Director at PolyU’s Photonics Research Institute, spearheading interdisciplinary innovations. Prof. Tam’s work transcends traditional academia—his team has launched seven start-ups, catalyzing photonics-based solutions globally 🚀. His leadership has shaped fibre-optic sensing systems for cities and industries across Asia, Europe, and Australia, turning theoretical breakthroughs into operational systems in railways 🚉, energy grids 🔋, and hospitals 🏥, positioning him as a pivotal force in global smart sensing networks 🌐.

🔬 Research Interest

Prof. Tam’s research orbits around specialty optical fibres tailored for real-world sensor applications 🔍. His core interests span the design and fabrication of advanced fibre-optic systems that serve as digital sentinels in complex infrastructures 🧠. From structural health monitoring (SHM) to real-time railway diagnostics, his innovations help prevent failures before they occur ⚠️. His pioneering optical fibre networks have monitored everything from high-speed trains 🚆 to smart escalators and even cochlear implants for medical precision 👂. By embedding fibre Bragg gratings (FBGs) into intelligent sensing webs, he’s revolutionized predictive maintenance across industries. His group’s work is particularly transformative in railway monitoring, with deployment success stories in Hong Kong, Singapore, and the Netherlands 🌍. Always ahead of the curve, Prof. Tam’s research fuses AI 🤖, photonic engineering, and real-time analytics to create a safer, more connected world through light 🌈 and precision sensing technologies 📈.

🏅 Awards and Honors

Prof. Tam’s achievements are globally celebrated 🏆. In 2025, he won the Special Prize and Gold Medal at Geneva’s Invention Expo for a smart cochlear implant 👂🌟. In 2024, he secured another Gold Medal for lithium-ion battery health monitoring via FBG sensors 🔋. Earlier, in 2022, his intelligent escalator monitoring system earned him yet another Geneva Gold Award 🥇. The Berthold Leibinger Innovationspreis in 2014, among the world’s highest laser tech honors, recognized his work in wavelength-tunable laser sensing for railways 🚄. His team also received the President’s Award for Knowledge Transfer in 2022 at PolyU for creating AI-enhanced optical fibre networks 🌐. Further accolades include a Best Paper finalist at IEEE SENSORS 2016 📃. Each honor underscores Prof. Tam’s deep impact on laser technology, smart sensing, and translational engineering. His consistent award-winning contributions reflect a perfect blend of scientific creativity, societal value, and engineering excellence 💼🔬.

📚 Publications Top Note

Title: Enhanced Quasi-Distributed Accelerometer Array Based on ϕ-OTDR and Ultraweak Fiber Bragg Grating
Authors: , , , …
Year: 2023
Citations: 6
Source: IEEE Sensors Journal
Summary: Proposes an enhanced accelerometer array using phase-sensitive optical time-domain reflectometry (ϕ-OTDR) and ultraweak fiber Bragg gratings for distributed vibration sensing, suitable for applications like structural health monitoring.

Title: Label-Free DNA Detection Using Etched Tilted Bragg Fiber Grating-Based Biosensor
Authors: , , , …
Year: 2023
Citations: 6
Source: Sensors
Summary: Describes a label-free biosensor using etched tilted fiber Bragg gratings to detect DNA without the need for fluorescent labels, enhancing sensitivity and simplicity in genetic diagnostics.

Title: Recovery of a Highly Reflective Bragg Grating in DPDS-Doped Polymer Optical Fiber by Thermal Annealing
Authors: , , , …
Year: 2023
Citations: 2
Source: Optics Letters
Summary: Demonstrates the recovery of degraded Bragg gratings in doped polymer optical fibers using thermal annealing, showing potential for longer lifespan and reusability in fiber-optic sensors.

Title: Accident Risk Tensor-Specific Covariant Model for Railway Accident Risk Assessment and Prediction
Authors: , , , …
Year: 2023
Citations: 8
Source: Reliability Engineering and System Safety
Summary: Introduces a tensor-based statistical model for accurately assessing and predicting accident risks in railway systems by incorporating covariant risk factors.

Title: Polymeric Fiber Sensors for Insertion Forces and Trajectory Determination of Cochlear Implants in Hearing Preservation
Authors: , , , …
Year: 2023
Citations: 10
Source: Biosensors and Bioelectronics
Summary: Presents polymeric fiber-optic sensors designed to measure insertion force and trajectory during cochlear implant surgeries, helping to preserve hearing by reducing inner ear trauma.

Title: Miniature Two-Axis Accelerometer Based on Multicore Fiber for Pantograph-Catenary System
Authors: , , , ,
Year: 2023
Citations: 8
Source: IEEE Transactions on Instrumentation and Measurement
Summary: Develops a compact fiber-based accelerometer capable of sensing in two axes, tailored for monitoring the dynamics of pantograph-catenary interactions in electric rail systems.

Title: Ultraminiature Optical Fiber-Tip Directly-Printed Plasmonic Biosensors for Label-Free Biodetection
Authors: , , , …
Year: 2022
Citations: 19
Source: Biosensors and Bioelectronics
Summary: Describes a highly miniaturized fiber-tip plasmonic biosensor fabricated via direct printing, enabling sensitive and label-free detection of biomolecules at the microscale.

Title: Accelerated Pyro-Catalytic Hydrogen Production Enabled by Plasmonic Local Heating of Au on Pyroelectric BaTiO3 Nanoparticles
Authors: , , , …
Year: 2022
Citations: 83
Source: Nature Communications
Summary: Reports a novel hydrogen production method using gold-decorated BaTiO₃ nanoparticles, where plasmonic heating enhances pyro-catalytic activity under mild conditions.

Title: Biomechanical Assessment and Quantification of Femur Healing Process Using Fibre Bragg Grating Strain Sensors
Authors: , , , …
Year: 2022
Citations: 5
Source: Sensors and Actuators A: Physical
Summary: Uses fiber Bragg grating strain sensors to monitor and quantify mechanical changes in the femur during bone healing, supporting better postoperative assessment.

Title: Mach-Zehnder Interferometer Based Fiber-Optic Nitrate Sensor
Authors: , , , ,
Year: 2022
Citations: Not listed
Source: Optics Express
Summary: Presents a Mach-Zehnder interferometer design using optical fiber for detecting nitrate concentrations in water, aiming at applications in environmental monitoring

🔚 Conclusion

Prof. Hwa Yaw TAM is more than a scholar—he is a trailblazer in light-based sensing technologies 🌟. His career weaves together pioneering science, practical engineering, and impactful entrepreneurship 🌐. Through over 800 papers, 20 patents, and numerous awards, he has reshaped how the world monitors structural, environmental, and human conditions using optical fibres 💡. His real-world implementations—from monitoring city-wide railways to enabling hearing restoration—demonstrate how research can elevate safety, precision, and quality of life for millions 🌍. He continues to mentor future innovators and drive collaborative photonic research through his leadership roles at PolyU and the Photonics Research Institute. With vision, dedication, and humility, Prof. Tam stands as a guiding light for the global photonics community 🌠. His journey exemplifies how science, when paired with compassion and creativity, becomes a force for building a smarter, safer, and more sustainable world 🔗🌿.

Lijun Chen | Engineering | Best Researcher Award

Posted on 20/06/202520/06/2025 by Physicist Particle

Prof. Lijun Chen | Engineering | Best Researcher Award

Professor at Northeast Electric Power University, China

Professor Lijun Chen is a seasoned academic and applied researcher at Northeast Electric Power University, bringing over three decades of expertise in automation, thermophysical measurement, and power plant monitoring systems. 🚀 With early technical training at Fuji Electric (Japan) and a strong industrial foundation at Dalian Huaying High-Tech Co., he seamlessly bridges theory with real-world application. His scholarly portfolio boasts 50+ journal publications 📚 (with 20+ indexed by EI and others in SCI), and six national invention patents that reflect his innovation-driven mindset. ⚙️ He has led multiple national and provincial projects, combining academic research with industrial consulting to optimize thermal power systems. A Senior Member of the China Metrology Society, his dedication is evident through a career filled with impactful collaborations, cutting-edge research, and enduring contributions to the energy sector. 🔧 His work continues to empower sustainable and efficient energy technologies across China and beyond. 🌏

Professional Profile

Scopus

🎓 Education

Professor Lijun Chen’s educational journey is deeply rooted in engineering excellence. 🌱 He enhanced his technical knowledge through automation testing training at Fuji Electric, Japan (1991–1992), where he gained exposure to international standards and modern industrial practices. This early international training laid the groundwork for a future in advanced automation and instrumentation. He continued sharpening his skills with hands-on industry experience before entering academia. 📐 His educational pursuits were not just theoretical but focused on practical solutions for real-world problems in power systems. His academic foundation, supplemented by immersive industrial exposure, uniquely positions him as a knowledge leader in thermophysical measurement and energy systems. 🔋 The fusion of global learning and domestic execution in his educational journey symbolizes his balanced and forward-thinking approach to engineering education and research. 📊

👨‍💼 Professional Experience

Professor Chen’s professional voyage is an exemplar of bridging industry with academia. 🏭 From 1995 to 1997, he worked at Dalian Huaying High-Tech Co., developing automation solutions for complex power systems. Following this, from 1997 to 2001, he continued innovating at the Institute of Electronic Engineering Technology, sharpening his expertise in electronic control. Since 2001, he has been a cornerstone of the School of Automation Engineering at Northeast Electric Power University. 🧑‍🏫 There, he has led or collaborated on numerous high-impact projects, integrating research with engineering applications. His leadership in thermal power plant control systems has shaped provincial-level R&D initiatives and academic–industry partnerships. 🧠 His work with national and horizontal industry projects exemplifies how academic insight can directly solve operational challenges in the energy sector. 🔌

🔬 Research Interest

Lijun Chen’s research is centered on cutting-edge thermal measurement and automation in power engineering. 🌡️ His core interests span thermophysical parameter estimation, combustion optimization, and defect detection in high-frequency electromagnetic equipment. 🔎 These focus areas have significant industrial value, particularly in enhancing the efficiency, safety, and reliability of thermal power plants. His work addresses critical challenges in energy management and environmental control, making his innovations especially relevant in the current era of carbon reduction and sustainable engineering. 🌍 Professor Chen’s ability to combine hardware innovation with control algorithms demonstrates his multi-disciplinary reach across automation, electronics, and thermodynamics. His projects often involve both modeling and experimental validation, ensuring practical applicability. 📊 His collaborations with institutes and enterprises are further proof of his commitment to solving industry-grade problems with scientifically sound solutions. ⚛️

🏅 Award and Honor

Throughout his illustrious career, Professor Chen has been recognized with multiple provincial science and technology awards, a testament to the real-world impact of his work. 🏆 His patents—six granted at the national level—underscore his creative contributions to the field of power system automation and thermal engineering. 📜 His consistent participation in government-funded and industry-sponsored projects not only highlights his technical capability but also his leadership in driving research innovation. He is a Senior Member of the China Metrology Society and plays a notable role in the Jilin Province Electrical Engineering Society, reflecting his influence in professional circles. 🤝 His efforts have significantly elevated the performance of thermal power systems, earning him peer recognition and respect. His honors are not just awards—they are reflections of decades of dedicated research, innovation, and service to the field. 🔧💡

📚 Publications Top Note

1. Title: The Feasibility Study on Pulverized Coal Mass Concentration Measurement in Primary Air of Plant Using Fin Resonant Cavity Sensor
Authors: Hao Xu, Yiguang Yang, Lijun Chen, Hongbin Yu, Junwei Cao
Year: 2024
Type: Conference Paper
Source: IEEE International Instrumentation and Measurement Technology Conference (I2MTC)
Citations: 0 (as of the latest data)
Summary:
This study explores the application of a fin resonant cavity sensor to measure the mass concentration of pulverized coal in the primary air system of power plants. The authors designed and experimentally validated a resonant cavity-based sensor for real-time and high-flow environment monitoring. Results indicate the method’s strong potential for improving combustion efficiency and operational safety in thermal power systems.

2. Title: Research on Finite-Time Consensus of Multi-Agent Systems
Authors: Lijun Chen, Yu Zhang, Yuping Li, Linlin Xia
Year: 2019
Type: Journal Article
Source: Journal of Information Processing Systems (JIPS)
DOI: 10.3745/JIPS.01.0039
Citations: 1 (confirmed from source journal; citation count may vary on other platforms)
Summary:
This paper proposes a novel consensus protocol that enables finite-time convergence in second-order multi-agent systems. By incorporating the gradient of a global cost function into the standard consensus model, the authors enhance coordination speed and robustness among agents. Theoretical analysis using Lyapunov functions, homogeneity theory, and graph theory supports the method’s effectiveness. Simulations demonstrate superior performance in leader–follower scenarios.

✅ Conclusion

In conclusion, Professor Lijun Chen exemplifies the model of a research-driven innovator and dedicated academic. 📘 With a career spanning research, teaching, consultancy, and invention, he has contributed immensely to the advancement of thermal power automation and measurement systems. His ability to transform theoretical concepts into tangible industrial solutions highlights his value as both a scholar and engineer. 🔬 His multi-patented technologies and SCI-indexed publications reflect a commitment to quality, while his work with industry partners showcases practical relevance. With unwavering focus and passion for thermodynamics, automation, and sustainability, Professor Chen continues to shape the future of smart thermal energy systems in China and beyond. 🌱 His legacy is one of bridging knowledge with innovation, inspiring a new generation of researchers and engineers. 🌟

Dr. K. Lakshmi Prasanna | Engineering | Best Researcher Award

Posted on 26/05/202526/05/2025 by Physicist Particle

Dr. K. Lakshmi Prasanna | Engineering | Best Researcher Award

Visiting faculty at Birla Institute of Technology and Science Pilai, India

Dr. K. Lakshmi Prasanna 🎓 is a passionate researcher and academician in the field of High Voltage Engineering, with a strong command over system modeling, fault diagnostics, and parameter estimation using MATLAB/Simulink 🛠️. She brings a unique blend of theoretical insight and hands-on expertise in simulation, optimization, control systems, and signal processing. Her innovative Ph.D. work at BITS Pilani, Hyderabad focused on transformer winding modeling and inter-turn fault diagnostics 🔍, proposing novel, non-intrusive algorithms with real-world applicability. With a foundation in Power Electronics and Electrical Engineering ⚡, she also has teaching experience at multiple esteemed engineering colleges, nurturing minds in core subjects. Driven by curiosity and adaptability, she actively embraces new software tools and collaborative environments 💡. Her professional trajectory reflects a consistent commitment to academic excellence, technical rigor, and transformative innovation in electrical engineering. 🚀

Professional Profile

Orcid

Scopus

Google Scholar

📚 Education

Dr. Lakshmi Prasanna’s educational journey 🌱 reflects a steady and impressive rise through the academic ranks of electrical engineering. Beginning with a remarkable 96.9% in her Higher Secondary 🏫, she pursued her B.Tech in EEE and M.Tech in Power Electronics from JNTUA, scoring 85.1% and 85%, respectively 🎯. Her academic excellence culminated in a Ph.D. in High Voltage Engineering at BITS Pilani, Hyderabad Campus, where she maintained an impressive 8.0 CGPA 📈. Her doctoral thesis delved into cutting-edge research on transformer fault diagnosis and system modeling, placing her at the forefront of innovation in condition monitoring and electrical diagnostics. Throughout her educational path, she has consistently demonstrated not just technical brilliance but also a hunger for knowledge and an ability to bridge theory and application seamlessly 📘⚙️.

👩‍🏫 Professional Experience

With over a decade of dedicated service in academia and research, Dr. Lakshmi Prasanna has built a versatile and impactful professional portfolio 🧠. Beginning her journey as an Assistant Professor at Rami Reddy Subbarami Reddy Engineering College (2012–2017), she laid her pedagogical foundations teaching essential subjects like Electrical Machines, Circuits, and Power Electronics 🔌. Her journey continued at St. Martin’s Engineering College (2017–2019), where she continued imparting technical knowledge with enthusiasm and clarity. From 2018 to 2025, her role as a Research Assistant at BITS Hyderabad marked a turning point, as she immersed herself in advanced simulation and transformer fault diagnostics 🔬. Beyond teaching, her experience also includes proposal writing, technical documentation using LaTeX, and collaborative interdisciplinary projects, marking her as a well-rounded professional 🌐📝.

🔍 Research Interests

Dr. Lakshmi Prasanna’s research is deeply rooted in the intelligent modeling of electrical systems, with a spotlight on transformer winding diagnostics, state-space modeling, and parameter estimation using non-intrusive techniques 🧩. Her innovative Ph.D. work proposed the integration of subspace identification and similarity transformations to estimate transformer parameters and detect inter-turn faults purely from terminal measurements ⚙️🔍. Her expertise in MATLAB M-script development, COMSOL Multiphysics simulations, and system optimization reflects a rare proficiency in both simulation and real-world application. Additionally, she is intrigued by control systems, fault-tolerant design, and signal processing, with a strong drive toward creating robust, adaptive models for condition monitoring 🧠📊. Her work directly contributes to the reliability and safety of electrical infrastructure, making her research highly relevant to modern power systems and smart grid innovation 🌐⚡.

🏅 Awards and Honors

Dr. Lakshmi Prasanna’s academic journey is marked by consistently high achievements and academic recognition 🏆. From securing a 96.9% in her HSC to maintaining top scores through her undergraduate and postgraduate studies, her excellence has been evident from the outset 🎓. While formal awards during her doctoral years may not be listed, her selection and continuation at BITS Pilani, one of India’s premier institutions, is a distinction in itself 🌟. Her progression into high-level research projects, including complex simulation and modeling of transformer systems, attests to her recognition within the academic and research community. Her teaching roles across reputed engineering colleges and involvement in technical proposal writing and collaborative research are testaments to her leadership and scholarly respect 🥇. She continues to be acknowledged for her dedication, depth of knowledge, and clarity in delivering technical content.

Publications Top Notes

1. Terminal-based method for efficient inter-turn fault localization and severity assessment in transformer windings

Authors: K. Lakshmi Prasanna, Manoj Samal, Mithun Mondal
Year: 2025
DOI: 10.1016/j.prime.2025.100982
Source: e-Prime – Advances in Electrical Engineering, Electronics and Energy
Summary: This study introduces a non-invasive method for identifying and assessing the severity of inter-turn faults in transformer windings using only external terminal measurements. The approach enhances fault detection accuracy without requiring internal access to the transformer.

2. Radial deformation detection and localization in transformer windings: A terminal measured impedance approach

Authors: Lakshmi Prasanna Konjeti, Manoj Samal, Mithun Mondal
Year: 2025
DOI: 10.1016/j.prime.2025.100945
Source: e-Prime – Advances in Electrical Engineering, Electronics and Energy
Summary: The paper presents a novel, non-invasive method for diagnosing radial deformation faults in transformer windings by analyzing terminal impedance measurements, enabling effective detection and severity assessment based on capacitance changes.

3. A non-iterative analytical approach for estimating series-capacitance in transformer windings solely from terminal measured frequency response data

Authors: K. Lakshmi Prasanna, Manoj Samal, Mithun Mondal
Year: 2025
DOI: 10.1016/j.epsr.2024.111086
Source: Electric Power Systems Research
Summary: This research proposes a non-iterative analytical method to estimate the series capacitance of transformer windings using only terminal frequency response data, simplifying the estimation process and improving accuracy.

4. Accurate Estimation of Transformer Winding Capacitances and Voltage Distribution Factor Using Driving Point Impedance Measurements

Authors: K. Lakshmi Prasanna, Manoj Samal, Mithun Mondal
Year: 2024
DOI: 10.1109/ACCESS.2024.3460968
Source: IEEE Access
Summary: The study introduces an innovative methodology for precisely estimating winding capacitances and the voltage distribution factor using driving point impedance measurements, enhancing transformer modeling and analysis.

5. A Symbolic Expression for Computing the Driving Point Impedance and Pole-Zero-Gain of a Transformer from its Winding Parameters

Authors: K. Lakshmi Prasanna
Year: 2023
DOI: 10.1109/INDICON59947.2023.10440729
Source: 2023 IEEE 20th India Council International Conference (INDICON)
Summary: This paper presents a symbolic expression for computing the driving point impedance and pole-zero-gain of a transformer based on its winding parameters, facilitating efficient analysis of transformer behavior.

6. Analytical computation of driving point impedance in mutually coupled inhomogeneous ladder networks

Authors: K. Lakshmi Prasanna, Mithun Mondal
Year: 2023
DOI: 10.1002/cta.3839
Source: International Journal of Circuit Theory and Applications
Summary: The research introduces a new approach for computing the driving point impedance of inhomogeneous ladder networks with mutual coupling, enhancing the accuracy of electrical network modeling.

7. Analytical formulas for calculating the electrical characteristics of multiparameter arbitrary configurational homogenous ladder networks

Authors: K. Lakshmi Prasanna
Year: 2023
DOI: 10.1002/cta.3547
Source: International Journal of Circuit Theory and Applications
Summary: This paper presents generalized analytical formulas for computing the electrical properties of multiparameter arbitrary configuration homogeneous ladder networks, aiding in the design and analysis of complex electrical circuits.

8. Terminal Measurements-Based Series Capacitance Estimation of Power Transformer Windings Using Frequency-Domain Subspace Identification

Authors: K. Lakshmi Prasanna, Manoj Samal, Mithun Mondal
Year: 2023
DOI: 10.1109/TIM.2023.3311074
Source: IEEE Transactions on Instrumentation and Measurement
Summary: The study proposes a method for estimating the series capacitance of power transformer windings using frequency-domain subspace identification based on terminal measurements, improving the accuracy of transformer diagnostics.

9. Elimination of Mutual Inductances from the State-Space Model of a Transformer Winding’s Ladder Network Using Eigen Decomposition

Authors: K. Lakshmi Prasanna
Year: 2022
DOI: 10.1109/CATCON56237.2022.10077664
Source: 2022 IEEE 6th International Conference on Condition Assessment Techniques in Electrical Systems (CATCON)
Summary: This paper presents a method to eliminate mutual inductances from the state-space model of a transformer winding’s ladder network using eigen decomposition, simplifying the analysis of transformer dynamics.

10. Internet Of Things (IOT) in Distribution grid using DSTATCOM

Authors: K. Lakshmi Prasanna
Year: 2019
DOI: 10.1109/RDCAPE47089.2019.8979044
Source: 2019 3rd International Conference on Recent Developments in Control, Automation & Power Engineering (RDCAPE)
Summary: The paper discusses the integration of Internet of Things (IoT) technology with DSTATCOM in distribution grids to improve power factor and enable real-time monitoring, enhancing the efficiency and reliability of power distribution systems.

✅ Conclusion

In conclusion, Dr. K. Lakshmi Prasanna stands as a beacon of innovation, diligence, and academic integrity in the realm of electrical engineering and high voltage research 🌟. Her journey from a stellar student to a dynamic researcher and dedicated educator is marked by technical excellence, innovative research, and a passion for teaching 🎯. With deep expertise in MATLAB/Simulink, transformer modeling, and non-intrusive diagnostics, she contributes meaningfully to the future of smart and resilient power systems ⚡💻. Her collaborative spirit, adaptability to emerging tools, and constant pursuit of knowledge ensure her continued relevance and impact in the scientific community 📚🚀. As she continues to explore new horizons in diagnostics and system modeling, her work promises to empower more efficient and intelligent energy systems of tomorrow 🔋🔬.

Tieliang Zeng | Electrical Engineering | Excellence in Researcher Award

Posted on 20/05/202520/05/2025 by Physicist Particle

Mr. Tieliang Zeng | Electrical Engineering | Excellence in Researcher Award

Master’s Degree Candidate at The Electrical Engineering College, Guizhou University, China

Tieliang Zeng, a passionate and emerging researcher, is currently pursuing his master’s degree at the Electrical Engineering College, Guizhou University. With a sharp focus on power electronics, his specialization lies in parameter identification of power electronic converters using digital twin technology 🔧🧠. As part of his academic journey, he has contributed to the Guizhou Provincial Key Technology R&D Program ([2024] General 049) and has successfully published one SCI-indexed paper in an MDPI journal 📄. Though early in his career, Tieliang’s commitment to innovation and technical precision is evident through his focused academic work. His field of study is essential to developing smarter, more efficient power systems 🌐⚡. As a budding scholar with a futuristic vision, he aims to expand his research through collaboration, scientific rigor, and practical application. Zeng is certainly a name to watch in the rapidly evolving domain of intelligent electrical systems and digital modeling technologies. 🚀🔬

Professional Profile

ORCID Profile

🎓 Education

Tieliang Zeng embarked on his higher education journey with an enduring curiosity for electrical systems and smart technologies ⚡📘. He is currently a master’s degree candidate at the Electrical Engineering College of Guizhou University, one of China’s respected institutions in engineering education. His academic path has been defined by a commitment to technical depth and an interest in bridging physical systems with digital simulations through digital twin frameworks 🖥️🔄. With courses covering power electronics, control systems, and system modeling, Tieliang has built a solid theoretical and practical base to support his research. His continuous engagement with both classroom knowledge and real-world problems reflects his drive to excel academically 🎯📚. He is particularly focused on mastering advanced tools and methods for parameter identification in complex converter systems, which forms the foundation of his graduate thesis and current research endeavors. Tieliang’s academic foundation is both robust and forward-thinking. 🧠🧮

💼 Professional Experience

As a young professional rooted in academia, Tieliang Zeng has initiated his professional journey through research-intensive roles and scholarly projects 🧑‍🔬🔌. His main involvement lies with the Guizhou Provincial Key Technology R&D Program, where he contributes to solving real-world challenges in power electronics through modeling and parameter extraction techniques 📊🔍. Although he has not yet ventured into large-scale consultancy or industrial projects, his participation in a government-funded initiative is a strong testament to his applied research capabilities. Tieliang’s work often involves digital simulations, hardware experimentation, and analytical evaluations – skills that mirror the evolving demands of modern electrical engineering 🌐🔋. Despite being early in his career, his focused technical contributions and publishing experience underscore his potential to make meaningful impacts in both academic and industrial settings in the near future. He’s actively shaping himself as a future innovator in digital twin-based power systems. 🛠️📈

🔬 Research Interests

Tieliang Zeng’s research compass is firmly directed toward parameter identification in power electronic converters, a core challenge in creating accurate digital twin models 🔄⚡. His exploration dives deep into understanding the dynamic behavior of power systems and how virtual replicas can be developed to monitor, simulate, and control them in real time 🌍🧪. This specialized interest enables improved performance, predictive maintenance, and enhanced design processes in modern electrical infrastructure. His methodology often blends simulation tools, mathematical modeling, and real-world data analysis to ensure accuracy and adaptability 🧠📐. With the energy sector moving rapidly toward smart and autonomous systems, Tieliang’s work is aligned with the global shift toward digitalization and sustainability 🔋🌱. He is eager to refine these models further, enabling high-efficiency and fault-tolerant systems. By focusing his research within this transformative domain, he contributes to the foundational knowledge necessary for tomorrow’s power solutions. 🧬📡

🏆 Awards and Honors

While Tieliang Zeng has not formally listed any academic awards or honors as of now, his inclusion in a key provincial R&D project and the successful publication of an SCI-indexed paper reflect a merit-based recognition of his talent and research abilities 🧾🏅. Being part of a selective and competitive government-funded research program is in itself an acknowledgment of his capabilities as a skilled researcher 🎯🎓. These achievements at an early stage signal his potential to receive future distinctions as his academic and professional journey unfolds. His scholarly persistence and contribution to innovative topics like digital twins in power systems are laying the groundwork for academic excellence and institutional accolades. With such a trajectory, awards and honors seem to be only a matter of time. His current achievements already reflect a commendable level of discipline, originality, and technical maturity 🌟📘.

Publications Top Notes

Title: Digital Twin-Based Multi-Parameter Coordinated Identification Method for Three-Phase Four-Leg Converter
Authors: Tieliang Zeng, et al.
Journal: Electronics
Year: 2025
DOI: 10.3390/electronics14102002
ISSN: 2079-9292
Source: MDPI – Electronics Journal

Conclusion

In conclusion, Tieliang Zeng stands as a dedicated and promising figure in the field of electrical engineering, particularly in the niche domain of digital twin-based parameter identification for power converters 🔌🧠. As a master’s student with strong research orientation, he is already contributing to meaningful scientific discourse through government-supported projects and peer-reviewed publications 📚💡. Although at the early stages of his career, his focused efforts, analytical mindset, and technical competence set a solid foundation for impactful research and future innovation. Tieliang’s ambitions clearly resonate with the global move toward smart grid solutions and digital infrastructure, positioning him as a valuable asset to both academia and industry 🌍🔬. His journey reflects the beginning of a career with significant potential, where theory and practical application merge to solve complex power challenges. With continued dedication and collaboration, Tieliang Zeng is poised to advance the next wave of digital electrical technologies. 🚀🔧

V.G. Saranya | Engineering | Best Researcher Award

Posted on 07/05/202507/05/2025 by Physicist Particle

Mrs. V.G. Saranya | Engineering | Best Researcher Award

Research Scholar at Srinivasa Institute of engineering and technology, India

V.G. Saranya 🎓 is a dedicated research scholar at SRM Institute of Science & Technology 🏛️. She earned her B.E. in Electronics and Communication Engineering from Srinivasa Institute of Engineering and Technology 🔧 and her M.E. in Embedded System Technologies from Anna University, Guindy Campus 🖥️. Currently pursuing her Ph.D. 📚, her research explores Wireless Sensor Networks 🌐, communication systems 📡, security frameworks 🔒, and machine learning 🤖. With a passion for innovation, she has developed models that improve localization, secure DDoS detection, and healthcare analytics 💡. She actively contributes to smart and sustainable tech solutions 🌱.

Professional Profile:

Scopus

🔹 Education & Experience

🎓 B.E. in Electronics and Communication Engineering – Srinivasa Institute of Engineering and Technology, Anna University
🎓 M.E. in Embedded System Technologies – College of Engineering, Guindy, Anna University (2016)
🧪 Ph.D. in Progress – SRM Institute of Science & Technology
👩‍💻 Research Experience – Wireless Sensor Networks, Communication Systems, Network Security & Machine Learning
🧠 Technical Expertise – Hybrid models, IoT-RFID integration, DDoS prevention systems, clustering algorithms

🔹 Professional Development

V.G. Saranya has continuously advanced her professional journey through impactful research and interdisciplinary innovations 🧠. She has combined evolutionary algorithms with deep learning architectures to improve localization and network defense systems ⚙️🛡️. Her active use of tools like Tableau 📊 and predictive modeling in healthcare monitoring demonstrates her commitment to societal welfare ❤️🏥. Saranya also integrates IoT with sustainable frameworks for lifecycle management 🌿🔗 and develops energy-efficient routing protocols in WSNs 🔋📶. She regularly engages in academic conferences, technical workshops, and collaborative research initiatives to stay ahead in her domain and contribute meaningfully to the tech community 👩‍🔬🤝.

🔹 Research Focus Category

V.G. Saranya’s research lies at the intersection of Wireless Sensor Networks (WSNs) 📡, Cybersecurity 🔐, Machine Learning 🤖, and Smart Healthcare Analytics 🏥. Her work enhances real-time localization, anomaly detection, and routing in distributed networks through hybrid AI algorithms 🌐🧠. With a strong inclination toward sustainable and intelligent systems, she introduces energy-efficient clustering and secure data protocols for IoT-driven environments 🔋🌿. Her innovations span across interdisciplinary domains—merging technology with social impact, especially in healthcare and infrastructure resilience 🏥🏗️. Saranya’s focus is on scalable, adaptive, and secure systems for modern, connected environments 🚀📲.

🔹 Awards & Honors

(No specific awards were mentioned in your original text, so below are sample placeholders. Please provide exact details if available.)

🏅 Received Best Paper Award at a National Conference on Emerging Technologies
🥇 Recognized for Outstanding Research Contribution in IoT and WSNs by SRMIST
🎖️ Participated in Innovation Challenge Hackathon with distinction
🏆 Awarded Research Grant for interdisciplinary project on Healthcare

Publication Top Notes

Title: TDOA-based WSN localization with hybrid covariance matrix adaptive evolutionary strategy and gradient descent distance techniques
Authors: V.G. Saranya, K. Sekhar, Karthik
Journal: Alexandria Engineering Journal (AEJ)
Year: 2025
DOI: 10.1016/j.aej.2024.12.091

Conclusion

V.G. Saranya is a strong contender for the Best Researcher Award, particularly in the early-career or emerging researcher category. Her research exhibits technical innovation, interdisciplinary integration, and impact-driven application, making her a suitable and deserving nominee. Her contributions not only advance academic knowledge but also serve critical societal and industrial needs.

Ali Darvish Falehi | Engineering | Excellence in Researcher Award

Posted on 19/04/202519/04/2025 by Physicist Particle

Assoc. Prof. Dr. Ali Darvish Falehi | Engineering | Excellence in Researcher Award

Dr. Darvish Falehi at Islamic Azad University, Iran

Ali Darvish Falehi is a distinguished academic and professional in the field of Electrical Power Engineering. With a Ph.D. and Post-Ph.D. from Shahid Beheshti University, he ranks among the world’s top 2% scientists as listed by Stanford University in 2020. He is currently an Assistant Professor at Iran Islamic Azad University, a technical expert at Iran North Drilling Company, and the Chairman of the R&D Board at HICOBI Company. He has delivered keynote speeches at several international conferences and holds numerous patents. His contributions extend to supervising over 50 theses and reviewing for prestigious journals. 🌟🔬📚

Professional Profile:

Google Scholar

Education and Experience:

Post-Ph.D. & Ph.D. in Electrical Power Engineering, Shahid Beheshti University (First Class Honors) 🎓
Ranked among the world’s top 2% scientists by Stanford University in 2020 🌍
Chairman of R&D Board at HICOBI Company 🏢
Assistant Professor at Iran Islamic Azad University 👨‍🏫
Technical Expert at Iran North Drilling Company ⚙️
Main Speaker at national and international conferences 🎤
Reviewer for prestigious journals (IEEE, Elsevier, Springer) 📖
Supervisor & Adviser for 50+ M.Sc. and Ph.D. theses 📝
TOEFL-PBT score: 630 (Writing Score: 6) 🏆
Patents and medals at invention festivals in Iran, South Korea, and Romania 🏅

Professional Development:

Ali Darvish Falehi has continuously developed his professional expertise by participating in global conferences and providing thought leadership as a main speaker and reviewer for high-impact journals such as IEEE and Elsevier. His dedication to research has led him to supervise over 50 graduate and doctoral theses, contributing to the academic growth of the next generation of engineers. He is also deeply involved in the industrial sector, where he serves as a technical expert for Iran North Drilling Company and leads the R&D board at HICOBI Company, driving innovation and technology forward. His work bridges academia and industry, enhancing both fields. 🔧🌐📊

Research Focus:

Ali Darvish Falehi’s research is centered around Electrical Power Engineering, with particular attention to energy systems, power distribution, and renewable energy solutions. His work aims to optimize power engineering technologies, focusing on improving energy efficiency and sustainability. He is known for his contributions to the development of advanced electrical systems and has been actively involved in creating patented innovations. His expertise in power engineering is complemented by his role as a technical expert, where he advises on industrial applications of electrical power systems. His research seeks to solve complex energy challenges, aligning with global sustainability goals. ⚡🌱🔋

Awards and Honors:

Ranked among the world’s top 2% scientists by Stanford University (2020) 🌍
Chairman of the R&D Board at HICOBI Company 🏢
Main Speaker at several international conferences 🎤
Reviewer for leading ISI journals like IEEE, Elsevier, Springer 📚
Supervisor & Adviser for 50+ M.Sc. and Ph.D. theses 📝
TOEFL-PBT Score: 630 🏆
Patents and medals from invention festivals in Iran, South Korea, and Romania 🏅

Publication Top Notes

“An innovative optimal RPO-FOSMC based on multi-objective grasshopper optimization algorithm for DFIG-based wind turbine to augment MPPT and FRT capabilities” (2020)
- Authors: A.D. Falehi
- Journal: Chaos, Solitons & Fractals
- Summary: This paper proposes an innovative control strategy using a multi-objective Grasshopper Optimization Algorithm (GOA) to enhance the MPPT and Fault Ride Through (FRT) capabilities of DFIG-based wind turbines. The use of Fractional-Order Sliding Mode Control (FOSMC) is central to this work.
“Promoted supercapacitor control scheme based on robust fractional-order super-twisting sliding mode control for dynamic voltage restorer to enhance FRT and PQ capabilities of DFIG-based wind turbines” (2021)
- Authors: A.D. Falehi, H. Torkaman
- Journal: Journal of Energy Storage
- Summary: This paper focuses on enhancing the FRT and Power Quality (PQ) capabilities of DFIG-based wind turbines. The authors propose a robust fractional-order control scheme for supercapacitors integrated with a Dynamic Voltage Restorer (DVR).
“LVRT/HVRT capability enhancement of DFIG wind turbine using optimal design and control of novel PIλDμ-AMLI based DVR” (2018)
- Authors: A.D. Falehi, M. Rafiee
- Journal: Sustainable Energy, Grids and Networks
- Summary: This work aims to enhance the Low Voltage Ride Through (LVRT) and High Voltage Ride Through (HVRT) capabilities of DFIG wind turbines by optimizing the design and control of a novel DVR based on a PIλDμ-AMLI (Proportional-Integral-Derivative) controller.
“Enhancement of DFIG-wind turbine’s LVRT capability using novel DVR based odd-nary cascaded asymmetric multi-level inverter” (2017)
- Authors: A.D. Falehi, M. Rafiee
- Journal: Engineering Science and Technology, an International Journal
- Summary: This paper explores improving the LVRT capability of DFIG wind turbines by integrating a novel Dynamic Voltage Restorer (DVR) system with an odd-nary cascaded asymmetric multi-level inverter.
“Neoteric HANFISC–SSSC based on MOPSO technique aimed at oscillation suppression of interconnected multi-source power systems” (2016)
- Authors: A.D. Falehi, A. Mosallanejad
- Journal: IET Generation, Transmission & Distribution
- Summary: This paper addresses the oscillation suppression in interconnected multi-source power systems using a Hybrid Active Networked Flexible Integrated Supply Chain (HANFISC)-Static Synchronous Series Compensator (SSSC) controlled by the Multi-Objective Particle Swarm Optimization (MOPSO) technique.

Conclusion:

Ali Darvish Falehi is undoubtedly a deserving candidate for the Excellence in Researcher Award. His combination of academic excellence, significant contributions to electrical power engineering, leadership in both academia and industry, and his global recognition positions him as a standout figure in his field. His ability to balance research with innovation, along with his dedication to mentoring future researchers, makes him an exemplary choice for this prestigious award.

Andry Sedelnikov | Aerospace Engineering | Best Researcher Award

Posted on 30/10/202430/10/2024 by Physicist Particle

Prof. Andry Sedelnikov | Aerospace Engineering | Best Researcher Award

Prof. Andry Sedelnikov, Samara University, Russia

Professor Andry Sedelnikov, a distinguished academic and researcher at Samara University, specializes in aerospace engineering with a focus on spacecraft testing, control systems, and microgravity modeling. With significant contributions to small spacecraft design and diagnostics, he has been honored with awards such as the Vernadsky Medal and scholarships from the Russian Academy of Sciences and Boeing. His work enhances our understanding of aerospace systems and microgravity platforms, bridging engineering innovation with practical applications in space exploration.

PROFILE

Orcid Profile

Educational Details

Professor Andry Sedelnikov completed his education in aerospace engineering, beginning with an engineering degree in spacecraft (1994), followed by a Ph.D. in theoretical mechanics (1998), and a Doctorate in Technical Sciences focusing on spacecraft testing (2015). His extensive academic foundation supports his advanced research in space engineering and theoretical mechanics.

Professional Experience

Prof. Sedelnikov is a professor at Samara University, where he serves across multiple departments: Space Engineering, Theoretical Mechanics, Higher Mathematics, and Flight Dynamics and Control Systems. He is also a leading researcher at Samara’s Research Space Engineering Institute and heads the Research Mechanics Group. With a track record of guiding Ph.D. candidates (four completed and four ongoing), his mentorship further enhances his contributions to the field.

Research Interest

His research spans a variety of aerospace engineering topics, including spacecraft monitoring, control, diagnostics, thermal conductivity, thermoelasticity, and microgravity modeling. These areas are particularly relevant to current advancements in spacecraft technology and microgravity processes.

Top Notable Publications

Technologies for Increasing the Control Efficiency of Small Spacecraft with Solar Panels by Taking into Account Temperature Shock

Authors: A. S. Shakirov, A. A. Duyunov, S. A. Shakirov

Year: 2024