Tag: best engineering award

🎓 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. 🌟

Sławomir Michalak | Engineering | Industry Impact Award

Posted on 18/06/202518/06/2025 by Physicist Particle

Assist. Prof. Dr. Sławomir Michalak | Engineering | Industry Impact Award

Avionics Division Manager at Air Force Institute of Technology, Poland

Prof. Sławomir Michalak, Ph.D., D.Sc. Eng. ✈️, is a distinguished aviation expert whose work bridges academia, defense, and engineering innovation. With decades of experience in avionics systems, aircraft diagnostics, and battlefield electronic warfare systems 🛠️📡, he has led the Avionics Department at the Air Force Institute of Technology since 2001. His pioneering efforts span system integration, reliability assessment, and phonoscopic analysis, influencing modern aviation practices. Michalak is a prolific contributor 📚 with numerous publications and nine recognized implementations. As a mentor and reviewer, he has significantly shaped doctoral and post-doctoral research. He has also educated future aviation professionals 👨‍🏫 at institutions like the Warsaw University of Technology and the SIMP NOT Technical School. Actively involved in national defense research and scientific committees, his legacy resonates across Polish military aviation and beyond 🌍. His commitment to innovation and education makes him a keystone figure in aviation sciences and applied technologies.

Professional Profile

🎓 Education

Dr. Sławomir Michalak’s academic journey 🚀 is deeply rooted in technical aviation sciences, marked by a robust specialization in avionics and aircraft navigation systems. He earned his doctorate in engineering and later achieved the prestigious Doctor of Science (D.Sc.) degree in technical sciences in 2016 🎓, with a concentration on machine construction and operational disciplines. His educational trajectory demonstrates a relentless pursuit of advanced knowledge in complex aircraft systems, enhancing Poland’s aerospace education infrastructure. Moreover, his authorial role in crafting and teaching curricula—especially the subject “Aviation Equipment” approved by Warsaw’s Education Board—reflects a deep commitment to pedagogy. His teaching efforts spanned nearly three decades and included lectures at Warsaw University of Technology’s Faculty of Transport, focusing on Air Navigation 🧭. His foundation in education has not only equipped him with specialized skills but has also enabled him to disseminate that knowledge to future leaders of aviation systems engineering.

💼 Professional Experience

With an illustrious career spanning over three decades, Prof. Michalak has held pivotal roles that define Poland’s aviation research and development landscape ✈️. Since 2001, he has been the head of the Avionics Department at the Air Force Institute of Technology, where he currently serves as a professor 👨‍🔬. His career is marked by excellence in integrating avionics systems, reliability diagnostics, and designing solutions for modern combat operations, including electronic countermeasures 🛡️. He has played a key advisory role in national aviation safety as a long-standing member of the Aircraft Accident Investigation Board, later incorporated into the State Aviation Accident Investigation Board 🕵️. He also lends expertise to the Polish Academy of Sciences’ Transport Committee. Parallelly, he has served as a reviewer and board member for multiple doctoral/post-doctoral theses, as well as contributing to national defense and R&D projects funded by premier agencies like the National Center for Research and Development 💡.

🔬 Research Interests

Prof. Michalak’s research interests are deeply embedded in the critical functionalities of advanced aircraft systems, with a core emphasis on avionics integration and optimization 🚁. His scholarly pursuits center on diagnostics, system reliability, and onboard information processing, including phonoscopic and parametric analysis of flight data recorders 📈🔊. He investigates navigation system integrity, real-time data interpretation, and complex multi-sensor integration essential for military reconnaissance and electronic warfare systems. His innovations directly impact aircraft survivability and mission effectiveness in modern combat environments ⚙️. His work also extends to analyzing flight incident data, enhancing aviation safety and post-mission assessments. Furthermore, his involvement in the Electromobility and Autonomous Transport Section reveals his forward-looking vision in adapting aviation technologies to land-based and autonomous platforms 🚗📡. Through interdisciplinary collaborations and defense-funded projects, his research acts as a crucial bridge between theoretical foundations and operational implementation across aviation and defense sectors.

🏅 Awards and Honors

Though specific award titles are not explicitly listed, Prof. Michalak’s array of achievements reflects a highly decorated academic and technical career 🏆. His recognition stems from the practical impact of nine notable implementation projects that brought real-world improvements in avionics system performance and safety ✨. His invitations to serve on scientific committees, review doctoral works, and lecture at renowned institutions showcase the esteem he holds in academic and defense circles. His prolonged contribution to the Aircraft Accident Investigation Board—spanning eras of structural reorganization—further demonstrates his trusted leadership in critical national aviation oversight roles ✈️. Being part of elite organizations like the Transport Committee of the Polish Academy of Sciences and guiding R&D projects funded by the Ministry of Defense affirms his reputation as a thought leader 🧠. These honors, both formal and implied, are a testament to his sustained excellence and unwavering dedication to enhancing Poland’s aerospace defense and academic frontiers.

📚 Publications Top Note

1. Power Quality in the Context of Aircraft Operational Safety
Authors: Tomasz Tokarski, Sławomir Michalak, Barbara Kaczmarek, Mariusz Zieja, Tomasz Polus
Year: 2025 (Published April 10)
Journal: Energies
DOI: 10.3390/en18081945
Source: Crossref / MDPI
Summary:
This article investigates how power quality, particularly from Ground Power Units (GPUs), affects aircraft operational safety. It focuses on GPUs used by the Polish Armed Forces and highlights how aging equipment (some over 40 years old) leads to degraded performance in transient conditions, contributing to aircraft unserviceability. The paper proposes diagnostic methodologies in line with Polish military standards and emphasizes the need for modern monitoring systems to ensure power reliability.

2. Selected Problems of Determining Pilot Survival Time in Cold Water after the Aircraft Crash
Authors: Przemysław Stężalski, Sławomir Michalak, Jerzy Borowski
Year: 2025 (Published January 17)
Journal: The Polish Journal of Aviation Medicine, Bioengineering and Psychology
DOI: 10.13174/pjambp.17.12.2024.04
Source: Crossref
Summary:
This research introduces a computational model to estimate pilot survival times in cold water following an aircraft crash. Using a thermodynamic body simulation with nonlinear heat transfer equations, the model accounts for factors such as temperature, body mass, clothing, and body position. The output helps in estimating hypothermia onset and unconsciousness time, aiding in rescue and survival strategy development.

3. The Effect of the Operation Time of the Aircraft Power System on Power Quality in Transient States
Authors: Not explicitly listed (likely includes Tomasz Tokarski and/or Sławomir Michalak)
Year: 2024 (Published March 29)
Journal: Journal of Konbin
DOI: 10.5604/01.3001.0054.4462
Source: Crossref
Summary:
The paper examines how long-term use and aging of aircraft power systems impact power quality, especially during transient events such as engine starts or system switches. It shows that older systems cause higher voltage deviations and fluctuations, compromising avionics performance and reliability. The findings support the importance of upgrading aging infrastructure to maintain operational integrity.

4. The Overview of Ecologic Military and Civilian Power Systems
Authors: Not specified
Year: 2024 (Published March 29)
Journal: Journal of Konbin
DOI: 10.5604/01.3001.0054.4461
Source: Crossref
Summary:
This review paper presents current trends in environmentally friendly power systems used in both civilian and military aviation. It discusses energy-efficient GPU technologies, emission reduction strategies, and renewable energy integration, underlining how ecological considerations are increasingly shaping power system design without sacrificing reliability and performance.

5. The Polish Helmet Mounted Display Systems for Military Helicopters
Author: Sławomir Michalak
Year: 2016 (June)
Conference: 2016 IEEE Metrology for Aerospace (MetroAeroSpace)
DOI: 10.1109/metroaerospace.2016.7573240
Source: Crossref
Summary:
The paper discusses development, features, and performance evaluation of Polish helmet-mounted display systems for military helicopter pilots. It includes metrological approaches for assessing system reliability and precision in dynamic environments.

6. Metrology Tools of Computer Communication Control on Board Military Aircraft
Author: Sławomir Michalak
Year: 2015
Journal: Przeglad Elektrotechniczny
DOI: 10.15199/48.2015.08.13
Source: Scopus / Crossref
Summary:
This article covers the development of metrology tools designed to monitor and control server communications onboard military helicopters. The study emphasizes reliability and diagnostic accuracy in harsh operational environments.

7. AFIT’s Laboratory Test Equipment to Optimise the Integrated Avionics Systems for Polish Military Aircrafts
Author: Sławomir Michalak
Year: 2014 (May)
Conference: 2014 IEEE Metrology for Aerospace (MetroAeroSpace)
DOI: 10.1109/metroaerospace.2014.6865904
Source: Crossref
Summary:
The study describes laboratory instrumentation developed by AFIT to test and optimize avionics systems in Polish military aircraft. It focuses on system integration, fault simulation, and metrological evaluation.

8. AFIT’s Laboratory Test Equipment to Optimise the Integrated Communication Systems for Polish Military Helicopters
Author: Sławomir Michalak
Year: 2014 (May)
Conference: 2014 IEEE Metrology for Aerospace (MetroAeroSpace)
DOI: 10.1109/metroaerospace.2014.6865949
Source: Crossref
Summary:
This paper presents laboratory tools developed for assessing and refining communication systems in military helicopters. The research highlights signal integrity testing and communication protocol validation in simulated airborne conditions.

9. Computer Aided Diagnosis of Technical Condition of the SWLP-1 Helmet Mounted Flight Parameters Display System
Author: Sławomir Michalak
Year: 2014
Journal: Journal of KONBiN
DOI: 10.2478/jok-2014-0025
Source: Crossref
Summary:
The paper introduces a computer-based diagnostic system for evaluating the SWLP-1 helmet display used in flight operations. It supports preventive maintenance through automated fault detection and performance assessment.

10. Nahełmowy System Celowniczy NSC-1 Orion dla Polskich Śmigłowców Wojskowych
Author: Sławomir Michalak
Year: 2013
Journal: Scientific Letters of Rzeszow University of Technology – Mechanics
DOI: 10.7862/rm.2013.30
Source: Crossref
Summary:
This Polish-language article covers the NSC-1 Orion helmet-mounted sighting system, developed for Polish military helicopters. It details its targeting features, integration with aircraft systems, and effectiveness in operational scenarios.

🔚 Conclusion

Prof. Sławomir Michalak stands out as a trailblazer in aviation science, with his influence permeating research, defense, and education 🌐. His technical command in avionics, experience in accident investigation, and commitment to academic excellence place him among Poland’s most respected aerospace experts 🚀. From developing navigation systems to interpreting flight data and advising national safety boards, his work has safeguarded lives and advanced technologies alike. His three-decade-long dedication to instructing young minds and contributing to global conferences reflects his dual passion for knowledge dissemination and innovation 💬📘. As a visionary integrating evolving avionics with real-time diagnostics and battlefield adaptability, he exemplifies the ideal intersection of theory and application 🛫. With continued contributions to autonomous systems and electromobility, Michalak remains not only a legacy figure in aerospace engineering but also a forward-thinker shaping its future. His professional journey is a compelling blueprint for excellence, innovation, and impactful service 💡🎖️.

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

📚 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 🔋🔬.

Prof. Dr. Jian Chen | Engineering | Best Researcher Award

Posted on 21/05/202521/05/2025 by Physicist Particle

Prof. Dr. Jian Chen | Engineering | Best Researcher Award

Associate Researcher at Changchun Institute of Optics, Fine Mechanics and Physics, Chinese Academy of Sciences, China

Dr. Jian Chen 🎓, an accomplished Associate Research Fellow at the Changchun Institute of Optics, Fine Mechanics and Physics, Chinese Academy of Sciences 🏛️, brings over 20 years of rigorous academic and professional experience. With a steadfast foundation in Communication Engineering and a doctorate in Mechanical and Electrical Engineering, Dr. Chen has contributed extensively to the scientific community 📚. His scholarly portfolio includes 39 academic articles, 3 granted patents 🧠🔧, and active participation as an editorial board member and reviewer for 25 prominent journals, including SCI and EI indexed publications 🌐. His consistent commitment to research, innovation, and peer-review excellence marks him as a dedicated scholar in the field of optics and fine mechanics. His career trajectory is a testimony to persistence, insight, and global scientific collaboration 🌟.

Professional Profile

ORCID Profile

🎓 Education

Dr. Jian Chen’s academic journey 🌱 began at Jilin University, where he pursued both his Bachelor’s (2001–2005) and Master’s (2005–2007) degrees in Communication Engineering 🛰️. Driven by a passion for applied science, he later obtained his Doctorate in Mechanical and Electrical Engineering from the University of Chinese Academy of Sciences (2011–2014) ⚙️. His studies reflect a rare combination of precision communication systems and multi-disciplinary engineering expertise 🧠. This robust academic progression laid the intellectual groundwork for his future research in optics, electromechanics, and fine instrumentation. The strong theoretical foundations combined with practical insight enabled him to tackle cutting-edge challenges in optics and engineering technologies with a holistic mindset 📘🔬.

🧑‍🔬 Professional Experience

Since 2007, Jian Chen has served as an Associate Research Fellow at the prestigious Changchun Institute of Optics, Fine Mechanics and Physics, CAS 🏢. Over 14 years, he has cultivated deep expertise in electromechanical systems, optical instrumentation, and advanced mechanics 💡. His work is not just academic; it holds tangible value, evidenced by his 3 granted patents 🔍📑. Dr. Chen also stands out as a peer-review gatekeeper—serving on the editorial boards of 25 respected journals, including those indexed by SCI and EI 🧾📖. His research environment fosters both independent innovation and collaborative exploration, positioning him as a central contributor to China’s optics and precision mechanics research domain 🔧🌍.

🔬 Research Interest

Jian Chen’s research interests orbit around the convergence of optics, mechanical design, and electrical systems 🔭⚙️. His studies delve into fine optical mechanics, signal processing, and advanced instrumentation, where accuracy meets innovation 💡🔧. He has a keen focus on integrating communication systems with mechanical-electrical interfaces, aiming to improve efficiency, precision, and reliability across applied research platforms 📡🔍. Through over 39 academic publications and patent filings, he continually addresses real-world problems with scientifically grounded solutions. His passion lies in turning theoretical concepts into functional technologies, especially those impacting optics and information transfer systems 🚀. Dr. Chen’s vision includes pushing boundaries in smart optical devices and advancing China’s high-tech research infrastructure 📈.

🏆 Award and Honor

With a track record of consistent scholarly output, Jian Chen has earned high regard in his field 🌟. His appointment as an Editorial Board Member and reviewer for 25 journals, including SCI and EI indexed ones 🏅📘, speaks volumes about his recognition in the global academic community. This role is both prestigious and demanding, requiring sharp insight, peer leadership, and deep subject-matter expertise 🧠✒️. The successful granting of 3 patents in his field further confirms his inventive spirit and commitment to practical innovation. While specific awards are not listed, the honors bestowed upon him through editorial responsibilities, patents, and research publications reflect a career shaped by excellence, discipline, and global relevance 🧬🕊️.

Publications Top Notes

1. Multihop Anchor-Free Network With Tolerance-Adjustable Measure for Infrared Tiny Target Detection

Journal: IEEE Transactions on Instrumentation and Measurement
Year: 2025
DOI: 10.1109/TIM.2025.3545998

This paper introduces a multihop anchor-free network designed to detect tiny infrared targets in complex backgrounds. The proposed method employs a tolerance-adjustable measure to enhance detection accuracy without relying on predefined anchor points. This approach improves the detection of small targets that are easily obscured by background noise.

2. A Novel Equivalent Combined Control Architecture for Electro-Optical Equipment: Performance and Robustness

Journal: Applied Sciences
Publication Date: August 1, 2024
DOI: 10.3390/app14156708

This study proposes a novel equivalent composite control structure for electro-optical equipment. The architecture aims to balance tracking performance and robustness by adjusting the time coefficient of the compensation loop. The paper analyzes the impact of this adjustment on system dynamics, providing insights into optimizing performance without compromising stability.

3. CA-U2-Net: Contour Detection and Attention in U2-Net for Infrared Dim and Small Target Detection

Journal: IEEE Access
Year: 2023
DOI: 10.1109/ACCESS.2023.3305942

This paper presents CA-U2-Net, an enhanced version of U2-Net tailored for detecting infrared dim and small targets. By integrating contour detection and attention mechanisms, the model achieves a detection rate of 97.17%, maintaining accurate target shapes even in challenging conditions.

4. A POCS Super Resolution Restoration Algorithm Based on BM3D

Journal: Scientific Reports
Publication Date: November 8, 2017
DOI: 10.1038/s41598-017-15273-0

This research combines the Projection Onto Convex Sets (POCS) method with BM3D filtering to enhance super-resolution image restoration. The approach addresses the noise sensitivity of traditional POCS by incorporating BM3D’s denoising capabilities, resulting in improved restoration quality for low-resolution images affected by various noise types.

🧾 Conclusion

Dr. Jian Chen’s career is a synthesis of academic strength, research innovation, and peer leadership 📚🌟. From earning degrees in communication and electromechanical engineering to publishing influential papers and contributing patented solutions, his journey underscores a rare dedication to the advancement of science and technology 🌐. His service as a reviewer and editor across 25 journals illustrates not only his expertise but also the respect he commands among peers. Jian Chen exemplifies what it means to be a scholar-practitioner—someone who not only explores ideas but also brings them to life 🔬💡. With two decades of impact in optics and mechanical systems, his legacy is both intellectual and tangible, influencing future researchers and technologies across the globe 🌏📈.

Ehsan Adibnia | Engineering | Best Academic Researcher Award

Posted on 24/04/202524/04/2025 by Physicist Particle

Dr. Ehsan Adibnia | Engineering | Best Academic Researcher Award

Dr. Ehsan Adibnia at University of Sistan and Baluchestan, Iran

Dr. Ehsan Adibnia 🎓 is a dedicated academic researcher in electrical engineering ⚡, specializing in cutting-edge fields such as artificial intelligence 🤖, machine learning 📊, deep learning 🧠, nanophotonics 💡, optics 🔬, and plasmonics ✨. He is proficient in Python 🐍, MATLAB 🧮, and Visual Basic, and utilizes simulation tools like Lumerical 📈, COMSOL 🧪, and RSoft 🔧 to drive innovative research. Fluent in English 🇬🇧 and Persian 🇮🇷, Dr. Adibnia contributes to academic conferences and peer-reviewed journals 📚. He is currently pursuing his Ph.D. and actively engaged in interdisciplinary scientific exploration 🌐.

Professional Profile:

🔹 Education & Experience

🎓 Ph.D. in Electrical Engineering – University of Sistan and Baluchestan, Zahedan, Iran (Expected 2025)
🎓 B.S. in Electrical Engineering – University of Sistan and Baluchestan, Zahedan, Iran (2014)
🧑‍💼 Executive Committee Member – 27th Iranian Conference on Optics and Photonics & 13th Conference on Photonic Engineering and Technology
🖋️ Assistant Editor – International Journal (Name not specified)
🔍 Researcher – Actively engaged in interdisciplinary AI & photonics research projects

🔹 Professional Development

Dr. Ehsan Adibnia continually enhances his professional growth through active participation in conferences 🧑‍🏫, committee leadership 🗂️, and editorial work 📑. He develops algorithms and conducts simulations using advanced tools such as Lumerical 🔬, COMSOL 🧪, and RSoft 💻. His expertise in AI and photonics drives innovative research and collaboration 🌍. He also hones his programming skills in MATLAB 🧮, Python 🐍, and VBA 🧠, ensuring precision in modeling and data analysis. His hands-on knowledge in PLC systems 🤖 and industrial automation makes him versatile across both academic and applied research settings 🏭.

🔹 Research Focus

Dr. Adibnia’s research focuses on the fusion of artificial intelligence 🤖 and photonics 💡. His work explores machine learning 📊, deep learning 🧠, nanophotonics 🔬, plasmonics ✨, optical switching 🔁, and slow light 🐢 technologies. He is particularly interested in leveraging these technologies in biosensors 🧫, metamaterials 🔷, and quantum optics ⚛️. Through simulation and algorithm development, he aims to optimize performance in optoelectronic and photonic systems 🔍. His interdisciplinary research bridges electrical engineering with physics and AI, creating advanced systems for diagnostics, sensing, and smart environments 🌐.

🔹 Awards & Honors

🏅 Executive Committee Role – 27th Iranian Conference on Optics and Photonics
🏅 Executive Committee Role – 13th Iranian Conference on Photonic Engineering and Technology
📜 Assistant Editor – International scientific journal (name not specified)
🧠 Scopus-indexed Researcher – Scopus ID: 58485414000

Publication Top Notes

🔹 High-performance and compact photonic crystal channel drop filter using P-shaped ring resonator

Journal: Results in Optics
Date: Dec 2025
DOI: 10.1016/j.rio.2025.100817
Summary: Proposes a novel P-shaped ring resonator design for channel drop filters in photonic crystal structures. Focuses on achieving high performance in terms of compactness and spectral selectivity for integrated optical circuits.

🔹 Optimizing Few-Mode Erbium-Doped Fiber Amplifiers for high-capacity optical networks using a multi-objective optimization algorithm

Journal: Optical Fiber Technology
Date: Sep 2025
DOI: 10.1016/j.yofte.2025.104186
Summary: Introduces a multi-objective optimization approach for designing few-mode EDFAs, targeting performance improvements in next-gen high-capacity optical networks.

🔹 Inverse design of octagonal plasmonic structure for switching using deep learning

Journal: Results in Physics
Date: Apr 2025
DOI: 10.1016/j.rinp.2025.108197
Summary: Utilizes deep learning for the inverse design of an octagonal plasmonic structure used in optical switching, demonstrating enhanced precision and compact design capability.

🔹 Chirped apodized fiber Bragg gratings inverse design via deep learning

Journal: Optics & Laser Technology
Date: 2025
DOI: 10.1016/J.OPTLASTEC.2024.111766
WOS UID: WOS:001311493000001
Summary: Applies deep learning to the inverse design of chirped apodized fiber Bragg gratings, optimizing the spectral characteristics for filtering and sensing applications.

🔹 Inverse Design of FBG-Based Optical Filters Using Deep Learning: A Hybrid CNN-MLP Approach

Journal: Journal of Lightwave Technology
Date: 2025
DOI: 10.1109/JLT.2025.3534275
Summary: Proposes a hybrid CNN-MLP architecture to design fiber Bragg grating (FBG) optical filters, improving accuracy and speed in the inverse design process using deep learning techniques.

Conclusion

Dr. Adibnia is still in the process of completing his Ph.D., his broad technical expertise, multidisciplinary research focus, early academic leadership roles, and active participation in both national and international platforms make him a highly promising candidate for the Best Academic Researcher Award in the early-career researcher or emerging researcher category.

Shirko Faroughi | Engineering | Best Researcher Award

Posted on 29/03/202529/03/2025 by Physicist Particle

Prof. Shirko Faroughi | Engineering | Best Researcher Award

Academic at Urmia University of Technoloy, Iran

Dr. Shirko Faroughi, an esteemed Professor of Mechanical Engineering at Urmia University of Technology, Iran, specializes in Computational Mechanics, Isogeometric Analysis, and Finite Element Methods. With a Ph.D. from Iran University of Science and Technology, he has held research positions at KTH University (Sweden), Swansea University (UK), and Bauhaus University Weimar (Germany). His work spans fracture mechanics, machine learning, and 3D printing simulations. As a CICOPS Scholar at the University of Pavia, Italy, Dr. Faroughi actively collaborates on international research projects, contributing significantly to advanced numerical methods. 📚🌍

Professional Profile:

Education & Experience 🎓📜

Ph.D. in Mechanical Engineering (2010) – Iran University of Science and Technology 🏛️
M.S. in Mechanical Engineering (2005) – Iran University of Science and Technology 🏗️
B.S. in Mechanical Engineering (2003) – Tabriz University 🚗

🔹 Academic Roles

Professor (2020 – Present) – Urmia University of Technology 👨‍🏫
Associate Professor (2015 – 2020) – Urmia University of Technology 🔬
Assistant Professor (2011 – 2015) – Urmia University of Technology 📖
Visiting Researcher (2008 – 2009) – KTH University, Sweden 🇸🇪

🔹 Administrative & International Positions

Dean of Mechanical Engineering Department (2022 – Present) 🏢
CICOPS Scholar – University of Pavia, Italy (2022) 🇮🇹
Research Collaborator – Swansea University, UK (2015 – Present) 🇬🇧
Research Collaborator – New Mexico State University, USA (2016 – Present) 🇺🇸
Research Collaborator – Bauhaus University Weimar, Germany (2017 – Present) 🇩🇪

Professional Development 🌍📚

Dr. Shirko Faroughi has made remarkable contributions to mechanical engineering through computational mechanics, finite element analysis, and machine learning. His research advances superconvergent mass and stiffness matrices, isogeometric methods, phase-field methods, and energy harvesting. He also integrates AI-driven techniques to enhance engineering simulations. His collaborations span Europe and the U.S., working with top researchers on thin structures, 3D printing, and structural dynamics. As a department dean and international collaborator, he plays a pivotal role in engineering education and research innovations, fostering global academic partnerships. 🌎💡

Research Focus 🔍🧠

Dr. Faroughi’s research primarily revolves around Computational Mechanics and Advanced Numerical Methods, integrating Artificial Intelligence and Machine Learning for engineering applications. His work focuses on:

Superconvergent mass and stiffness matrices 📐🔬
Isogeometric and finite element methods 🏗️📊
Fracture mechanics and phase-field modeling 🏚️💥
Tensegrity structures and energy harvesting ⚡🔩
Machine learning and transfer learning in mechanical simulations 🤖📈
3D printing simulations and advanced material modeling 🖨️🧩

His research bridges traditional mechanical engineering with AI and computational techniques, pushing engineering boundaries through innovative numerical simulations. 🚀🔢

Awards & Honors 🏆🎖️

CICOPS Scholarship – University of Pavia, Italy (2022) 🇮🇹
Visiting Researcher – KTH University, Sweden (2008-2009) 🇸🇪
Research Collaborator – Swansea University, UK (2015-Present) 🇬🇧
Research Collaborator – Bauhaus University Weimar, Germany (2017-Present) 🇩🇪
Research Collaborator – New Mexico State University, USA (2016-Present) 🇺🇸
Dean of Mechanical Engineering Department – Urmia University of Technology (2022-Present) 🏛️
Multiple Grants for Advanced Computational Mechanics Research 🎓🔍

Publication Top Notes

Wave Propagation in 2D Functionally Graded Porous Rotating Nano-Beams
- Authors: S. Faroughi, A. Rahmani, M.I. Friswell
- Published in Applied Mathematical Modelling (2020)
- Citations: 71
- Focus: Investigates wave propagation in porous nano-beams using a general nonlocal higher-order beam theory, considering functionally graded materials and rotation effects.
Vibration of 2D Imperfect Functionally Graded Porous Rotating Nanobeams
- Authors: A. Rahmani, S. Faroughi, M.I. Friswell
- Published in Mechanical Systems and Signal Processing (2020)
- Citations: 54
- Focus: Examines vibration behavior of imperfect functionally graded porous rotating nanobeams based on a generalized nonlocal theory.
Non-linear Dynamic Analysis of Tensegrity Structures Using a Co-Rotational Method
- Authors: S. Faroughi, H.H. Khodaparast, M.I. Friswell
- Published in International Journal of Non-Linear Mechanics (2015)
- Citations: 47
- Focus: Develops a co-rotational method for analyzing nonlinear dynamics of tensegrity structures.
Physics-Informed Neural Networks for Solute Transport in Heterogeneous Porous Media
- Authors: S.A. Faroughi, R. Soltanmohammadi, P. Datta, S.K. Mahjour, S. Faroughi
- Published in Mathematics (2023)
- Citations: 40
- Focus: Uses physics-informed neural networks (PINNs) with periodic activation functions to model solute transport in heterogeneous porous media.
Nonlinear Transient Vibration of Viscoelastic Plates Using a NURBS-Based Isogeometric HSDT Approach
- Authors: E. Shafei, S. Faroughi, T. Rabczuk
- Published in Computers & Mathematics with Applications (2021)
- Citations: 30
- Focus: Investigates nonlinear transient vibrations of viscoelastic plates using an isogeometric high-order shear deformation theory (HSDT) approach.

Mahmood Shakiba | Engineering | Best Researcher Award

Posted on 20/03/202520/03/2025 by Physicist Particle

Assist. Prof. Dr. Mahmood Shakiba | Engineering | Best Researcher Award

Faculty member at Ferdowsi University of Mashhad, Iran

Dr. mahmood shakiba 🇮🇷 is an assistant professor at Ferdowsi University of Mashhad, specializing in petroleum engineering with expertise in hydrocarbon reservoirs and enhanced oil recovery (EOR) 🛢️. He earned his Ph.D. from Amirkabir University of Technology (2020) 🎓, focusing on nano-assisted smart water for sand production control. With extensive experience in CO₂ and H₂ underground storage projects, reservoir characterization, and formation damage remediation, he has held key academic and industrial roles. As a researcher and educator, he has contributed significantly to petroleum engineering, guiding students and leading innovative studies in reservoir engineering and geomechanics 🔬📚.

Professional Profile

Education & Experience

Education 🎓

✅ Ph.D. in Petroleum Engineering (Hydrocarbon Reservoirs), Amirkabir University of Technology (2016-2020)

Thesis: Nano-assisted smart water for sand production in unconsolidated sandstone reservoirs.

✅ M.Sc. in Petroleum Engineering (Hydrocarbon Reservoirs), Shiraz University (2012-2014)

Thesis: Enhanced oil recovery & CO₂ storage via carbonated water injection.

✅ B.Sc. in Petroleum Engineering (Reservoir Engineering), Shiraz University (2008-2012)

Thesis: Simulation of solution gas drive in fractured reservoirs.

Work Experience 🛠️

🔹 Assistant Professor – Ferdowsi University of Mashhad (2023-Present)
🔹 Project Supervisor – Underground CO₂ Storage (2023-Present)
🔹 Researcher – Underground H₂ Storage, RIPI (2023-Present)
🔹 Technical Manager – Upstream Oil Research Center, Sharif University (2020-2022)
🔹 Technical Supervisor – MAPSA Co., Tehran (2019-2020)
🔹 Industrial Consultant – MAPSA Co., Tehran (2019-2020)
🔹 Senior Lab Equipment Designer – MAPSA Co., Tehran (2018-2019)
🔹 Researcher – Advanced EOR Research Center, Shiraz University (2011-2014)

Professional Development 🌟

Dr. mahmood shakiba has significantly contributed to petroleum engineering through teaching, research, and industrial consulting 📖🔬. His expertise spans reservoir engineering, well testing, and gas reservoirs 🚀. At Ferdowsi University, he educates students on reservoir management and maintenance, while leading projects on underground CO₂ and H₂ storage. His industry experience includes technical supervision, reservoir characterization, and EOR techniques 🏭. Dr. shakiba has also played a key role in laboratory equipment design and geomechanical feasibility studies. His dedication to advancing sustainable energy storage and petroleum recovery has established him as a leader in the field 🌍💡.

Research Focus 🔬

Dr. shakiba’s research primarily focuses on enhanced oil recovery (EOR), underground storage of CO₂ and H₂, and reservoir geomechanics 🏗️. His experimental and simulation studies have explored innovative methods for improving oil recovery and mitigating environmental impact 🌱. He has investigated nano-assisted smart water flooding, formation damage remediation, and CO₂ sequestration to optimize hydrocarbon reservoir performance. His geological and geomechanical feasibility studies have contributed to safe underground hydrogen storage ⚡. His work advances sustainable energy solutions while improving oil and gas recovery efficiency for the future 🌍🔋.

Awards & Honors 🏆

🏅 Technical Leadership Award – Upstream Oil Research Center, Sharif University
🏅 Outstanding Research Contribution – Research Institute of Petroleum Industry (RIPI)
🏅 Best Thesis Award – Amirkabir University of Technology (2020)
🏅 Top Researcher Recognition – Shiraz University EOR Research Center
🏅 Best Instructor Award – Ferdowsi University of Mashhad (2023)

Publication Top Notes

Investigation of oil recovery and CO₂ storage during secondary and tertiary injection of carbonated water in an Iranian carbonate oil reservoir
- Journal of Petroleum Science and Engineering (2016)
- Citations: 79
- Examines how carbonated water injection (CWI) enhances oil recovery and CO₂ storage efficiency in carbonate reservoirs under secondary and tertiary injection scenarios.
A mechanistic study of smart water injection in the presence of nanoparticles for sand production control in unconsolidated sandstone reservoirs
- Journal of Molecular Liquids (2020)
- Citations: 35
- Investigates how smart water, combined with nanoparticles, helps mitigate sand production in weakly consolidated sandstone reservoirs while improving oil recovery.
The impact of connate water saturation and salinity on oil recovery and CO₂ storage capacity during carbonated water injection in carbonate rock
- Chinese Journal of Chemical Engineering (2019)
- Citations: 29
- Analyzes how variations in connate water saturation and salinity influence oil displacement efficiency and CO₂ trapping during CWI in carbonate formations.
Effects of type and distribution of clay minerals on the physico-chemical and geomechanical properties of engineered porous rocks
- Scientific Reports (2023)
- Citations: 21* (recently published)
- Studies how different clay minerals affect the structural integrity and chemical behavior of engineered porous rocks, impacting reservoir performance.
An experimental insight into the influence of sand grain size distribution on the petrophysical and geomechanical properties of artificially made sandstones
- Journal of Petroleum Science and Engineering (2022)
- Citations: 15
- Explores the role of sand grain size variations in determining the permeability, porosity, and mechanical strength of artificial sandstone samples.

Zhou Zhiwu | Engineering | Best Researcher Award

Posted on 20/03/202520/03/2025 by Physicist Particle

Assoc. Prof. Dr. Zhou Zhiwu | Engineering | Best Researcher Award

School of Civil and Environmental Engineering at Hunan University of Science and Engineering, China

Zhou zhiwu, a senior engineer and registered tester, is an associate professor and master’s supervisor at hunan university of science and engineering. he earned his ph.d. in transportation infrastructure and territory from the polytechnic university of valencia (🇪🇸) with top honors, including the UPV Outstanding Doctorate and the 2023 Spanish Outstanding Doctoral Award 🏆. with 15 years in national engineering projects, he has led major constructions, published 28 research papers 📄, and serves as a reviewer for 20 SCI journals. his expertise spans (ancient) bridge monitoring, high-speed railway track optimization, and sustainable structural design.

Professional Profile