Weimin Xu | Engineering | Best Researcher Award

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Mr. Weimin Xu | Engineering | Best Researcher Award 

Associate professor, at Shanghai Maritime University, China.

Dr. Weimin Xu, Ph.D., is an accomplished associate professor specializing in Control Science and Engineering. 🎓 With a career spanning over three decades, Dr. Xu earned his bachelor’s degree in Automation from Northeastern University, China, in 1985, followed by a master’s in 1992 and a Ph.D. in 1997 from the same institution. He has been actively contributing to academia and research at Shanghai Maritime University since 2009. In 2013, he further enriched his academic exposure through a one-year visiting research program at the University of Southern California 🇺🇸. Dr. Xu’s expertise lies in nonlinear systems, adaptive and intelligent control, and robotics. 🤖 He has authored over 30 academic papers and holds more than 20 invention patents. His work significantly impacts robotics and intelligent systems, blending theoretical foundations with practical applications in automation and control.

Professional Profile

Scopus

🎓 Education 

Dr. Weimin Xu pursued all his academic qualifications from Northeastern University, China. He began with a Bachelor’s degree in Automation in 1985, where he gained foundational knowledge in electrical and mechanical systems. With a growing interest in system dynamics and process automation, he continued his studies at the same university, earning a Master’s degree in Control Science and Engineering in 1992. Driven by a deep curiosity about system behavior and advanced control theories, he completed his Ph.D. in Control Science and Engineering in 1997. 🧠 His doctoral research laid the groundwork for his current expertise in nonlinear and intelligent control systems. Later, in 2013, Dr. Xu broadened his international academic horizon through a one-year visiting research program at the University of Southern California, where he collaborated with global experts and explored modern advancements in robotics and adaptive control. 🌐

👨‍🏫 Experience 

Dr. Xu began his professional journey in academia shortly after completing his Ph.D. in 1997. His early career involved contributing to control engineering projects and mentoring students at various institutions. Since 2009, he has been serving as a faculty member at Shanghai Maritime University, actively involved in teaching, supervising graduate students, and leading advanced research in control systems. 🏫 His academic responsibilities are complemented by hands-on research in intelligent systems and automation. In 2013, he was a visiting scholar at the University of Southern California, a pivotal experience that allowed him to engage with cutting-edge research and collaborate internationally. Over the years, Dr. Xu has become a recognized expert in the control and automation field, integrating theoretical knowledge with real-world applications in robotics, crane systems, and intelligent automation. ⚙️ His contributions have significantly enhanced the university’s research capabilities in engineering and intelligent control.

🔍 Research Interests 

Dr. Xu’s research explores the dynamic landscape of control theory and intelligent systems. His key focus areas include nonlinear system theory, adaptive control, and sliding mode control—each critical for understanding and controlling complex engineering systems. ⚙️ He is particularly passionate about robot manipulator control, where precision and adaptability are essential. In addition, Dr. Xu’s work delves into bridge crane state detection and intelligent control, reflecting his commitment to real-world industrial applications. 🚢 His research often integrates classical control methodologies with modern AI techniques, creating intelligent, robust, and adaptive control strategies. Dr. Xu continually investigates how automation can enhance operational efficiency and safety in engineering systems. 🤖 His innovative approaches aim to bridge the gap between control theory and practice, ultimately improving the reliability and intelligence of machinery across various sectors.

🏅 Awards 

Throughout his academic career, Dr. Xu has received multiple awards and recognitions that highlight his contributions to control engineering and intelligent systems. 🏆 His work on bridge crane detection and robotic control has earned accolades for both innovation and practical relevance. With more than 20 authorized invention patents, many of which focus on automation and intelligent detection, Dr. Xu’s inventive spirit has been consistently celebrated at national and institutional levels. 🇨🇳 He has also been recognized for excellence in research and teaching at Shanghai Maritime University, where he has played a pivotal role in advancing engineering education. His dedication to integrating cutting-edge research into student learning and real-world applications has made him a valuable mentor and leader. Dr. Xu’s achievements are a testament to his commitment to continuous innovation and the impactful dissemination of knowledge in the engineering community. 📘

📚 Top Noted Publications 

Dr. Xu has published over 30 peer-reviewed academic papers, contributing significantly to nonlinear systems and intelligent control. His research is widely cited, reflecting his influence in the academic community. 📖 Some of his representative publications include:

1. Xu, W., et al. (2021)

Title: Adaptive Sliding Mode Control for Robot Manipulators with Input Nonlinearity
Journal: Robotics and Autonomous Systems
Citations: 45

Summary:
This paper presents an adaptive sliding mode control (ASMC) approach designed specifically for robot manipulators with significant input nonlinearities such as dead zones and input saturation. The authors develop a robust controller that adapts in real time to system uncertainties and unmodeled dynamics while preserving stability and convergence.

Key Contributions:

  • A novel ASMC framework incorporating adaptive laws to handle unknown input nonlinearities.

  • Lyapunov-based stability analysis ensures system convergence.

  • Simulation and experimental results on a 2-DOF manipulator show improved trajectory tracking and robustness compared to traditional SMC.

Impact:
Widely cited for its robustness in dealing with non-ideal actuator behavior in robotics applications.

2. Xu, W., et al. (2020)

Title: Intelligent Control of Bridge Crane Based on Sensor Fusion and Neural Networks
Conference: IEEE Conference on Control and Automation
Citations: 30

Summary:
This work proposes an intelligent control strategy for bridge cranes using a combination of sensor fusion (gyroscopes, vision, encoders) and neural network-based control algorithms. The aim is to reduce swing and improve payload accuracy during transport.

Key Contributions:

  • Development of a sensor fusion algorithm to accurately estimate the payload position and velocity.

  • Neural networks are trained to mimic optimal control behavior under different load conditions.

  • Simulation and real-time experiments confirm the effectiveness in swing suppression and trajectory accuracy.

Impact:
Recognized for advancing automation in industrial lifting systems using AI-based techniques.

3. Xu, W., et al. (2019)

Title: Nonlinear Adaptive Control with Observer for Uncertain Systems
Journal: Wireless Networks
Citations: 28

Summary:
This paper addresses the control of nonlinear uncertain systems using a nonlinear adaptive control scheme combined with an observer design to estimate unmeasurable states. The focus is on wireless-enabled systems with uncertain parameters and delays.

Key Contributions:

  • Design of a state observer for nonlinear systems with partially known dynamics.

  • Use of adaptive control to handle parametric uncertainties and time-varying disturbances.

  • Stability proofs using Barbalat’s Lemma and Lyapunov theory.

Impact:
Cited in research on wireless sensor-actuator networks and embedded control in uncertain environments.

4. Xu, W., et al. (2018)

Title: Intelligent Fault Detection in Industrial Systems using Hybrid Neural Models
Journal: Expert Systems with Applications
Citations: 52

Summary:
This paper proposes a hybrid neural network model for fault detection in industrial systems, combining convolutional neural networks (CNNs) and recurrent neural networks (RNNs). It targets early-stage anomaly detection in time-series data from manufacturing sensors.

Key Contributions:

  • A novel hybrid model that captures both spatial features (via CNN) and temporal dynamics (via RNN).

  • A feature fusion strategy for improved diagnostic performance.

  • Evaluation on real-world datasets from manufacturing processes shows high accuracy and low false alarm rates.

Impact:
One of the most cited papers in intelligent maintenance and predictive diagnostics, influencing work on Industry 4.0 and smart manufacturing.

Conclusion

Dr. Weimin Xu is a strong candidate for the Best Researcher Award due to his broad and practical research contributions, notable patent record, and long-standing academic service. His work bridges theoretical advancement and practical application in intelligent control systems, aligning with the priorities of innovation-driven recognition.

Liyan Wen | Aircraft | Best Researcher Award

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Dr. Liyan Wen | Aircraft | Best Researcher Award

Associate Professor at Nanjing University of Aeronautics and Astronautics, China

Dr. Wen Liyan is an Associate Professor at Nanjing University of Aeronautics and Astronautics, specializing in adaptive fault-tolerant control and its applications in aerospace systems. With a strong foundation in nonlinear system control, she leads projects funded by China’s National Natural Science Foundation. She has authored over 60 academic papers, holds 9 patents, and actively contributes to several technical committees within the Chinese Association of Automation. Her work bridges theoretical research with real-world aerospace engineering, earning her multiple national-level recognitions. Dr. Wen’s contributions significantly advance the control systems field in both academia and industry. 🌟

Publication Profile

Google Scholar

Academic Background 🎓

Dr. Wen earned her Ph.D. in Control Science and Engineering in 2016, under the supervision of IEEE Fellows Prof. Gang Tao (University of Virginia) and Prof. Jiang Bin (President of NUAA). Her doctoral work laid the foundation for her later research in adaptive and fault-tolerant control. Prior to her Ph.D., she completed her undergraduate and master’s studies in engineering, with a focus on automation and control systems. Her education reflects a strong blend of theoretical expertise and practical application in control engineering, preparing her to contribute to high-impact research in aviation and aerospace control technologies. 🎓

Professional background

Dr. Wen Liyan is currently an Associate Professor at NUAA, where she leads advanced research in nonlinear adaptive control. Her post-Ph.D. career has been marked by multiple research grants, successful collaborations with AVIC research institutes, and leadership in UAV swarm control projects. She has guided numerous graduate students and published extensively in prestigious journals such as Automatic, IEEE Transactions, and AIAA. Her work is not only theoretical but also integrated with real-world aircraft systems. Through her academic and industrial collaborations, she plays a key role in advancing modern flight control technologies. 🛫

Awards and Honors

Dr. Wen has received several top-level honors, including the First-Class Natural Science Award from both the Chinese Association of Automation (CAA) and the Jiangsu Association of Automation. She has published 23 high-impact papers and earned multiple patents for her innovations. Her research excellence has been recognized nationally, and she continues to secure competitive grants from the National Natural Science Foundation of China (NSFC). These accolades reflect her leadership and sustained contributions to adaptive control and aerospace engineering. 🏅

Research Focus

Dr. Wen’s research focuses on adaptive and fault-tolerant control systems, especially in uncertain and nonlinear environments. Her work includes modeling and control of novel aircraft, robust system design under actuator faults and turbulence, and UAV swarm trajectory planning. She pioneered piecewise adaptive control frameworks and has demonstrated over 95% diagnostic accuracy in practical applications. Her projects bridge theory and practice, enabling breakthroughs in autonomous flight, distributed control, and dynamic system adaptation. Her contributions support safer, smarter, and more resilient aerospace control systems. 🚀

Publication Top Notes

📄 Attitude stabilization of a flexible spacecraft under actuator complete failure
Year: 2016 | Cited by: 39 | 🛰️

📄 Adaptive actuator failure compensation for possibly nonminimum-phase systems using control separation based LQ design
Year: 2018 | Cited by: 35 | ⚙️📉

📄 Aircraft turbulence compensation using adaptive multivariable disturbance rejection techniques
Year: 2015 | Cited by: 32 | ✈️🌪️

📄 An adaptive disturbance rejection control scheme for multivariable nonlinear systems
Year: 2016 | Cited by: 29 | 🔄📊

Conclusion 

Dr. Wen Liyan is an exceptional candidate for the Best Researcher Award, demonstrating excellence in both academic research and practical innovation. As an Associate Professor at NUAA, she brings a strong academic foundation, having earned her Ph.D. under the guidance of two IEEE Fellows. Her research in adaptive fault-tolerant control and nonlinear systems is cutting-edge and highly relevant to aerospace applications, including UAV swarm control and advanced aircraft modeling. With 60 publications-23 in top-tier journals-and 9 China patents, her output is both prolific and impactful. Recognized with prestigious national awards and actively engaged in multiple professional committees, she exemplifies leadership and community contribution. Her collaborations with AVIC institutes and development of diagnostic systems with over 95% accuracy highlight her ability to translate theory into real-world solutions, making her a highly deserving recipient of this award.

 

 

Manjunath Thindlu Rudrappa | Engineering | Best Researcher Award

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Mr. Manjunath Thindlu Rudrappa | Engineering | Best Researcher Award

Mr. Manjunath Thindlu Rudrappa, Fraunhofer Institute for High Frequency Physics and Radar Techniques, Germany

Manjunath Thindlu Rudrappa is an accomplished researcher specializing in radar signal processing, object tracking, and space object characterization. He is currently a Doctoral Researcher at Fraunhofer FHR, Germany, focusing on phased array radar networks. With a strong academic background from RWTH Aachen University and Visvesvaraya Technological University, his expertise spans ISAR imaging, interferometry, and machine learning applications in radar technology. He has contributed significantly to the field through high-impact publications and innovative research in MIMO radar systems. Manjunath has also worked with industry leaders such as Bosch and Fraunhofer, gaining extensive experience in embedded systems and radar post-processing. His research excellence has been recognized with prestigious awards, including the Young Scientist Award and the Argus Science Award. Passionate about advancing radar and space technology, he continues to drive innovation in signal processing and object detection methodologies. 🚀📡

Publication Profile

Google Scholar

📚 Education

Manjunath earned his Bachelor of Engineering (B.E.) in Electronics and Communication from Visvesvaraya Technological University, India, graduating with an impressive 86.41% aggregate. His bachelor thesis focused on developing an intelligent paradigm for electric vehicles using buck-boost converters, super-capacitors, and regenerative braking, under the guidance of Dr. Bhakthavatsalam and Mr. Gowranga K.H from IISc Bangalore. He pursued his Master of Science (M.Sc.) in Communication Engineering at RWTH Aachen University, Germany, achieving a 1.5 aggregate. His master thesis at Fraunhofer FHR was on vital parameter detection of moving persons using MIMO radar, supervised by Prof. Dr.-Ing Peter Knott and Dr.-Ing Reinhold Herschel. Currently, he is a PhD researcher at RWTH Aachen University, working on the characterization of resident space objects using phased array radar networks, pushing the boundaries of radar and space object detection technology. 🎓📡

💼 Experience

Manjunath began his career as an Embedded Software Engineer at Robert Bosch Engineering and Business Solutions Limited (2014–2017) in India, working on software development for automotive systems. Moving to Bosch Engineering GmbH, Germany, he served as an Embedded Application Software Developer (2018–2019), specializing in software solutions for automotive applications. His transition to Fraunhofer FHR in Germany marked his entry into radar research, where he worked as a Work Student (2019–2020) on vital parameter estimation, detection, tracking, and clustering. Since 2020, he has been a Doctoral Researcher and Wissenschaftlicher Mitarbeiter at Fraunhofer FHR, contributing to advanced radar signal processing, ISAR imaging, interferometry, and object tracking. His research spans both defense and space applications, making significant contributions to radar-based object detection and feature extraction techniques. 🔬🚀

🏆 Awards & Honors

Manjunath has received prestigious recognitions for his contributions to radar signal processing and communication technology. In October 2020, he won the Young Scientist Award at the International Radar Symposium in Warsaw, Poland, for his research on vital parameter detection of non-stationary human subjects using MIMO Radar. His master thesis on signal processing and microwave technology earned him the Argus Science Award 2020 from Hensoldt, Germany, recognizing his exceptional contributions to the field. His work has been highly regarded in the academic and industrial research community, reinforcing his status as a leading researcher in radar technology, space object tracking, and embedded systems. 🏅📡

🔬 Research Focus

Manjunath’s research is centered on radar signal processing, object tracking, and space object characterization. His expertise includes ISAR imaging, interferometry, feature extraction, machine learning, and deep learning for radar applications. He has worked extensively with MIMO radar systems, contributing to human vital sign detection, tracking, and clustering. His PhD research explores phased array radar networks for resident space object characterization, a crucial area in space surveillance and satellite tracking. Additionally, he has experience in embedded systems, automotive radar applications, and defense technology, making significant contributions to intelligent sensing and radar post-processing methodologies. His work bridges the gap between academic research and industrial innovation, shaping the future of radar and communication engineering. 🌍📡🚀

Publication Top Notes

1️⃣ Moving human respiration sign detection using mm-wave radar via motion path reconstructionCited by: 17 | Year: 2021 📡👤💨
2️⃣ Vital parameters detection of non-stationary human subject using MIMO radarCited by: 11 | Year: 2020 📡🔬🧍
3️⃣ Distinguishing living and non-living subjects in a scene based on vital parameter estimationCited by: 8 | Year: 2021 🔍👤🏠
4️⃣ Characterisation of resident space objects using multistatic interferometric inverse synthetic aperture radar imagingCited by: 4 | Year: 2024 🛰️📡📊
5️⃣ 3D reconstruction of resident space objects using radar interferometry and nonuniform fast Fourier transform from sparse dataCited by: 4 | Year: 2022 🌍📡📉
6️⃣ Improvements of GESTRA—A phased-array radar network for the surveillance of resident space objects in low-Earth orbitCited by: 2 | Year: 2023 🚀🛰️📶
7️⃣ RSO feature extraction using Super Resolution Wavelets and Inverse Radon TransformCited by: 1 | Year: 2022 📡📊📉
8️⃣ High-resolution human clustering based on complex signal correlation coefficientsCited by: 1 | Year: 2022 🏠📡📊
9️⃣ Characterisation of Resident Space Objects and Synchronisation Error Compensation in Multistatic Interferometric Inverse Synthetic Aperture Radar ImagingYear: 2025 🛰️📡📊
🔟 Clusterung von DetektionenYear: 2022 📡📍🔍

Conclusion

Mr. Manjunath Thindlu Rudrappa has a strong research profile, with high-impact contributions in radar signal processing, object tracking, and communication engineering. His awards, affiliations, and research publications make him a highly suitable candidate for the Research for Best Researcher Award. His expertise in machine learning applications in radar, feature extraction, and interferometry aligns with modern advancements in the field, further strengthening his candidacy.

NIMET YILDIRIM TİRGİL | Engineering | Best Researcher Award

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Assoc. Prof. Dr. NIMET YILDIRIM TİRGİL | Engineering | Best Researcher Award 

Associate Professor, at Ankara Yildirim Beyazit University, Turkey.

Dr. Nimet Yildirim Tirgil is an Assistant Professor in Biomedical Engineering at Ankara Yıldırım Beyazıt University. She specializes in biosensor technology, nanomaterials, and electrochemical analysis for environmental and medical applications. With a strong background in bioengineering and biochemistry, Dr. Yildirim Tirgil has led multiple research projects funded by TÜBİTAK and TÜSEB, focusing on biosensing platforms for rapid diagnostics, including COVID-19 antibody detection, tumor DNA analysis, and neurotransmitter monitoring. Her work has led to several patents, high-impact publications, and collaborations in the field of biosensor innovation. Dr. Yildirim Tirgil is committed to advancing analytical chemistry and nanotechnology to develop cutting-edge biosensing solutions.

Professional Profile

Scopus

ORCID

Google Scholar

🎓 Education

Dr. Yildirim Tirgil holds a Ph.D. in Bioengineering from Northeastern University (2016), where she developed next-generation biosensor systems for environmental water quality monitoring under the supervision of Prof. April Z. Gu. She earned her M.Sc. in Biochemistry from Ege University (2009), focusing on bacterial sensors and nanomaterial-modified electrodes, and completed her B.Sc. in Biochemistry (2007) from the same university. Her academic journey has equipped her with interdisciplinary expertise in bioengineering, nanotechnology, and analytical chemistry, enabling her to contribute significantly to biosensor research and development.

💼 Experience

Dr. Yildirim Tirgil has been an Associate Professor at Ankara Yıldırım Beyazıt University since 2018, leading research in biomedical engineering. She has extensive experience in supervising graduate theses, mentoring students in biosensor technology, and developing nanomaterial-based detection systems. She has served as Principal Investigator on numerous national and international research projects, including the development of electrochemical biosensors for detecting environmental pollutants, disease biomarkers, and bioterrorism agents. Her collaborations extend to government-funded research programs and industrial partnerships, advancing biosensing technologies for healthcare, food safety, and environmental monitoring.

🔬 Research Interests

Dr. Yildirim Tirgil’s research focuses on biosensor development, nanotechnology, and electrochemical analysis for medical diagnostics and environmental applications. Her primary interests include:

  • Aptamer-based biosensors for disease biomarker detection.

  • Electrochemical sensing platforms for rapid pathogen and toxin identification.

  • Nanomaterial-modified electrodes for enhanced biosensing performance.

  • Wearable and paper-based biosensors for real-time health monitoring.

  • Smart biosensor integration for food safety and environmental protection.

Her interdisciplinary research integrates biotechnology, analytical chemistry, and materials science to develop innovative biosensing solutions with high sensitivity and specificity.

🏆 Awards & Recognitions

Dr. Yildirim Tirgil has received multiple awards for her groundbreaking work in biosensor technology, including:

  • Best Research Paper Award in Analytical Chemistry (2024).

  • TÜBİTAK Research Excellence Award for contributions to biosensor innovation (2023).

  • Outstanding Young Scientist Award in Biomedical Engineering (2022).

  • Top Cited Researcher Recognition in ACS Applied Polymer Materials (2025).

  • Innovation Award for the development of a smartphone-assisted biosensor system (2021).

Her achievements highlight her impact on sensor technology and analytical diagnostics, making her a leading figure in biosensing research.

📚 Top Noted Publications

Dr. Yildirim Tirgil has published extensively in high-impact journals. Some of her key publications include:

  • Sanattalab, E., Ayni, E., Kaya, K., & Yildirim‐Tirgil, N. (2025).
    Applications of Magnetic Nanocomposites in Lateral Flow Assays.
    Journal: ChemistrySelect
    Summary: This paper explores the use of magnetic nanocomposites in lateral flow assays, enhancing sensitivity and specificity for rapid diagnostic applications.

  • Yildirim-Tirgil, N., Ayni, E., & Kaya, K. (2025).
    Electrochemical Detection of SARS-CoV2 IgG Using Magnetic Nanocomplexes.
    Journal: Journal of Nanoparticle Research
    Summary: The study presents a novel electrochemical biosensor utilizing magnetic nanocomplexes for detecting SARS-CoV-2 IgG antibodies, providing a potential point-of-care diagnostic solution.

  • Avci, M. B., Kocer, F., Yildirim-Tirgil, N., et al. (2025).
    Optofluidic Guided-Mode Resonance Platform for Binding Kinetics.
    Journal: IEEE Sensors Journal
    Summary: This research introduces an optofluidic guided-mode resonance platform for real-time analysis of biomolecular interactions, focusing on binding kinetics measurements.

  • Yildirim-Tirgil, N., et al. (2025).
    Development of a Polypyrrole–Chitosan Nanofiber-Based Enzymatic Biosensor.
    Journal: ACS Applied Polymer Materials
    Summary: The paper discusses the fabrication and characterization of an enzymatic biosensor using polypyrrole–chitosan nanofibers for enhanced sensitivity in biochemical detection.

  • Didarian, R., Ozbek, H. K., Ozalp, V. C., Erel, O., & Yildirim-Tirgil, N. (2024).
    Enhanced SELEX Platforms for Aptamer Selection.
    Journal: Molecular Biotechnology
    Summary: The study proposes improvements in SELEX (Systematic Evolution of Ligands by EXponential Enrichment) methodologies for more efficient aptamer selection, applicable in biosensing and therapeutics.

  • Cuhadar, S. N., Durmaz, H., & Yildirim-Tirgil, N. (2024).
    Multi-Detection of Serotonin and Dopamine via Electrochemical Aptasensor.
    Journal: Chemical Papers
    Summary: This paper introduces an electrochemical aptasensor for the simultaneous detection of serotonin and dopamine, contributing to advancements in neurochemical monitoring.

  • Sahin, S., & Tirgil, N. Y. (2024).
    Circulating Tumor DNA (ctDNA) Detection via Electrochemical Biosensing.
    Journal: MANAS Journal of Engineering
    Summary: The study develops an electrochemical biosensor for detecting circulating tumor DNA (ctDNA), offering potential applications in early cancer diagnostics.

Conclusion

Dr. Nimet Yildirim Tirgil is a highly qualified and competitive candidate for the Best Researcher Award. Her groundbreaking work in biosensors, nanomaterials, and biomedical applications, along with strong project leadership and patent contributions, position her as a leader in her field. Enhancing international collaborations and industry partnerships could further elevate her candidacy.

Ukte Aksen | Aerospace | Best Researcher Award

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Dr. Ukte Aksen | Aerospace | Best Researcher Award

Lead Engineer at Aselsan, Turkey

🚀 Dr. Ukte Aksen is an aerospace engineer specializing in flight mechanics, aerodynamics, and hybrid rocket propulsion. He holds a PhD in Aerospace Engineering from Istanbul Technical University (ITU), where he researched hybrid rocket motors for small satellite launch vehicles. With experience at ASELSAN as a Lead Engineer, he previously worked at Milli Savunma Üniversitesi and Roketsan in guidance systems, flight dynamics, and simulation modeling. His expertise spans launch vehicle simulations, UAV dynamics, and hybrid propulsion. A CATIA, MATLAB/Simulink, and ANSYS expert, he has contributed to rocket and UAV projects. Fluent in English and German, he actively advances aerospace innovation. ✈️🚀

Publication Profile

Scopus

Orcid

🎓 Educational Background

🚀 Dr. Ukte Aksen earned his PhD in Aerospace Engineering from Istanbul Technical University (ITU) (2018-2024), focusing on the optimization of hybrid rocket motors for small satellite launch vehicles, under Prof. Dr. Alim Rüstem Aslan. He completed his Master’s in Aerospace Engineering (2016-2018) at ITU, specializing in six-degree-of-freedom modeling and launch vehicle simulations. Dr. Aksen obtained his Bachelor’s in Space Engineering (2011-2016) from ITU, ranking 2nd in his department. He attended Üsküdar Ahmet Keleşoğlu Anadolu High School (2007-2011), excelling in academics and achieving B1/C1 German proficiency. ✈️🚀

🏆 Professional Experience

🚀 Dr. Ukte Aksen is a Lead Engineer at ASELSAN (2022-present) in the Aerodynamics and Flight Dynamics Unit. Previously, he was a Research Assistant at National Defense University – Air Force Academy (2019-2022), specializing in flight mechanics and control. At İTÜNOVA TTO (2017-2019), he contributed to helicopter vibration reduction projects. He worked at Roketsan (2016-2017) in flight and orbital mechanics. His experience includes an internship at General Electric Aviation (2015) and Pegasus Airlines (2015). Early in his career, he gained customer service experience at LC Waikiki and LTB. His expertise spans aerospace systems, simulations, and propulsion technologies. ✈️🚀

💻 Technical Skills

Dr. Ukte Aksen possesses extensive expertise in engineering software and programming tools essential for aerospace applications. He is proficient in MATLAB/Simulink, Octave, and Scilab for computational modeling and simulation. His experience includes CATIA, UG/NX, and ANSYS for design and analysis, along with Hypermesh for advanced meshing. He is skilled in Datcom, RockSim, and XFLR5 for aerodynamic and flight simulations. Additionally, he has experience with C programming and MiniTab for statistical analysis. His knowledge extends to ArcGIS for geospatial applications, making him a versatile expert in aerospace engineering and computational analysis. 🚀💡

🚀 Research Focus

Dr. Ukte Aksen specializes in aerospace engineering, with a primary focus on trajectory design, optimization, flight dynamics, and space vehicle performance. His research includes six-degree-of-freedom trajectory modeling, multistage launch vehicle sensitivity analysis, and hybrid rocket propulsion. He also investigates geomagnetic storm effects on aviation safety and structural optimization of missile components. His expertise spans computational simulations, aerodynamics, and control systems for space applications. Through his contributions to Applied Sciences, Advances in Space Research, and Turkish Journal of Engineering, he advances aerospace technology and space mission design. 🌍🚀📡

Publication Top Notes

1️⃣ Aksen, U. et al. (2024)The effect of geomagnetic storms on aircraft accidents (1919–2023)Advances in Space Research, 73(1), 807-830 🌍✈️
2️⃣ Aksen, U. et al. (2024)Six-DOF Trajectory Optimization of a Launch Vehicle with Hybrid Last Stage (PSO Algorithm)Applied Sciences, 14(9), 3891 🚀📊
3️⃣ Aksen, U. et al. (2024)Sensitivity Analysis Tool for Multistage Launch VehiclesTurkish Journal of Engineering, 8(2), 254-264 📈🛰️
4️⃣ Aksen, U. (2023)Multi-Objective Geometric Optimization of a Missile WingAfyon Kocatepe Univ. Sci. & Eng. Journal 🎯🚀
5️⃣ Aksen, U. (2022)Effects of Wing Parameters on Glider PerformanceIGRS, Istanbul ✈️📉
6️⃣ Aksen, U. (2022)Aeroelastic Analysis of SMA Modeled Wing ProfileUHUK, Izmir 🛩️🔬
7️⃣ Aksen, U. (2022)Impact of Wind Models on Glider Flight DynamicsSavtek, Ankara 🌬️📊
8️⃣ Aksen, U. (2017)Importance of Atmosphere Models in Aerospace Trajectory SimulationAIAC, Ankara ☁️🚀
9️⃣ Aksen, U. (2016)FuegoSat: Real-Time Earth Observation Nano-Satellite DesignUHUK, Kocaeli 🛰️🌍

 

Gang Li | Mechanical Engineering | Best Researcher Award

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Assoc. Prof. Dr. Gang Li | Mechanical Engineering | Best Researcher Award

Associate professor, Northeast Electric Power University, China

🔬 Assoc. Prof. Dr. Gang Li is a distinguished researcher in mechanical manufacturing and automation at Northeast Electric Power University. He holds a PhD from South China University of Technology and has led numerous projects in metal material processing, mechanical equipment development, and metrological verification. His expertise includes Ti-6Al-4V material processing, intelligent metering systems, and unmanned technology research. He has authored 10+ SCI papers, holds multiple patents, and has contributed to national and provincial research projects. Passionate about innovation and automation, he actively explores advancements in mechanical engineering. ✨🔧📡

 

Publication Profile

Scopus

🎓 Educational Background

Assoc. Prof. Dr. Gang Li has a strong academic foundation in mechanical engineering and automation. He earned his PhD (2013-2017) 🎓 from South China University of Technology, specializing in Mechanical Manufacturing and Automation. Prior to this, he completed a Master’s degree (2010-2013) 🏅 at Changchun University of Science and Technology, focusing on Machinery Manufacturing and Automation. His first Master’s degree (2004-2008) 🏆 was from Inner Mongolia University of Science and Technology, specializing in Mechanical Design, Manufacture, and Automation. His extensive academic training has contributed significantly to his expertise in mechanical innovation and research. 🔧📡

🔬 Project Experience

Assoc. Prof. Dr. Gang Li has contributed to multiple mechanical and automation research projects. His work on Ti-6Al-4V cutting and surface strengthening technology 🏗️ optimized machining parameters and tools for titanium alloy casing. He played a key role in the Guangdong Provincial Energy Metering and Verification Center ⚡, overseeing equipment installation and debugging. His research on intelligent, unmanned metrological verification 🏭 focused on fault detection and automation. As the principal investigator of the intelligent metering turnover cabinet 📟, he developed a system for efficient energy meter management, enhancing automation and operational efficiency. 🔧🚀

🔬 Research Focus

Assoc. Prof. Dr. Gang Li specializes in mechanical engineering 🏭, with a focus on materials processing and surface strengthening technologies. His research explores electropulsing-assisted ultrasonic strengthening ⚡🔊, particularly its impact on fatigue properties of Ti–6Al–4V alloys 🏗️. He also investigates fretting friction characteristics 🔧, optimizing heat-treated alloys for enhanced durability. His contributions in metallurgical and materials science 🏺 are crucial for improving the performance and lifespan of structural components in aerospace ✈️, automotive 🚗, and energy sectors ⚡. With multiple publications and citations, his work advances manufacturing and materials innovation. 🚀

Publication Top Notes

Effect of Electropulsing-Assisted Ultrasonic Strengthening on Fatigue Properties of HIP Ti–6Al–4V Alloy

Study on surface fretting friction properties of heat-treated HIP Ti-6Al-4 V alloy after heating-assisted ultrasonic surface strengthening