Tag: Engineering Scientist Award

Feyyaz Alpsalaz | Engineering | Research Excellence Award

Published on by World Science Awards

Research Excellence Award

Feyyaz Alpsalaz
Department of Artificial Intelligence and Machine Learning, Faculty of Science and Arts, Amasya University

Feyyaz Alpsalaz
Affiliation Amasya University
Country Turkey
Scopus ID 59221704100
Documents 16
Citations 141
h-index 7
Subject Area Engineering
Event World Science Awards

Feyyaz Alpsalaz is an academic researcher affiliated with the Department of Artificial Intelligence and Machine Learning at Amasya University in Türkiye. His research integrates advanced computational intelligence with engineering systems, focusing on machine learning applications in energy systems, predictive maintenance, explainable artificial intelligence, and intelligent fault detection. His scholarly work contributes to the development of robust AI-based analytical models that enhance the reliability, monitoring, and predictive capabilities of modern technological infrastructures. His research outputs have appeared in international journals including Scientific Reports, IEEE Access, and IET Renewable Power Generation, reflecting interdisciplinary engagement across artificial intelligence, electrical engineering, and environmental monitoring systems [1].

Abstract

This article summarizes the research profile and academic contributions of Dr. Feyyaz Alpsalaz, a researcher specializing in artificial intelligence and machine learning applications in engineering systems. His work focuses on predictive analytics, hybrid machine learning models, explainable artificial intelligence, and intelligent diagnostics for power systems and environmental monitoring. Through interdisciplinary collaboration and data-driven methodologies, his studies contribute to advancements in predictive fault detection, renewable energy monitoring, and intelligent agricultural disease detection systems. The integration of deep learning, ensemble learning, and signal processing techniques within his work highlights the growing importance of AI-driven solutions in complex engineering infrastructures [1].

Keywords

  • Artificial Intelligence
  • Machine Learning
  • Explainable Artificial Intelligence
  • Fault Detection Systems
  • Renewable Energy Monitoring
  • Predictive Maintenance

Introduction

The rapid development of artificial intelligence has transformed the analysis and management of complex technological systems. Researchers across engineering and computational sciences are increasingly integrating machine learning algorithms to enhance predictive capabilities and optimize system performance. Dr. Feyyaz Alpsalaz contributes to this evolving domain by applying machine learning methodologies to energy infrastructure monitoring, environmental prediction systems, and biomedical data analysis. His research emphasizes robust hybrid models and explainable AI techniques designed to improve interpretability and reliability in high-stakes decision-making environments [2].

Research Profile

Dr. Alpsalaz conducts research at the intersection of artificial intelligence, electrical engineering, and environmental monitoring. His work explores the design of hybrid machine learning frameworks capable of identifying anomalies, forecasting environmental parameters, and diagnosing mechanical faults in complex engineering systems. His research integrates deep neural networks, ensemble learning strategies, signal processing methods, and explainable AI models to improve predictive accuracy and system interpretability. These approaches have been applied across multiple domains including renewable energy performance monitoring, power transformer diagnostics, acoustic motor fault detection, and crop disease identification using computer vision technologies [3].

Research Contributions

  • Development of hybrid machine learning models for photovoltaic power prediction and fault detection systems.
  • Application of explainable artificial intelligence methods to interpret complex deep learning models in engineering diagnostics.
  • Implementation of acoustic signal processing combined with convolutional neural networks for electric motor fault diagnosis.
  • Machine learning frameworks for environmental forecasting, particularly air quality prediction using ensemble models.
  • Deep learning-based image classification models for agricultural disease detection and plant pathology research.

Publications

  1. Hybrid Machine Learning Approach for Enhanced Fault Detection and Power Estimation in Photovoltaic Systems. IET Renewable Power Generation. DOI: https://doi.org/10.1049/rpg2.70153
  2. Hybrid Machine Learning Approach for Predicting Power Transformer Failures Using IoT Monitoring and Explainable AI. IEEE Access. DOI: https://doi.org/10.1109/access.2025.3583773
  3. Classification of Maize Leaf Diseases with Deep Learning. Chemometrics and Intelligent Laboratory Systems. DOI: https://doi.org/10.1016/j.chemolab.2025.105412
  4. Air Quality Forecasting Using Machine Learning. Water, Air, & Soil Pollution. DOI: https://doi.org/10.1007/s11270-025-08122-8
  5. Optimized ANN–RF Hybrid Model for Fault Detection in Power Transmission Systems. Scientific Reports. DOI: https://doi.org/10.1038/s41598-025-31008-y
  6. Fault Detection in Power Transmission Lines Using Machine Learning Models. Maintenance & Reliability. DOI: https://doi.org/10.17531/ein/203949
  7. Acoustic-Based Fault Diagnosis of Electric Motors Using CNNs. Scientific Reports. DOI: https://doi.org/10.1038/s41598-025-33269-z
  8. Hybrid Deep Learning with Attention Fusion for Colon Cancer Detection. Scientific Reports. DOI: https://doi.org/10.1038/s41598-025-29447-8
  9. Hybrid Deep Learning Model for Maize Leaf Disease Classification. New Zealand Journal of Crop and Horticultural Science.
  10. Detection of Arc Faults in Transformer Windings via Transient Signal Analysis. Applied Sciences. DOI: https://doi.org/10.3390/app14209335

Research Impact

The research contributions of Dr. Alpsalaz demonstrate the growing relevance of artificial intelligence in predictive engineering systems and sustainable infrastructure management. His studies integrate machine learning techniques with engineering diagnostics to improve reliability and predictive maintenance capabilities. Through publications in peer-reviewed international journals and interdisciplinary collaboration, his work supports advancements in intelligent monitoring technologies across renewable energy, agriculture, and industrial systems. These contributions illustrate the practical impact of AI-driven analytical methods in modern scientific and engineering research environments [1].

Award Suitability

Dr. Alpsalaz’s scholarly activities demonstrate interdisciplinary innovation within artificial intelligence applications for engineering systems. His work combines computational intelligence, predictive analytics, and explainable AI frameworks to address real-world challenges in energy infrastructure and environmental monitoring. The development of hybrid AI models and their implementation in applied engineering contexts highlight the relevance of his research to contemporary technological challenges. Such contributions align with the evaluation criteria commonly associated with international research recognition programs focused on artificial intelligence innovation and technological impact [3].

Conclusion

The academic profile of Dr. Feyyaz Alpsalaz reflects the integration of artificial intelligence techniques with complex engineering applications. His research emphasizes hybrid machine learning architectures, explainable AI methodologies, and predictive diagnostic systems designed to enhance reliability across multiple technological domains. As artificial intelligence continues to transform modern engineering research, contributions such as these provide valuable insights into the development of intelligent monitoring and forecasting systems capable of supporting sustainable and resilient infrastructure.

References

  1. Elsevier. (n.d.). Scopus author details: Feyyaz Alpsalaz, Author ID 59221704100. Scopus.
    https://www.scopus.com/authid/detail.uri?authorId=59221704100
  2. Google Scholar. (n.d.). Scholar profile of Feyyaz Alpsalaz.
    https://scholar.google.com.tr/citations?user=EP2ybTEAAAAJ&hl=tr&oi=ao
  3. ORCID. (n.d.). ORCID record for Feyyaz Alpsalaz.
    https://orcid.org/0000-0002-7695-6426

Kai Zhao | Engineering | Best Researcher Award

Published on by World Science Awards

Assoc. Prof. Dr. Kai Zhao | Engineering | Best Researcher Award

Dalian Maritme University, China

Assoc. Prof. Dr. Kai Zhao is an accomplished researcher and academic at the School of Information Science and Technology, Dalian Maritime University, specializing in optoelectronic information science, micro-nano sensing, and environmental monitoring technologies. He obtained his Ph.D. in Mechanical and Mechatronics Engineering from the University of Waterloo, Canada, in 2019, and subsequently completed a postdoctoral fellowship at ETH Zurich, Switzerland, before joining Dalian Maritime University as an Associate Professor in 2020. His professional experience covers teaching and research in areas such as micro-nanophotonic integration, digital logic design, signal and image processing, and optoelectronic detection systems, coupled with leadership in advanced projects funded by the National Natural Science Foundation of China, Liaoning Provincial Foundation, and international innovation programs. Dr. Zhao’s research interests focus on micro-nano sensing and detection, microfluidic chips, artificial intelligence for micro-nano target recognition, intelligent sensing of marine micropollutants, microbial detection, clean energy, and invasive species identification, all of which reflect his commitment to sustainable marine technology and global environmental solutions. He is highly skilled in micro-nano device fabrication, photoelectric detection, signal analysis, microfluidics, and integrated circuit applications, with an impressive publication record of 36 research articles, cited over 704 times with an h-index of 15, in leading journals including Nature Communications, Environmental Pollution, Analytical Chemistry, ACS Applied Materials & Interfaces, IEEE Transactions on Instrumentation and Measurement, and Nanoscale. His academic excellence has been recognized with numerous awards and honors, such as the First Prize of Guangdong Environmental Protection Science and Technology Award (2024), the Innovation Team Award from the China Society of Naval Architecture and Shipbuilding (2023), the Science and Technology Progress Award of the China Instrument and Control Society (2022), and the National Teachers’ Teaching Innovation Competition Prize (2023). In conclusion, Dr. Zhao’s blend of strong academic foundations, pioneering research achievements, international collaborations, and leadership in both teaching and mentorship demonstrate his exceptional contributions to science, positioning him as a rising global leader in optoelectronics, micro-nano sensing, and environmental monitoring technologies.

Profiles:  Scopus | ORCID | Google Scholar | LinkedIn

Featured Publications

  1. chDing, S., Dang, Y. G., Li, X. M., Wang, J. J., & Zhao, K. (2017). Forecasting Chinese CO₂ emissions from fuel combustion using a novel grey multivariable model. Journal of Cleaner Production, 162, 1527–1538.

  2. Zhao, K., Wei, Y., Dong, J., Zhao, P., Wang, Y., Pan, X., & Wang, J. (2022). Separation and characterization of microplastic and nanoplastic particles in marine environment. Environmental Pollution, 297, 118773

  3. Zhao, K., Larasati, Duncker, B. P., & Li, D. (2019). Continuous cell characterization and separation by microfluidic alternating current dielectrophoresis. Analytical Chemistry, 91(9), 6304–6314.

  4. Alvarez, L., Fernandez-Rodriguez, M. A., Alegria, A., Arrese-Igor, S., Zhao, K., & others. (2021). Reconfigurable artificial microswimmers with internal feedback. Nature Communications, 12, 4762.

  5. Zhao, K., & Li, D. (2017). Continuous separation of nanoparticles by type via localized DC-dielectrophoresis using asymmetric nano-orifice in pressure-driven flow. Sensors and Actuators B: Chemical, 250, 274–284.

Le Chang | Engineering | Best Researcher Award

Published on by World Science Awards

Assist. Prof. Dr. Le Chang | Engineering | Best Researcher Award

Xi’an Jiaotong University | China

Dr. Le Chang is an Assistant Professor at the College of Electric Power Engineering, Shanghai University of Electric Power, China, specializing in networked control systems and nonlinear dynamics. He earned his Ph.D. from Shandong University, focusing on control theory and its applications. His professional experience includes serving as a Research Associate at the College of Electric Power Engineering, where he contributes to the development of advanced control strategies for complex systems. Dr. Chang’s research interests encompass the analysis and design of control systems in the presence of network-induced delays and nonlinearities, aiming to enhance the stability and performance of interconnected systems. His research skills are demonstrated through his work on cascade control for post-chlorine dosage during drinking water treatment under cyber attacks, published in the IEEE Transactions on Automation Science and Engineering. Additionally, he has contributed to the global stabilization of strict-feedback nonlinear systems with applications to circuits, employing an intermittent impulsive control approach, as detailed in the IEEE Control Systems Letters. Dr. Chang’s work on global output regulation for uncertain feedforward nonlinear systems with unknown nonlinear growth rates has been published in the International Journal of Robust and Nonlinear Control. His contributions to global output feedback stabilization for nonlinear systems via a switching control gain approach are featured in the International Journal of Control. Furthermore, his research on global sampled-data output feedback stabilization for nonlinear systems via intermittent hold has been published in the IEEE/CAA Journal of Automatica Sinica. Dr. Chang’s innovative approaches to stabilization and regulation in nonlinear systems have significantly advanced the field of control engineering. In conclusion, Dr. Le Chang’s academic background, professional experience, and research contributions underscore his expertise in control systems, particularly in addressing challenges posed by networked and nonlinear dynamics. His work continues to influence the development of robust control strategies in various engineering applications.

Profile: Scopus

Featured Publications

1. Liu, D., Chang, L., He, W., Wei, K., & Zhang, A. (2025). Wideband low-directivity cavity-backed Yagi-Uda dipole antenna for electrically large laptops. IEEE Transactions on Antennas and Propagation, in press.

2. Zhang, H., Chang, L., Chen, X., Chen, J., & Zhang, A. (2025). Ultra-low-profile and ultra-wideband microstrip patch antenna based on hybrid coupling for mobile Wi-Fi 6/6E and UWB channels 5–11 applications. IEEE Transactions on Antennas and Propagation, in press.

3. Wang, S., Bu, H., Zhang, Y., Chang, L., Chen, X., Wei, K., & Li, Y. (2025). Active antenna hub: A multi-port shared-antenna architecture for scalable internet of things devices. IEEE Internet of Things Journal, in press.

4. Zhao, Z., Chang, L., Cui, Y., & Zhang, A. (2025). Miniaturized and wideband metasurface antenna sensor for breast tumor detection. Sensors and Actuators: A. Physical, in press.

5. Chen, M., Chang, L., Cao, Y., Yan, S., & Zhang, A. (2025). Simultaneous enhancements of bandwidth and isolation of frame monopoles utilizing elongated back cover patches for smartphones. IEEE Transactions on Antennas and Propagation, in press.

Guocheng Qin | Engineering | Best Researcher Award

Published on by World Science Awards

Mr. Guocheng Qin | Engineering | Best Researcher Award

Researcher from Chongqing Institute of Surveying and Monitoring for Planning and Natural Resources, China

Qin Cheng is a dedicated and innovative civil engineering researcher with a strong focus on integrating advanced digital technologies such as Building Information Modeling (BIM), 3D laser scanning, and Unmanned Aerial Vehicle (UAV) systems into modern construction and infrastructure projects. Born in March 1994, he has consistently demonstrated academic excellence, practical engineering insight, and a deep interest in smart city development and sustainable infrastructure. His work spans across both academic and applied settings, with a particular emphasis on intelligent monitoring systems, reverse modeling, and digital design optimization. He has contributed to various high-profile research initiatives and collaborative international projects, particularly during his tenure as a visiting scholar at the University of Louvain. Qin Cheng has also been actively involved in training graduate students, guiding technical design, and promoting intelligent construction practices. His experience working with institutions such as the Chongqing Leuven Institute of Smart City and Sustainable Development and contributions to international exhibitions like the China Intelligent Industry Expo reflect his ability to bridge academic research with real-world applications. With a clear commitment to advancing civil engineering practices through technology and innovation, Qin Cheng continues to emerge as a promising voice in the field of smart construction and structural engineering.

Professional Profile

Education

Qin Cheng’s academic journey in civil engineering began with a Bachelor of Engineering from Zhengzhou Institute of Technology and Business, where he studied from September 2013 to July 2017. Building on a solid undergraduate foundation, he pursued a Master of Engineering in Civil Engineering with a structural specialization at Chongqing Jiaotong University from September 2017 to July 2020. During his master’s studies, Qin demonstrated exceptional academic and research abilities, further enriching his education through international exposure. Between October 2018 and January 2019, he served as a visiting scholar at the University of Louvain in Belgium, engaging in scholarly exchanges focused on construction waste regeneration and sustainable urban development. This international experience broadened his perspective on global engineering practices and enhanced his research on smart city applications. His academic background is marked by strong technical competence in structural systems, intelligent monitoring, and construction digitization. Through both domestic and international institutions, Qin Cheng has built a strong academic profile grounded in research excellence, multidisciplinary learning, and hands-on application of modern civil engineering technologies.

Professional Experience

Qin Cheng has built a diverse portfolio of professional experience that merges academic research, international collaboration, and field application. One of his notable professional engagements was his time as a visiting scholar at the University of Louvain (October 2018 to January 2019), where he contributed to academic exchanges on sustainable urban development and construction waste regeneration. He also engaged with world-renowned engineering firms such as Jan de Nul Group to explore cutting-edge civil engineering practices. Qin served as a researcher at the Chongqing Leuven Institute of Smart City and Sustainable Development, where he played a key role in conducting technical breakthroughs in forward design, reverse modeling, and intelligent monitoring systems. His responsibilities included training graduate students in architectural information technology, guiding bridge reverse modeling projects in Norway, and participating in major events such as the China International Intelligent Industry Expo. His professional activities emphasize the integration of BIM and 3D technologies into infrastructure development. Through his involvement in large-scale projects such as the Taihong Yangtze River Bridge and the FAW-Volkswagen Digital Factory, Qin has effectively applied his academic expertise to real-world engineering challenges. His career path reflects a commitment to technological innovation, cross-border collaboration, and the advancement of intelligent infrastructure systems.

Research Interests

Qin Cheng’s research interests center on the integration of advanced digital technologies in civil engineering, with a particular focus on intelligent construction and infrastructure management. He is deeply engaged in developing and applying Building Information Modeling (BIM), 3D laser scanning, and UAV technologies to improve the design, monitoring, and maintenance of civil structures. His work explores how digital tools can optimize construction processes, enhance precision in modeling, and support virtual simulations for pre-assembly. Qin is also interested in reverse modeling techniques for complex structures, smart monitoring of bridges and buildings, and the use of point cloud data in structural analysis. His international collaborations have further shaped his interest in sustainable urban development, where he examines how smart technologies can be leveraged to build resilient, efficient cities. Through projects focused on highway management systems, digital curtain wall design, and large-scale bridge construction, he aims to create innovative solutions that address contemporary challenges in civil engineering. Qin’s research embodies a forward-thinking approach that blends theoretical modeling with practical application, striving to make infrastructure safer, more efficient, and more intelligent through continuous technological advancement.

Research Skills

Qin Cheng possesses a robust set of research skills that enable him to address complex challenges in civil and structural engineering through technological innovation. His core competencies include advanced proficiency in Building Information Modeling (BIM) and 3D laser scanning, which he has used extensively for deformation monitoring, digital pre-assembly, and reverse modeling of both buildings and bridges. He is skilled in UAV route planning and tilt photography for site inspections and large-scale mapping, showcasing his adaptability in remote sensing applications. His hands-on experience with point cloud data processing enables him to conduct accurate structural analysis and digital model construction. Qin is also proficient in integrating BIM with IoT systems for smart bridge management, combining sensor data with digital modeling for real-time infrastructure monitoring. In academic and collaborative environments, he has guided graduate students in technical training and project design, demonstrating strong mentorship capabilities. He is comfortable working across international platforms and has presented his work at major conferences. Qin’s methodological rigor, combined with his technical agility, allows him to innovate across design, monitoring, and operational aspects of civil engineering projects. His ability to apply research techniques to practical scenarios is a key strength in his professional and academic career.

Awards and Honors

Throughout his academic and early research career, Qin Cheng has received several prestigious awards and honors that reflect his dedication, excellence, and potential in the field of civil engineering. During his undergraduate studies, he was consistently recognized with merit-based scholarships, including the National Encouragement Scholarship and first-class and second-class academic scholarships. His excellence continued into his postgraduate years at Chongqing Jiaotong University, where he was awarded the Beijing CCCC Road Tong Million Scholarship and the first-class postgraduate scholarship. In 2020, he won the second prize in the “My College Life” competition and the third prize in the “Transportation BIM Engineering Innovation Award” from the China Highway Society. These accolades highlight both his academic achievements and his contributions to engineering innovation. His participation in various international academic events and his role in large-scale national infrastructure projects further affirm his growing reputation in the field. The consistent recognition of his work through these awards underscores his capability to combine theoretical knowledge with practical engineering excellence. These honors are a testament to his talent, perseverance, and impact in advancing intelligent construction technologies and modern infrastructure development.

Conclusion

In conclusion, Qin Cheng emerges as a highly motivated and capable young researcher with a strong foundation in civil engineering and a clear commitment to technological innovation in infrastructure development. His integration of BIM, 3D laser scanning, and UAV systems into design and monitoring processes showcases his forward-thinking approach and alignment with the needs of smart and sustainable urban construction. With a solid academic background, international experience, and a growing body of research publications, he brings both technical expertise and practical insight to the field. Although he currently holds a master’s degree, his trajectory suggests significant potential for further academic advancement and research leadership. He has demonstrated the ability to bridge academic research with real-world engineering applications, making valuable contributions to both scholarly and professional communities. While increasing publication in top-tier journals and engaging in patent development could further enhance his profile, Qin Cheng has already laid a strong foundation for a successful research career. He is a suitable and deserving candidate for recognition in early-stage researcher or emerging researcher award categories and has the capacity to evolve into a leading expert in smart construction and digital civil engineering in the years ahead.

Publications Top Notes

  1. Title: Automatic Construction of 3D Building Property Rights Model Based on Visual Programming Language in China
    Authors: Qin, Guocheng; Hu, Yuqing; Wang, Ling; Liu, Ke; Hou, Yimei
    Journal: Advances in Civil Engineering
    Year: 2024

Abrham Kassie | Engineering | Best Researcher Award

Published on by World Science Awards

Mr. Abrham Kassie | Engineering | Best Researcher Award

Lecturer at Bahir Dar Institute of Technology, Bahir Dar University, Ethiopia

Abrham Tadesse Kassie is a dedicated researcher and academic specializing in electrical and computer engineering, particularly in industrial control and instrumentation. With a strong background in control systems, renewable energy, and artificial intelligence-based control strategies, he has contributed significantly to the field through research and teaching. He has served as a lecturer at Bahir Dar University and Debre Tabor University, mentoring students and conducting advanced research. His expertise spans control system design for robotics, electric vehicles, renewable energy systems, and smart grids. Through numerous publications and ongoing research, he continues to advance the field of intelligent control systems.

Professional Profile

Education

Abrham Tadesse Kassie obtained a Bachelor of Science degree in Electrical and Computer Engineering (Industrial Control Engineering) from Hawassa University in 2015, graduating with distinction. He then pursued a Master of Science in Electrical and Computer Engineering (Control and Instrumentation Engineering) at Addis Ababa Science and Technology University, earning his degree in 2019 with honors. His coursework included advanced studies in optimal control, nonlinear and adaptive control, digital signal processing, embedded systems, and artificial intelligence-based control. His strong academic performance reflects his commitment to excellence in engineering and research.

Professional Experience

Mr. Kassie has extensive teaching and research experience. He began his academic career as an Assistant Lecturer at Debre Tabor University in 2015 before being promoted to Lecturer in 2019. In 2021, he joined Bahir Dar Institute of Technology, Bahir Dar University, where he continues to serve as a Lecturer. Additionally, from November 2022 to January 2025, he held the position of Chairholder of Industrial Control Engineering (ABET Accredited) at Bahir Dar University. His role involves curriculum development, research supervision, and leading innovative projects in control engineering.

Research Interest

His research interests are centered around control system design for robotics, electric vehicles, renewable energy, airborne wind energy, and smart grids/microgrids. He is particularly focused on developing intelligent control strategies using machine learning and optimization techniques. His work includes designing adaptive and robust controllers for renewable energy applications, trajectory tracking for robotic systems, and enhancing the efficiency of industrial control processes. His research aims to bridge the gap between theoretical advancements and real-world engineering applications.

Research Skills

Mr. Kassie possesses strong technical skills in programming languages, modeling, and simulation software. He is proficient in Python, C++, C, Java, MATLAB, and TIA Portal for PLC programming. Additionally, he has expertise in using simulation tools like Multisim, Proteus, Circuit Maker, and LabVIEW for system modeling and testing. His expertise extends to machine learning applications in control systems, optimization techniques, and intelligent control algorithms. His ability to integrate theoretical models with practical implementations makes him a valuable contributor to advanced engineering research.

Awards and Honors

Throughout his academic journey, Mr. Kassie has received recognition for his outstanding performance. He graduated with distinction during his undergraduate studies and earned his Master’s degree with honors. His role as Chairholder of Industrial Control Engineering at Bahir Dar University is a testament to his leadership and contributions to academia. Additionally, his research publications have gained citations and recognition, demonstrating the impact of his work in the field of electrical and control engineering.

Conclusion

Abrham Tadesse Kassie is a highly skilled researcher with a strong academic and professional background in electrical and control engineering. His contributions to intelligent control systems, renewable energy, and robotics highlight his commitment to advancing technology. While his research is impactful, expanding international collaborations and increasing publication impact can further strengthen his recognition in the field. His expertise, dedication, and innovative mindset make him a strong candidate for the Best Researcher Award.

Publications Top Notes

  1. Title: Design of Neuro Fuzzy Sliding Mode Controller for Active Magnetic Bearing Control System

    • Authors: HF Asres, AT Kassie
    • Year: 2023
    • Citations: 5

  2. Title: Evaluation of intelligent PPI controller for the performance enhancement of speed control of induction motor

    • Authors: TG Workineh, YB Jember, AT Kassie
    • Year: 2023
    • Citations: 3

  3. Title: Direct Adaptive Fuzzy PI Strategy for a Smooth MPPT of Variable Speed Wind Turbines

    • Authors: A Tadesse, E Ayenew, V LNK
    • Year: 2021
    • Citations: 2

  4. Title: Dynamic programming strategy in optimal controller design for a wind turbine system

    • Authors: A Abate Mitaw, A Tadesse Kassie, D Shiferaw Negash
    • Year: 2024

  5. Title: Fuzzy Model Based Model Predictive Control for Biomass Boiler

    • Authors: GA Nibiret, AT Kassie
    • Year: 2024

  6. Title: Wind Energy Resource Potential Evaluation based on Statistical Distribution Models at Four Selected Locations in Amhara Region, Ethiopia

    • Authors: YB Jember, GL Hailu, AT Kassie, DA Bimrew
    • Year: 2023

  7. Title: Direct Adaptive Fuzzy Proportional Integral Strategy for a Combined Maximum Power Point Tracking-Pitch Angle Control of Variable Speed Wind Turbine

    • Authors: AT Kassie
    • Year: 2019