Rania Loukil | Deep Learning | Best Scholar Award

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Mr. Rania Loukil | Deep Learning | Best Scholar Award

Maitre Assistant at Ecole Nationale d’Ingenieurs de Tunis, Tunisia

Dr. Rania Loukil is a Tunisian researcher and academic specializing in Artificial Intelligence, Embedded Systems, and Control Engineering. Currently serving as a Maître Assistant (Assistant Professor) at the Higher Institute of Technology and Computer Science (ISTIC), University of Carthage, she has over a decade of experience in teaching, research, and interdisciplinary collaboration. Her research merges deep learning with practical domains like IoT, smart grids, and fault diagnosis, reflecting a strong commitment to innovation and applied AI solutions.

🔹Professional Profile:

Scopus Profile

Orcid Profile

🎓Education Background

  • Ph.D. in Electrical Engineering, National Engineering School of Sfax (ENIS), University of Sfax, Tunisia | 2010–2014

  • Master Project, INRIA Paris / ENIS | 2008–2009

  • Engineering Degree in Electrical Engineering, ENIS, Sfax | 2005–2008

  • Preparatory Classes (MP), IPEIS, Sfax | 2003–2005

  • Baccalaureate in Mathematics, Tunisia | 2002–2003 – Mention Bien

💼 Professional Development

  • Maître Assistant in Artificial Intelligence, ISTIC, University of Carthage | Jan 2018–Present

  • Coach Junior, BIAT Foundation | Nov 2018–Present

  • Maître Assistant in AI, ISI Gabes | Sep 2015–Dec 2017

  • Head of Electrical Engineering Department, Ecole Polytechnique Centrale Privée de Tunis | Feb 2015–Aug 2015

  • Permanent Faculty, Ecole Polytechnique Centrale Privée de Tunis | Oct 2014–Jan 2015

🔬Research Focus

  • Artificial Intelligence & Deep Learning (RNNs, Transformers, Bayesian Networks)

  • Fault Diagnosis and Nonlinear Control (Sliding Mode, Observers)

  • IoT and Embedded Systems

  • Smart Grids and Microgrid Energy Management

  • Nanocomposite Classification and Materials Informatics

📈Author Metrics:

  • Published in leading journals including Expert Systems with Applications and Scientific Reports

  • Recent works involve hybrid deep learning approaches for nanocomposite classification and smart energy systems

  • Selected publications:

    • Classification of Nanocomposites using RNN Transformer & Bayesian Network, ESWA, 2025

    • Probabilistic and Deep Learning Approaches for Conductivity-Driven Nanocomposite Classification, Scientific Reports, 2025

    • IoT Solution for Energy Management, IREC 2023

🏆Awards and Honors:

  • Recognized contributor to interdisciplinary AI projects

  • Regular presenter at international conferences on AI, control systems, and energy informatics

  • Acknowledged for excellence in education and mentorship through BIAT Foundation coaching initiatives

📝Publication Top Notes

1. Classification of a Nanocomposite Using a Combination Between Recurrent Neural Network Based on Transformer and Bayesian Network for Testing the Conductivity Property

Journal: Expert Systems with Applications
Publication Date: April 2025
DOI: 10.1016/j.eswa.2025.126518
ISSN: 0957-4174
Authors: Wejden Gazehi, Rania Loukil, Mongi Besbes
Abstract: This study presents a hybrid AI model combining Transformer-based RNN and Bayesian Networks to classify nanocomposites based on conductivity, demonstrating improved interpretability and predictive accuracy.

2. Probabilistic and Deep Learning Approaches for Conductivity-Driven Nanocomposite Classification

Journal: Scientific Reports
Publication Date: March 7, 2025
DOI: 10.1038/s41598-025-91057-1
ISSN: 2045-2322
Authors: Wejden Gazehi, Rania Loukil, Mongi Besbes
Abstract: This paper explores probabilistic learning and deep learning methods for classifying nanocomposites with a focus on electrical conductivity, emphasizing model generalizability.

3. Enhanced Nanoparticle Classification Through Optimized Artificial Neural Networks

Conference: 2024 International Conference on Decision Aid Sciences and Applications (DASA)
Presentation Date: December 11, 2024
DOI: 10.1109/dasa63652.2024.10836425
Authors: Wejden Gazehi, Rania Loukil, Mongi Besbes
Abstract: The paper demonstrates how optimized ANN architectures can significantly improve nanoparticle classification in terms of conductivity profiling, offering an efficient pipeline for smart material characterization.

4. Improving the Classification of a Nanocomposite Using Nanoparticles Based on a Meta-Analysis Study, Recurrent Neural Network and Recurrent Neural Network Monte-Carlo Algorithms

Journal: Nanocomposites
Publication Date: July 8, 2024
DOI: 10.1080/20550324.2024.2367181
ISSN: 2055-0324, 2055-0332
Authors: Rania Loukil, Wejden Gazehi, Mongi Besbes
Abstract: Through a comparative analysis using RNN and Monte-Carlo RNN algorithms, this work proposes a robust framework for classifying nanocomposites, supported by meta-analytical insights.

5. Design and Implementation of an IoT Solution for Energy Management\

Conference: 14th International Renewable Energy Congress (IREC 2023)
Presentation Date: December 16, 2023
Authors: Rania Loukil, Neila Bediou, Hatem Oueslati, Majdi Hazami
Abstract: This contribution introduces a practical IoT-based architecture for optimizing energy consumption and monitoring within renewable energy systems, aligning with smart grid principles.

.Conclusion:

Dr. Rania Loukil stands out as an exemplary scholar combining deep learning, embedded systems, and energy informatics. Her cross-disciplinary work addresses both academic challenges and societal needs, aligning well with the objectives of a Best Scholar Award. Given her solid track record, thematic relevance, and academic leadership, she is highly deserving of this recognition.

➡️ Recommendation: Strongly endorse her nomination for the Best Scholar Award, with suggestions to highlight international collaborations, quantitative metrics, and applied impacts during the award presentation or application.

Yu Sha | Deep Learning | Best Researcher Award

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Dr. Yu Sha | Deep Learning | Best Researcher Award

Yu Sha at Xidian University, China.

Yu Sha is a doctoral researcher specializing in artificial intelligence applications for cavitation detection and intensity recognition. He is pursuing a Doctor of Engineering at Xidian University, China, and was a visiting PhD student at the Frankfurt Institute for Advanced Studies, Germany. His research focuses on AI-driven fault detection in industrial systems, with multiple publications, patents, and academic honors to his name.

Professional Profile:

Scopus

Google Scholar

Education Background

1.  Xidian University, China (2019 – Present)

    • Ph.D. in Computer Science and Technology (College of Artificial Intelligence)
    • Research Focus: Cavitation detection and intensity recognition via deep learning
    • Anticipated Graduation: June 2024

2.  Frankfurt Institute for Advanced Studies, Germany (2020 – 2022)

    • Visiting PhD Researcher (Cavitation and leakage detection using AI)

3.  Lanzhou University of Technology, China (2015 – 2019)

    • B.Sc. in Information and Computing Science
    • Ranked 1st out of 54 students

Professional Development

Yu Sha has contributed to multiple research projects at Xidian University, including AI-driven battlefield situation analysis and decision-making. His work at the Frankfurt Institute for Advanced Studies focused on AI-based cavitation and leakage detection in large-scale pump and pipeline systems. His research expertise extends to deep learning, fault diagnosis in industrial systems, and reinforcement learning.

Research Focus

  • AI-driven cavitation detection and intensity recognition
  • Fault diagnosis and predictive maintenance in industrial systems
  • Deep learning and reinforcement learning applications in engineering

Author Metrics:

  • Publications: Articles accepted in high-impact journals like Machine Intelligence Research and Mechanical Systems and Signal Processing.
  • Conferences: Research presented at ACM SIGKDD and other international venues.
  • Patents: Multiple invention patents related to cavitation detection, face aging estimation, and heart rate estimation

Awards and Honors:

  • Outstanding Doctoral Student, Xidian University (2021, 2022)
  • Multiple Graduate Student Academic Scholarships (First & Second Level)
  • National Encouragement Scholarship (2016, 2017)
  • First Prize in multiple mathematical modeling and AI competitions, including MCM/ICM, MathorCup, and Teddy Cup Data Mining Challenge

Publication Top Notes

1. A Multi-Task Learning for Cavitation Detection and Cavitation Intensity Recognition of Valve Acoustic Signals

  • Authors: Yu Sha, Johannes Faber, Shuiping Gou, Bo Liu, Wei Li, Stefan Schramm, Horst Stoecker, Thomas Steckenreiter, Domagoj Vnucec, Nadine Wetzstein, Andreas Widl, Kai Zhou
  • Published In: Engineering Applications of Artificial Intelligence, Volume 113, August 2022, Article 104904
  • DOI: 10.1016/j.engappai.2022.104904
  • Publisher: Elsevier Ltd.
  • Abstract: The paper proposes a novel multi-task learning framework using 1-D double hierarchical residual networks (1-D DHRN) for simultaneous cavitation detection and cavitation intensity recognition in valve acoustic signals. The approach addresses challenges such as limited sample sizes and poor separability of cavitation states by employing data augmentation techniques and advanced neural network architectures. The framework demonstrated high prediction accuracies across multiple datasets, outperforming other deep learning models and conventional methods.
  • Access: The full paper is available at https://www.sciencedirect.com/science/article/pii/S0952197622001361

2. An Acoustic Signal Cavitation Detection Framework Based on XGBoost with Adaptive Selection Feature Engineering

  • Authors: Yu Sha, Johannes Faber, Shuiping Gou, Bo Liu, Wei Li, Stefan Schramm, Horst Stoecker, Thomas Steckenreiter, Domagoj Vnucec, Nadine Wetzstein, Andreas Widl, Kai Zhou
  • Published In: Measurement, Volume 192, June 2022, Article 110897
  • DOI: 10.1016/j.measurement.2022.110897
  • Publisher: Elsevier Ltd.
  • Abstract: This study introduces a framework combining XGBoost with adaptive selection feature engineering (ASFE) for detecting cavitation in valves using acoustic signals. The methodology includes data augmentation through a non-overlapping sliding window, feature extraction using fast Fourier transform (FFT), and adaptive feature engineering to enhance input features for the XGBoost algorithm. The framework achieved satisfactory prediction performance in both binary and four-class classifications, outperforming traditional XGBoost models.
  • Access: The full paper is available at https://www.sciencedirect.com/science/article/pii/S0263224122001798

3. Regional-Local Adversarially Learned One-Class Classifier Anomalous Sound Detection in Global Long-Term Space

  • Authors: Yu Sha, Shuiping Gou, Johannes Faber, Bo Liu, Wei Li, Stefan Schramm, Horst Stoecker, Thomas Steckenreiter, Domagoj Vnucec, Nadine Wetzstein, Andreas Widl, Kai Zhou
  • Published In: Proceedings of the 28th ACM SIGKDD Conference on Knowledge Discovery and Data Mining, August 2022
  • DOI: 10.1145/3534678.3539133
  • Publisher: Association for Computing Machinery (ACM)
  • Abstract: This paper introduces a multi-pattern adversarial learning one-class classification framework for anomalous sound detection (ASD) in mechanical equipment monitoring. The framework utilizes two auto-encoding generators to reconstruct normal acoustic data patterns, extending the discriminator’s role to distinguish between regional and local pattern reconstructions. A global filter layer is also presented to capture long-term interactions in the frequency domain without human priors. The proposed method demonstrated superior performance on four real-world datasets from different industrial domains, outperforming recent state-of-the-art ASD methods.
  • Access: The full paper is available at https://dl.acm.org/doi/10.1145/3534678.3539133

4. A Study on Small Magnitude Seismic Phase Identification Using 1D Deep Residual Neural Network

  • Authors: Wei Li, Megha Chakraborty, Yu Sha, Kai Zhou, Johannes Faber, Georg Rümpker, Horst Stöcker, Nishtha Srivastava
  • Published In: Artificial Intelligence in Geosciences, Volume 3, December 2022, Pages 115-122
  • DOI: 10.1016/j.aiig.2022.10.002
  • Publisher: KeAi Publishing Communications Ltd.
  • Abstract: This study develops a 1D deep Residual Neural Network (ResNet) to address the challenges of seismic signal detection and phase identification, particularly for small magnitude events or signals with low signal-to-noise ratios. The proposed method was trained and tested on datasets from the Southern California Seismic Network, demonstrating high accuracy and robustness in identifying seismic phases, thereby offering a valuable tool for seismic monitoring and analysis.
  • Access: The full paper is available at https://www.sciencedirect.com/science/article/pii/S2666544122000284

5. Deep Learning-Based Small Magnitude Earthquake Detection and Seismic Phase Classification

  • Authors: Wei Li, Yu Sha, Kai Zhou, Johannes Faber, Georg Ruempker, Horst Stoecker, Nishtha Srivastava
  • Published In: arXiv preprint arXiv:2204.02870, April 2022
  • DOI: N/A
  • Publisher: arXiv
  • Abstract: This paper investigates two deep learning-based models, namely 1D

Conclusion

Dr. Yu Sha is a highly deserving candidate for the Best Researcher Award due to his pioneering contributions to AI-driven cavitation detection, deep learning applications, and fault diagnosis in industrial systems. His strong academic record, international exposure, high-impact publications, and patent portfolio make him a standout researcher in deep learning for industrial applications. With further industry collaborations and expanded leadership roles, he could solidify his reputation as a global leader in AI-based fault detection.

Mohammad Reza Nikpour | Artificial Intelligence | Best Researcher Award

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Assoc. Prof. Dr. Mohammad Reza Nikpour | Artificial Intelligence | Best Researcher Award

Mohammad Reza Nikpour at University of Mohaghegh Ardabili, Iran📖

Dr. Mohammad Reza Nikpour is an esteemed scholar in Water Engineering, currently serving as a faculty member at the University of Mohaghegh Ardabili, Iran. His expertise lies in hydrodynamics, river engineering, and water resource management, with extensive contributions to computational modeling and environmental sustainability.

Profile

Scopus Profile

Orcid Profile

Google Scholar Profile

Education Background🎓

  • Ph.D. in Water Engineering, University of Mohaghegh Ardabili, Iran
  • M.Sc. in Water Engineering, University of Mohaghegh Ardabili, Iran
  • B.Sc. in Water Engineering, University of Mohaghegh Ardabili, Iran

Professional Experience🌱

Dr. Nikpour has been actively involved in academic research and teaching at the University of Mohaghegh Ardabili. His work focuses on computational hydrodynamics, groundwater quality assessment, and flood prediction modeling. He has collaborated with international researchers and contributed to innovative water management solutions through data-driven models.

Research Interests🔬

Her research interests include:

  • Hydrodynamics and River Engineering
  • Groundwater Quality Assessment
  • Soft Computing and AI Applications in Water Resource Management
  • Flood Prediction and Climate Change Impact Studies

Author Metrics

Dr. Mohammad Reza Nikpour has established a strong academic presence with numerous publications in high-impact journals, including River Research and Applications, Journal of Cleaner Production, and Stochastic Environmental Research and Risk Assessment. His research contributions have been widely recognized, earning him a growing citation count on Google Scholar and an impressive h-index on Scopus (to be verified). As a highly cited researcher in water engineering, his work has significantly influenced hydrodynamics, groundwater quality assessment, and computational water resource management. His ORCID ID is 0000-0003-4332-0525, and his research continues to shape innovative solutions in environmental sustainability and AI-driven water system modeling.

Awards and Honors
  • Recognized for outstanding contributions in hydrodynamic modeling and water resource sustainability.
  • Published multiple high-impact research papers in top-tier journals such as River Research and Applications, Journal of Cleaner Production, and Stochastic Environmental Research and Risk Assessment.
  • Recipient of research grants and funding for pioneering studies in environmental and computational water management.
Publications Top Notes 📄

1. Estimation of daily pan evaporation using two different adaptive neuro-fuzzy computing techniques

  • Authors: H. Sanikhani, O. Kisi, M.R. Nikpour, Y. Dinpashoh
  • Journal: Water Resources Management
  • Volume: 26
  • Pages: 4347-4365
  • Year: 2012
  • Citations: 70
  • Summary: This study applies adaptive neuro-fuzzy inference system (ANFIS) models to estimate daily pan evaporation, comparing their accuracy and efficiency in hydrological forecasting.

2. Experimental and numerical simulation of water hammer

  • Authors: M.R. Nikpour, A.H. Nazemi, A.H. Dalir, F. Shoja, P. Varjavand
  • Journal: Arabian Journal for Science and Engineering
  • Volume: 39
  • Pages: 2669-2675
  • Year: 2014
  • Citations: 48
  • Summary: This paper investigates water hammer phenomena using both experimental methods and numerical simulations, providing insights into fluid dynamics and pipeline safety.

3. Exploring the application of soft computing techniques for spatial evaluation of groundwater quality variables

  • Authors: F. Esmaeilbeiki, M.R. Nikpour, V.K. Singh, O. Kisi, P. Sihag, H. Sanikhani
  • Journal: Journal of Cleaner Production
  • Volume: 276
  • Article: 124206
  • Year: 2020
  • Citations: 31
  • Summary: This research explores soft computing techniques, such as machine learning, for the spatial analysis of groundwater quality, enhancing environmental monitoring and sustainability.

4. Hydrodynamics of river-channel confluence: toward modeling separation zone using GEP, MARS, M5 Tree, and DENFIS techniques

  • Authors: O. Kisi, P. Khosravinia, M.R. Nikpour, H. Sanikhani
  • Journal: Stochastic Environmental Research and Risk Assessment
  • Volume: 33 (4-6)
  • Pages: 1089-1107
  • Year: 2019
  • Citations: 28
  • Summary: The study applies various data-driven models, including gene expression programming (GEP) and M5 Tree, to model separation zones in river confluences, improving hydrodynamic predictions.

5. Application of novel data mining algorithms in prediction of discharge and end depth in trapezoidal sections

  • Authors: P. Khosravinia, M.R. Nikpour, O. Kisi, Z.M. Yaseen
  • Journal: Computers and Electronics in Agriculture
  • Volume: 170
  • Article: 105283
  • Year: 2020
  • Citations: 16
  • Summary: This paper investigates the use of advanced data mining techniques to predict discharge and end depth in trapezoidal channels, optimizing water resource management and agricultural planning.

Conclusion

Dr. Mohammad Reza Nikpour is an exceptional researcher in AI-driven water resource management, making him a strong candidate for the Best Researcher Award. His pioneering work in soft computing and AI applications for hydrology and environmental sustainability sets him apart in his field. Expanding into deep learning, increasing industry collaborations, and engaging in AI conferences could further solidify his leadership in AI for water engineering.