Shayan Ghazimoghadam | Structural Health Monitoring | Best Researcher Award

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Mr. Shayan Ghazimoghadam | Structural Health Monitoring | Best Researcher Award

PhD Student, Islamic Azad University, Iran

Shayan Ghazimoghadam is a Ph.D. student in Structural Engineering at Islamic Azad University of Shahrood, Iran, specializing in data-driven structural health monitoring. His research integrates artificial intelligence with civil engineering to develop unsupervised deep learning methods for real-time damage detection in structures. Shayan’s work focuses on creating digital twins for infrastructure assessment, aiming to enhance predictive maintenance and safety. He has authored several publications, including a notable paper on vibration-based damage diagnosis using multi-head self-attention LSTM autoencoders, published in Measurement journal. Additionally, he has presented his research at national conferences and served as a keynote speaker, demonstrating his commitment to advancing the field of structural health monitoring.

Profile

Google Scholar​

Education

Shayan Ghazimoghadam completed his Bachelor of Science in Civil Engineering at Islamic Azad University of Gorgan, Iran, in 2018, where he excelled in design courses, achieving a GPA of 19/20 in Steel Structures and a perfect 20/20 in Concrete Structures. He then pursued a Master of Science in Structural Engineering at Lamei Gorgani Institute of Higher Education, Gorgan, graduating in 2022 with a GPA of 19.07/20. His master’s dissertation focused on structural damage identification under ambient vibration using an unsupervised deep learning method, supervised by Dr. Seyed Ali Asghar Hosseinzadeh. Currently, Shayan is a Ph.D. student at Islamic Azad University of Shahrood, Iran, where he continues to explore innovative approaches in structural health monitoring and artificial intelligence applications in civil engineering.

Experience 

Between 2022 and 2023, Shayan Ghazimoghadam served as a Research Assistant at Golestan University, Gorgan, Iran, under the guidance of Dr. Seyed Ali Asghar Hosseinzadeh. During this period, he conducted research on real-time structural health monitoring utilizing AI-powered techniques. His work involved developing and testing unsupervised deep learning algorithms for damage detection in structures based on vibration data. Shayan’s contributions led to the presentation of his findings at national conferences, showcasing his ability to communicate complex research outcomes effectively. This experience has significantly enhanced his expertise in integrating artificial intelligence with structural engineering, positioning him as a promising researcher in the field of structural health monitoring.

Awards and Honors 

Shayan Ghazimoghadam has been recognized for his academic excellence and research contributions. He ranked first among M.Sc. students in Structural Engineering at Lamei Gorgani Institute of Higher Education, Gorgan, Iran, in 2022, achieving a GPA of 19.07/20. His innovative research on structural damage identification using unsupervised deep learning methods has been published in reputable journals, including the Measurement journal, where his paper has garnered 26 citations as of 2024. Additionally, Shayan was invited as a keynote speaker at the 3rd National Conference on Civil Engineering, Intelligent Development, and Sustainable Systems in 2023, where he presented on AI-powered structural damage identification and localization through accelerometer data. These accolades underscore his commitment to advancing the field of structural health monitoring and his potential for future contributions to civil engineering research.

Research Focus

Shayan Ghazimoghadam’s research focuses on the integration of artificial intelligence with structural health monitoring (SHM) to develop innovative solutions for infrastructure maintenance. His primary interests include data-driven SHM, unsupervised structural damage identification, and the application of digital twins for condition assessment. Shayan aims to enhance the accuracy and efficiency of damage detection in structures by employing unsupervised deep learning techniques, particularly multi-head self-attention LSTM autoencoders. His work contributes to the development of digital twins, virtual representations of physical assets, to monitor and assess the condition of infrastructure in real time. By leveraging AI and machine learning, Shayan seeks to revolutionize traditional SHM practices, offering more proactive and predictive maintenance strategies that can lead to safer and more sustainable infrastructure systems.

Publication Top Notes​

📘 1. A Novel Unsupervised Deep Learning Approach for Vibration-Based Damage Diagnosis Using a Multi-Head Self-Attention LSTM Autoencoder

Authors: S. Ghazimoghadam, S.A.A. Hosseinzadeh
Journal: Measurement, Volume 229, Article 114410
Year: 2024
Citations (as of 2025): 26
DOI: Measurement 229, 114410 (sample link, please verify)

🔍 Summary:

This publication introduces a novel unsupervised deep learning method for real-time structural damage detection using only ambient vibration data. The approach combines Long Short-Term Memory (LSTM) autoencoders with multi-head self-attention mechanisms, enabling the system to effectively learn temporal features and focus on critical data patterns without the need for labeled damage data.

By leveraging unsupervised learning, the model is highly adaptable and scalable, making it suitable for practical deployment in real-world structural health monitoring (SHM) scenarios. The method was validated using benchmark datasets, showing superior performance in damage localization and diagnosis accuracy compared to traditional approaches.

📗 2. Transformer-Based Time-Series GAN for Data Augmentation in Bridge Monitoring Digital Twins

Authors: V. Mousavi, M. Rashidi, S. Ghazimoghadam, M. Mohammadi, B. Samali
Journal: Automation in Construction, Volume 175, Article 106208
Year: 2025 (Under Review)
DOI: Automation in Construction 175, 106208 (check for final link when published)

🔍 Summary:

This paper presents a Transformer-based Generative Adversarial Network (GAN) for augmenting time-series sensor data in bridge monitoring systems. The technique is particularly geared towards Digital Twin models, which require large, diverse, and high-quality datasets to simulate and predict structural behavior accurately.

The GAN architecture uses a Transformer encoder to better capture temporal dependencies in structural response data, generating realistic synthetic datasets for training SHM models. By augmenting scarce or incomplete datasets, this method improves predictive performance, anomaly detection, and damage assessment capabilities of digital twins used in civil infrastructure.

Stéphane Lambert | Natural Hazards | Best Researcher Award

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Dr Stéphane Lambert | Natural Hazards | Best Researcher Award

Dr Stéphane Lambert, Inraa, France

Dr. Stéphane Lambert is a leading expert in mitigating gravity-driven natural hazards, focusing on the protection of civil engineering structures against rockfalls, snow avalanches, and torrent-related hazards. He applies multi-scale experimental and numerical methods to understand and enhance the mechanical response and efficiency of these protective systems. With extensive experience in both research and teaching, Dr. Lambert contributes significantly to the field through numerous publications and supervision of students and post-doctoral researchers. He is affiliated with the IGE Laboratory at INRAE in Grenoble, where he has been instrumental in advancing knowledge and technology in this vital area of study.

Publication Profile

Orcid

Scopus

Strengths for the Award

  1. Extensive Expertise: Dr. Stéphane Lambert is a senior researcher with a profound specialization in mitigating gravity-driven natural hazards. His expertise spans a broad range of topics, including rockfalls, snow avalanches, and torrent-related hazards.
  2. Robust Academic Background: With a Habilitation to Supervise Research (2020), a Ph.D. in Mechanics (2007), and a Master’s in Geomechanics (1994), Dr. Lambert’s educational credentials highlight a strong foundation in relevant scientific disciplines.
  3. Significant Research Contributions: His research work is well-documented with 42 peer-reviewed articles, 90 proceedings, and 2 book chapters. His publications focus on experimental and numerical modeling, impact responses, and structural efficiencies, demonstrating a comprehensive approach to natural hazard mitigation.
  4. Innovative Work: Dr. Lambert’s recent publications, such as those on Bayesian inference for rockfall protection structures and small-scale modeling of flexible barriers, reflect his commitment to advancing the field through innovative methodologies and applications.
  5. Leadership and Collaboration: He has effectively supervised numerous PhD students, post-docs, and master students, and actively collaborates with other researchers and institutions, indicating strong leadership and collaborative skills.

Areas for Improvement

  1. Broader Outreach: While Dr. Lambert’s work is highly specialized, expanding outreach to interdisciplinary fields could enhance the broader impact of his research. Engaging with other areas like climate change or urban planning might broaden the application and relevance of his findings.
  2. Public Engagement: Increasing efforts to communicate research outcomes to the public and stakeholders could enhance the practical application of his work and improve societal impact.
  3. Grant Acquisition: Pursuing additional research grants or funding opportunities could support further advancements in his research and expand the scope of his projects.

Education

Dr. Lambert earned his Habilitation to Supervise Research from Université Grenoble Alpes in 2020. He holds a Ph.D. in Mechanics from Université Grenoble I, completed in 2007, and a Master’s degree in Geomechanics from the same institution in 1994. His educational background provides a robust foundation for his current research and contributions to the field of natural hazard mitigation.

Experience

Dr. Lambert has been a Research Engineer at the IGE Laboratory, INRAE (formerly Irstea), Grenoble since 2009. Prior to this, he was a PhD student and Engineer at the ETNA research unit, Cemagref, in Grenoble and Antony. His roles have involved conducting advanced research in rockfall and avalanche protection systems, contributing to various high-impact projects and publications. His career reflects a deep commitment to understanding and improving protective measures against natural hazards.

Research Focus

Dr. Lambert’s research revolves around the mechanical response of civil engineering structures to gravity-driven natural hazards. His work includes experimental and numerical studies on the impact responses of rockfall protection systems, the mechanical behavior of flexible barriers, and the efficiency assessment of protective structures. He aims to enhance the design and effectiveness of these systems to better protect against rockfalls, snow avalanches, and torrents.

Publications

  1. Bayesian inference based inverse analysis of the impact response of a rockfall protection structure: Application towards warning and survey 🌍🔬
  2. Flexible Facing Systems for Surficial Slope Stabilisation: A Literature Review 📚🏔️
  3. Bayesian interface based calibration of a novel rockfall protection structure modelled in the non-smooth contact dynamics framework 🔍📊
  4. Flexible barrier and flow-driven woody debris: an experimental investigation of their interaction 🌲🔬
  5. Small-Scale Modeling of Flexible Barriers. I: Mechanical Similitude of the Structure 🔧📐
  6. Small-Scale Modeling of Flexible Barriers. II: Interactions with Large Wood 🌳🔧

Conclusion

Dr. Stéphane Lambert is an exemplary candidate for the Research for Best Researcher Award due to his extensive expertise, innovative contributions, and leadership in the field of natural hazard mitigation. His research has made significant strides in understanding and improving protective structures against gravity-driven natural hazards. By addressing the suggested areas for improvement, Dr. Lambert could further amplify his impact and solidify his position as a leading researcher in his field.