This book provides a broad understanding of tracking climate change impacts on the coastal dynamics and their impacts on coastal geomorphological changing. Advanced InSAR techniques are discussed including a case study focussing on the coastal urban of Alexandria city in Egypt, Singaporean urban zone and other possible coastal cities.
Interferometric Synthetic Aperture Radar (InSAR) technology is an operational tool for measuring and monitoring coastal urban stability, including the disappearance of coastal cities. This book provides a comprehensive understanding of how to track climate change impacts on coastal dynamics and their consequent effects on coastal geomorphological changes. Advanced InSAR techniques are discussed, including case studies focusing on the coastal urban areas of Alexandria, Egypt, and Singapore, as well as other potential coastal cities. This book:
- Describes the use of advanced radar technology for monitoring wave impacts and coastal city damage
- Introduces new InSAR technologies for assessing coastal infrastructure and urban disappearance
- Addresses the integration of modern radar interferometry modeling in coastal city sustainability
- Discusses innovative approaches to model and simulate coastal sediment processes and erosion using space-based interferometry
- Explores the forecasting of city disappearance and collapse through examples utilizing TerraSAR spot mode data
This book is intended for graduate students and researchers in coastal engineering, environmental sciences, remote sensing, computer modeling, and image/signal processing.
1.Principles of Nonlinear Mechanisms Governing Water Wave Theories
2.
Theoretical Analysis of Nonlinear Sea-Level Rise and Its Impact on Coastal
Subsidence
3. Quantization Principles in Radar and Radar Interferometry
Signal Processing
4. Novel Quantum-Theoretic Synthetic Aperture Radar Imaging
Mechanism for Ocean Wave Spectra
5. MAGEDISM Framework for Retrieving
Shoreline Deformation from Nonlinear Wave Spectra Derived from Polarimetric
SAR Observations
6. MAGEDISM Theory for Retrieving Shoreline Change Rates
Using Along-Track Interferometry
7. Microwave Altimetry Principles: A
Comprehensive Analysis of Satellite Data
8. Investigating Nonlinear
Variations in Sea Surface Height Levels in Coastal Waters through Advanced
Interferometric Satellite Altimetry Data
9. MAGEDISM Quantum Topological
Algorithm and Quantum Multi-Temporal InSAR for Coastal Land Deformation
Modeling: A Case Study of Singapore
10. Quantum Neural Networks and MAGEDISM
Quantum Topology Spectra for Coastal Subsidence Monitoring: A Case Study of
Jakarta, Indonesia
11. Tsunami Inundation and Coastal Impact Simulation Using
Quantum Convolutional Neural Networks: Insights from the 2004 Banda Aceh Case
Study
12. Four-Dimensional Marghany Hologram-TomoSAR Algorithm for Coastal
Monitoring and Disappearance Risk Assessment in Alexandria
Maged Marghany, the visionary behind the innovative theory titled "Quantized Marghanys Front," is the Director at Safanad Information Technology in Malaysia. Dr. Marghany has been listed among the top 2% of scientists for four consecutive years2020, 2021, 2022, 2023, and 2024 by Stanford University. Furthermore, his profound impact is reflected in the recognition of two of his books, acknowledged among the best genetic algorithm books of all time. His ongoing commitment continues to shape the landscape of scientific thought and geoinformation expertise. Additionally, Maged Marghany achieved the remarkable distinction of being ranked first among oil spill scientists in a global list spanning the last 50 years, compiled by the prestigious Universidad Estadual de Feira de Santana in Brazil. He also a distinguished visiting professor at Malikussaleh University and other universities in Indonesia. In previous roles, He was directed some initiations in Malaysia. His educational journey includes a post-doctoral degree in radar remote sensing, a PhD in environmental remote sensing, and a Master of Science in physical oceanography. With over 250 papers and influential books like "Advanced Remote Sensing Technology for Tsunami Modeling and Forecasting," Dr. Marghany's significant contributions shape global perspectives in remote sensing, geospatial applications, and environmental science.
