At ISPRS GSW 2025, we are excited to offer four tutorials carefully crafted to align with the conference theme, “Photogrammetry and Remote Sensing for a Better Tomorrow.” These tutorials will take place on Sunday, April 6th, 2025, providing a dedicated day for in-depth learning and skill development. Each tutorial will run for 3 hours, divided into two 1.5-hour sessions with a 30-minute break in between.
The tutorials will cover topics spanning photogrammetry, remote sensing, spatial sciences, and related technologies, ensuring participants gain a well-rounded understanding of the field. Designed to address recent advancements, methodologies, tools, and practical applications, these sessions will equip attendees with the knowledge needed to tackle current challenges and innovate for the future. Whether you are a researcher, practitioner, or student, these tutorials promise an engaging and enriching learning experience.
6th April 2025 | 09:00 – 12:30 | Hall A
Presented By: Ayman F. Habib, Thomas A. Page Professor in Civil Engineering, Lyles School of Civil and Construction Engineering, Purdue University, USA
Objectives and Learning Outcomes: This tutorial will provide an overview of recent activities focusing on UAV-based mapping while highlighting:
Target audience and prerequisites: The tutorial is targeted for researchers and practitioners interested in using uncrewed aerial vehicles for near proximal sensing using directly georeferenced imagery and/or LiDAR data for cost-effective mapping to address the needs of various applications (e.g., transportation, agriculture, forestry, public safety, and infrastructure monitoring). The basic principles of photogrammetric and LiDAR mapping will be covered. The audience should have some background in using geospatial data and products from imaging and ranging systems.
Technical requirements (software, hardware, etc.): Trial version of PIX4Dmapper for the first practical exercise and CloudCompare for the second one. A laptop with reasonable processing power will be sufficient. Wireless or wired internet connection is required.
Brief biography of the instructor: Dr. Habib is the Thomas A. Page professor of Civil and Construction Engineering at Purdue University and the Co-Director of the Civil Engineering Center for Applications of UAS for a Sustainable Environment (CE-CAUSE). He is also the Associate Director of Purdue University’s Joint Transportation Research Program (JTRP) and Institute of Digital Forestry (iDiF). His research interests span the fields of terrestrial and aerial mobile mapping systems. Over the last ten years, he has been involved in the development, integration, and utilization of wheel-based and UAV-based mobile mapping systems for a wide range of applications in precision agriculture, geometric documentation of transportation corridors, digital forestry, crash scene reconstruction, cultural heritage documentation, environmental management, and infrastructure monitoring.
6th April 2025 | 09:00 – 12:30 | Hall B
Overview: This tutorial provides a hands-on approach to urban monitoring and analysis using remote sensing and spatial information technology. Participants will explore key concepts like urban heat islands, local climate zones, urban air quality, and spatial patterns. Through guided exercises and case studies attendees will learn practical techniques for urban data extraction, classification, and spatial analysis. The session is ideal for those with GIS skills, basic programming knowledge, and an active Google Earth Engine account.
Objectives and Learning Outcomes : The tutorial will focus on urban monitoring and analysis with remote sensing and spatial information technology, providing participants with a comprehensive understanding of the subject matter, including recent advancements, methodologies, tools, and practical applications. Attendees will learn about the urban heat island effect and the local climate zone classification system. They will learn how to conduct a local climate zone classification for urban environments. The tutorial will last 3 hours. A 10-minute brief introduction will be given at the beginning. Then four lectures will be arranged, each lasting about 30 minutes, and 10 minutes will be left for Q&A.
Target audience and prerequisites: Good GIS skills, and a basic understanding of remote sensing, image processing, and classification techniques. Basic programming skills (Python, JavaScript). Activated Google Earth Engine account.
Technical requirements (software, hardware, etc.): Projector, computer, microphone, laser pointer, and other essentials to have QGIS (long term release) installed to carry out the practical part.
Brief introduction of instructors:
Prof. Maria Antonia Brovelli, Politecnico di Milano (POLIMI), Italy, Moderator
Maria Antonia Brovelli holds a Ph.D. in Geodesy and Cartography and serves as a Professor of GIS and The Copernicus Green Revolution for Sustainable Development at Politecnico di Milano (PoliMI). With a career spanning from researcher to Full Professor and Vice-Rector for the Como Campus at PoliMI, she also lectures at ETH Zurich and holds prominent roles in international organizations. As Vice President of the ISPRS Technical Commission on Spatial Information Science, co-chair of the United Nations Open GIS Initiative, chair of the UN-GGIM Academic Network, and curator of the GEO series at AI For Good Summit, she influences global spatial information science. Brovelli’s extensive publication record and involvement in national and European projects have earned her prestigious awards and editorial roles, highlighting her significant contributions and leadership in the field.
Prof. JIANG Jie, Beijing University of Civil Engineering and Architecture (BUCEA), China, Moderator
Prof. Dr. JIANG Jie received her BSc. and MSc. degrees in Applied Geophysics from the Changchun University of Geology, China, and PhD in Surveying Engineering from China University of Mining and Technology (Beijing). She worked as a remote sensing and GIS specialist in National Geomatics Center of China. Since October 2018, she serves as full professor in School of Geomatics and Urban Spatial Informatics, BUCEA. Her recent research focuses on spatial-temporal modelling for smart city. She is now ISPRS Fellow, and the Secretary General of ISPRS (for term 2022-2026).
Overview: Google Earth Engine (GEE) is a powerful cloud-based platform designed for geospatial processing, providing unmatched capabilities for analyzing and visualizing vast amounts of satellite imagery and spatial data. Its ability to process data at scale makes it an essential tool for Land Use and Land Cover (LULC) classification, a critical task for accurately mapping land types and supporting informed decision-making in fields such as urban planning, resource management, and environmental conservation.
In this tutorial, participants will explore GEE’s JavaScript interface (GEE JS) to conduct supervised LULCC, showcasing its analytical strength in spatial analysis. Through a hands-on exercise, participants will not only gain practical experience but also enhance their understanding of key concepts in remote sensing, spatial analysis, and cloud computing. By working with real-world examples, they will learn to apply these skills effectively in diverse contexts.
Objectives and Learning Outcomes: By the end of this tutorial, participants will:
The tutorials’ outlines are listed below:
1. Introduction to Google Earth Engine (GEE)
2. Accessing and preparing Satellite Imagery
3. Working with Training Data
4. Supervised Classification Algorithms
5. Validating and Evaluating the Classification
6. Visualizing and Exporting Results
7. Case Study: LULC Classification of a Specific Region
8. Q&A and Troubleshooting
Target audience and prerequisites: This tutorial is ideal for environmental scientists, practitioners, and researchers involved in Land Use and Land Cover (LULC) analysis, as well as students and professionals in GIS, remote sensing, data science, and spatial data analysis. It is also suitable for those with basic programming skills who wish to expand their knowledge of Google Earth Engine (GEE) and LULC classification techniques. Participants should have a Google Earth Engine account, a foundational understanding of remote sensing and geographic information systems (GIS), and familiarity with basic programming skills
Technical requirements (software, hardware, etc.): Participants need an activated Google Earth Engine (GEE) account, a stable internet connection, a modern web browser, and a computer with 8 GB RAM. Basic programming skills and access to external GIS data files are also recommended.
Brief biography of the instructor:
Dr. Rifaat Abdalla is a faculty member in the Department of Earth Sciences at the College of Science, Sultan Qaboos University. With expertise in geospatial science and environmental analysis, Dr. Abdalla has contributed extensively to research in Earth sciences, specializing in remote sensing and land use classification.
Dr. Eltaib Saeed Ganawa is a professor at the Faculty of Geographical and Environmental Sciences at the University of Khartoum, Sudan. Dr. Ganawa’s work focuses on GIS, spatial data analysis, and environmental management, with a strong background in integrating geospatial technology into environmental research.
Dr. Mohammed Mahmoud Musa is a member of the Faculty of Computer Science and Information Technology at Alzaiem Alazhari University, Sudan. His research spans GIS applications, data processing, and remote sensing, applying computational techniques to environmental and geographical studies.
Dr. Anwarelsadat Eltayeb Elmahal also serves at the Faculty of Geographical and Environmental Sciences, University of Khartoum. With a background in geospatial analysis, Dr. Elmahal specializes in environmental assessment and spatial data applications, contributing valuable insights into regional land use and environmental policy.
Overview: In this course, different methods for using SAR systems for surface motion estimation are introduced. Students will learn how to develop code for using these methods further by using large language models (LLM). It is designed for graduate students in Geographic Information Sciences and Remote Sensing. The course includes the following topics:
Objectives and Learning Outcomes:
Target Audience and Prerequisites: This course is designed for graduate students in Geographic Information Sciences, Remote Sensing, or related fields who have a foundational understanding of SAR remote sensing and image processing. Participants should be comfortable with Python programming, as coding for SAR methods is a core component of the course. Prior exposure to differential SAR interferometry (D-InSAR) and Permanent Scatterer Interferometry (PSInSAR) is helpful but not required. An interest in using large language models (LLMs) for coding support and processing chain development will also be beneficial.
Technical requirements (software, hardware, etc.): Participants need a stable internet connection, a modern web browser (preferably Chrome or Firefox), and a computer with at least 8 GB of RAM. Python programming environment set up is also required for hands-on coding exercises.
Brief introduction of instructors:
Prof. Timo Balz is an expert in remote sensing and Geographic Information Sciences, with a focus on synthetic aperture radar (SAR) technology for environmental monitoring and surface motion estimation. He has published extensively and contributed to significant research projects in advanced remote sensing methodologies.
Assoc. Prof. Bahaa Mohamadi specializes in remote sensing and geospatial analysis, particularly in differential SAR interferometry (D-InSAR). He is known for developing innovative techniques for analyzing SAR data and integrating machine learning into remote sensing research, with numerous publications and collaborative contributions to the field.