LiDAR Principles, Processing and Applications in Forest Ecology
Autor Qinghua Guo, Yanjun Su, Tianyu Huen Limba Engleză Paperback – 9 mar 2023
Sections give a brief history and introduce the principles of LiDAR, as well as three commonly seen LiDAR platforms. The book lays out step-by-step coverage of LiDAR data processing and forest structure parameter extraction, complete with Python examples. Given the increasing usefulness of LiDAR in forest ecology, this volume represents an important resource for researchers, students and forest managers to better understand LiDAR technology and its use in forest ecology across the world. The title contains over 15 years of research, as well as contributions from scientists across the world.
- Presents LiDAR applications for forest ecology based in real-world experience
- Lays out the principles of LiDAR technology in forest ecology in a systematic and clear way
- Provides readers with state-of the-art algorithms on how to extract forest parameters from LiDAR
- Offers Python code examples and sample data to assist researchers in understanding and processing LiDAR data
- Contains over 15 years of research on LiDAR in forest ecology and contributions from scientists working in this field across the world
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Specificații
ISBN-13: 9780128238943
ISBN-10: 0128238941
Pagini: 510
Ilustrații: 708 illustrations (100 in full color)
Dimensiuni: 152 x 229 x 34 mm
Greutate: 0.82 kg
Editura: ELSEVIER SCIENCE
ISBN-10: 0128238941
Pagini: 510
Ilustrații: 708 illustrations (100 in full color)
Dimensiuni: 152 x 229 x 34 mm
Greutate: 0.82 kg
Editura: ELSEVIER SCIENCE
Cuprins
1. The Origin and Development of LiDAR Active Remote Sensing Technology
2. Working principle of LiDAR 2.1 Ranging principle of LiDAR
3. Field work flow and system error source of LiDAR
4. LiDAR data format
5. LiDAR data filtering and digital elevation model generation
6. Data Analysis and Feature Extraction of Terrestrial LiDAR
7. Data Analysis and Feature Extraction of Airborne LiDAR
8. Data Analysis and Feature Extraction of Spaceborne LiDAR
9. Forest Structural Parameters Extraction
10. Ecosystem Function Parameters Inversion and Large-scale Simulation
11. Applications of LiDAR in dynamic monitoring of forest ecosystem
12. Applications of LiDAR technology in forest biodiversity, hydrology, and ecological models
13. 3D visualization and reconstruction of vegetation based on LiDAR technology
14. Emerging and ecological application of the near-surface LiDAR platform
15. Challenges and applications of LiDAR
2. Working principle of LiDAR 2.1 Ranging principle of LiDAR
3. Field work flow and system error source of LiDAR
4. LiDAR data format
5. LiDAR data filtering and digital elevation model generation
6. Data Analysis and Feature Extraction of Terrestrial LiDAR
7. Data Analysis and Feature Extraction of Airborne LiDAR
8. Data Analysis and Feature Extraction of Spaceborne LiDAR
9. Forest Structural Parameters Extraction
10. Ecosystem Function Parameters Inversion and Large-scale Simulation
11. Applications of LiDAR in dynamic monitoring of forest ecosystem
12. Applications of LiDAR technology in forest biodiversity, hydrology, and ecological models
13. 3D visualization and reconstruction of vegetation based on LiDAR technology
14. Emerging and ecological application of the near-surface LiDAR platform
15. Challenges and applications of LiDAR
Notă biografică
Dr. Qinghua Guo is currently a professor in Peking University, and serves as the director of the Institute of Remote Sensing & Geographical Information System, Peking University. He received the B.S. and M.S. degrees in Peking University, and the Ph.D degrees in University of California Berkeley. His recent research interests lie in developing near-surface (e.g., backpack, UAV and mobile) Lidar hardware and data processing software systems and combining them with airborne and spaceborne remote sensing data to map vegetation attributes (e.g., tree height, LAI, AGB, vegetation type) from individual plant scale to national and global scales. So far, he has published over 160 peer-reviewed papers.