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Machine Learning for Planetary Science
- 1st Edition - March 22, 2022
- Editors: Joern Helbert, Mario D'Amore, Michael Aye, Hannah Kerner
- Language: English
- Paperback ISBN:9 7 8 - 0 - 1 2 - 8 1 8 7 2 1 - 0
- eBook ISBN:9 7 8 - 0 - 1 2 - 8 1 8 7 2 2 - 7
Machine Learning for Planetary Science presents planetary scientists with a way to introduce machine learning into the research workflow as increasingly large nonlinear datasets… Read more
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Request a sales quoteMachine Learning for Planetary Science presents planetary scientists with a way to introduce machine learning into the research workflow as increasingly large nonlinear datasets are acquired from planetary exploration missions. The book explores research that leverages machine learning methods to enhance our scientific understanding of planetary data and serves as a guide for selecting the right methods and tools for solving a variety of everyday problems in planetary science using machine learning. Illustrating ways to employ machine learning in practice with case studies, the book is clearly organized into four parts to provide thorough context and easy navigation.
The book covers a range of issues, from data analysis on the ground to data analysis onboard a spacecraft, and from prioritization of novel or interesting observations to enhanced missions planning. This book is therefore a key resource for planetary scientists working in data analysis, missions planning, and scientific observation.
- Includes links to a code repository for sharing codes and examples, some of which include executable Jupyter notebook files that can serve as tutorials
- Presents methods applicable to everyday problems faced by planetary scientists and sufficient for analyzing large datasets
- Serves as a guide for selecting the right method and tools for applying machine learning to particular analysis problems
- Utilizes case studies to illustrate how machine learning methods can be employed in practice
Graduate students and researchers working in planetary science, especially data analysis and planetary missions
- Cover image
- Title page
- Table of Contents
- Copyright
- Contributors
- Foreword
- References
- Chapter 1: Introduction to machine learning
- Abstract
- 1.1. Overview of machine learning methods
- 1.2. Supervised learning
- 1.3. Unsupervised learning
- 1.4. Semisupervised learning
- 1.5. Active learning
- 1.6. Popular machine learning methods
- 1.7. Data set preparation
- References
- Chapter 2: The new and unique challenges of planetary missions
- Abstract
- 2.1. Introduction
- References
- Chapter 3: Finding and reading planetary data
- Abstract
- 3.1. Data acquisition in planetary science
- Chapter 4: Introduction to the Python Hyperspectral Analysis Tool (PyHAT)
- Abstract
- Acronyms
- Acknowledgements
- 4.1. Introduction
- 4.2. PyHAT library architecture
- 4.3. PyHAT orbital
- 4.4. PyHAT in-situ
- 4.5. Conclusion
- References
- Chapter 5: Tutorial: how to access, process, and label PDS image data for machine learning
- Abstract
- Acknowledgements
- 5.1. Introduction
- 5.2. Access to PDS data products
- 5.3. Preprocessing PDS data products into standard image formats
- 5.4. Labeling image data
- 5.5. Example PDS image classifier results
- 5.6. Summary
- References
- Chapter 6: Planetary image inpainting by learning mode-specific regression models
- Abstract
- 6.1. Introduction
- 6.2. Related works
- 6.3. Experimental data
- 6.4. Proposed method
- 6.5. Network architecture
- 6.6. Experimental results
- 6.7. Conclusion
- References
- Chapter 7: Automated surface mapping via unsupervised learning and classification of Mercury Visible–Near-Infrared reflectance spectra
- Abstract
- Acknowledgement
- 7.1. Introduction
- 7.2. Mercury and the MASCS instrument
- 7.3. Data preparation
- 7.4. Learning from multivariate data
- References
- Chapter 8: Mapping storms on Saturn
- Abstract
- 8.1. Introduction
- 8.2. Exploratory principal component analysis
- 8.3. A deep learning approach
- 8.4. Saturn's feature map
- References
- Chapter 9: Machine learning for planetary rovers
- Abstract
- 9.1. Introduction
- 9.2. Risk- and resource-aware AutoNav
- 9.3. Drive-by-science
- 9.4. Demonstration on a test rover
- 9.5. Conclusion and future work
- References
- Chapter 10: Combining machine-learned regression models with Bayesian inference to interpret remote sensing data
- Abstract
- 10.1. The need for accurate fast-forward functions
- 10.2. Bayesian approach to inverse problems
- 10.3. Machine-learning-based surrogate models
- 10.4. Case study: constraining the thermal properties of asteroids with surrogate models
- 10.5. Future perspectives for data fusion
- References
- Index
- No. of pages: 232
- Language: English
- Edition: 1
- Published: March 22, 2022
- Imprint: Elsevier
- Paperback ISBN: 9780128187210
- eBook ISBN: 9780128187227
JH
Joern Helbert
MD
Mario D'Amore
MA
Michael Aye
HK