Book contents
- Climate Risk and Sustainable Water Management
- Climate Risk and Sustainable Water Management
- Copyright page
- Contents
- Contributors
- Preface
- Acknowledgements
- Part I Water-Related Risks under Climate Change
- Part II Climate Risk to Human and Natural Systems
- Part III Sustainable Water Management under Future Uncertainty
- 15 Managing Urban Flood Risk and Building Resilience in a Changing Climate
- 16 Soft Computing Methods and Water Management
- 17 Rainwater Harvesting for Sustainable Water Resource Management under Climate Change
- 18 Variability of Runoff Coefficient and Precipitation Elasticity at Watersheds across China
- 19 Contribution of Hydrological Model Calibration Uncertainty to Future Hydrological Projections over Various Temporal Scales
- 20 Future Water Scarcity over the Yellow River Basin and the Effects of Adaptive Measures
- 21 Shrinking Lake Urmia
- Index
- References
16 - Soft Computing Methods and Water Management
from Part III - Sustainable Water Management under Future Uncertainty
Published online by Cambridge University Press: 17 March 2022
Book contents
- Climate Risk and Sustainable Water Management
- Climate Risk and Sustainable Water Management
- Copyright page
- Contents
- Contributors
- Preface
- Acknowledgements
- Part I Water-Related Risks under Climate Change
- Part II Climate Risk to Human and Natural Systems
- Part III Sustainable Water Management under Future Uncertainty
- 15 Managing Urban Flood Risk and Building Resilience in a Changing Climate
- 16 Soft Computing Methods and Water Management
- 17 Rainwater Harvesting for Sustainable Water Resource Management under Climate Change
- 18 Variability of Runoff Coefficient and Precipitation Elasticity at Watersheds across China
- 19 Contribution of Hydrological Model Calibration Uncertainty to Future Hydrological Projections over Various Temporal Scales
- 20 Future Water Scarcity over the Yellow River Basin and the Effects of Adaptive Measures
- 21 Shrinking Lake Urmia
- Index
- References
Summary
This chapter reviews recent developments in modern soft computing models, including heuristic algorithms, extreme learning machines and models based on deep learning strategies applied to water management. In this context, we describe the basics and fundamentals of the mentioned soft computing methods. We then provide a brief review of the models applied in three fields of water management: drought forecasting, evapotranspiration modelling and rainfall-runoff simulation. Thus, we provide guidelines for modern soft computing techniques applied to water management.
Keywords
- Type
- Chapter
- Information
- Climate Risk and Sustainable Water Management , pp. 342 - 373Publisher: Cambridge University PressPrint publication year: 2022
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