| Description |
1 online resource (viii, 259 pages) : illustrations (some color) |
| Series |
Water resource planning, development and management |
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Water resource planning, development and management series.
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| Contents |
Intro -- Contents -- Preface -- Chapter 1 -- Integrated Approaches toward Sustainable Urban Water Resources Management -- Abstract -- Introduction -- Water Resource Challenges in Cities -- Conventional Water Resource Management -- Integrated Urban Water Management (IUWM) -- Decentralized Water Management -- Water Sensitive Urban Design -- Application of GIS for Water Resource Management -- Conclusion -- References -- Chapter 2 -- Water Resources Modeling: Model Selection, Validation and Uncertainty Analysis -- Abstract -- Introduction -- Model Types |
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Different Types of Equations in the Hydrologic System -- Mass Balance Equations -- Empirical Equations -- Analytical Equations -- Numerical Equations -- Categories of Hydrologic Models -- Mass Balance Screening Models -- GIS Based Screening Models -- Surface Water Models -- Subsurface Models -- Vadose Zone Models -- Groundwater Models -- Integrated Watershed Models -- Model Selection Process -- Introduction -- Factors to Consider in Model Selection -- Status of Watershed -- Regulatory and Environmental Issues -- Hydrologic, Chemical, and Physical Processes -- Relative Costs of a Model |
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Information Needs -- Pollutant Fate and Transport Processes -- Selecting Models that Incorporate the Appropriate Pollutant Transport Mechanisms -- Model Parsimony and Transparency -- Model Calibration, Validation and Uncertainty Analysis -- Introduction -- Model Setup -- Model Initialization -- Model Calibration -- Sensitivity Analysis -- Model Validation -- Model Evaluation -- Model Uncertainty -- Conclusion -- References -- Chapter 3 -- Computer Tools for Urban Hydrology and Water Quality Management -- Abstract -- Introduction -- Classification of Urban Watershed Models -- Model Descriptions |
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Simple Models/Tools -- Complex Models -- Storm Water Management Model (SWMM) -- Hydrological Simulation Program -- Fortran (HSPF) -- Windows Technical Release-55 (TR-55) -- MIKE URBAN -- The Hydrologic Modeling System (HEC-HMS) -- Urban Volume and Quality (UVQ) -- Model for Urban Stormwater Improvement Conceptualisation (MUSIC) -- Storage, Treatment, Overflow, Runoff Model (STORM) -- Source Loading and Management Model (WinSLAMM) -- System for Urban Stormwater Treatment and Analysis Integration (SUSTAIN) -- Gridded Surface Subsurface Hydrologic Analysis (GSSHA) -- Watershed Management System (WMS) |
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New Generation Urban Watershed Models -- Conclusion -- References -- Chapter 4 -- Numerical Simulation to Quantify Present Status and Future Prediction of Water Quality of To-Lich River, Hanoi, Vietnam -- Abstract -- Introduction -- Study Area and Methodology -- Study Area -- Basic Information Regarding the Model and Data Requirement -- Model Setup -- Result and Discussions -- Precipitation Change -- Population Growth -- Water Quality -- Model Performance Evaluation -- Scenario Analyses -- Conclusion and Recommendations -- References -- Chapter 5 |
| Summary |
"Population growth, increasing living standards, and rapidly changing climate have resulted in an increasing demand for freshwater, accelerating the water degradation challenges. There is a compelling need to minimize water consumption and develop approaches to effectively manage existing water resources. On a positive note, water resource management strategies discussed in this book present innovative ways to conserve both quality and quantity. Chapter 1 discusses decentralized water management approaches for intervening the urban water cycle to minimize the environmental and socioeconomic impacts. This chapter concludes with a need to use a suite of tools based on decision support systems for managing urban water resources. Chapter 2 discusses the need for assessing suitability of various types of models for a specific scenario based on the required level of complexity. This chapter discusses in detail the underlying criteria behind model selection, validation, and uncertainty analysis. Urban watersheds can be more challenging compared to natural watersheds. The urban watersheds include parking lots, roads, and developed structures, all of which contribute to a myriad of anthropogenic pollutants through stormwater runoff. Computer-based models can be used to study water quality issues and to develop a plan to manage watershed level resources. Chapter 3 compares pros and cons of the state-of-the-art watershed models used for managing water resources. Numerical simulations can be performed to compare the current and future water quality scenarios of a given watershed and to estimate the impact of potential water resource management strategies. Chapter 4 presents a case study of an urban region in Hanoi, Vietnam. Water evaluation and planning simulation tool was used to predict the trends and drivers of wastewater generation. Considering rapidly changing climate and associated weather impacts, it is critical to secure water resources in addition to dealing with the water quality issues. Chapter 5 suggests that climate change models and watershed and precipitation models should be jointly used in order to capture uncertainties in ecological functions, energy and food production and water supply sources. Chapter 6 presents a water use estimation and management tool that examines the effect of climate change and drought conditions on water supplies to ensure adequate buffalo forage. Sustaining both buffalo forage and water supplies during drought conditions requires preparedness and adaptation in response to unfavorable conditions. Finally, water reuse can alleviate the stress on available water resources. For example, effluents from wastewater treatment plants and desalination plants can be treated and reused for managing water crisis. Chapter 7 emphasizes that it is critical to optimize both economical and sustainability parameters during treatment of wastewater effluents and desalination concentrate. In certain cases, valuable metals can be recovered from the concentrate"-- Provided by publisher |
| Bibliography |
Includes bibliographical references and index |
| Notes |
Description based on online resource; title from digital title page (viewed on July 08, 2020) |
| Subject |
Water resources development.
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Water reuse.
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Sustainable engineering.
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Water-supply engineering.
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Water conservation.
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water resources development.
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Sustainable engineering
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Water conservation
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Water resources development
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Water reuse
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Water-supply engineering
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| Form |
Electronic book
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| Author |
Gude, Veera Gnaneswar, 1978- editor.
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Gadhamshetty, Venkataramana, 1977- editor
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Kandiah, Ramanitharan, editor.
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| LC no. |
2020000196 |
| ISBN |
9781536173369 |
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1536173363 |
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