"This book will present the best practices for designing, implementing, and deploying cyber-physical systems tailored to the needs of smart water grids. These grids can utilize the intelligence, autonomy, and adaptability offered by CPS for data on consumption, new alternatives for water treatment and reusability, and the impacts of climate change on water sources and urban infrastructure. It will examine topics such as smart sensing, distributed processing, networked control, enabling technologies, and heterogeneous networked topologies, and will also include case studies which will cover different aspects of the water life cycle, such as desalination, distribution, treatment, and recycling."--Provided by publisher.

The effects of climate change, rapid urbanization, and aging infrastructure challenge water policymakers to confront a radical paradigm shift in water resources utilization. Recent advances in sensing, networking, processing, and control have provided the means for sustainable solutions in water management, and their implementation in water infrastructures is collectively referred to as "smart water grids." Smart water grids depend upon cyber-physical system principles to effectively respond to issues regarding the scalability and reliability of dynamic and inaccessible environments. As such, unique smart water grid issues associated with front-end signal processing, communication, control, and data analysis must be jointly addressed, while sophisticated techniques for data analytics must be introduced into cyber-physical systems research. This book provides a thorough description of the best practices for designing and implementing cyber-physical systems that are tailored to different aspects of smart water grids. It is organized into three distinct, yet complementary areas, namely: the theory behind water-oriented cyber-physical systems with an emphasis on front-end sensing and processing, communication technologies, and learning techniques over water data; the applications and emerging topics of cyber-physical systems for water urban infrastructures, including real-life deployments, modern control tools, and economic aspects for smart water grids; and the applications and emerging topics across natural environments, emphasizing the evolution of fresh water resources. The structured discussion yields a rich, comprehensive body of knowledge on this emerging topic of research and engineering. As water issues intensify on a global scale, this book offers an algorithmic and practical toolkit for intermediate and advanced readers as well as professionals and researchers who are active in, or interested in, learning more about smart water grids. Key Features: Emphasizes the multidisciplinary nature of this emerging topic, covering both theoretical and practical aspects of this area while providing insights on existing deployments, which can serve as design examples for new applications. Explores how modern signal processing and machine learning techniques can contribute and enrich the potential of smart water grids, well beyond conventional closed-loop control techniques. Highlights complementary aspects that will help shape the future of smart water grids, such as consumption awareness, economic aspects, and control tools in industrial water treatment as well as the impact of climate change on fresh water resources. Enables the reader to better understand this emerging topic, investing in current state-of-the-art and future technological roadmaps for smart water grids.

The United States repeatedly experiences floods along the Midwest's large rivers and droughts in the arid Western States that cause traumatic environmental disasters with huge economic impact. These problems can be alleviated with an integrated approach and comprehensive solution. Withdrawing flood water from the Mississippi River and its tributaries will mitigate the damage of flooding and provide a new resource of fresh water to the Western States. The existence of a trend of increasing heavy precipitation and flooding on the Midwest's Rivers is supported by a growing body of scientific literature that documents the effects of climate change since 1993. Flooding in Iowa, North Dakota, Tennessee, Arkansas and along the Mississippi River from 1993 to 2010 are prime examples. The Colorado River Basin and the western states are experiencing a protracted multi-year drought. Fresh water can be pumped via pipelines and aqueducts from areas of overabundance/flood to areas of drought or high demand. Calculations document 10 to 60 million acre feet (maf) of fresh water per flood event can be captured from the Midwest's Rivers and pumped via pipelines to the Colorado River and introduced upstream of Lake Powell, Utah, also to destinations near Denver, Colorado, and used in areas along the new water transportation routes. Water users of the Colorado River include the cities in southern Nevada, southern California, northern Arizona, Colorado, Utah, Indian Tribes, and Mexico. The proposed starting, end points, and routes of the water transportation routes are documented, including information on right-of-ways necessary for state and federal permits. The National Smart Water Grid™ (NSWG) could create a million new jobs for construction, operation, and maintenance and save billions per year in drought and flood damage reparations tax dollars. The socio-economic benefits include decreased flooding in the Midwest; increased agriculture, and recreation and tourism; improved national security, transportation, and fishery and wildlife habitats; decreased salinity in Colorado River water crossing the US-Mexico border; and decreased eutrophication/hypoxia (excessive plant growth and decay) in the Gulf of Mexico to name a few. The sale of captured flood water could pay for the National Smart Water Grid™. The cost benefit analysis indicates that the NSWG should be net beneficial. A detailed feasibility studies for each pipeline/aqueduct transportation route is warranted.The Second Edition expands flooding and recent climate change data, emphasis on cost/benefit analysis, details on the engineered features such as pipes, pumps, aqueducts, and patent pending modified levees.Water is a $400 billion industry, the third largest behind oil and electricity. The U.S. has a Strategic Petroleum Reserve and needs a comparable Strategic Water Reserve. The National Smart Water Grid could become a Strategic Water Reserve and augment the National Energy Grid. The availability and sustainability of freshwater is the most important issue facing humanity in this century.

An Insightful Examination of Smart Water Systems and Technology Inland water supplies are under increasing pressure. Climate, social, and demographic change have begun tipping the balance toward demand management, as supplies begins to dwindle. Water and wastewater infrastructure will play a central role in the management of this increasingly valuable resource, and Smart Water Technologies and Techniques: Data Capture and Analysis for Sustainable Water Management provides insight on a key part of the solution. Smart water applications optimise the way water and wastewater services are used, allowing more efficient allocation of limited resources while adding flexibility to the system. Automation, real-time data capture, and rapid interpretation allow utilities and users to monitor, manage, and act on the part of the water cycle that matters to them, minimizing costs of providing service through optimal use of extant assets. This book brings together the core principles, key developments, and current state-of-the-art into a single resource that: Considers smart water within operational, economic, policy, and regulatory contexts Provides a comprehensive overview of the smart water concept and the latest advances in the field Examines key considerations and objections raised to date Discusses the potential value of smart water, from perception to policy Shows how smart water systems can optimize efficiency and flexibility of water and wastewater management Explores future directions for smart water development in the pursuit of balanced supply and demand Although primarily designed for water supply and sanitation, smart water systems may be applied to irrigation, reservoir and dam management, inland water flows, and more, making it a valuable asset as water scarcity begins to spread around the globe. This book answers the questions, assuages concerns, and explains the technology that could revolutionize the way water is accessed and supplied.

The effects of climate change, rapid urbanization, and aging infrastructure challenge water policymakers to confront a radical paradigm shift in water resources utilization. Recent advances in sensing, networking, processing, and control have provided the means for sustainable solutions in water management, and their implementation in water infrastructures is collectively referred to as "smart water grids." Smart water grids depend upon cyber-physical system principles to effectively respond to issues regarding the scalability and reliability of dynamic and inaccessible environments. As such, unique smart water grid issues associated with front-end signal processing, communication, control, and data analysis must be jointly addressed, while sophisticated techniques for data analytics must be introduced into cyber-physical systems research. This book provides a thorough description of the best practices for designing and implementing cyber-physical systems that are tailored to different aspects of smart water grids. It is organized into three distinct, yet complementary areas, namely: the theory behind water-oriented cyber-physical systems with an emphasis on front-end sensing and processing, communication technologies, and learning techniques over water data; the applications and emerging topics of cyber-physical systems for water urban infrastructures, including real-life deployments, modern control tools, and economic aspects for smart water grids; and the applications and emerging topics across natural environments, emphasizing the evolution of fresh water resources. The structured discussion yields a rich, comprehensive body of knowledge on this emerging topic of research and engineering. As water issues intensify on a global scale, this book offers an algorithmic and practical toolkit for intermediate and advanced readers as well as professionals and researchers who are active in, or interested in, learning more about smart water grids. Key Features: Emphasizes the multidisciplinary nature of this emerging topic, covering both theoretical and practical aspects of this area while providing insights on existing deployments, which can serve as design examples for new applications. Explores how modern signal processing and machine learning techniques can contribute and enrich the potential of smart water grids, well beyond conventional closed-loop control techniques. Highlights complementary aspects that will help shape the future of smart water grids, such as consumption awareness, economic aspects, and control tools in industrial water treatment as well as the impact of climate change on fresh water resources. Enables the reader to better understand this emerging topic, investing in current state-of-the-art and future technological roadmaps for smart water grids.

Investigates the systems of infrastructure that sustain the world and the cultures of historical periods, following various elements, from electricity and pavement to water and waste disposal, back to their origins and people who operate them.

Smarter Water - Increase Revenue - Decrease Costs - Delight Customers - Preserve Our Most Vital Resource Solving the Water Crisis With Data Supply-side engineering - massive reservoirs, colossal water diversion schemes, pumping rivers across mountaintops, and even desalination - are relics of a bygone era in water management. The environmental and financial costs are simply too high. No supply-side solution can match the simplicity, resilience and effectiveness of a data-driven demand-side management program that reduces consumption, identifies losses, increases the life of our existing infrastructure and improves the financial capabilities of our utilities. The development of the smart grid for water is, for the first time, providing water managers with a complete understanding of not only how much water is used, but where and when. The 21st century water manager needs to manage the flow of data and information as well as the flow of water. Our future depends on it.