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Urban Hydrology, Watershed Management and Socio-Economic Aspects (2016)

Singh, Vijay P. 1946- ; Kartha, Suresh A. ; Bhattacharjya, Rajib K.

Cham : Springer

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Keywords: Environment ; Hydrology ; Environmental management ; Climate change ; Remote sensing ; Urban geography ; Water pollution ; Environment ; Hydrology ; Environmental management ; Climate change ; Remote sensing ; Urban geography ; Water pollution

Description / Table of Contents: Tentative: 1. Impact of slope and vegetation on hydrological processes -- 2. Impact of total and effective imperviousness of runoff prediction -- 3. Rainfall characteristics in inner Bangkok, Thailand -- 4. Issues of urban drainage-present status and the way forward -- 5. Impact of urban habitat patterns on surface water and subsurface water bodies and human health -- 6. Present review of studies of meteorological disasters in the north-eastern region of India subcontinent -- . 7. Remote Sensing, GIS and DEM for urban hydrology modeling -- 8. Surface runoff depth by SCS curve number method integrated with satellite image and GIS -- 9. Impact of vegetation change on soil erosion in the Majuli island of Assam- the largest river island of the world -- 10. Impact of temporal variation in land use on urban hydrology: A case study of Cochin, Kerala, India -- 11. Flood plain characterization of a river in lower Assam using digital elevation model data -- 12. Groundwater management in urban areas -- 13. Ground water modeling in Kosthaliyar river basin- A case study -- 14. Linked optimization model for groundwater monitoring network design -- 15. Soil-water characteristic curve for hill soil of North East India -- 16. Ground water management- sustainability and methodology -- 17. Integrated management of ground water with artificial recharge and rain water harvesting for an urban water supply system -- 18. Two dimensional numerical model for urban drainage system -- 19. Need of two-dimensional consideration for modeling urban drainage -- 20. Integrated flood risk modeling for an urban area -- 21. Modeling well level fluctuation as seismograph -- 22. Flow analysis in compound channel considering momentum transfer mechanism -- 23. Optimal reservoir operation considering environmental flows for Ranganadi hydro project in Arunachal Pradesh, India -- 24. Analysis of water distribution network using EPANET and vertex method -- 25. Application of wavelet transform technique in hydrology-A brief review -- 26. Urban roadway drainage issues and its management – A key component of urban PMS -- 27. ANN and ANFIS modeling of failure trend analysis in urban water distribution network -- 28. River flood modeling using wavelet-auto regression conjunction model -- 29. Effects of data preprocessing on the prediction accuracy of artificial neural network model in non-stationary hydrological time series -- 30. Urban water consumption estimation using artificial intelligence techniques -- 31. An ecological perspective of Brahmaputra river floodplain -- 32. Optimal allocation of ecological management practices in a hilly urban watershed -- 33. Assessment of carrying capacity for hilly urban areas: Applicability of the concept at the ground level -- 34. Perception of the household environment and its effects on academic performance of students in Department of Geography, Benue State University -- 35. Empowering community for the river basin management -- 36. Effect on migrants due to urbanization: A study of slum area in New Delhi -- 37. Role of urban local bodies and opportunities in municipal solid waste management -- 38. Sustainable urban development and the role of the government (with special reference to Assam) -- 39. Socio-economic aspects of urban development - A case study of Surat city of India -- 40. Economic evaluation of transportation project – a case study of ferry system for IIT Guwahati -- 41. A project of competitive, inclusive and sustainable city -- 42. An integrated approach to urban water management: The case of Guwahati city - need, scope and challenges.

Type of Medium: Online Resource

Pages: Online-Ressource (XIV, 370 p. 136 illus., 99 illus. in color, online resource)

ISBN: 9783319401959

Series Statement: Water Science and Technology Library 73

URL: https://doi.org/10.1007/978-3-319-40195-9

URL: http://dx.doi.org/10.1007/978-3-319-40195-9

DOI: 10.1007/978-3-319-40195-9

RVK:

RB 10363

Language: English

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Development of Water Resources in India (2017)

Singh, Vijay P. 1946- ; Raj, Vijay

Cham : Springer

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Keywords: Water ; Climate change ; Engineering geology ; Engineering Geology ; Foundations ; Hydraulics ; Water pollution ; Environment

Description / Table of Contents: This proceedings volume, with more than 30 chapters, is based on the presentations given at the National Conference on Water Resources and Hydropower (WRHP-2016) and represents the state-of-the-art in water resources in India. It includes experimental investigations, field studies, theoretical developments, numerical methods, as well as engineering achievements in water resources. The contributions are organised under four main topics: • Water Resources and Management: covers the issues related to water resources planning and management, water conservation, flood mitigation, policies and governance, conflict over rivers and planning of groundwater evolution, Assessment of Sedimentation, Surface water quality, Rainfall assessment, • Climate Change and Global Warming: includes chapters on the impact of climate on water resources and groundwater, hydrological impacts of climate change, Ground Water Contaminants, Assessment of Evaporation and evapotranspiration effects on global warming • Hydraulic Structures: presents contributions on fluvial hydraulics,flow through Weirs, Open Channel flow, river flood control, scour and erosion, dam and dowstream block failures and protection, Losses in pipes By combining these topics, the book provides a valuable resource for practitioners and researchers, including field engineers, academicians, planners, health specialists, disaster managers, decision makers and policy makers engaged in various aspects of water resources and hydropower. The WRHP-2016 was organised in association with the Indian Institute of Technology, Roorkee, Uttrakhand Jal Vidyut Nigam Limited and the Indian Society for Hydraulics, Pune and was held in University of Petroleum and Energy Studies, Dehradun, India from June 17-18, 2016

Type of Medium: Online Resource

Pages: Online-Ressource (XI, 537 p. 267 illus., 187 illus. in color, online resource)

ISBN: 9783319551258

Series Statement: Water Science and Technology Library 75

URL: https://doi.org/10.1007/978-3-319-55125-8

URL: https://swbplus.bsz-bw.de/bsz490764274cov.jpg

DOI: 10.1007/978-3-319-55125-8

Language: English

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Planning and Evaluation of Irrigation Projects : Methods and Implementation. (2017)

Rai, Raveendra Kumar.

San Diego :Elsevier Science & Technology,

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Keywords: Irrigation--Management. ; Electronic books.

Type of Medium: Online Resource

Pages: 1 online resource (680 pages)

Edition: 1st ed.

ISBN: 9780128118566

URL: https://ebookcentral.proquest.com/lib/geomar/detail.action?docID=4838040

DDC: 333.913

Language: English

Note: Front Cover -- Planning and Evaluation of Irrigation Projects -- Dedication -- Planning and Evaluationof Irrigation Projects Methods and Implementation -- Copyright -- Contents -- Preface -- Acknowledgments -- 1 - INTRODUCTION -- 1.1 IRRIGATION: DEFINITION, FUNCTIONS, ADVANTAGES, AND DISADVANTAGES -- 1.2 IRRIGATION PLANNING -- 1.3 NEED OF EVALUATION: BENCHMARKING AND WATER AUDITING -- 1.4 ORGANIZATION OF THIS BOOK -- 2 - IRRIGATION PROJECT PLANNING -- 2.1 PLANNING STAGES -- 2.1.1 PROJECT IDENTIFICATION -- 2.1.2 PROJECT PREPARATION AND ANALYSIS -- 2.1.3 PROJECT APPRAISAL -- 2.1.4 PROJECT IMPLEMENTATION -- 2.1.5 MONITORING AND EVALUATION -- 2.2 INVESTIGATION PHASES AND DATA COLLECTION -- 2.2.1 DATA COLLECTION -- 2.3 SCOPE OF WORK FOR PLANNING OR PREFEASIBILITY REPORT STAGE -- 2.4 SCOPE OF WORK FOR DETAILED INVESTIGATION OR DETAILED PROJECT REPORT STAGE -- 2.4.1 ACTIVITIES FOR THE PREPARATION OF DETAILED PROJECT REPORT -- 2.4.2 DELIVERABLES AND IMPLEMENTATION PLAN TO BE INCORPORATED IN DETAILED PROJECT REPORT -- 2.5 FACTORS AFFECTING THE DEVELOPMENT OF IRRIGATION FACILITIES -- 2.5.1 SOIL -- 2.5.2 CLIMATE -- 2.5.3 TOPOGRAPHY -- 2.5.4 WATER SOURCE -- 2.5.5 WATER QUANTITY -- 2.5.6 WATER QUALITY -- 2.5.7 CROP(S) TO BE CULTIVATED -- 2.5.8 ENERGY -- 2.5.9 LABOR -- 2.5.10 CAPITAL -- 2.5.11 ECONOMIC FACTOR -- 2.5.12 ENVIRONMENTAL ASPECTS -- 2.5.13 NATIONAL POLICY AND PRIORITY -- 2.5.14 SOCIOCULTURAL ASPECTS -- 2.5.15 INSTITUTIONAL INFRASTRUCTURE -- REFERENCES -- 3 - BASIC HYDRAULIC COMPUTATIONS -- 3.1 BASIC TERMINOLOGY -- 3.1.1 CLASSIFICATION OF OPEN CHANNEL FLOW -- 3.2 CONSERVATION LAWS -- 3.2.1 LAW OF MASS CONSERVATION OR CONTINUITY EQUATION -- 3.2.2 LAW OF MOMENTUM CONSERVATION -- 3.2.2.1 Specific Force -- 3.2.3 LAW OF ENERGY CONSERVATION -- 3.2.3.1 Steady-State Flow Equation -- 3.2.3.2 Specific Energy Equation -- 3.2.3.3 Application of Specific Energy. , 3.2.3.3.1 Channel Transition -- 3.3 HYDRAULIC JUMP -- 3.3.1 ELEMENTS OF HYDRAULIC JUMP -- 3.3.1.1 Chaurasia (2003) -- 3.3.1.2 Swamee and Rathie (2004) -- 3.4 COMPUTATION OF CRITICAL DEPTH -- 3.5 UNIFORM FLOW COMPUTATION -- 3.5.1 COMPUTATION OF NORMAL DEPTH -- 3.5.1.1 Explicit Method of Computing the Normal Depth -- 3.6 GRADUALLY VARIED FLOW -- 3.6.1 CLASSIFICATION OF GRADUALLY VARIED FLOW -- 3.6.2 COMPUTATION OF GRADUALLY VARIED FLOW OR WATER LEVEL PROFILE -- 3.6.2.1 Direct Integration Method -- 3.6.2.2 Direct Step Method -- 3.6.2.3 Standard Step Method -- 3.6.2.4 Predictor-Corrector Method -- 3.7 CONCLUDING REMARKS -- REFERENCES -- FURTHER READING -- 4 - HYDROLOGIC COMPUTATIONS -- 4.1 ANALYSES OF RAINFALL DATA -- 4.1.1 OPTIMUM NUMBER OF RAIN GAUGES -- 4.1.1.1 Coefficient of Variation Technique -- 4.1.2 ESTIMATION OF AVERAGE RAINFALL -- 4.1.3 ESTIMATION OF RAINFALL TRENDS FOR CLIMATIC VARIATION: THE MANN-KENDALL TEST -- 4.2 HYDROLOGIC CYCLE -- 4.2.1 COMPONENTS OF HYDROLOGIC CYCLE AND IMPORTANT TERMINOLOGY -- 4.3 HYDROLOGIC EQUATION AND WATER BALANCE -- 4.3.1 PERIOD OF WATER-BALANCE EXERCISE -- 4.3.2 PURPOSE OF WATER BALANCE -- 4.4 ESTIMATION OF RESERVOIR INFLOW USING OBSERVED DATA -- 4.4.1 DETERMINATION OF CATCHMENT OR RESERVOIR YIELD -- 4.5 ESTIMATE OF CATCHMENT YIELD USING RAINFALL-RUNOFF MODELING -- 4.5.1 STRANGE TABLE -- 4.5.2 SIMPLE WATER-BALANCE MODEL -- 4.5.2.1 Components of SWMB -- 4.5.2.1.1 Upper Layer Water Balance -- 4.5.2.1.2 Lower Layer Water Balance -- 4.5.2.1.3 Subsurface Runoff -- 4.5.2.1.4 Surface Runoff -- 4.5.2.2 Runoff Routing -- 4.5.3 MODIFIED SCS-CN MODEL -- 4.5.3.1 Rainfall-Excess Computation -- 4.5.3.2 Soil Moisture Budgeting -- 4.5.3.3 Computation of Evapotranspiration -- 4.5.3.4 Catchment Routing -- 4.5.3.5 Baseflow Computation -- 4.6 INFLOW ESTIMATION IN MULTI-RESERVOIR CASE. , 4.6.1 RESERVOIR ROUTING: STORAGE-INDICATION METHOD -- 4.6.2 CHANNEL ROUTING -- 4.6.2.1 The Muskingum Method -- 4.6.2.1.1 Parameter Estimation of the Muskingum Method -- 4.6.2.2 The Muskingum-Cunge Method -- 4.6.2.3 Modified Muskingum-Cunge Method (Ponce and Yevjevich, 1978) -- 4.7 DESIGN-FLOOD ESTIMATION FOR FIXING THE SPILLWAY CAPACITY -- 4.7.1 UNIT HYDROGRAPH METHOD -- 4.7.1.1 Assumptions of the Unit Hydrograph -- 4.7.1.2 Derivation of Unit Hydrograph -- 4.7.1.3 Unit Duration of UH -- 4.7.1.4 Limitations of Unit Hydrograph -- 4.7.1.5 Computation of Floods From UH Using Convolution -- 4.7.1.6 Changing the Duration of UH -- 4.7.1.6.1 Principle of Superposition -- 4.7.1.6.2 S-Hydrograph Method -- 4.7.2 SYNTHETIC HYDROGRAPH METHOD -- 4.7.2.1 Snyder's Method -- 4.7.2.2 SCS Synthetic UH Method -- 4.7.2.3 Synthetic Unit Hydrograph Method of CWC -- 4.7.3 CONCEPTUAL MODELS -- 4.7.3.1 The Clark-Based IUH Model -- 4.7.3.1.1 Parameters of the Clark Model -- 4.7.3.1.1.1 Time of Concentration, tc -- 4.7.3.1.1.2 Time-Area (TA) Diagram -- 4.7.3.1.1.2.1 TA Diagram Using the DEM -- 4.7.3.1.1.2.2 Synthetic TA and TAC Curve -- 4.7.3.1.1.3 Storage Coefficient, K -- 4.7.3.1.2 Governing Equation of the Clark Model -- 4.7.3.1.2.1 Derivation of Routing Equation -- 4.7.4 DESIGN-FLOOD ESTIMATION USING FLOOD-FREQUENCY ANALYSIS -- 4.7.4.1 Components of Frequency Analysis -- 4.8 RESERVOIR SIZING -- 4.8.1 STORAGE ZONES IN A RESERVOIR -- 4.8.2 AREA-ELEVATION AND CAPACITY-ELEVATION CURVES -- 4.8.3 DETERMINATION OF RESERVOIR CAPACITY -- 4.8.3.1 Flow-Mass Curve Analysis -- 4.8.3.2 Sequent Peak Algorithm -- 4.8.3.2.1 Graphical Procedure -- 4.8.3.2.2 Analytical Procedure -- 4.8.4 RESERVOIR OPERATION -- 4.8.4.1 Standard Operating Policy -- 4.8.5 RESERVOIR RULE CURVE -- 4.9 RESERVOIR SEDIMENTATION -- 4.9.1 DIRECT MEASUREMENT OF SEDIMENT YIELD AND EXTENSION OF MEASURED DATA. , 4.9.1.1 Extension of Sediment Data -- 4.9.1.2 Estimating Sediment Yield -- 4.9.2 TRAP EFFICIENCY OF RESERVOIR -- 4.9.2.1 Brune (1953) Method -- 4.9.2.2 USDA-SCS (1983) Method -- 4.9.2.3 Churchill (1948) Method -- 4.9.3 SEDIMENT DISTRIBUTION IN RESERVOIR -- 4.9.3.1 Empirical Methods for Evaluating Sediment Distribution -- 4.9.3.1.1 Area-Increment Method -- 4.9.3.1.2 Empirical Area-Reduction Method -- 4.10 CONCLUDING REMARKS -- REFERENCES -- FURTHER READING -- 5 - ESTIMATION OF LAKE EVAPORATION AND POTENTIAL EVAPOTRANSPIRATION -- 5.1 ESTIMATION OF LAKE EVAPORATION -- 5.2 ESTIMATION OF REFERENCE CROP EVAPOTRANSPIRATION -- 5.2.1 FAO-56 AND ASCE-EWRI METHOD -- 5.2.2 HARGREAVES METHOD -- 5.3 CONCLUDING REMARKS -- REFERENCES -- 6 - ESTIMATING IRRIGATION DESIGN PARAMETERS -- 6.1 ESTIMATION OF CROP WATER REQUIREMENT -- 6.1.1 CROP GROWTH STAGE -- 6.1.2 CROP COEFFICIENTS -- 6.1.3 PRINCIPAL CROPS AND THEIR WATER REQUIREMENT AND CRITICAL STAGES -- 6.2 IRRIGATION WATER REQUIREMENT -- 6.2.1 WATER REQUIRED FOR LAND SOAKING, WRLS -- 6.2.2 WATER REQUIRED FOR LAND PREPARATION, WRLP -- 6.2.3 WATER REQUIRED FOR LEACHING, WRL -- 6.2.4 GROSS IRRIGATION WATER REQUIREMENT, GIWR -- 6.3 IRRIGATION EFFICIENCY -- 6.3.1 WATER CONVEYANCE EFFICIENCY (EC) -- 6.3.2 WATER APPLICATION EFFICIENCY (EA) -- 6.3.3 SCHEME IRRIGATION EFFICIENCY -- 6.4 IRRIGATION COMMAND AREA -- 6.4.1 IRRIGATION INTENSITY -- 6.4.2 PEAK IRRIGATION DEMAND -- 6.4.3 WATER ALLOWANCE -- 6.4.4 DUTY, DELTA, AND BASE PERIOD -- 6.4.4.1 Duty, D -- 6.4.4.2 Delta, Δ -- 6.4.4.3 Base Period, B -- 6.4.5 RELATIONSHIP BETWEEN DUTY, DELTA, AND BASE PERIOD -- 6.5 DETERMINATION OF IRRIGATED COMMAND AREA, PROJECT DUTY, DUTY AT OUTLET HEAD AND CANAL HEAD, WATER ALLOWANCE, AND CANAL CAPACITY -- REFERENCES -- FURTHER READING -- 7 - DESIGN OF IRRIGATION CANALS -- 7.1 TYPICAL CANAL GEOMETRY -- 7.2 DESIGN OF LINED CANALS. , 7.2.1 DESIGN OF THE MOST ECONOMICAL SECTION -- 7.3 DESIGN OF STABLE UNLINED CANALS USING THE REGIME THEORY -- 7.4 DESIGN OF UNLINED CANAL USING TRACTIVE FORCE APPROACH -- 7.4.1 DESIGN OF UNLINED CANAL USING KENNEDY'S THEORY -- 7.5 DETERMINING L-SECTION OF THE CANAL -- 7.6 DEVELOPMENT OF DRAW-OFF STATEMENT FOR THE CANAL -- 7.7 CONCLUDING REMARKS -- REFERENCES -- FURTHER READING -- 8 - DESIGN OF CANAL OUTLETS AND THEIR CALIBRATION -- 8.1 CLASSIFICATION OF OUTLETS -- 8.2 PERFORMANCE OF MODULE OR OUTLET -- 8.2.1 FLEXIBILITY -- 8.2.2 PROPORTIONALITY AND SETTING -- 8.2.3 SENSITIVITY -- 8.3 DESIGN OF OUTLETS: DISCHARGE THROUGH OUTLETS -- 8.3.1 NONMODULAR OUTLET -- 8.3.2 SEMIMODULAR OUTLET -- 8.3.2.1 Pipe Outlet Discharging Freely Into the Water Course -- 8.3.2.2 Open Flume Outlet -- 8.3.2.3 Adjustable Orifice Semimodules -- 8.4 CALIBRATION OF OUTLET -- 8.5 CONCLUDING REMARKS -- REFERENCES -- FURTHER READING -- 9 - CANAL ARCHITECTURE -- 9.1 CANAL CLASSIFICATION -- 9.1.1 CLASSIFICATION ACCORDING TO FUNCTION OF THE CANAL -- 9.1.2 CLASSIFICATION ACCORDING TO ALIGNMENT -- 9.1.3 CLASSIFICATION ACCORDING TO NATURE OF SOURCE AND SUPPLY -- 9.1.4 CLASSIFICATION ACCORDING TO DISCHARGE AND RELATIVE IMPORTANCE -- 9.2 COMMAND AREA SURVEY -- 9.2.1 SURVEY MAPS FOR INITIAL PLANNING -- 9.2.2 SURVEY MAPS FOR DETAILED PLANNING -- 9.3 CANAL ALIGNMENT -- 9.3.1 IMPORTANT POINTS FOR CANAL ALIGNMENT -- 9.4 MARKING AND FINALIZATION OF AREA PROPOSED TO BE IRRIGATED BY EACH CHANNEL -- 9.5 DESIGN OF CANAL -- 9.6 CONCLUDING REMARKS -- REFERENCES -- FURTHER READING -- 10 - IRRIGATION METHODS -- 10.1 METHODS OF IRRIGATION -- 10.1.1 BASIN IRRIGATION -- 10.1.2 FURROW IRRIGATION -- 10.1.3 BORDER IRRIGATION -- 10.1.4 SPRINKLER IRRIGATION -- 10.1.5 DRIP IRRIGATION -- 10.2 FACTORS AFFECTING THE SELECTION OF IRRIGATION METHOD -- 10.3 LAYOUT OF BASIN IRRIGATION. , 10.4 LAYOUT FOR FURROW IRRIGATION.

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