COURSE CURRICULUM DEPARTMENT OF CIVIL...
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COURSE CURRICULUM
DEPARTMENT OF CIVIL ENGINEERING
(w.e.f. Session 2015-16)
INSTITUTE OF ENGINEERING & TECHNOLOGY
Course Curriculum (w.e.f. Session 2015-16)
DEPARTMENT OF CIVIL ENGINEERING, Institute of Engineering & Technology
Table of Contents
M.Tech. (WRE) Course Structure…………………………………….…………………………………………………….……..……..i M.Tech. (WRE) Syllabus ................................................................................................................ 1
Course Curriculum (w.e.f. Session 2015-16)
M.Tech. (Water Resources Engineering)
DEPARTMENT OF CIVIL ENGINEERING, Institute of Engineering & Technology
COURSE STRUCTURE
M.TECH. (WATER RESOURCES ENGINEERING)
Course Curriculum (w.e.f. Session 2015-16)
M.Tech. (Water Resources Engineering)
DEPARTMENT OF CIVIL ENGINEERING, Institute of Engineering & Technology
First Semester
S.
NO. CODE SUBJECT
TEACHING SCHEME CREDITS
CONTACTS HR/WK
L T P
1 MCE-1031 Applied Hydrology 3 1 - 4 4
2 MCE-1032 Fluid Flow in Pipes and Channels 4 1 - 5 5
3 MCE-1033 Socio-economic and environment
evaluation of water resources projects
3 0 - 3 3
4 MCE-1034 Irrigation and Drainage Engineering 3 1 - 4 4
5 MCE-1015 Advanced Numerical Analysis 3 1 - 4 4
TOTAL 16 4 00 20 20
Second Semester
S.
NO. CODE SUBJECT
TEACHING SCHEME CREDITS
CONTACTS HRS/WK
L T P
1 MCE-2031 Water Resources Planning And
Management
3 0 - 3 3
2 MCE-2032 Hydraulic structures 3 1 - 4 4
3 MCE-2033 Hydropower Engineering 3 1 - 4 4
4 MCE-2034 Hydraulics Laboratory - - 2 1 2
5 Elective I 3 1 - 4 4
6 Elective II 3 1 - 4 4
TOTAL 15 4 02 20 21
Course Curriculum (w.e.f. Session 2015-16)
M.Tech. (Water Resources Engineering)
DEPARTMENT OF CIVIL ENGINEERING, Institute of Engineering & Technology
Third Semester
S. No. SUBJECT
CODE SUBJECT
PERIODS
CREDITS CONTACT HRS/WK
L T P
1 MCE-3031 Project/Seminar*
- - - 4
2 MCE-3032 Dissertation –I**
- - - 8
3 --- Elective –III 3 1
4 4
4 ----- Elective-IV 3 1
4 4
TOTAL 6 2
20
Fourth Semester
S. No.
SUBJECT CODE
SUBJECT PERIODS
CREDITS CONTACT HRS/WK L T P
1 MCE-4031 Dissertation –II - - - 20
TOTAL
20
TOTAL CREDIT OF ALL THE SEMESTERS
80
*=PROJECT WILL INVOLVE COMPLETE DESIGN OF A LIVE STRUCTURE OR SOME SUCH EQUIVALENT WORK. SEMINAR WILL REQUIRE STATE-OF-ART REPORT ON A TOPIC RELEVANT TO THE SPECIALIZATION. TOPIC OF PROJECT/SEMINAR WILL BE ALLOTED AT THE END OF THE SECOND SEMESTER OF THE FIRST YEAR. PROJECT/SEMINAR WORK WILL BE REQUERED TO BE COMPLETED (SUBMISSION AND PRESENTATION BY OCTOBER OF THE THIRD SEMESTER)
**=DISSERTATION TOPIC WILL BE ALLOTED AT THE END OF THE SECOND SEMESTER OF THE FIRST YEAR. REVIEW (LITERCATURE SURVEY) AND WORK PLAN CONCERNING DISSERTATION TOPIC WILL BE WORKED UPON DURING THE SUMMER VACATION (SIMULTANEOUSLY WITH THE PROJECT/SEMINAR RELATED WORKS). THIS WORK WILL BE PRESENTED IN THE FORM OF SEMINAR IN THE MONTH OF SEPTEMBER.
Course Curriculum (w.e.f. Session 2015-16)
M.Tech. (Water Resources Engineering)
DEPARTMENT OF CIVIL ENGINEERING, Institute of Engineering & Technology
ELECTIVES
SL. NO.
CODE SUBJECT TEACHING SCHEME
CREDITS CONTACTS HR/WK
L T P
1. Elective
I
MCE-2035 Fluvial Hydraulics 3 1 0 4 4
2.
MCE-2036 Embankment Dams 3 1 0 4 4
3.
Elective
II
MCE-2011 Finite Element Methods 3 1 0 4 4
4.
MCE-0001 Soft Computing Methods
in Engineering Problem
Solving 3 1 0 4 4
5.
Elective
III
MCE-3033 Watershed Development
and Management 3 1 0 4 4
6. MCE-3034 Ground Water Hydrology
3 1 0 4 4
7.
Elective
IV
MCE-0002 Optimization methods in
Civil Engineering 3 1 0 4 4
8.
MCE-0003 Theory and Applications
of GIS to Water
Resources 3 1 0 4 4
Course Curriculum (w.e.f. Session 2015-16)
M.Tech. (Water Resources Engineering)
DEPARTMENT OF CIVIL ENGINEERING, Institute of Engineering & Technology
SYLLABUS M.TECH.
(WATER RESOURCES ENGINEERING)
Course Curriculum (w.e.f. Session 2015-16)
M.Tech. (Water Resources Engineering)
DEPARTMENT OF CIVIL ENGINEERING, Institute of Engineering & Technology
1
MCE 1031: APPLIED HYDROLOGY
Credits: 04 L-T-P: 3-1-0
Reference Books/ Text Book / Cases:
Chow,V.T.,Maidment,D.R.andMays,W.L.,"AppliedHydrology", McGraw
Hill.
Ojha,C.S.P.,Berndtsson,R.andBhunya,P.,“EngineeringHydrology”,
OxfordUniversityPress.
Wanielista, M.,Kersten, R.and Eaglin, R., “Hydrology”, JohnWiley.
Module No.
Contents Teaching
Hours
I
Introduction: Hydrologic system and hydrologic budget, fundamental laws
of hydrology; atmospheric water vapor. Hydrologic Inputs: Precipitation and its forms, snowfall and rainfall; measurement techniques and space-time characteristics HydrologicAbstractions:Infiltration,depression,storage,evapotranspiration; measurement techniques and their modeling
12
II
HydrologicAbstractions:Infiltration,depression,storage,evapotranspiration;
measurement techniques and their modeling Systems Approach: Unit Hydrograph, IUH, GIUH Hydrological routing: Flood forecasting, Advance regression and correlation analysis. Advanced Method of Frequency Analysis: Outliers, Time series analysis.
16
III Definition of ground water, role of ground water in hydrological cycle,
ground water bearing formations, classification of aquifers, flow and storage characteristics of aquifers, Darcy’s law, anisotropy and heterogeneity.
12
Course Curriculum (w.e.f. Session 2015-16)
M.Tech. (Water Resources Engineering)
DEPARTMENT OF CIVIL ENGINEERING, Institute of Engineering & Technology
MCE-1032 FLUID FLOW IN PIPES AND CHANNELS
Credits: 04 L-T-P: 3-1-0
Module No.
Contents Teaching
Hours
I
Kinematics of Flow : Equation of continuity in Cartesian, polar and
cylindrical coordinates, dilation, Standard 2-D Flow Patterns: Source, sink, doublet and their
combinations, construction of flows by superposition, D’Alembert’s paradox. Laplace Equation: Solution by relaxation methods, conformal mapping, solution by separation of variables. Laminar Flow: Derivation of Navier-Stokes equations–exact solutions
for flow between parallel plates, Couette flow, flow near a suddenly
accelerated plate and an oscillating plate.
Boundary Layers: Similarity solutions of boundary layer equations,
Falkner-Skan Wedge flows, Karman-Paul Hausen approximate solution,
separation in boundary layer under adverse pressure gradient.
18
II
Turbulent Flows: Reynolds equations of motion, semi-empirical theories of turbulence, velocity profiles for inner, outer and overlap
layers, equilibrium boundary layers. Measurement of Turbulence and Statistical Theory of Turbulence: Isotropic and homogeneous turbulence, probability density functions,
correlation coefficients, decay of isotropic turbulence
Hydraulic Jump: hydraulic jump in variety of situations including
contracting and expanding geometries and rise in floor levels, control of
hydraulic jump using baffle walls and cross jets. Supercritical Flows: Flow past deflecting boundaries, oblique shockwaves.
20
III
Spatially Varied Flows: Flows past side weirs, De Marchie quations,
design of side weirs, flow past bottom racks, trench weirs and waste water gutters. Aerated Flows: Bulking of flow, mechanism of air entrainments,
modeling of aerated flows, development of self-aerated flows, uniform
aerated region, and aeration over spillway. Stratified Flows: Thermal stratification in water bodies including reservoirs, modeling of stratified flows. Unsteady Flows: St.Venant’s equations and their solution using method of characteristics and finite difference schemes; dam break problem,
hydraulic flood routing. Channel Transitions: Sub-critical and supercritical
14
Course Curriculum (w.e.f. Session 2015-16)
M.Tech. (Water Resources Engineering)
DEPARTMENT OF CIVIL ENGINEERING, Institute of Engineering & Technology
Reference Books/ Text Book / Cases:
S. No.
Name of Authors/Books/Publishers
Year of Publication/
Reprint
1.
White, F.M., "Fluid Mechanics", McGraw-Hill.
1979
2.
Schlichting, H., "Boundary Layer Theory", McGraw-Hill.
1979
3.
Garde, R.J., "Turbulent Flow", Wiley Eastern Limited.
1994
4.
Pope, S. B.,"Turbulent Flows", Cambridge UniversityPress.
2000
5.
Rouse, H., "Advanced Mechanics of Fluids",JohnWiley.
1959
6.
Ojha,C.S.P.,Berndtsson,R.andChandaramouli,P.N.,“FluidMechanics”,Oxford
University Press.
2010
7. Asawa, G.L., “Fluid Flow in Pipes and Channels”, CBS Publishers, New Delhi 2014
8. Chow, V.T., “Open Channel Hydraulics”, McGraw Hill.
1959
9. Choudhary, M.H., "Open-Channel Flows", Prentice-Hall.
1994
10. RangaRaju, K.G., “Flow Through Open Channels, Tata McGraw Hill.
2003
11. Chanson, H., “The Hydraulics of Open Channel Flow:An Introduction”, Elsevier.
2004
12. French, R.H., "Open-Channel Hydraulics", McGraw-Hill.
1994
13. Wood, I.R., “Air Entrainment in Free-Surface Flows”, A.A. Balkema.
1991
Course Curriculum (w.e.f. Session 2015-16)
M.Tech. (Water Resources Engineering)
DEPARTMENT OF CIVIL ENGINEERING, Institute of Engineering & Technology
MCE-1033 SOCIO ECONOMIC AND ENVIRONMENTAL EVALUATION OF WATER RESOURCES PROJECTS
Credits: 04 L-T-P: 3-1-0
Reference Books/ Text Book / Cases:
S. No.
Name of Authors/Books/Publishers
Year of Publication/
Reprint
1.
Economic development and Environmental Issues by P.A. Modi 1984
2.
Water Resources and their Environmental Impacts by S.A. Abbasi. 1978
Module No.
Contents Teaching
Hours
I
Water Resources Projects: Need and importance of Water Resources Projects, Types of projects. Socio-Economic Analysis : Social and Economic evaluation of population, standards of living, Community needs, Socio-Economic objectives.
12
II
Environment: Eco systems, Habitat assessment, Environmental objectives, study of available resources, Environmental monitoring, and Environmental evaluation techniques. Project Proposal and Implementation: Project planning, selection of project, Public awareness programme, feasibility reports, Eco-friendly projects, Project funding and expenditure, Cost and benefits, Risk assessment
16
III
Project Evaluation: Evaluation and impact of projects like irrigation, Power Supply, Water Supply, Flood Control, Sewage, etc. Facilities generated, negative effects- inundation, migration, etc. Case Studies: Case studies and evaluation of some important water Resources Projects in India and abroad.
12
Course Curriculum (w.e.f. Session 2015-16)
M.Tech. (Water Resources Engineering)
DEPARTMENT OF CIVIL ENGINEERING, Institute of Engineering & Technology
MCE-1034 IRRIGATION AND DRAINAGE ENGINEERING
Module No.
Content Teaching
Hours
I
Introduction, objectives of irrigation, types of irrigation and suitability;
selection of irrigation method.
Irrigation requirement, water balance, soil water relationships, water storage zone, infiltration. Flow of moisture through root zone, soil’s physical and chemical properties, crop’s evaporative and drainage requirements, irrigation efficiency and uniformity.
14
II
Surface irrigation systems, types of surface systems, basin irrigation, border irrigation, furrow irrigation, field measurement techniques, flow measurement, flumes, weirs, irrigation events, advance, wetting, depletion and recession phases. Infiltration, infiltrometer, ponding methods, soil water, tensiometers,
neutron probe, time domain reflectometer, evapotranspiration, crop coefficient, leaf area index, FAO guide lines on evapotranspiration estimation. Fundamentals of surface irrigation hydraulics, continuity equation, momentum equation
14
III
Hydrodynamic model, zero inertia models, kinematic wave model.
Drainage principles, need for drainage, steady state equations, Hooghoudt, Kirkham, Dagan and Ernst equations. Salt balance, water and salt balance of the root zone, salt equilibrium equation and leaching requirement, leaching efficiency.
12
Reference Books:
S. No.
Name of Authors/Books/Publishers
Year of Publication/
Reprint
1.
Walker, W.R., and Skogerboe, G.V., "Surface Irrigation Theory and Practice", Prentice Hall, INC.
1987
2.
Drainage Principles and Applications, "International Institute for Land Reclamation and Improvement", Wageningen.
1973
3.
Michael, A.M., "Irrigation: Theory and Practice", Vikas Publishing House.
1978
4.
Asawa, G.L., "Irrigation and Water Resources Engineering", New Age
Internationa
International Publishers, New Delhi AgeInternationalPublishers.
2014
5.
Majumdar, D.K., “Irrigationn Water Management”, PHI Learning.
2009
6.
Luthin, J.N., "Drainage Engineering", John Wiley.
1966
L–T–P: 3–1–0 Credits: 04
Course Curriculum (w.e.f. Session 2015-16)
M.Tech. (Water Resources Engineering)
DEPARTMENT OF CIVIL ENGINEERING, Institute of Engineering & Technology
MCE- 1015 ADVANCED NUMERICAL ANALYSIS
Module No.
Content Teaching
Hours
I
Introduction, roots of a non-linear equation and roots of a polynomial of
nthdegree [incremental search method, method of successive approximations,
Newton’s method, bisection method, secant method, Müller’s method , synthetic division, Bairstow’s method] and convergence study Solutionof(non-homogeneous)linearalgebraicequations,reviewofmatrixalgebra, Gausseliminationmethod,Cholesky’sdecompositionmethod,householdermethod, Gauss-Siedal iterative method
12
II
Solution of non-linear algebraic equations, method of successive approximation, Newton’s method, modified Newton– Raphson method, secant method Eigen values and Eigen vectors, reduction of generalized Eigen value problem
to the standard Eigen value problem, methods for obtaining Eigen values and Eigenvectors [polynomial method, vector iteration method, Misespower method, Jacobi method]
14
III
Time marching schemes for solution of problems in time domain, numerical integration (2 – D) [Newton– Cotes method, Gauss –Legendre method] Solution of ordinary and partial differential equations, Euler’s method, Runge– Kutta method, finite difference method, applications to problems of beam and
plates on elastic foundation, Laplacian equation, consolidation equation, laterally loaded piles etc
14
Reference Books:
S. No.
Name of Authors/Books/Publishers
Year of Publication/
Reprint
1.
Chapra,S.C.andCanaleR.P.,“NumericalMethodsforEngineers”,Tata McGraw hill
2003
2.
Carnahan,B.,Luther,H.A.andWilkes,J.O.,“AppliedNumericalMethods”, John Wiley
1969
3.
Heath,M.T. ,”Scientific Computing: An Introductory Survey”, McGrawhill
1997
4.
Douglas Faires,J. andRichard Burden,“Numerical Methods”,Thomson
2003
5.
Rajasekaran, S.,“Numerical Methods in Science and Engineering”,S. Chand
1999
L–T–P: 3–1–0 Credits: 04
Course Curriculum (w.e.f. Session 2015-16)
M.Tech. (Water Resources Engineering)
DEPARTMENT OF CIVIL ENGINEERING, Institute of Engineering & Technology
MCE-2031 WATER RESOURCES PLANNING AND MANAGEMENT
Credits: 04 L-T-P: 3-1-0
Reference Books/ Text Book / Cases:
S. No.
Name of Authors/Books/Publisher
Year of Publication/
Reprint
1.
Asawa, G.L., "Irrigation and Water Resources Engineering", New Age
Internationa
International Publishers, New Delhi AgeInternationalPublishers.
2014
2.
Bear, J., "Hydraulics of Ground Water", McGraw.
1979
3.
Walton, W.C., "Ground Water Resources Evaluation", McGraw Hill.
1970
4.
Economic development and Environmental Issues by P.A. Modi 1984
5.
Water Resources and their Environmental Impacts by S.A. Abbasi. 1978
Module No.
Contents Teaching
Hours
I
Objectives of water resource development; needs and opportunities; societal
goals. Spatial and temporal characteristics of water resources; constraints for its development like non-reversibility; planning r e g i o n and horizon.
Financial analysis of water resources projects; allocation of cost of multipurpose projects; repayment of cost
16
II
Demand for drinking water; irrigation, hydropower;
navigational; planning for flood control.
Characteristics and functions of reservoir; reservoir sedimentation; conservation storage; conflict among uses, Reservoir operation studies - effect on river regime; long term simulation; reliability; resiliency and vulnerability assessment.
12
III
Ground water evaluation; conjunctive use of surface and ground water. Discounting techniques; benefit cost parameters; estimation of benefits
and costs; appraisal criteria; social benefit cost analysis. Basin planning;
inter-basin transfer of water.
Environmental impacts assessment guidelines and case studies.
12
Course Curriculum (w.e.f. Session 2015-16)
M.Tech. (Water Resources Engineering)
DEPARTMENT OF CIVIL ENGINEERING, Institute of Engineering & Technology
MCE-2032 HYDRAULIC STRUCTURES
Credits: 04 L-T-P: 3-1-0
Reference Books/ Text Book / Cases:
S. No.
Name of Authors/Books/Publisher
Year of Publication/
Reprint
1.
Peterka, A.J, “Hydraulic Design of Stilling Basins and Energy Dissipators”, USBR Engineering Monographs No. 25”.
1984
2.
"Design of Small Dams", Third Edition, Water Resources Technical Publication– US Bureau of Reclamation.
1987
3.
Singh, B., and Varshney, R.S., "Embankment Dam and Engineering", Nem Chand and Brothers.
2004
4.
Chanson, H., “The Hydraulics of Open Channel Flow: An Introduction”, Elsevier Scientific Publications.
2004
5.
Novak, P. and Nalluri, C., “Hydraulic Structures”, Edition 4, Taylor & Francis.
2007
Module No.
Contents Teaching
Hours
I
Introduction: Hydraulic structures for water resources projects. Embankment Dams: Types, design considerations, seepage analysis and control, stability analysis, construction techniques.
12
II
Gravity Dams: Forces acting on failure of a gravity dam, stress analysis, elementary profile, design of gravity dam, other functional features of a gravity dam. Dam Outlet Works: Types of outlet structures, ogee spillway, chute spillway, siphon spillway, side channel spillway, Labyrinth and Piano key weir.
16
III
Terminal Structures: Hydraulic jump types, stilling basin, roller bucket, ski jump basin, baffled spillway, drop structure Hydraulic Modeling: Basic principles, dimensional analysis, modeling
free-surface flows, design of physical models.
12
Course Curriculum (w.e.f. Session 2015-16)
M.Tech. (Water Resources Engineering)
DEPARTMENT OF CIVIL ENGINEERING, Institute of Engineering & Technology
MCE-2033 HYDRO POWER ENGINEERING
Module No.
Content Teaching
Hours
I
Water Power: Introduction, sources of energy, role of hydropower in a power system. Estimation of Water Power Potential: Flow duration curves of gauged and ungauged streams, load curve, load factor, capacity factor, utilization factor, diversity factor, load duration curve, firm power, secondary power, prediction of load.
14
II
Types of Hydro-power Plants: Run of river plants, general arrangement
of run of river plants, valley dam plants, diversion canal plants, high head diversion plants, storage and pondage, pumped storage power plants. Penstocks: General classification, design criteria, economical diameter, losses, anchor blocks, valves, bends and manifolds. Trash racks: Types, losses, design, stability.
14
III
Intakes: Types, losses, air entrainment, anti-vortex device, airvent, power channels, fore bay, tunnel. Turbines: Introduction, types of turbines, hydraulics of turbines, velocity triangles, draft tubes, cavitation in turbines, turbine model testing, characteristics of turbines. Water Hammer and Surges: Introduction, water hammer, transients caused by turbine, load acceptance and rejection, resonance in penstocks,
surge tanks, channel surges.
12
Reference Books:
S. No.
Name of Authors/Books/Publishers
Year of Publication
/ Reprint
1.
Dandekar, M.M., and Sharma, K.N., "Water Power Engineering", Vikas Publishing House Pvt. Ltd.
2000
2.
Barrows, H.K., "Water Power Engineering", Tata McGraw Hill Publishing
Company Ltd.
1943
3.
Varshney, R.S., "Hydro Power Structures", Nem Chand &Bros.
2001
4.
Nigam, P.S., "Hydro Electric Engineering", Nem Chand &Bros.
2001
5.
Choudhary, M.H., "Applied Hydraulic Transients", Van Nostrand Reinhold Company
1987
6.
Streeter,V.L., andWylie, B., "Fluid Transients", McGraw-Hill Book Company.
1967
7.
Warnick, C.C., "Hydropower Engineering", Prentice-Hall.
1984
8.
Norwegian Institute of Technology: Hydropower Development: Vols. 3,4, 5&6, Division of Hydraulic Engineering.
1992-93
L–T–P: 3–1–0 Credits: 03
Course Curriculum (w.e.f. Session 2015-16)
M.Tech. (Water Resources Engineering)
DEPARTMENT OF CIVIL ENGINEERING, Institute of Engineering & Technology
MCE-2034 HYDRAULICS ENGINEERING LABORATORY
Credits: 01 L–T–P: 0–0–1
Module No.
Content Teaching
Hours
I
Boundary layer over a flat plate
Drag around a cylinder
Uniform flow in a channel
Velocity distribution in a channel
14
II
Vertical contraction in a channel
Horizontal contraction in a channel
Broad-Crested weir
14
III
Hydraulic jump
Forced hydraulic jump
Free overfall
Sediment distribution at off takes
12
Reference Books:
S. No.
Name of Authors/Books/Publishers
Year of Publication
/ Reprint
1.
G.L. ASAWA, “laboratory work in hydraulic engineering”, new age international publishers
2006
2.
S.K.LIKHI, “hydraulics laboratory manual”, new age international publishers 2006
Course Curriculum (w.e.f. Session 2015-16)
M.Tech. (Water Resources Engineering)
DEPARTMENT OF CIVIL ENGINEERING, Institute of Engineering & Technology
MCE-2035 FLUVIAL HYDRAULICS
Credits: 04 L-T-P: 3-1-0
Reference Books/ Text Book / Cases:
S. No.
Name of Authors/Books/Publisher
Yearof Publication/
Reprint
1.
Garde, R.J., “River Morphology”, New International Publishers.
2006
2.
Julien, P.Y., “Erosion and Sedimentation”, Cambridge University Press.
1998
3.
Jansen, P.P.H., “Principals of River Engineering”, VSSD Publications.
1994
4.
Garde, R.J. and Ranga Raju, K.G., "Mechanics of Sediment Transportation and Alluvial Stream Problems", Wiley Eastern Limited.
2006
Module No.
Contents Teaching
Hours
I
The sediment problems, properties of sediments, incipient motion of uniform and non-uniform sediments. Bed forms and channel resistance. Bed load and suspended load transport for uniform and non-uniform bed material, total load equations, sediment sampling.
12
II
Stable channel design and sediment control. Bed level variations, local scour, degradation, aggradation and reservoir sedimentation.
16
III
Physical and mathematical models. Design of guide bunds and other river training works.
12
Course Curriculum (w.e.f. Session 2015-16)
M.Tech. (Water Resources Engineering)
DEPARTMENT OF CIVIL ENGINEERING, Institute of Engineering & Technology
MCE- 2036 EMBAMKMENT DAMS
Credits: 01 L–T–P: 0–0–1
Module No.
Content Teaching
Hours
I
Introduction, Types and advantages of Embankment dams, Factors affecting the design of Embankment dams, safety criteria
14
II
Theoretical analysis of seepage through embankment and its applications, Control of seepage through embankment dams, Stability analysis including seismic stability.
14
III
Construction methods, Instrumentation, Typical problems and their solutions in Embankment dams.
12
Reference Books:
S.No.
Name of Authors/Book/Publishers
Yearof Publication/
Reprint
1.
Anderson, M.G. and Richards, K.S.; Slope Stability, John Wiley, 1987.
1987
2.
Sherard, J.L.;Woodward, R.J. Gizienski; and Clevenger, W.A.; Earth and Earth Rock Dams, John Wiley, 1963.
1963
3.
Chowdhury, D.F.; Slope Analysis, Prentice Hall, 1988.
1988
4.
McCarthy, R.N.; Essentials of Soil Mechanics and Foundations, Prentice Hall, 1988.
1988
Course Curriculum (w.e.f. Session 2015-16)
M.Tech. (Water Resources Engineering)
DEPARTMENT OF CIVIL ENGINEERING, Institute of Engineering & Technology
MCE-3033 WATERSHED DEVELOPMENT AND MANAGEMENT
Credits: 04 L-T-P: 3-1-0
Reference Books/ Text Book / Cases: S. No. Name of Authors /Book /Publishers Year of
Publication/Reprint
1. Das, G., “Hydrology and Soil Conservation Engineering”, Prentice Hall. 2002
2. Debarry, P. A., “Watershed: Processes, Assessment and Management”,
John Wiley.
2004
3. Lyon, J. G., “GIS for Water Resources and Watershed Management”,
Taylor and Francis.
2003
4. Schwab, G.O., Fangmeier, D.D., Elliot, W. J., Frevert, R. K., “Soil and
Water Conservation Engineering”, John Wiley.
2002
5. Suresh, R., “Soil and Water Conservation Engineering”, Standard
Publishers.
2006
6. Tideman, E.M., “Watershed Management”, Omega Scientific Publisher. 2002
Module No.
Contents Teaching
Hours
I
Components of watershed and need of watershed management; Principal factors influencing watershed operations; Delineation of watersheds; Engineering surveys; Data requirement. Watershed hydrology, water resources assessment in watershed, hydrological cycle; Surface water assessment- rainfall-runoff analysis; Groundwater assessment, infiltration and its measurement. Watershed Behavior- Physical elements of watershed, effects of land use
changes on hydrological cycle components, watershed experiments
12
II
Land capability classification; Erosion process- factors affecting erosion,
types of erosion, soil erosion models. Engineering measures for soil and water conservation- Contour bunding, graded bunding, bench terracing, land leveling and grading; Small storage structures- Types and design data requirement, loose boulder dams, gabions, check dams and their design criteria..
16
III
Rainwater harvesting, direct and indirect methods, filter design, planning and design; Layout and execution; Impact assessment, operation and maintenance issues. Watershed management plan- Methodology of planning a watershed, identification of watershed problems, socio-economic issues including application of Remote sensing and GIS in watershed management.
12
Course Curriculum (w.e.f. Session 2015-16)
M.Tech. (Water Resources Engineering)
DEPARTMENT OF CIVIL ENGINEERING, Institute of Engineering & Technology
. MCE-3034 GROUND WATER HYDROLOGY
Credits: 04 L-T-P: 3-1-0
Reference Books/ Text Book / Cases:
S. No.
Name of Authors/Books/Publisher
Year of Publication/
Reprint
1.
Bear, J., "Hydraulics of Ground Water", McGraw.
1979
2.
Walton, W.C., "Ground Water Resources Evaluation", McGraw Hill.
1970
3.
Freeze and Cherry, "Ground Water", Prentice Hall.
1979
4.
Driscoll, F.G., "Ground Water and Wells", Johnson Division.
1986
5.
Raghunath, H.M., "Ground Water", New Age International (P) Limited.
2007
Module No.
Contents Teaching
Hours
I
Introduction: Definition of ground water, role of ground water in
hydrological cycle, ground water bearing formations, classification of aquifers, flow and storage characteristics of aquifers, Darcy’s law,
anisotropy and heterogeneity. Governing Equations for Ground water Flow: Dupuit-Forchheimer
assumptions, general differential equations governing groundwater flows, analytical solutions. Wells and Well Hydraulics: Different types of wells, construction of wells, steady and unsteady state solutions for confined, unconfined and
leaky aquifers, effect of boundaries, method of images, pumping test analysis.
16
II
Ground water Conservation: Regional ground water budget; resource assessment; estimation of recharge, Indian practice, artificial recharge Ground water Quality: General problem of contamination of ground water, sources, remedial and preventive measures, seawater intrusion in
coastal aquifers.
12
III
Ground water Flow Modeling: Role of ground water flow models,
reference to hydraulic, Hele-Shaw and analog models, introduction to numerical modeling. Planning of Ground water Development: constraints on the development, role of flow models, optimal groundwater development.
12
Course Curriculum (w.e.f. Session 2015-16)
M.Tech. (Water Resources Engineering)
DEPARTMENT OF CIVIL ENGINEERING, Institute of Engineering & Technology
MCE-2011 FINITE ELEMENT METHOD
Credits: 04 L-T-P: 3-1-0
Reference Books/ Text Book / Cases: 1. Finite Element Method for Engineers and scientists – O.C.Zienkiewicz
2. Numerical Methods in Finite Element Analysis – K.J.Bathe&E.L.Wilson
3. Matrix Computations for Engineers & scientists – Alan Jennings
4. Introduction to Finite Element Method – C.S.Desai&J.F.Abel
5. Finite Element Method in Engineering – S.S. Rao
Module No.
Contents Teaching Hours
I
Introduction to Finite Element Analysis: Introduction Basic Concepts of
Finite Element Analysis Introduction to Elasticity Steps in Finite Element
Analysis
Finite Element Formulation Techniques: Virtual Work and Variation
Principle, Galerkin Method, Finite Element Method: Displacement
Approach, Stiffness Matrix and Boundary Conditions
12
II
Element Properties: Natural Coordinates, Triangular Elements, Rectangular
Elements, Lagrange and Serendipity Elements, Solid Elements,
Isoparametric Formulation, Stiffness Matrix of Isoparametric Elements,
Numerical Integration: One Dimensional. Numerical Integration: Two and
Three Dimensional
Analysis of Frame Structures: Stiffness of Truss Members, Analysis of
Truss, Stiffness of Beam Members, Finite Element Analysis of Continuous
Beam, Plane Frame Analysis, Analysis of Grid and Space Frame
16
III
FEM for Two and Three Dimensional Solids: Constant Strain Triangle,
Linear Strain Triangle, Rectangular Elements, Numerical Evaluation of
Element Stiffness, Computation of Stresses, Geometric Nonlinearity and
Static Condensation, Axi symmetric Element, Finite Element Formulation of
Axi symmetric Element, Finite Element Formulation for 3 Dimensional
Elements
Introduction to Plates and Shells
12
Course Curriculum (w.e.f. Session 2015-16)
M.Tech. (Water Resources Engineering)
DEPARTMENT OF CIVIL ENGINEERING, Institute of Engineering & Technology
MCE-0001 SOFT COMPUTING METHODS FOR CIVIL ENGINEERING
Module No.
Content Teaching
Hours
I
Expert System: Theory of representation; Working principles of ANN; Two
computational paradigms: Multi-layer networks; Auto associative and hetero
associative nets; Learning in neural nets: Supervised and unsupervised
learning; Application of neural nets; Neural network simulators.
13
II
Genetic algorithm and Traditional optimization methods; Simple genetic
algorithms- reproduction, crossover and mutation; Analysis of GA-
operators; Deception; Working principles of genetic algorithms; Multi-
model and multi-objective optimization; Engineering applications;
Introduction with applications for Evolution strategy. Combined use of
ANN-GA.
13
III
Fuzzy sets, fuzzy numbers, fuzzy relations, fuzzy measures, fuzzy logic and
the theory of uncertainty and information; applications of the theory to
inference and control, clustering, image processing and data handling.
Neuro-fuzzy systems, application of Neuro-fuzzy systems;
Term Paper: Based on applications and/or algorithms development.
14
Reference Books:
1. Neural Networks and Fuzzy Systems: A Dynamical Systems Approach to Machine Intelligence - Bart, K.
2. Evolutionary Multiobjective Optimization Algorithms- Deb, K.
3. Genetic Algorithms in Search, Optimization and Machine learning- Goldberg, D. E.
4. Neural Networks: A Comprehensive Foundations- Haykin, S.
5. Fuzzy Logic with Engineering Applications- Ross, T. J.
6. Introduction to Artificial Neural Systems- Zurada, J.M.
L–T–P: 3–1–0 Credits: 04
Course Curriculum (w.e.f. Session 2015-16)
M.Tech. (Water Resources Engineering)
DEPARTMENT OF CIVIL ENGINEERING, Institute of Engineering & Technology
MCE-0002 OPTIMIZATION METHODS IN CIVIL ENGINEERING
Module
No. Content
Teaching
Hours
I
Introduction: Engineering application of Optimization, Formulation of design
problems as mathematical programming problems, classification of
optimization problems.
Optimization Techniques: Classical optimization, multivariable with no
constraints, unconstrained minimization techniques, penalty function
techniques, Lagrange multipliers and feasibility techniques.
Linear Programming: Graphical method, Simplex method, Duality in linear
programming (LP),Sensitivity analysis Applications in civil engineering.
14
II
Non Linear Programming techniques/method: Unconstrained optimization,
one dimensional minimization, golden section, elimination, quadratic and
cubic, Fibonacci, interpolation, Direct search, Descent, Constrained
optimization, Direct and indirect, Optimization with calculus, Khun‐Tucker
conditions.
14
III Constrained optimization techniques ‐ Direct, complex, cutting plane, exterior
penalty function methods for structural engineering problems. 12
Reference Books:
1. Optimization Methods for Engineering Design – R.L.Fox
2. Optimization Techniques, Theory and applications – S.S.Rao
3. Introduction to Dynamic Programming – L.Cooper & M.W.Cooper
4. Non-Linear programming: Sequential Unconstrained Minimization Techniques-
A.V.Fiacco&G.P.McCormic
5. Geometric Programming – Duffin, Peterson &Zenar
6. Foundation of Optimization – J.D.Wilde&C.L.Beightler
7. An introduction to OR – H Taha
Course Curriculum (w.e.f. Session 2015-16)
M.Tech. (Water Resources Engineering)
DEPARTMENT OF CIVIL ENGINEERING, Institute of Engineering & Technology
MCE-0003 THEORY AND APPLICATIONS OF GIS
Module No.
Content Teaching
Hours
I
Introduction, Geographical concepts and Terminology, Difference
between Image Processing system and GIS, Utility of GIS. Various GIS packages and their salient features, Essential components of
GIS, Data acquisition through scanners and digitizers Raster and Vector Data: Introduction, Descriptions: Raster and Vector
data, Raster Versus Vector, Raster to Vector conversion, Remote Sensing
Data in GIS, Topology and Spatial Relationships, Data storage
verification and editing
14
II
Data preprocessing, Geo referencing, Data compression and reduction techniques, Run length encoding, Interpolation of data, Database Construction, GIS and the GPS, Data Output Data base structure, Hierarchical data, Network systems, Relational data base, Data base management, Data manipulation and analysis Spatial and mathematical operations in GIS, Overlay, Query-based Measurement and statistical modeling, Buffers, Spatial Analysis, Statistical Reporting and Graphing
12
III
Programming languages in GIS, Virtual GIS, Web GIS Application of GIS to various natural resources mapping and monitoring and engineering problems
14
Reference Books:
Sl. No.
Name of Authors/Books/Publishers
Year of Publication/
Reprint
1
Burrough, P.A. and McDonnel, R.A., “Principles of Geographic Information System”, Oxford University Press.
2000
2
Chrisman, Nicholas R., “Exploring Geographic Information Systems”, John Wiley.
2002
3
Demers,MichaelN.,“FundamentalsofGeographicInformationSystem”,2
ndEd. Wiley.
2008
4
Ghosh, S.K. and Chandra, A.M., “Remote Sensing and GIS”, Narosa Publishing House.
2008
5
Lo, C.P. and Young, A.K.W., “Concepts and Techniques of Geographical Information System”, Prentice Hall India.
2002
6
Longley,PaulA,Goodchild,MichaelF.,Maguire,DavidJ.andRhind,DavidW., “Geographic Information Systems and Science”, Wiley
2001
L–T–P: 3–1–0 Credits: 04