APPLIED MECHANICS DEPARTMENT

L D COLLEGE OF ENGINEERING
LINKS OF VIDEO LECTURES OF VARIOUS SUBJECTS

Subject Coordinated By Link Remarks

Mechanics of Prof. U. Saravanan https://nptel.ac.in/courses/105/106/105106172/

Materials

MECHANICS OF PRIYANKA GHOSH https://nptel.ac.in/courses/105/104/105104160/

SOLIDS

STRUCTURAL PROF AMIT SHAW, IIT https://nptel.ac.in/courses/105/105/105105166/

ANALYSIS-I Kharagpur https://www.youtube.com/watch?
v=sGJtiVQOhpY&list=PLn31MR-8SyINd9PNUR-
UlIPmJMdjSGSZ4

STRUCTURAL PROF P BANERJEE, IIT https://www.youtube.com/watch?v=qhEton-

ANALYSIS-II Mumbai EEOw&list=PL83821B43A558F579

ADVANCED Prof. Devdas Menon IIT https://nptel.ac.in/courses/105/106/105106050/

Madras
STRUCTURAL https://www.youtube.com/watch?
ANALYSIS v=s4CN6aVKhPo&list=PLPVT1x8nIoniJnsBFCu6bbhdL
r4JWW5Ws
MATRIX PROF AMIT SHAW, IIT
METHODS OF Kharagpur https://nptel.ac.in/courses/105/105/105105180/
STRUCTURAL
ANALYSIS

MAINTENANCE PROF. RADHAKRISHNA https://nptel.ac.in/courses/105/106/105106202/

AND REPAIR OF G. PILLAI
CONCRETE
STRUCTURES

SOIL by PROF.KOUSIK DEB https://nptel.ac.in/courses/105/105/105105200/

STRUCTURE
INTERACTION
GEOTECHNICA by PROF. DEVENDRA https://nptel.ac.in/courses/105/101/105101201/
L NARAIN SINGH
ENGINEERING-
1
DESIGN OF PROF. ARUN MENON https://nptel.ac.in/courses/105/106/105106197/
MASONRY
STRUCTURES
GEOTECHNICA by PROF. DILIP KUMAR https://nptel.ac.in/courses/105/105/105105185/
L BAIDYA Department of
ENGINEERING Civil Engineering IIT
II/ Kharagpur
FOUNDATION
ENGINEERING
FOUNDATION by PROF. KOUSIK DEB https://nptel.ac.in/courses/105/105/105105176/
ENGINEERING
Theory of Amit Shaw Institute: IIT https://nptel.ac.in/courses/105/105/105105177/
Elasticity Civil Kharagpur
Engineering

ADVANCED PROF. MANU https://nptel.ac.in/courses/105/106/105106176/

CONCRETE SANTHANAM
TECHNOLOGY
Soil Prof.Dilip Kumar https://nptel.ac.in/courses/105/105/105105168/
Mechanics/Ge Baidya
otechnical
Engineering I

REINFORCED PROF. NIRJHAR DHANG https://nptel.ac.in/courses/105/105/105105165/

CONCRETE
ROAD BRIDGES
FOUNDATION N R PATRA https://nptel.ac.in/courses/105/104/105104162/
DESIGN

Geology and PRIYANKA GHOSH https://nptel.ac.in/courses/105/104/105104147/

Soil Mechanics
Structural By PRADEEP KUMAR https://nptel.ac.in/courses/105/106/105106151/
Dynamics
FEM FOR BY Prof. C.S. Manohar https://nptel.ac.in/courses/105/108/105108141/
VIBRATION
ANALYSIS AND
STABILITY

Advanced –
Geotechnical https://nptel.ac.in/courses/105/101/105101001/
Engineering
Seismic Dr. Ashok Gupta https://nptel.ac.in/courses/105/102/105102016/
Analysis of Department of Civil
Structures EngineeringIIT Delhi
Dr. T.K. Datta
Department of Civil
EngineeringIIT Delhi

CONCRETE PROF. B. https://nptel.ac.in/courses/105/102/105102012/

TECHNOLOGY BHATTACHARJEE
Department of Civil
Engineering IIT Delhi

Concrete Dr. Sudhir Misra https://nptel.ac.in/courses/105/104/105104030/

Engineering Department of Civil
and EngineeringIIT Kanpur
Technology
Geotechnical Dr. Deepankar https://nptel.ac.in/courses/105/101/105101134/
Earthquake Choudhury
Engineering Department of Civil
EngineeringIIT Bombay

Advanced Dr. Kousik Deb https://nptel.ac.in/courses/105/105/105105039/

Foundation Department of Civil
Engineering EngineeringIIT
Kharagpur
Structural Dr. P. Banerji https://nptel.ac.in/courses/105/101/105101006/
Dynamics Department of Civil
EngineeringIIT Bombay
Soil Dynamics Dr. Deepankar https://nptel.ac.in/courses/105/101/105101005/
Choudhury
Department of Civil
EngineeringIIT Bombay
Numerical Dr. A. Deb Department https://nptel.ac.in/courses/105/105/105105043/
Methods in of Civil EngineeringIIT
Civil Kharagpur
Engineering

Ground Dr. G.L. Sivakumar https://nptel.ac.in/courses/105/108/105108075/

Improvement Babu Department of
Techniques Civil EngineeringIISc
Bangalore
Geosynthetics Dr. K. Rajagopal https://nptel.ac.in/courses/105/106/105106052/
and Reinforced Department of Civil
Soil Structures EngineeringIIT Madras
–

Soil Mechanics Dr. B.V.S. https://nptel.ac.in/courses/105/101/105101084/

– Viswanadham
Department of Civil
EngineeringIIT Bombay

Finite Element Dr. B.N. Rao https://nptel.ac.in/courses/105/106/105106051/

Analysis – Department of Civil
EngineeringIIT Madras

Foundation Prof. Mahendra Singh https://nptel.ac.in/courses/105/107/105107120/

Engineering Department of Civil
EngineeringIIT Roorkee
Prof. N.K. Samadhiya
Department of Civil
EngineeringIIT Roorkee
Prof. Priti Maheswari
Department of Civil
EngineeringIIT Roorkee

MECHANICS OF PROF. PRIYANKA https://nptel.ac.in/courses/105/106/105106116/

SOLIDS GHOSH ( IIT Kanpur -
 Civil Engineering )

Pre-stressed Dr. Amlan Kumar https://nptel.ac.in/courses/105/106/105106118/

Concrete Sengupta Department
Structures – of Civil EngineeringIIT
Madras
Prof. Devdas Menon
Department of Civil
EngineeringIIT Madras

DESIGN OF PROF. NIRJHAR DHANG

REINFORCED Department of Civil https://nptel.ac.in/courses/105/105/105105105/
CONCRETE Engineering IIT
STRUCTURES Kharagpur
STRUCTURAL ANALYSIS-I
PROF AMIT SHAW, IIT Kharagpur
https://nptel.ac.in/courses/105/105/105105166/
https://www.youtube.com/watch?v=sGJtiVQOhpY&list=PLn31MR-8SyINd9PNUR-UlIPmJMdjSGSZ4
Week 1: Equilibrium, Stability and Determinacy of structures; Review of shear force and bending
moment diagram in beams and frames
Week 2: Analysis of statically determinate structures 1; Plane truss: method of joints and method of
sections
Week 3: Analysis of statically determinate structures 2; Deflection of truss: Method of virtual work
Week 4: Analysis of statically determinate structures 3; Deflection of beams and frames 1: Moment
area method, conjugate beam method and virtual work method
Week 5: Analysis of statically determinate structures 4; Deflection of beams and frames 2: Moment
area method, conjugate beam method and virtual work method
Week 6: Analysis of statically determinate structures 5; Influence line diagram and moving loads
Week 7: Analysis of statically indeterminate structures 1; Introduction to force and stiffness method
Week 8: Analysis of statically indeterminate structures 2; Plane truss using method of consistent
deformations
Week 9: Analysis of statically indeterminate structures 3; Beams and Frames: Method of consistent
deformations
Week 10: Analysis of statically indeterminate structures 4; Beams and Frames: Moment distribution
method
Week 11: Analysis of statically indeterminate structures 5; Beams and Frames: Slope deflection
method
Week 12: Introduction to direct stiffness method

STRUCTURAL ANALYSIS-II
PROF P BANERJEE, IIT Mumbai
https://www.youtube.com/watch?v=qhEton-EEOw&list=PL83821B43A558F579

1. Introduction (2 lectures) - Review of basic concepts o Equilibrium Equations o Constitutive

Relations/Force-displacement Relations o Compatibility Conditions
2. Analysis of Statically Determinate Structures (10 lectures) - SF, BM diagrams - Determination of
forces in trusses, frames, arches, and cables
3. Principle of virtual work (2 lectures)
4. Energy Principle (2 lectures)
5. Maxwell's and Betti's laws (2 lectures)
6. Computation of Displacements (8 lectures) - Moment area method - Conjugate beam method -
Virtual work methods
7. Introduction to statically Indeterminate Structures (2 lectures) - Concept of static and kinematic
indeterminacy - Determination of static and kinematic redundancy
8. Influence Lines (4 lectures) - Equilibrium methods - Muller Breslau principle
9. Force Method - Introduction and Applications (12 lectures) - Axially loaded members - Plane truss
- Beams - Frames

ADVANCED STRUCTURAL ANALYSIS by Prof. Devdas Menon IIT Madras

https://nptel.ac.in/courses/105/106/105106050/
https://www.youtube.com/watch?v=s4CN6aVKhPo&list=PLPVT1x8nIoniJnsBFCu6bbhdLr4JWW5Ws

1 Review of basic concepts in structural analysis: structure (structural elements, joints and supports,
stability,rigidity and static indeterminacy, kinematic indeterminacy); loads (direct actions, indirect
loading); response (equilibrium, compatibility, force-displacement relations); levels of analysis;
analysis of statically determinate structures (trusses, beams, frames); applications of principle of
virtual work and displacement-based and force-based energy principles; deriving stiffness and
flexibility coefficients.
2 Review of analysis of indeterminate structures: Force methods: Statically indeterminate structures
(method of consistent deformations; theorem of least work). Displacement Methods: Kinematically
indeterminate structures (slope-deflection method; moment distribution method). 4
3 Matrix concepts and Matrix analysis of structures: Matrix; vector; basic matrix operations; rank;
solution of linear simultaneous equations; eigenvalues and eigenvectors. Introduction; coordinate
systems; displacement and force transformation matrices; Contra-gradient principle; element and
structure stiffness matrices; Element and structure flexibility matrices; equivalent joint loads;
stiffness and flexibility approaches
4 Matrix analysis of structures with axial elements: Introduction: Axial stiffness and flexibility;
stiffness matrices for an axial element (two dof), plane truss element (four dof) and space truss
element (six dof); One-dimensional axial structures: Analysis by conventional stiffness method (two
dof per element) and reduced element stiffness method (single dof);Analysis by flexibility method;
Plane trusses: Analysis by conventional stiffness method (four dof per element) and reduced
element stiffness method (single dof);Analysis by flexibility method; Space trusses: Analysis by
conventional stiffness method (six dof per element) and reduced element stiffness method (single
dof). 8
5 Matrix analysis of beams and grids: Conventional stiffness method for beams: Beam element
stiffness (four dof); generation of stiffness matrix for continuous beam; dealing with internal hinges,
hinged and guided-fixed end supports; accounting for shear deformations; Reduced stiffness method
for beams: Beam element stiffness (two dof); dealing with moment releases, hinged and guided-
fixed end supports; Flexibility method for fixed and continuous beams: Force transformation matrix;
element flexibility matrix; solution procedure (including support movements); Stiffness method for
grids: Introduction; torsional stiffness of grid element and advantage of torsion release; analysis by
conventional stiffness method using grid element with six dof; analysis by reduced stiffness method
(three dof per element);
6 Matrix analysis of plane and space frames: Conventional stiffness method for plane frames:
Element stiffness (six dof); generation of structure stiffness matrix and solution procedure; dealing
with internal hinges and various end conditions; Reduced stiffness method for plane frames:
Element stiffness (three dof); ignoring axial deformations; dealing with moment releases, hinged and
guidedfixed end supports; Flexibility method for plane frames: Force transformation matrix; element
flexibility matrix; solution procedure (including support movements); Ignoring axial deformations;
Stiffness method for space frames: Introduction; element stiffness matrix of space frame element
with 12 dof and 6 dof; coordinate transformations; analysis by reduced stiffness method (six dof per
element); 7
7 Analysis of elastic instability and second-order effects: Effects of axial force on flexural stiffness:
Review of buckling of ideal columns; flexural behaviour and stiffness measures for beam-columns -
braced and unbraced, under axial compression; Solution by slope deflection method: Slope
deflection equations for prismatic beam columns using stability functions; modifications for pinned
and guided-fixed-end conditions; fixedend moments in beam-columns; Solution by matrix method:
Stiffness matrix for prismatic beamcolumn element; estimation of critical elastic buckling loads;
second-order analysis;
MATRIX METHODS OF STRUCTURAL ANALYSIS
PROF AMIT SHAW, IIT Kharagpur

https://nptel.ac.in/courses/105/105/105105180/
Introduction Structures, loads and response; determinate and indeterminate structures; stiffness
and Review of analysis of Indeterminate structures: Force and displacement methods Mathematical
preliminaries: Review of concept of matrix algebra; stiffness and flexibility matrices Analysis of
Trusses Analysis of Beams Analysis of plane frames Implementation issues Beyond matrix method:
Introduction to finite element method

MAINTENANCE AND REPAIR OF CONCRETE STRUCTURES

PROF. RADHAKRISHNA G. PILLAI
https://nptel.ac.in/courses/105/106/105106202/
Week 1: Introduction, significance of corrosion, and corrosion mechanisms
Week 2: Embedded metal corrosion
Week 3: Deterioration of cementitious systems – Sulphate and Acid attack
Week 4: Deterioration of cementitious systems – Alkali Silica Reaction (ASR), Shrinkage, and others
Week 5: Concrete assessment using non-destructive tests (NDT)
Week 6: Concrete assessment and load effects
Week 7: Surface repair – Condition assessment
Week 8: Surface repair – Analysis, strategy, and design
Week 9: Surface repair – Material requirement, surface preparation, placement of repair material
Week 10:Strengthening and stabilization – Introduction and beam shear capacity strengthening
Week 11: Strengthening and stabilization – Column strengthening    
Week 12: Strengthening and stabilization – Flexural strengthening

SOIL STRUCTURE INTERACTION by PROF.KOUSIK DEB

https://nptel.ac.in/courses/105/105/105105200/
Week 1 : Introduction, critical study of conventional methods of shallow foundation design
Week 2 : Critical study of conventional methods of shallow foundation design (continued),
Week 3 : Determination of subgrade modulus and parameters influencing subgrade
modulus(continued)
Week 4 : Time-dependent response, Beams on Elastic Foundation, infinite beam.
Week 5 : Infinite beam (continued),
Week 6 : Semi-infinite beam (continued)
Week 7 : Beams with finite length and various end conditions
Week 8 : Continuity among the foundation soil layers
Week 9 : Plates on Elastic Foundation (rectangular and circular)
Week 10 : Use of Finite Difference Method (FDM) for soil structure interaction problems
Week 11 : Group action of pile, Elastic Analysis, settlement of pile group under compressive load by
Interaction Factor Approach, negative skin friction.
Week 12 : Laterally loaded piles, Reese and Matlock’s generalized solution, displacement of pile
group under lateral load by Interaction Factor Approach, Uplift capacity of piles and anchors.

GEOTECHNICAL ENGINEERING- 1 by PROF. DEVENDRA NARAIN SINGH

https://nptel.ac.in/courses/105/101/105101201/
Week 1: Origin of Soils and Rocks, Rock cycle
Week 2: Basic relationships, Index properties of aggregates
Week 3: Soil structure, Soil classification
Week 4: Soil compaction
Week 5: Soil-water Statics
Week 6: Flow through soils, Quick sand condition
Week 7: Permeability and methods for its determination
Week 8: Flow-nets, Stresses in soil from surface loads
Week 9: Boussinesq theory
Week 10: New marks chart, Contact pressures
Week 11: Consolidation of soils
Week 12: Settlement of compressible soil layers

DESIGN OF MASONRY STRUCTURES by PROF. ARUN MENON

https://nptel.ac.in/courses/105/106/105106197/
Week 1: Introduction
Week 2: Masonry Materials and Properties
Week 3: Strength and Behaviour of Masonry
Week 4: Strength and Behaviour of Masonry (contd)
Week 5: Strength and Behaviour of Masonry (contd)
Week 6: Design of Reinforced Masonry  
Week 7: Design of Reinforced Masonry (contd)  
Week 8: Design of Reinforced Masonry (contd)  
Week 9: Design of Reinforced Masonry (contd)  
Week 10: Design of Reinforced Masonry (contd)  
Week 11: Design of Reinforced Masonry (contd)
Week 12: Confined Masonry, Infill Masonry,

GEOTECHNICAL ENGINEERING II/ FOUNDATION ENGINEERING by PROF. DILIP KUMAR BAIDYA

Department of Civil Engineering IIT Kharagpur
https://nptel.ac.in/courses/105/105/105105185/
Introduction and quick review of Soil Mechanics Shallow Foundation and Bearing Capacity Bearing
Capacity theories and its application Settlement of Footing Soil Exploration and Geotechnical
Investigation Earth Pressure Theories Stability Analysis of Retaining wall Deep Foundations type,
selection and load transfer mechanism Pile capacity, pile load test and settlement Sheet pile wall
Deep Excavation Introduction to Machine foundation

FOUNDATION ENGINEERING by PROF. KOUSIK DEB

https://nptel.ac.in/courses/105/105/105105176/
PROF. KOUSIK DEB Department of Civil Engineering IIT Kharagpur
Introduction, Soil Exploration   Penetration Tests, Geophysical Exploration Bearing capacity of
shallow foundation  Settlement of shallow foundations  Design of shallow foundation  Deep
foundation, load transfer mechanism in piles, pile capacity, Pile load test  Pile group capacity,
settlement of pile, Design of Pile Foundation  Lateral Earth Pressures-I  Lateral Earth Pressures-II
Earth retaining structures  Sheet Piles and Braced Excavation  Soil Arching, Underground Conduits

Theory of Elasticity Civil Engineering

Instructor Name: Amit Shaw Institute: IIT Kharagpur
https://nptel.ac.in/courses/105/105/105105177/
1 Mathematical Preliminaries Introduction to Tensor
2 Concept of Stresses and Strains
3 Material Behaviour– 1 General anisotropic material, strain energy density, constitutive relation 4
Material Behaviour– 2 Material symmetry, linear elastic material, Generalized Hook’s law
5 Formulation of boundary value problems in elasticity Equilibrium, compatibility, formulation in
Cartesian and Polar coordinates
6 Solution of boundary value problems in elasticity– 1 Plane stress and plane strain problems
7 Solution of boundary value problems in elasticity– 1 Problems in flexure
8 Solution of boundary value problems in elasticity– 1 Problems in Torsion
9 Introduction to Thermo-elasticity
10 Introduction to photo-elasticity
11 Introduction Nonlinear elasticity
12 Numerical methods in elasticity

ADVANCED CONCRETE TECHNOLOGY COURSE by PROF. MANU SANTHANAM

https://nptel.ac.in/courses/105/106/105106176/
PROF. MANU SANTHANAM Department of Civil Engineering IIT Madras
Cement production and composition Cement chemistry  Aggregates for concrete Chemical
admixtures Chemical and Mineral admixtures Mineral admixtures High performance concrete
mixture proportioning Topics in fresh concrete Topics in hardened concrete Creep and shrinkage
Durability of concrete Durability of concrete

Mechanics of Materials Civil Engineering Instructor Name: Prof. U. Saravanan

https://nptel.ac.in/courses/105/106/105106172/

Soil Mechanics/Geotechnical Engineering I

Civil Engineering Instructor Name: Prof.Dilip Kumar Baidya
https://nptel.ac.in/courses/105/105/105105168/

REINFORCED CONCRETE ROAD BRIDGES by PROF. NIRJHAR DHANG

https://nptel.ac.in/courses/105/105/105105165/
Introduction, design considerations, loads and IRC codes Flexural and shear strength of reinforced
concrete members Solid slab bridge design T-beam bridge design

MECHANICS OF SOLIDS By PRIYANKA GHOSH

https://nptel.ac.in/courses/105/104/105104160/

FOUNDATION DESIGN By N R PATRA

https://nptel.ac.in/courses/105/104/105104162/

Geology and Soil Mechanics – PRIYANKA GHOSH

https://nptel.ac.in/courses/105/104/105104147/
1 Description of soil, engineering geology of soils and their formation, clay mineralogy 2 Index
properties of soil 3 Classification of soils 4 Soil compaction 5 Permeability in soil 6 Seepage in soil and
flow net construction 7 Seepage in soil and flow net construction 8 In-situ stresses and criteria for
filter design 9 Effective stress principle and soil-water systems: capillarity 10 Fundamental of
consolidation 11 Fundamental of consolidation 12 Shear strength of soil Shear strength of soil NPTEL
http://nptel.ac.in Civil Engineering Pre-requisites: Mechanics of solids/Strength of materials
Coordinators: Dr. Priyanka Ghosh Department of Civil EngineeringIIT Kanpur 13 Shear strength of soil
14 Shear strength of soil 15 Stress in soil 16 Earth pressure theories
Structural Dynamics By PRADEEP KUMAR
https://nptel.ac.in/courses/105/106/105106151/
Week 1: Basics of Structural Dynamics Module 1: Introduction of Structural Dynamics Module 2:
Differential Equations in Civil Engineering Module 3: Types ofAnalysis/Static and Dynamic load
Module 4: Degrees of Freedom (Ex: Generation of Stiffness matrix) Module 5: Dynamic Equilibrium
Equation Module 6:Solution of Equilibrium Equation
Week 2: Free Vibration of SDOF Module 1: Undamped free Vibration Module 2:Solution, Natural
Period/Frequency Module 3:Energy in Free Vibration Module 4: Damped Free Vibration Module 5:
Types of damping Module 6: Logarithmic decrement equation
Week 3: Forced Vibration of SDOF Module 1: Undamped Forced vibration Module 2:Amplitude &
Phase Angle Module 3: Dynamic amplification factor for deflection (Rd) Module 4: Damped Forced
vibration Module 5: Relationship between Rd, Rv and Ra
Week 4: Force Transmission, Vibration Measurement Module 1: Resonant frequency and Half power
band width Module 2: Force Transmission and Isolation Module 3: Design of Vibration Measuring
Instruments
Week 5: Response to Arbitrary Motions Module 1: Response to Unit Impulse Module 2: Response to
Arbitrary Force (Duhamel's Integral) Module 3: Response to Step and Ramp Forces Module 4:
Response to Rectangular Pulse, Half Sinusoidal wave
Week 6: Numerical Methods of Solution Module 1: Time Stepping Methods Module 2: Central
Difference Method Module 3: Newmark's Method
Week 7: Response Spectrum Module 1: Concept of Response Spectrum Module 2: Uses of Response
Spectrum Module 3:Special Cases in Spectrum Module 4: Development of Tripartite Plot Module
5:Example:Base Shear and Base Moment Module 6: Response of Structure in Frequency Domain
Week 8: Module 1:Equation of Motion for MDOF System NPTEL http://nptel.ac.in Civil Engineering
Pre-requisites: Basic understanding of structural analysis and knowledge of engineering
mathematics. Coordinators: Prof. Ramancharala Pradeep Kumar Earthquake Engineering Research
CentreIIIT Hyderabad Week 8: Multi-Degree of Freedom Systems Module 2:Solution of Equation,
Natural Frequencies and mode Shapes (60) Module 3: Modal Orthogonality Module 4:Approximate
Method for finding Natural frequency
Week 9: Earthquake Response of MDOF Systems Module 1: Time History Analysis Module 2:
Response Spectrum Analysis Module 3: 3D Dynamic Analysis
Week 10: Dynamic Response of Continuous Systems Module 1:Vibration of Continuous systems
Module 2:Shear behavior and bending behavior Module 3: Generalized SDOF
Week 11: Dynamics of Rigid Blocks Module 1: Dynamics of Rigid Blocks Module 2: Non Structural
Elements Module 3: Floor Response Spectrum
Week 12: Vibration Control Module 1: Introduction to Vibration Control Module 2:Active Control
Module 3:Passive Control Module 4: Design of Tuned Mass Damper

FEM FOR VIBRATION ANALYSIS AND STABILITY BY Prof. C.S. Manohar

https://nptel.ac.in/courses/105/108/105108141/

Advanced Geotechnical Engineering –

https://nptel.ac.in/courses/105/101/105101001/
Dr. B.V.S. Viswanadham Department of Civil EngineeringIIT Bombay
1 Soil composition and soil structure: Soil formation; Types of soils and their characteristics; Particle
sizes and shapes; their impact on engineering properties; Soil structure; Clay mineralogy; Soil-air-
water interaction; Consistency; Soil compaction; Concept of effective stress.
2 Permeability and Seepage: Permeability; Seepage force and effective stress during seepage.
Laplace equations of fluid flow for 1-D, 2-D and 3D seepage, Flow nets, Anisotropic and
nonhomogeneous medium, Confined and Unconfined seepage. 7
3 Compressibility and Consolidation: Stresses in soil from surface loads; Terzagahi's 1- D
consolidation theory; Application in different boundary conditions; Ramp loading. Determination of
Coefficient of consolidation cv; Normally and Overconsolidated soils; Compression curves; Secondary
consolidation. Radial consolidation; Settlement of compressible soil layers and Methods for
accelerating consolidation settlements. 10
4 Stress-strain relationship and Shear strength of soils: Stress state, Mohr's circle analysis and Pole,
Principal stress space, Stress paths in p-q space; Mohr-coulomb failure criteria and its limitations,
correlation with p-q space; Stress-strain behaviour: Isotropic compression and pressure dependency,
confined compression, large stress compression, Definition of failure, Interlocking concept and its
interpretations, Drainage conditions; Triaxial behaviour, stress state and analysis of UC, UU, CU, CD,
and other special tests, Stress paths in triaxial and octahedral plane; Elastic modulus from triaxial
tests. 10
5 Stability of Slopes: Stability analysis of a slope and finding critical slip surface; Sudden Draw down
condition, effective stress and total stress analysis; Seismic displacements in marginally stable
slopes; Reliability based design of slopes, Methods for enhancing stability of unstable slopes. 8
6 Buried Structures: Load on Pipes, Marston's load theory for rigid and flexible pipes, Trench and
Projection conditions, minimum cover, Pipe floatation and Liquefaction. 3
7 Geotechnical Physical Modeling: Physical modeling methods; Application of centrifuge modeling
and its relevance to geotechnical engineering; Centrifuge modeling of geotechnical structures.

Seismic Analysis of Structures

Dr. Ashok Gupta Department of Civil EngineeringIIT Delhi
Dr. T.K. Datta Department of Civil EngineeringIIT Delhi
https://nptel.ac.in/courses/105/102/105102016/
1. Seismology 4
2. Seismic Inputs 4
3. Response Analysis for Specified Ground Motion 6
4. Frequency Domain Spectral Analysis 5
5. Response Spectrum Method of Analysis 5
6. Inelastic Seismic Response of Structures 6

CONCRETE TECHNOLOGY
PROF. B. BHATTACHARJEE Department of Civil Engineering IIT Delhi
https://nptel.ac.in/courses/105/102/105102012/
Introduction concrete as a material, ingredients, Production, composition, and properties; cement
chemistry. Types of cements; special cements, aggregates :properties, tests and standard Water
reducers, air entrainers, set controllers, specialty admixtures – structure properties, and eects on
concrete properties; Introduction to supplementary cementing materials and pozzolans. Fly ash,
blast furnace slag, silica fume, and metakaolin – their production, properties, and eects on concrete
properties; other reactive and inert mineral additives. Basic principles; IS method; ACI method; new
approaches based on rheology and particle packing. Batching of ingredients; mixing, transport, and
placement; consolidation, -nishing, and curing of concrete; initial and -nal set – signi-cance and
measurement; workability of concrete and its measurement Compressive strength and parameters
aecting it; Tensile strength – direct and indirect; Modulus of elasticity and Poisson’s ratio; Stress
strain response of concrete. Modulus of elasticity and Poisson’s ratio; Stress strain response of
concrete. Creep and relaxation – parameters aecting; Shrinkage of concrete – types and signi-cance;
parameters aecting shrinkage; measurement of creep and shrinkage Introduction to durability;
relation between durability and permeability; Chemical attack of concrete corrosion of steel rebars;
other durability issues Properties and applications of: High strength – high performance concrete,
reactive powder concrete; Lightweight, heavyweight, and mass concrete; Self-compacting concrete,
-bre reinforced concrete; self-compacting concrete; other special concretes.

Concrete Engineering and Technology

Dr. Sudhir Misra Department of Civil EngineeringIIT Kanpur
https://nptel.ac.in/courses/105/104/105104030/
1 Fundamental of concrete - constituents, proportioning, mixing, transportation, placing and curing.
2 Properties of fresh and hardened concrete. 03
3 Quality control in concrete construction. 02
4 Durability of concrete - alkali aggregate reaction,reinforcement corrosion, freezing and thawing,
etc. 10
5 Special concretes - high strength, low heat of hydration, high early strength, selfcompacting, etc.
6 Construction methods - shotcrete,roller compacted concrete, etc. 03
7 Reinforcing materials - epoxy coated bars, fibre-reinforced plastics. 04
8 Introduction to 'maintenance' of concrete structures - use of nondestructive testing, evaluation
criteria. 04

Geotechnical Earthquake Engineering

Dr. Deepankar Choudhury Department of Civil EngineeringIIT Bombay
https://nptel.ac.in/courses/105/101/105101134/
1 Introduction to Geotechnical Earthquake Engineering Scope and objective; Nature and types of
earthquake loading; Importance of Geotechnical Earthquake Engineering 01
2 Basics of Vibration theory Concept of dynamic load,Earthquake load,Single degree of freedom
system, Multiple degree of freedom system, Free and forced vibrations, Damped and undamped
systems, Equation of Motion, Response spectra. 04
3 Engineering Seismology Basic Seismology,Earthquake, List of major earthquakes, Causes of
earthquakes,Sources of earthquake data,Elastic rebound Theory, Faults, Plate tectonics,Seismograph
and Seismogram,Prediction of Earthquakes, Protection against earthquake damage, Origin of
Universe, Layers of Earth, Theory of Continental Drift, Hazards due to Earthquakes. 03 NPTEL
http://nptel.iitm.ac.in Civil Engineering Pre-requisites: Soil Mechanics (Geotechnical Engineering I)
Additional Reading: Journal and Conference papers in the area of Geotechnical Earthquake
Engineering. Coordinators: Dr. Deepankar Choudhury Department of Civil EngineeringIIT Bombay
4 Strong Ground Motion Size of Earthquake: Magnitude and Intensity of Earthquake, Modified
Mercalli Intensity Scale, Measuring of Earthquake,Earthquake MagnitudeLocal (Richter) magnitude,
surface wave magnitude, Moment magnitude, Seismic energy, Correlations. Spectral
Parameters:Peak Acceleration,Peak Velocity,Peak Displacement, Frequency Content and duration,
Spatial Variability of Ground Motion, Attenuation Relationships, Fourier Amplitude Spectra,Arias
Intensity. 03
5 Wave Propagation Elastic response of continua (one, two and three dimensional wave equations);
Waves in unbound media; Waves in semi-infinite media; Waves in layered media, Mohorovicic
Discontinuity and Gutenberg Discontinuity,Seismic Travel Time Curve, Three Circle Method for
locating an Earthquake’s Epicentre. 03
6 Dynamic Soil Properties Stiffness, damping and plasticity parameters of soil and their
determination (laboratory testing, intrusive and non intrusive in-situ testing); Correlations of
different soil parameters; Liquefaction (basics, evaluation and effects), Liquefaction hazard map,
Lateral Spreading. 05
7 Seismic Hazard Analysis Magnitude Indicators,Segmentation, Deterministic Seismic Hazard Analysis
(DSHA),Probabilistic Seismic Hazard Analysis (PSHA),Earthquake Source Characterization, Gutenberg-
Richter recurrence law,Predictive relationships, temporal uncertainty, Probability
computations,Seismic Hazard Curve, Logic tree methods. 06
8 Site Response Analysis Ground Response Analysis, Transfer Function, Non-linear approach.Site
Classification. 02
9 Seismic Analysis and Design of Various Geotechnical Structures Pseudo-static
method,Pseudodynamic method, other dynamic methods,Seismic analysis of retaining wall,Seismic
slope stability analysis, Behaviour of reinforced soil under seismic conditions,Seismic design of
retaining structures,Seismic analysis of Tailings Dam,Seismic displacement based analysis, seismic
design of shallow foundations, seismic design of pile foundations, seismic uplift capacity of ground
anchors, seismic design of Municipal Solid Waste (MSW) landfills. Codal provisions/guidelines for
seismic
10 design of geotechnical structures.

Advanced Foundation Engineering - Dr. Kousik Deb Department of Civil EngineeringIIT Kharagpur
https://nptel.ac.in/courses/105/105/105105039/
1 Introduction, soil exploration, analysis and interpretation of soil exploration data, estimation of soil
parameters for foundation design. 3
2 Shallow Foundations : Methods for bearing capacity estimation, total and differential settlements
of footing and raft, code provisions. Design of individual footings, strip footing, combined footing,
rigid and flexible mat, buoyancy raft, basement raft, underpinning. 8
3 Pile Foundations : Estimation load carrying capacity of single and pile group under various loading
conditions. Pile load testing (static, dynamic methods and data interpretation), settlement of pile
foundation, code provisions, design of single pile and pile groups, and pile caps. 8
4 Well Foundations : Types, components, construction methods, design methods (Terzaghi, IS and
IRC approaches), check for stability, base pressure, side pressure and deflection. 4
5 Retaining Walls : Types (types of flexible and rigid earth retention systems: counter fort, gravity,
diaphragm walls, sheet pile walls, soldier piles and lagging). Support systems for flexible retaining
walls (struts, anchoring), construction methods, stability calculations, design of flexible and rigid
retaining walls, design of cantilever and anchored sheet pile walls. 6
6 Soil-Foundation Interaction : Idealized soil, foundation and interface behavior. Elastic models of
soil behavior; Elastic-plastic and time dependent behavior of soil. Beams and plates on elastic
foundation; numerical analysis of beams and plates resting on elastic foundation. 5
7 Reinforced Earth : Geotechnical properties of reinforced soil, shallow foundation on soil with
reinforcement, retaining walls with reinforcements, design considerations

Structural Dynamics - Dr. P. Banerji Department of Civil EngineeringIIT Bombay

https://nptel.ac.in/courses/105/101/105101006/
1. Introduction: Types of dynamic loads; Basic background of methods available and motivation for
structural dynamics. 01
2. Dynamics of Single Degree-of-Freedom Structures: Dynamic equation of equilibrium; Free
vibration of single degree of freedom systems; Forced vibration: harmonic and periodic loadings;
Dynamic response functions, force transmission and vibration isolation; SDOF response to arbitrary
functions.
3. Numerical Evaluation of Dynamic Response of SDOF Systems: Time domain analysis: finite
difference methods; Frequency domain analysis: basic methodology. 04
4. Earthquake Response of SDOF Systems: Earthquake excitation, response history and construction
of response spectra; Response spectrum characteristics, tripartite plot, and design spectrum. 03
5. Multi Degree of Freedom Systems - Basics: Dynamic equations of equilibrium, static condensation;
Symmetricplan and plan-asymmetric systems. 03
6. Free Vibration Response of MDOF Systems: Undamped systems: natural modes and their
properties; Numerical solution for the eigenvalue problem; Solution of free vibration response for
undamped systems; Free vibration analysis of systems with damping. 05
7. Dynamic Analysis of Linear MDOF Systems: Introduction, modal analysis; Response-history for
earthquake excitations using modal analysis; Response spectrum analysis for peak responses;
Concept of Caughey damping as a general type of proportional damping. 05
8. Generalized Single Degree of Freedom Systems: Basic concepts, mass-spring system; Lumped
mass systems; Systems with distributed mass and elasticity; Rayleigh’s method, shape function
selection. 04
9. Introduction to Dynamics of Continuous Systems: Equations of motions for axial vibration of a
beam; Equations of motion for flexural vibration of a beam; Free vibration analysis; Introduction to
forced vibration analysis using modal superposition method.

Soil Dynamics
Dr. Deepankar Choudhury Department of Civil EngineeringIIT Bombay
https://nptel.ac.in/courses/105/101/105101005/
1. Introduction: Scope and objective; Nature and types of dynamic loading; Importance of soil
dynamics. 01
2. Vibration theory: Vibration of elementary systems; Degrees of freedom; Undamped and damped
free and forced vibrations; Forced vibrations due to support motions; Rotating mass and constant
force oscillators; Non harmonic forced vibrations; Duhamel’s integral; Introduction to Fourier
transform; Introduction to two and multi degrees of freedom systems; Response spectra. 08
3. Wave Propagation: Elastic response of continua (one, two and three dimensional wave equations);
Waves in unbound media; Waves in semiinfinite media; Waves in layered media.
4. Dynamic Soil Properties: Stiffness, damping and plasticity parameters of soil and their
determination (laboratory testing, intrusive and non intrusive in-situ testing); Correlations of
different soil parameters; Liquefaction (basics, evaluation and effects) 06
5. Machine Foundations: Types of motion; MSD model and EHS theory; Vertical, sliding, torsional
and rocking modes of oscillations; Coupled motion; Vibration control; Practical design considerations
and codal provisions 10
6. Soil Improvement Techniques: Basic concept of soil improvement due to dynamic loading; Various
methods; Mitigation of liquefaction. 03
7. Dynamic Soil-Structure Interaction: Behaviour of shallow underground foundations due to
dynamic loads; Response of pile foundations under dynamic loads; Design aspects for earth retaining
structures subjected to dynamic loads; Slope stability due to dynamic loads; Behaviour of subgrade
soil due to cyclic loads of railway, runway. 08
8. Generalized Single Degree of Freedom Systems: Basic concepts, mass-spring system; Lumped
mass systems; Systems with distributed mass and elasticity; Rayleigh’s method, shape function
selection. 04
9. Introduction to Dynamics of Continuous Systems: Equations of motions for axial vibration of a
beam; Equations of motion for flexural vibration of a beam; Free vibration analysis; Introduction to
forced vibration analysis using modal superposition method.

Numerical Methods in Civil Engineering

Dr. A. Deb Department of Civil EngineeringIIT Kharagpur
https://nptel.ac.in/courses/105/105/105105043/
1 Introduction to Numerical Methods: Why study numerical methods. Sources of error in numerical
solutions: truncation error, round off error. Order of accuracy - Taylor series expansion. 2
2 Direct Solution of Linear systems: Gauss elimination, Gauss Jordan elimination. Pivoting,
inaccuracies due to pivoting. Factorization, Cholesky decomposition. Diagonal dominance, condition
number, ill conditioned matrices, singularity and singular value decomposition. Banded matrices,
storage schemes for banded matrices, skyline solver.
3 Iterative solution of Linear systems: Jacobi iteration. Gauss Seidel iteration. Convergence criteria. 3
4 Direct Solution of Non Linear systems: Newton Raphson iterations to find roots of a 1D nonlinear
equation. Generalization to multiple dimensions. Newton Iterations, Quasi Newton iterations. Local
and global minimum, rates of convergence, convergence criteria. 4
5 Iterative Solution of Non Linear systems: Conjugate gradient. Preconditioning. 3
6 Partial Differential Equations: Introduction to partial differential equations. Definitions &
classifications of first and second order equations. Examples of analytical solutions. Method of
characteristics. 4
7 Numerical Differentiation: Difference operators (forward, backward and central difference).
Stability and accuracy of solutions. Application of finite difference operators to solve initial and
boundary value problems. 4
8 Introduction to the Finite Element Method as a method to solve partial differential equations:
Strong form of the differential equation. Weak form. Galerkin method: the finite element
approximation. Interpolation functions: smoothness, continuity, completeness, Lagrange
polynomials. Numerical quadrature: Trapezoidal rule, simpsons rule,Gauss quadrature.
9 Numerical integration of time dependent partial differential equations: Parabolic equations:
algorithms - stability, consistency and convergence, Lax equivalence theorem. Hyperbolic equations:
algorithms - Newmark's method,stability and accuracy, convergence, multistep methods. 4
10 Numerical solutions of integral equations: Types of integral equations. Fredholm integral
equations of the first and second kind. Fredholm's Alternative theorem. Collocation and Galerkin
methods for solving integral equations.

Ground Improvement Techniques

Dr. G.L. Sivakumar Babu Department of Civil EngineeringIISc Bangalore
https://nptel.ac.in/courses/105/108/105108075/
1 Introduction Need for Ground Improvement, Different types of problematic soils, Emerging trends
in ground Improvement. 3
2. Mechanical stabilization Shallow and deep compaction requirements, Principles and methods of
soil compaction, Shallow compaction and methods. Properties of compacted soil and compaction
control, Deep compaction and Vibratory methods Dynamic compaction.
3 Hydraulic modification Ground Improvement by drainage, Dewatering methods. Design of
dewatering systems, Preloading, Vertical drains, vacuum consolidation, Electro-kinetic dewatering,
design and construction methods. 8
4 Modification by admixtures Cement stabilization and cement columns, Lime stabilization and lime
columns. Stabilization using bitumen and emulsions, Stabilization using industrial wastes
Construction techniques and applications. 8
5 Grouting Permeation grouting, compaction grouting, jet grouting, different varieties of grout
materials, grouting under difficult conditions. 4
6 In situ soil treatment methods Soil nailing, rock anchoring, micro-piles, design methods,
construction techniques. 4
7 Case studies Case studies of ground improvement projects.

Geosynthetics and Reinforced Soil Structures –

Dr. K. Rajagopal Department of Civil EngineeringIIT Madras
https://nptel.ac.in/courses/105/106/105106052/
1 Introduction: Historical background of reinforced soil, Principles of reinforced soil through Mohr
circle analysis. 2
2 Different types of geosynthetics: Types of geosynthetics like geotextiles, geogrids, geonets,
geocells, geo-composites, their manufacturing methods. 4
3 Testing methods for geosynthetics: Techniques for testing of different index properties, strength
properties, Apparent Opening Size, In-plane and cross-plane permeability tests, assessment of
construction induced damage, extrapolation of long term strength properties from short term tests.
4 Reinforced Soil retaining walls: Different types of walls like wrap-around walls, full-height panel
walls, discrete-facing panel walls, modular block walls Design methods as per BS-8006 and FHWA
methods Construction methods for reinforced soil retaining walls. 9
5 Reinforced soil slopes: Basal reinforcement for construction on soft clay soils, construction of steep
slopes with reinforcement layers on comptenet soils, Different slope stability analysis methods like
planar wedge method, bi-linear wedge method, circular slip methods. Erosion control on slopes
using geosynthetics.
6 Applications in foundations: Binquet and Lee's approach for analysis of foundations with
reinforcement layers. 4
7 Drainage and filtration applications of geosynthetics: Different filtration requirements, filtration in
different types of soils and criteria for selection of geotextiles, estimation of flow of water in
retaining walls, pavements, etc. and selection of geosynthetics. 3
8 Pavement application: Geosynthetics for separation and reinforcement in flexible pavements,
design by Giroud-Noiray approach, reflection cracking and control using geosynthetics. Use of
geosynthetics for construction of heavy container yards and raiway lines. 4
9 Construction of landfills using geosynthetics: Different components of modern landfills, collection
techniques for leachate, application of different geosynthetics like geonets, geotextiles for drainage
in landfills, use of geomembranes and Geosynthetic Clay Liner (GCL) as barriers.

Soil Mechanics –
Dr. B.V.S. Viswanadham Department of Civil EngineeringIIT Bombay
https://nptel.ac.in/courses/105/101/105101084/
1 Introduction; Origin of soils; Basic Relationships; Properties of Soil Aggregate, Soil Structure; Soil
Classification. Nine
2 Soil Compaction; Laboratory compaction; Factors affecting soil compaction; Field compaction. Four
3 Soil-water Statics; Concept of Effective Stress Two
4 Flow through soils; Quick Sand condition; Permeability and methods for its determination;
Flownets Ten
5 Stresses in soil from surface loads; Boussinesq theory; Newmark’s chart Five
6 Consolidation of soils; Settlement of compressible soil layers; Sand drains. Eight
7 Shear strength; Mohr circle of stress; MohrCoulomb failure criterion; Estimation of shear strength
parameters; Stress paths. Ten
8 Earth Pressure theories- Retaining walls; Anchored bulkheads Eight
9 Stability of slopes; Infinite/Finite Slope Stability Analysis.

Finite Element Analysis –

Dr. B.N. Rao Department of Civil EngineeringIIT Madras
https://nptel.ac.in/courses/105/106/105106051/
1 Approximate solution of boundary value problems-Methods of weighted residuals,Approximate
solution using variational method, Modified Galerkin method,Boundary conditions and general
comments 04
2 Basic finite element concepts-Basic ideas in a finite element solution, General finite element
solution procedure, Finite element equations using modified Galerkin method,Application:Axial
deformation of bars,Axial spring element 02
3 Analysis of trusses-Two dimensional truss element, Three dimensional space truss
element,Stresses due to lack of fit and temperature changes 02
4 Beam bending-Governing differential equation for beam bending, Two node beam element,Exact
solution for uniform beams subjected to distributed loads using superposition, Calculation of
stresses in beams, Thermal stresses in beams 04
5 Analysis of structural frames-Plane frame element, Thermal stresses in frames, Three dimensional
space frame element 03
6 General one dimensional boundary value problem and its applications-One dimensional heat flow,
Fluid flow between flat plates-Lubrication Problem, Column buckling 02
7 Higher order elements for one dimensional problems-Shape functions for second order problems,
Isoparametric mapping concept, Quadratic isoparametric element for general one dimensional
boundary value problem, One dimensional numerical integration,Application: Heat conduction
through a thin film 03
8 Two dimensional boundary value problems using triangular elements,Equivalent functional for
general 2D BVP,A triangular element for general 2D BVP, Numerical examples 03
9 Isoparametric quadrilateral elements-Shape functions for rectangular elements, Isoparametric
mapping for quadrilateral elements, Numerical integration for quadrilateral elements, Four node
quadrilateral element for 2D BVP,Eight node serendipity element for 2D BVP
10 Isoparametric triangular elements-Natural (or Area) coordinates for triangles,Shape functions for
triangular elements, Natural coordinate mapping for triangles, Numerical integration for triangles,
Six node triangular element for general 2D BVP 02
11 Numerical integration-Newton-Cotes rules, Trapezium rule, Simpson’s rule,Error term, Gauss-
Legendre rules, Changing limits of integration, Gauss-Leguerre rule, Multiple integrals, Numerical
integration for quadrilateral elements, Numerical integration for triangular elements 02
12 Applications based on general two dimensional boundary value problem-Ideal fluid flow around
an irregular object, Two dimensional steady state heat flow, Torsion of prismatic bars 02
13 Two dimensional elasticity-Governing differential equations, Constant strain triangular element,
Four node quadrilateral element, Eight node isoparametric element 03
14 Axisymmetric elasticity problems-Governing equations for axisymmetric elasticity,Axisymmetric
linear triangular element, Axisymmetric four node isoparametric element 02
15 Three dimensional elasticity-Governing differential equations, Four node tetrahedral
element,Eight node hexahedral (brick) element, Twenty node isoparametric solid
element,Prestressing, initial strains and thermal effects

Foundation Engineering
Prof. Mahendra Singh Department of Civil EngineeringIIT Roorkee
Prof. N.K. Samadhiya Department of Civil EngineeringIIT Roorkee
Prof. Priti Maheswari Department of Civil EngineeringIIT Roorkee
https://nptel.ac.in/courses/105/107/105107120/
1. Soil Exploration and Geophysical Investigation (5 lectures) 1.9 Introduction 1.10 Planning for
subsurface exploration 1.11 Methods of exploration 1.12 Geophysical exploration 1.13 Soil
sampling and samplers 1.14 In-situ tests 1.15 Common soil tests 1.16 Soil investigation
report 2. Theory of Lateral Earth Pressure (5 lectures) 2.10 Introduction 2.11 Types of earth
 pressures 2.12 Different theories of earth pressures 2.13 Displacement-related earth
pressure 2.14 Rankine and Coulomb theory 2.15 Friction circle method 2.16 Terzaghi’s
analysis 2.17 Development of bearing capacity theory 2.18 Development of uplift capacity
theory 3. Methods of Analyses (5 lectures) 3.7 Introduction 3.8 Different methods of analysis
3.9 Limit equilibrium 3.10 Limit analysis 3.11 Method of characteristics 3.12 Finite element
method 4. Design of Shallow Foundations (5 lectures) 4.8 Introduction 4.9 Different types of
foundations 4.10 Calculation of bearing capacity 4.11 Stresses in soil 4.12 Concept of contact
pressure 4.13 Calculation of settlements 4.14 Codal provision 5. Design of Deep Foundations
(5 lectures) 5.10 Introduction 5.11 Different types of foundations 5.12 Design methodology
for piles 5.13 Calculation of pile capacity 5.14 Stresses in pile 5.15 Analysis of pile group 5.16
Settlement of pile group 5.17 Concept of negative skin friction 5.18 Piles subjected to lateral
loads 5.19 Pile load test 5.20 Design and construction of well foundation, piers etc. 6. Design
of Retaining Structures (5 lectures) 6.9 Introduction 6.10 Different types of retaining
structures 6.11 Stability analysis of rigid walls 6.12 Design of cantilever sheet piles 6.13
Design of anchored sheet piles 6.14 Bracing system for underground construction 6.15
Failure analysis for bracing system 6.1 6 D e w a te rin g 7 . Fo u n d a t i o n s i n D i ff i c u l t
G r o u n d s ( 5 l e c t u r e s ) 7.6 In t r o d u c tio n 7.7 Te c h niq u e s o f g r o u n d im p r o v
e m e n t 7.8 F o u n d a tio n s in s w ellin g s oil 7.9 Foundations in collapsible s oil 7.10 Use
of soil reinforcement 8. Design of Machine Foundat i o n s ( 5 l e c t u r e s ) 8.7 In t r o d u c
tio n 8.8 F r e e a n d fo r c e d vib r a tio n 8.9 Ly s m e r ’ s m e t h o d 8.1 0 D y n a mic ally lo
a d e d fo u n d a tio n s 8.1 1 D y n a mic s oil p r o p e r tie s 8.1 2 Vib r a tio n is ola tio n 9 . D
e s i g n o f Fo u n d a t i o n s u n d e r E a rt h q u a ke C o n d i t i o n s ( 5 l e c t u r e s ) 9.5 In
t r o d u c tio n 9.6 Diffe r e n t m e t h o d s o f a n aly sis 9.7 P s e u d o - s ta tic m e t h o d o f
d e sig n 9.8 E ffe c t o f e a r t h q u a k e fo r c e s o n v a rio u s fo u n d a tio n s

MECHANICS OF SOLIDS
PROF. PRIYANKA GHOSH ( IIT Kanpur - Civil Engineering )
https://nptel.ac.in/courses/105/106/105106116/
Week 1:Free body diagram with examples on modeling of typical supports and joints, Conditions for
equilibrium in 3D and 2D, Friction: limiting and non-limiting cases Week 2: Force-displacement
relationship and geometric compatibility (for small deformations) with illustrations through simple
problems on axially loaded members and thin walled pressure vessels Week 3: Concept of stress at a
point, Plane stress case: transformations of stresses at a point, Principal stresses and Mohr’s circle
Week 4:Displacement field, Concept of strain at a point, Plane strain case: transformation of strain at
a point, Principal strains and Mohr’s circle, Strain rosette Week 5:Discussion of experimental results
on 1D material behavior, Concepts of elasticity, plasticity, strain hardening, failure
(fracture/yielding), Idealization of 1D stress-strain curve, Generalized Hooke’s law (with and without
thermal strains) for isotropic materials, Complete equations of elasticity Week 6:Force analysis (axial
force, shear force, bending moment and twisting moment diagrams) of slender members Week
7:Torsion of circular shafts and thin-walled tubes (plastic analysis and rectangular shafts not to be
discussed Week 8:Moment curvature relationship for pure bending of beams with symmetric cross-
section, bending stress, shear stress (shear center and plastic analysis not to be discussed) Week
9:Cases of combined stresses, Concept of strain energy, Yield criteria

Pre-stressed Concrete Structures –

Dr. Amlan Kumar Sengupta Department of Civil EngineeringIIT Madras
Prof. Devdas Menon Department of Civil EngineeringIIT Madras
https://nptel.ac.in/courses/105/106/105106118/
Basic Concept Early Attempts of Prestressing Brief History Development of Building Materials 1
Definitions Advantages of Prestressing Limitations of Prestressing Types of Prestressing • Source of
prestressing force • External or internal prestressing • Pre-tensioning or post-tensioning • Linear or
circular prestressing • Full, limited or partial prestressing • Uniaxial, biaxial or multiaxial prestressing
1 Prestressing Systems and Devices Pre-tensioning • Introduction • Stages Advantages
Disadvantages Devices • Jacks • Anchoring devices • Harping devices 1 Post-tensioning •
Introduction • Stages Advantages Disadvantages Devices • Anchoring devices • Sequence of
anchoring • Jacks • Couplers • Grouting 1 Constituents of Concrete • Introduction • Aggregate •
Cement • Water • Admixtures Hardened Concrete • Strength of concrete • Stiffness of concrete •
Durability of concrete • High performance concrete • Allowable stresses in concrete 1 Hardened
Concrete • Stress-strain curves for concrete • Creep of concrete • Shrinkage of concrete Properties
of Grout Codal Provisions Prestressing Steel • Introduction • Forms of prestressing steel • Types of
prestressing steel • Properties of prestressing steel • Stress-strain curves for prestressing steel •
Relaxation of steel • Durability • Fatigue Codal Provisions 1 Module 2: Losses in Prestress (3 Hours)
Topic Hours Notations • Geometric properties • Load variables Losses in Prestress • Elastic
shortening • Pre-tensioned axial members • Pre-tensioned bending members • Post-tensioned axial
members • Post-tensioned bending members 1 Losses in Prestress (Part I) • Friction • Anchorage slip
Force Variation Diagram 1 Losses in Prestress (Part II) • Creep of concrete • Shrinkage of concrete •
Relaxation of steel Total Time-dependent Loss 1
Module 3: Analysis of Members (6 Hours) Topic Hours Analysis of Members Under Axial Load •
Introduction • Analysis at transfer • Analysis at services loads • Analysis of ultimate strength •
Analysis of behavior 1 Analysis of Member Under Flexure (Part I) • Introduction Analysis at Service
Loads • Based on stress concept • Based on force concept • Based on load balancing concept 1
Analysis of Member Under Flexure (Part II) • Cracking moment • Kern point • Pressure line 1
Analysis of Member Under Flexure (Part III) Analysis for Ultimate Strength • Variation of stress in
steel • Condition at ultimate limit state Analysis of Rectangular Sections 1 Analysis of Flanged
Sections 1 Analysis of Partially Prestressed Sections Analysis of Un-bonded Post-tensioned Beams
Analysis of Behaviour 1
Module 4: Design of Members (6 Hours) Topic Hours Design of Members • Calculation of demand
Design of members for Axial Tension • Design of prestressing force • Analysis of ultimate strength
Design of Member for Flexure • Calculation of moment demand. • Preliminary design Design of
Sections for Flexure (Part I) • Final design • Final design for type 1 members • Special case 1 Design
of Sections for Flexure (Part II) • Final design of type 2 members 1 Design of Sections for Flexure
(Part III) • Choice of sections • Determination of limiting zone • Post-tensioning in stages 1 Design of
sections for Flexure (Part IV) • Magnel’s graphical method 1 Detailing Requirements for Flexure
Detailing Requirements for Shear Detailing Requirements for Torsion 1
Module 5: Analysis and Design for Shear and Torsion (6 Hours) Topic Hours Analysis for Shear •
Introduction • Stress in an uncracked beam • Types of cracks • Components of shear resistance •
Modes of failure • Effect of prestressing force 1 Design for Shear (Part I) • Limit state of collapse for
shear • Maximum permissible shear stress • Design of transverse reinforcement • Detailing
requirement for shear 1 Design for Shear (Part II) • General comments • Design steps • Design of
stirrups for flange 1 Analysis for Torsion • Introduction • Stresses in an uncracked beam • Crack
pattern under pure torsion • Components of resistance for pure torsion • Modes of failure • Effect
of prestressing force 1 Design for Torsion (Part I) • Limit state of collapse for torsion • Design of
longitudinal reinforcement • Design of transverse reinforcement 1 Design for Torsion (Part II) •
Detailing requirements • General comments • Design steps 1
Module 6: Calculations of Deflection and Crack Width (1 Hour) Topic Hours Calculation of Deflection
• Deflection due to gravity loads • Deflection due to prestressing force • Total deflection • Limits of
deflection • Determination moment of inertia • Limits of span-to-effective depth ratio Calculation of
Crack Width • Method of calculation • Limits of crack width
Module 7: Transmission of Prestress (2 Hours) Topic Hours Transmission of Prestress (Part I) •
Introduction • Pre-tensioned members Transmission length Development length End zone
reinforcement 1 Transmission of Prestress (Part II) • Post-tensioned members End zone
reinforcement Bearing plate 1
Module 8: Cantilever and Continuous Beams (3 Hours) Topic Hours Cantilever Beams • Introduction
• Analysis • Determination of limiting zone • Cable profile 1 Continuous Beams (Part I) • Introduction
• Analysis • Incorporation of moment due to reactions • Pressure line due to prestressing force 1
Continuous Beams (Part II) • Concordant cable profile • Cable profiles • Partially continuous beams •
Analysis at ultimate limit state • Moment redistribution 1
Module 9: Special Topics (6 Hours) Topic Hours Composite Sections • Introduction • Analysis of
composite sections • Design of composite sections • Analysis for horizontal shear transfer 1 One-
way Slabs • Introduction • Analysis and design 1 Two-way Slabs (Part I) • Introduction • Analysis •
Features in modeling and analysis • Distribution of moments to strips 1 Two-way Slabs (Part II) •
Checking for shear capacity • Spandrel beams • Anchorage devices • Additional aspects 1
Compression Members • Introduction • Analysis • Development of interaction diagram • Effect of
prestressing force 1 Circular Prestressing • Introduction • General analysis and design • Prestressed
concrete pipes • Liquid storage tanks • Ring beams

DESIGN OF REINFORCED CONCRETE STRUCTURES

PROF. NIRJHAR DHANG Department of Civil Engineering IIT Kharagpur
https://nptel.ac.in/courses/105/105/105105105/
 Introduction, Dierent methods of  design of reinforced concrete structures   Working stress method
Limit state of collapse - exure  Design of singly reinforced beam  Design of doubly reinforced beam
Limit state of collapse - shear  Design for shear  Design of slab  Design of compression members
Design of footing  Design of staircase  Limit state of serviceability