Civil Engineering SEMESTER 3 PDF

Summary

This document is a syllabus for two courses in civil engineering, namely Mathematics for Electrical Science and Physical Science, and Fluid Mechanics, at the undergraduate level. Each course outlines concepts, modules, contact hours, and assessment methods. Keywords related to the subjects are included in the summary.

Full Transcript

SEMESTER 3
CIVIL ENGINEERING
 SEMESTER S3

MATHEMATICS FOR ELECTRICAL SCIENCE AND PHYSICAL
SCIENCE – 3

(Common to Group B & C)

Course Code GYMAT301 CIE Marks 40

Teaching Hours/Week
3:0:0:0 ESE Marks 60
(L: T:P: R)

Credits 3 Exam Hours 2 Hrs. 30 Min.
Basic knowledge in
Prerequisites (if any) Course Type Theory
complex numbers.

Course Objectives:

1. To introduce the concept and applications of Fourier transforms in various engineering fields.
2. To introduce the basic theory of functions of a complex variable, including residue integration
and conformal transformation, and their applications

SYLLABUS

Module Contact
Syllabus Description
No. Hours
Fourier Integral, From Fourier series to Fourier Integral, Fourier Cosine
and Sine integrals, Fourier Cosine and Sine Transform, Linearity,

1 Transforms of Derivatives, Fourier Transform and its inverse, Linearity, 9
Transforms of Derivative. (Text 1: Relevant topics from sections 11.7,
11.8, 11.9)
Complex Function, Limit, Continuity, Derivative, Analytic functions,
Cauchy-Riemann Equations (without proof), Laplace’s Equations,
Harmonic functions, Finding harmonic conjugate, Conformal mapping,
2 9
Mappings of w= 𝑧 , 𝑤=𝑒 , w= , 𝑤= 𝑠𝑖𝑛𝑧.

(Text 1: Relevant topics from sections 13.3, 13.4, 17.1, 17.2, 17.4)
Complex Integration: Line integrals in the complex plane (Definition &

3 Basic properties), First evaluation method, Second evaluation method, 9
Cauchy’s integral theorem (without proof) on simply connected domain,
 Independence of path, Cauchy integral theorem on multiply connected
domain (without proof), Cauchy Integral formula (without proof).
(Text 1: Relevant topics from sections 14.1, 14.2, 14.3)
Taylor series and Maclaurin series, Laurent series (without proof),
Singularities and Zeros – Isolated Singularity, Poles, Essential
Singularities, Removable singularities, Zeros of Analytic functions – Poles
4 9
and Zeros, Formulas for Residues, Residue theorem (without proof),
Residue Integration- Integral of Rational Functions of cosθ and sinθ.
(Text 1: Relevant topics from sections 15.4, 16.1, 16.2, 16.3, 16.4)

Course Assessment Method
(CIE: 40 marks, ESE: 60 marks)

Continuous Internal Evaluation Marks (CIE):

Internal Internal
Assignment/
Attendance Examination-1 Examination- 2 Total
Micro project
(Written) (Written )

5 15 10 10 40

End Semester Examination Marks (ESE)

In Part A, all questions need to be answered and in Part B, each student can choose any one
full question out of two questions

Part A Part B Total
 2 Questions from each  Each question carries 9 marks.
module.  Two questions will be given from each module,
 Total of 8 Questions, out of which 1 question should be answered.
each carrying 3 marks  Each question can have a maximum of 3 sub 60
divisions.
(8x3 =24marks) (4x9 = 36 marks)
 Course Outcomes (COs)

At the end of the course students should be able to:

Bloom’s
Course Outcome Knowledge
Level (KL)
Determine the Fourier transforms of functions and apply them to solve
CO1 K3
problems arising in engineering.
Understand the analyticity of complex functions and apply it in
CO2 K3
conformal mapping.
Compute complex integrals using Cauchy's integral theorem and
CO3 K3
Cauchy's integral formula.
Understand the series expansion of complex function about a singularity
CO4 K3
and apply residue theorem to compute real integrals.
Note: K1- Remember, K2- Understand, K3- Apply, K4- Analyse, K5- Evaluate, K6- Create

CO-PO Mapping Table:

PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10 PO11 PO12
CO1 3 3 - 2 - - - - - - - 2
CO2 3 3 - 2 - - - - - - - 2
CO3 3 3 - 2 - - - - - - - 2
CO4 3 3 - 2 - - - - - - - 2

Text Books
Name of the Edition and
Sl. No Title of the Book Name of the Author/s
Publisher Year
Advanced Engineering 10th edition,
1 Erwin Kreyszig John Wiley & Sons
Mathematics 2016
 Reference Books
Name of the Edition
Sl. No Title of the Book Name of the Author/s
Publisher and Year
Dennis G. Zill, Patrick D. 3rd edition,
1 Complex Analysis Jones & Bartlett
Shanahan 2015
Higher Engineering McGraw-Hill 39th edition,
2 B. V. Ramana Education 2023
Mathematics
44th
Higher Engineering
3 B.S. Grewal Khanna Publishers edition,
Mathematics
2018
Fast Fourier Transform - K.R. Rao, Do Nyeon 1st edition,
4 Springer
Algorithms and Applications Kim, Jae Jeong Hwang 2011
 SEMESTER S3

FLUID MECHANICS

Course Code PCCET302 CIE Marks 40

Teaching Hours/Week
3-1-0-0 ESE Marks 60
(L: T:P: R)

Credits 4 Exam Hours 2 Hrs. 30 Min.
GCEST103/
Prerequisites (if any) Course Type Theory
Equivalent

Course Objectives:

1. To familiarize the fundamental concepts of fluid mechanics and hydraulics in pipes and open
channels, pressure measurement and flow measurement systems

SYLLABUS

Module Contact
Syllabus Description
No. Hours
Fluid properties, Newton’s law of viscosity, types of fluids (description only)

Fluid Statics: Fluid pressure, Pascal’s Law, Hydrostatic law, Measurement of
fluid pressure using manometers -Simple manometer (Piezo meter and U tube
1 manometers) and Differential manometers (U tube differential manometer and 11
inverted U tube differential manometer) (include numerical problems),
Mechanical gauges (brief description only).

Determination of total pressure and centre of pressure on surfaces (include
numerical problems): Vertical plane surface, Horizontal plane surface, inclined
plane surface, curved surfaces,

2 Buoyancy and Floatation: Basic concepts, centre of buoyancy, meta-centre
and meta-centric height of floating bodies, determination of meta -centric 11
height using analytical and experimental method (include derivation and
numerical problems), conditions for stability of floating and submerged bodies

Fluid Kinematics: Methods of describing fluid motion, Lagrangian and
3 Eulerian methods.
11
 types of fluid flow, continuity equation in one, two and three dimensions
(include derivation and numerical problems)-4
Determination of velocity and acceleration at a point in fluid flow (include
numerical problems), Description of streamline, pathline and streakline,
velocity potential, stream function and flow net
Fluid dynamics: Forces in fluid motion, Derivation of Bernoulli’s equation
from Eulers’s equation of motion with assumptions, Practical Applications of
Bernoulli’s equation- Venturimeter, orifice meter and Pitot tube (include
numerical problems), Momentum equations and forces on Pipe bends
Flow through Orifices: hydraulic coefficients and experimental determination
of hydraulic coefficients
(associated numerical problems) Discharge through large orifices- rectangular
orifice (discharging freely, fully submerged and partially submerged), time of
emptying of a rectangular tank through an orifice at its bottom (include
numerical problems).
Pipe flow- Computation of major losses in pipes (derivation of Darcy
Weisbach equation) - Computation of minor losses in pipes (equations only) ,
4 hydraulic gradient line and total energy line, pipes in series and parallel -
11

equivalent pipes (include numerical problems from all sections)
Flow in Open channel: Comparison between pipe flow and open channel flow,
classification of flow in open channels
Flow through Notches and weirs: classification of notches and weirs,
discharge over a rectangular notch/weir, discharge over a triangular notch/weir,
discharge over a trapezoidal notch/weir, velocity of approach and end
contraction (include numerical problems).

Course Assessment Method
(CIE: 40 marks, ESE: 60 marks)

Continuous Internal Evaluation Marks (CIE):

Internal Internal
Assignment/
Attendance Examination-1 Examination- 2 Total
Micro project
(Written) (Written )

5 15 10 10 40
 End Semester Examination Marks (ESE)

In Part A, all questions need to be answered and in Part B, each student can choose any one
full question out of two questions

Part A Part B Total
 2 Questions from each  Each question carries 9 marks.
module.  Two questions will be given from each module,
 Total of 8 Questions, out of which 1 question should be answered.
each carrying 3 marks  Each question can have a maximum of 3 sub 60
divisions.
(8x3 =24marks) (4x9 = 36 marks)

Course Outcomes (COs)

At the end of the course students should be able to:

Bloom’s
Course Outcome Knowledge
Level (KL)
CO1 To understand the basic properties of fluids K2
To apply the fundamental principles of fluid statics and dynamics in K3
CO2
the solution of practical problems in Hydraulics Engineering

CO3 To evaluate the stability of floating and submerged bodies K3

CO4 To estimate the forces in pipe bends K3

CO5 To explain the fluid flow properties in pipes and open channels K3

Note: K1- Remember, K2- Understand, K3- Apply, K4- Analyse, K5- Evaluate, K6- Create

CO-PO Mapping Table (Mapping of Course Outcomes to Program Outcomes)

PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10 PO11 PO12
CO1 3 3

CO2 3 3

CO3 3 3

CO4 3 3

CO5 3 3
Note: 1: Slight (Low), 2: Moderate (Medium), 3: Substantial (High), -: No Correlation
 Text Books
Name of the Edition
Sl. No Title of the Book Name of the Author/s
Publisher and Year
Hydraulics and Fluid Mechanics Modi P. N. and S. M. S.B.H Publishers, New 22nd
1 edition
including Hydraulic machines, Seth, Delhi, 2019
5th edition
2 Flow in Open channels Subramanya K Tata McGraw-Hill
2019
2nd edition
3 Open - Channel Flow Hanif Chaudhary M Springer
2007
Fluid Mechanics and Hydraulic 10th
4 R K Bansal Laxmi Publications edition
Machines 2020
John F Douglas, Janusz.
6th edition
5 Fluid Mechanics Gasiorek, John A. Pearson Publications
2011
Swaffield, Lynne B. Jack

Reference Books
Name of the Edition
Sl. No Title of the Book Name of the Author/s
Publisher and Year
Victor Streeter , E. 9th
Mc Graw Hill edition
1 Fluid Mechanics Benjamin Wylie , K.W.
Publishers. 2017
Bedford
Munson, Young and Okiishi's Philip M. Gerhart John I.
John Wiley & Sons 9th edition
2 Fundamentals of Fluid Hochstein, Andrew L.
Inc 2020
Mechanics Gerhart
Bruce R. Munson, 5th
Fundamentals Of Fluid John Wiley & Sons edition
3 Donald F. Young,
Mechanics Inc 2005
Theodore H. Okiishi
Cambridge University
4 Introductory Fluid Mechanics Joseph Katz 2015
Press
Fluid Mechanics, Hydraulics
5 Arora.K.R, Standard Publishers 2005
and Hydraulic Machines
A First Course in Fluid University Press
6 Narasimhan S. 2006
Mechanics (India)
Mc Graw Hill 9th edition
7 Fluid Mechanics Frank.M.White
Publishers. 2022
Prentice Hall, New
8 Fluid Mechanics Mohanty.A.K. 2011
Delhi
Principles of Fluid Mechanics
9 Narayana Pillai,N University Press 2011
and Fluid Machines
Fluid Mechanics and Fluid
10 Kumar.D.N. S.K.Kataria & sons 2013
power Engineering
Theory and Applications of
11 Subramanya K Tata McGraw-Hill 1993
Fluid Mechanics
 Video Links (NPTEL, SWAYAM…)

Sl No. Link ID
https://onlinecourses.nptel.ac.in/noc22_me31/preview
1 https://www.youtube.com/playlist?list=PLPALMYFm0ysmjNIuw7eJ2ZGz_XSFkv6CI
https://drive.google.com/drive/folders/1DcQjcxeUCHyOqJh5x4lSjwhUbbQn2UI?usp=sharing
2 https://nptel.ac.in/courses/105103095

3 https://nptel.ac.in/courses/105103095

4 https://nptel.ac.in/courses/105107059
 SEMESTER S3

STRUCTURAL ANALYSIS - I

Course Code PCCET303 CIE Marks 40

Teaching Hours/Week
3:1:0:0 ESE Marks 60
(L: T:P: R)

Credits 4 Exam Hours 2 Hrs. 30 Min.

Prerequisites (if any) PCCEL205/Equivalent Course Type Theory

Course Objectives:

1. To provide students with a thorough understanding of the fundamental theory of structural analysis
2. To develop the student's ability to both model and analyse statically determinate and indeterminate
structures and to provide realistic applications encountered in professional practice
SYLLABUS

Module Contact
Syllabus Description
No. Hours
Statically determinate trusses: Analysis using method of joints and
method of sections.

Cables and Suspension bridges: Forces in loaded (concentrated and
uniformly distributed) cables - length of cables – supports at same and
different levels – maximum tension in the suspension cable and backstays,
pressure on towers.

1 Simple suspension bridges with three hinged stiffening girders - bending
12
moments and shear force diagrams.

Deformation Response of Statically Determinate Beams:

Moment area method–Mohr’s theorems, Applications to determinate
deformations of cantilever and simply supported beams (prismatic and
beams of varying cross section) subjected to concentrated and uniformly
distributed loads.
Deformation Response of Statically Determinate Beams:

2 Conjugate beam method– Real beam and conjugate beam, boundary
11
conditions; Applications to determinate deformations of cantilever and
 simply supported beams (prismatic and beams of varying cross section
subjected to concentrated and uniformly distributed loads.

Energy Principles and Energy Theorems:

Castigliano’s theorem I, Principle of virtual work, Betti’s theorem,
Maxwell’s law of reciprocal deflections.

Unit load method for determination of deflection of statically determinate
beams, frames and trusses.
Indeterminate Structures:

Introduction to force method of analysis. Static indeterminacy

Analysis of statically indeterminate structures

Castigliano’s theorem II, Minimum strain energy method for analysing
statically indeterminate structures (Illustration only)
3 10
Method of consistent deformations: Analysis of beams, frames and
trusses. (simple problems with one redundant, illustration only for two-
redundant problems).

Concepts of effect of pre-strain, lack of fit, temperature changes and
support settlement. (Illustration only).
Three Hinged Arches: Action of an arch - Eddy’s theorem – Three
hinged, parabolic and circular arches (with supports at same level) -
determination of horizontal thrust, bending moment, normal thrust and
radial shear.

Moving Loads and influence lines

4 Introduction to moving loads - concept of influence lines - influence lines 11
for reaction, shear force and bending moment in simply supported beams
and over hanging beams – analysis for different types of moving loads
(single concentrated load - several concentrated loads - uniformly
distributed load shorter and longer than the span) conditions for maximum
bending moment and shear force.
 Course Assessment Method
(CIE: 40 marks, ESE: 60 marks)

Continuous Internal Evaluation Marks (CIE):

Internal Internal
Assignment/
Attendance Examination-1 Examination- 2 Total
Micro project
(Written) (Written )

5 15 10 10 40

End Semester Examination Marks (ESE)

In Part A, all questions need to be answered and in Part B, each student can choose any one
full question out of two questions

Part A Part B Total
 2 Questions from each  Each question carries 9 marks.
module.  Two questions will be given from each module,
 Total of 8 Questions, out of which 1 question should be answered.
each carrying 3 marks  Each question can have a maximum of 3 sub 60
divisions.
(8x3 =24marks) (4x9 = 36 marks)

Course Outcomes (COs)

At the end of the course students should be able to:

Bloom’s
Course Outcome Knowledge
Level (KL)
Apply appropriate structural mechanics principles for estimation of K3
CO1
force and deformation response of structural elements.
Apply energy-based techniques for estimation of deformation response K3
CO2
of structural elements and simple structural systems.
CO3 Analyse statically indeterminate structures using force method. K3

CO4 Analyse the effects of moving loads on structures using influence lines K3

Note: K1- Remember, K2- Understand, K3- Apply, K4- Analyse, K5- Evaluate, K6- Create
 CO-PO Mapping Table (Mapping of Course Outcomes to Program Outcomes)

PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10 PO11 PO12
CO1 3 3 2

CO2 3 3 2

CO3 3 3 2

CO4 3 3 2
Note: 1: Slight (Low), 2: Moderate (Medium), 3: Substantial (High), -: No Correlation

Text Books
Name of the Edition
Sl. No Title of the Book Name of the Author/s
Publisher and Year
Mechanics of Structures Vol I & S.B. Junnarkar & H.J. Charotar Publishing
1 2015
II Shah House,

3rd
Narosa Publishers,
2 Structural Analysis Devdas Menon edition
NewDelhi
2023
10 th edn.
3 Structural Analysis R.C. Hibbler Pearson Education
2022
New Delhi: Tata 3 rd Edn.
4 Basic Structural Analysis, C.S. Reddy McGrawHill,
,2017
NewDelhi

Reference Books
Name of the Edition
Sl. No Title of the Book Name of the Author/s
Publisher and Year
Intermediate Structural Tata McGraw Hill
1 C.K. Wang 2017
Analysis, Publishers
J.B. Wilbur, C.H. McGraw Hill,
2 Elementary Structural Analysis 2006
Norris, and S. Utku NewYork
3 L.S. Negi and R.S. Jangid Structural Analysis Tata McGraw Hill 2006

Video Links (NPTEL, SWAYAM…)

Sl.No. Link ID
1 https://nptel.ac.in/courses/105105166
2 https://nptel.ac.in/courses/105105109
 SEMESTER S3

SURVEYING & GEOMATICS

Course Code PBCET304 CIE Marks 60

Teaching Hours/Week
3:0:0:1 ESE Marks 40
(L: T:P: R)

Credits 4 Exam Hours 2 Hrs. 30 Min.

Prerequisites (if any) Course Type Theory
GCEST104

Course Objectives:

1. To impart awareness on the principles of surveying, various methods, errors associated with
the field observations and advanced surveying techniques.
2. To impart practical knowledge on various surveying methods and enable students to utilize
advanced surveying techniques in field surveying

SYLLABUS

Module Contact
Syllabus Description
No. Hours
Introduction to Surveying : Principles, Linear, angular and graphical
methods, Survey stations, Survey lines- ranging, Bearing of survey lines,
Local attraction, Declination, Methods of orientation (by compass and

1 by back sighting).
9
Levelling : Principles of levelling- Dumpy level, booking and reducing
levels, Methods- simple, differential, reciprocal levelling, profile
levelling and cross sectioning. Digital and Auto Level, Errors in levelling

Contouring : Characteristics, methods, uses.

Areas and Volumes: computation of area by offsets to base line, by
dividing area into number of triangles; volume of level section by

2 prismoidal and trapezoidal formulae.
9
Mass diagram : Construction, Characteristics and uses

Triangulation: Triangulation figures, Triangulation stations, Inter
visibility of stations, Satellite Stations and reduction to centre.
 Theory of Errors : Types, theory of least squares, Weighting of
observations, Most probable value, Computation of indirectly observed
quantities - method of normal equations.

Total Station : Concept of EDM, principles and working, advantages
3 and applications, Global Positioning Systems-Components and 9
principles, satellite ranging-calculating position, signal structure,
application of GPS, GPS Surveying methods-Static, Rapid static,
Kinematic methods – DGPS,

Recent trends in Surveying : GNSS, Smart Station and LIDAR

Remote Sensing : Definition- Electromagnetic spectrum-Energy
interactions with atmosphere and earth surface features-spectral
reflectance of vegetation, soil and water- Classification of sensors-
Active and Passive, Resolution-spatial, spectral radiometric and
Temporal resolution, Multi spectral scanning-Along track and across
4 9
track scanning

Geographical Information System : Components of GIS, GIS
operations, Map projections- methods, Coordinate systems-Geographic
and Projected coordinate systems, Data Types- Spatial and attribute data,
Raster and vector data representation

Suggestion on Project Topics(8 hrs)

 On the first class before starting the first module, direct the students to select a land
region with defined boundary. The faculty in charge should ensure that the selected
region is appropriate for learning the concepts and methods through the project.
 The students should locate the geographic coordinate systems for the selected region
using applications like Bhuvan.
 Conduct the land surveying using linear measurements (tape or distomat).
 Determine the errors in traverse and apply corrections.
 Prepare the survey sketch.
 Determine the reduced levels and prepare the contour maps using conventional (level
or theodolite) methods.
 Conduct the total station survey of the same region and prepare the contour maps.
 Compare the results of the two methods.
  Determine the earthwork quantity – the faculty shall help the students by suggesting
either a region to fill or cut to find the earthwork quantity estimation requirement.
 Application of advanced surveying techniques including LIDAR is advised but not
mandatory.
 Prepare the survey report, print it and submit to the faculty.

Course Assessment Method
(CIE: 60 marks, ESE: 40 marks)

Continuous Internal Evaluation Marks (CIE):

Attendance Project Internal Ex-1 Internal Ex-2 Total

5 30 12.5 12.5 60

End Semester Examination Marks (ESE)

In Part A, all questions need to be answered and in Part B, each student can choose any one
full question out of two questions

Part A Part B Total
 2 Questions from each  2 questions will be given from each module, out
module. of which 1 question should be answered.
 Total of 8 Questions,  Each question can have a maximum of 2 sub
40
each carrying 2 marks divisions.
(8x2 =16 marks)  Each question carries 6 marks.
(4x6 = 24 marks)
 Course Outcomes (COs)

At the end of the course students should be able to:

Bloom’s
Course Outcome Knowledge
Level (KL)
CO1 Understand and apply the principles and techniques of surveying K2, K3
Apply the principles of surveying for triangulation, area and volume K3

CO2 computation, contour maps preparation and in the construction of mass
diagram
Understand the concept of least squares, weight of observations and to K2 k3
CO3
identify the possible errors in the field observations
Understand different surveying techniques using advanced surveying K2
CO4
equipments.

CO5 Prepare a survey report incorporating various concepts of surveying. K6

Note: K1- Remember, K2- Understand, K3- Apply, K4- Analyse, K5- Evaluate, K6- Create

CO-PO Mapping Table:

PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10 PO11 PO12
CO1 3 3 1 1

CO2 3 3 1 1

CO3 3 3 3 3

CO4 3 3 3 3 3

CO5 3 3 3 3 3 3 3 3 3
 Text Books
Sl. Name of the Edition and
Title of the Book Name of the Author/s
No Publisher Year
Dr. B C Punmia,Ashok Seventeenth
Laxmi Publications
1 Surveying Vol 1 Kumar Jain & Arun Edition Jan
(P) Ltd.
Kumar Jain 2016
Dr. B C Punmia,Ashok
Laxmi Publications
2 Surveying Vol II Kumar Jain & Arun July 2018
(P) Ltd.
Kumar Jain
Indian
Introduction to Geographic Mc Graw Hill
3 Kang-Tsung Chang Edition, July
Information Systems Education
2017
4 Fundamentals of Remote Sensing George Joseph Universities Press 2005

Reference Books
Sl. Name of the Edition and
Title of the Book Name of the Author/s
No Publisher Year
1 Textbook of Surveying C Venketaramaiah Universities Press 2011
Fifth
2 Surveying Vol I S K Duggal Mc Graw Hill
Edition,2019
Fifth
3 Surveying Vol II S K Duggal Mc Graw Hill
Edition,2019
A textbook of Surveying and
4 R Agor Khanna Publishers 2005
Levelling
Textbook of Remote Sensing
Fourth
5 And Geographical Ms. Anji Reddy B.S Publications
Edition,2012
Information Systems
Remote Sensing and Image
Thomas M Lillesand, Seventh
6 Interpretation,7 Ed(An Indian Wiley
Ralph W. Kiefer Edition,2000
Adaptation)
Principles of Geographical Oxford University
7 Burrough P 1998
Information Systems Press
 Video Links (NPTEL, SWAYAM…)

Sl. No. Link ID

https://nptel.ac.in/courses/105107122
1
Surveying Nptel IIT Roorkee , J K Ghosh
https://nptel.ac.in/courses/105107122
2
Surveying Nptel IIT Roorkee , J K Ghosh
https://archive.nptel.ac.in/courses/105/104/105104100/
3
Nptel Modern Surveying Techniques,IIT Kanpur
https://onlinecourses.nptel.ac.in/noc22_ce84/preview
4
Nptel Swayam Remote Sensing and GIS , Prof. Rishikesh Bharti ,IIT Guwahati

PBL Course Elements

L: Lecture R: Project (1 Hr.), 2 Faculty Members
(3 Hrs.) Tutorial Practical Presentation
Simulation/
Presentation
Laboratory
Lecture delivery Project identification (Progress and Final
Work/
Presentations)
Workshops
Group
Project Analysis Data Collection Evaluation
discussion
Question Project Milestone Reviews,
answer Analytical thinking
Feedback,
Sessions/ and Testing
Project reformation (If
Brainstorming self-learning
Sessions
required)
Poster Presentation/
Guest Speakers
Case Study/ Field Video Presentation: Students
(Industry Prototyping
Survey Report present their results in a 2 to 5
Experts)
minutes video

Assessment and Evaluation for Project Activity

Sl. No Evaluation for Allotted
Marks
1 Project Planning and Proposal 5
2 Contribution in Progress Presentations and Question Answer 4
Sessions
3 Involvement in the project work and Team Work 3
4 Execution and Implementation 10
5 Final Presentations 5
6 Project Quality, Innovation and Creativity 3
Total 30
1. Project Planning and Proposal (5 Marks)

 Clarity and feasibility of the project plan
 Research and background understanding
 Defined objectives and methodology
2. Contribution in Progress Presentation and Question Answer Sessions (4 Marks)

 Individual contribution to the presentation
 Effectiveness in answering questions and handling feedback
3. Involvement in the Project Work and Team Work (3 Marks)

 Active participation and individual contribution
 Teamwork and collaboration
4. Execution and Implementation (10 Marks)

 Adherence to the project timeline and milestones
 Application of theoretical knowledge and problem-solving
 Final Result
5. Final Presentation (5 Marks)

 Quality and clarity of the overall presentation
 Individual contribution to the presentation
 Effectiveness in answering questions

6. Project Quality, Innovation, and Creativity (3 Marks)

 Overall quality and technical excellence of the project
 Innovation and originality in the project
 Creativity in solutions and approaches
 SEMESTER S3

INTRODUCTION TO ARTIFICIAL INTELLIGENCE AND DATA
SCIENCE

Course Code GNEST305 CIE Marks 40

Teaching Hours/Week
3:1:0:0 ESE Marks 60
(L: T:P: R)

Credits 4 Exam Hours 2 Hrs. 30 Min.

Prerequisites (if any) None Course Type Theory

Course Objectives:

1. Demonstrate a solid understanding of advanced linear algebra concepts, machine learning
algorithms and statistical analysis techniques relevant to engineering applications,
principles and algorithms.
2. Apply theoretical concepts to solve practical engineering problems, analyze data to extract
meaningful insights, and implement appropriate mathematical and computational
techniques for AI and data science applications.

SYLLABUS

Module Contact
Syllabus Description
No. Hours
Introduction to AI and Machine Learning: Basics of Machine Learning
- types of Machine Learning systems-challenges in ML- Supervised
learning model example- regression models- Classification model
example- Logistic regression-unsupervised model example- K-means
1
clustering. Artificial Neural Network- Perceptron- Universal
11
Approximation Theorem (statement only)- Multi-Layer Perceptron- Deep
Neural Network- demonstration of regression and classification problems
using MLP.(Text-2)
Mathematical Foundations of AI and Data science: Role of linear

2 algebra in Data representation and analysis – Matrix decomposition-
Singular Value Decomposition (SVD)- Spectral decomposition- 11
 Dimensionality reduction technique-Principal Component Analysis
(PCA). (Text-1)
Applied Probability and Statistics for AI and Data Science: Basics of
probability-random variables and statistical measures - rules in
probability- Bayes theorem and its applications- statistical estimation-
3 11
Maximum Likelihood Estimator (MLE) - statistical summaries-
Correlation analysis- linear correlation (direct problems only)- regression
analysis- linear regression (using least square method) (Text book 4 )
Basics of Data Science: Benefits of data science-use of statistics and
Machine Learning in Data Science- data science process - applications of
Machine Learning in Data Science- modelling process- demonstration of

4 ML applications in data science- Big Data and Data Science. (For
11
visualization the software tools like Tableau, PowerBI, R or Python can
be used. For Machine Learning implementation, Python, MATLAB or R
can be used.)(Text book-5)

Course Assessment Method
(CIE: 40 marks, ESE: 60 marks)

Continuous Internal Evaluation Marks (CIE):

Internal Internal
Assignment/
Attendance Examination-1 Examination- 2 Total
Micro project
(Written) (Written )

5 15 10 10 40

End Semester Examination Marks (ESE)

In Part A, all questions need to be answered and in Part B, each student can choose any one
full question out of two questions

Part A Part B Total
 2 Questions from each  Each question carries 9 marks.
module.  Two questions will be given from each module,
 Total of 8 Questions, out of which 1 question should be answered.
each carrying 3 marks  Each question can have a maximum of 3 sub 60
divisions.
(8x3 =24marks) (4x9 = 36 marks)
 Course Outcomes (COs)

At the end of the course students should be able to:

Bloom’s
Course Outcome Knowledge
Level (KL)
Apply the concept of machine learning algorithms including neural K3

CO1 networks and supervised/unsupervised learning techniques for
engineering applications.
Apply advanced mathematical concepts such as matrix operations, K3

CO2 singular values, and principal component analysis to analyze and solve
engineering problems.
Analyze and interpret data using statistical methods including K3

CO3 descriptive statistics, correlation, and regression analysis to derive
meaningful insights and make informed decisions.
Integrate statistical approaches and machine learning techniques to K3
CO4
ensure practically feasible solutions in engineering contexts.
Note: K1- Remember, K2- Understand, K3- Apply, K4- Analyse, K5- Evaluate, K6- Create

CO-PO Mapping Table:

PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10 PO11 PO12
CO1 3 3 3 3

CO2 3 3 3 3

CO3 3 3 3 3

CO4 3 3 3 3

CO5 3 3 3 3
 Text Books
Name of the Name of the Edition
Sl. No Title of the Book
Author/s Publisher and Year
Wellesley-Cambridge 6th edition,
1 Introduction to Linear Algebra Gilbert Strang
Press 2023
Hands-on machine learning with 2nd
2 Scikit-Learn, Keras, and Aurélien Géron O'Reilly Media, Inc. edition,202
TensorFlow 2
Deisenroth, Marc
Cambridge University 1st edition.
3 Mathematics for machine learning Peter, A. Aldo Faisal,
Press 2020
and Cheng Soon Ong
Fundamentals of mathematical Gupta, S. C., and V. 9th edition,
4 Sultan Chand & Sons
statistics K. Kapoor 2020
Introducing data science: big data,
Cielen, Davy, and 1st edition,
5 machine learning, and more, using Simon and Schuster
Arno Meysman 2016
Python tools

Reference Books

Kotu,
Data science: concepts and Vijay, and
1 practice
Morgan Kaufmann 2nd edition, 2018
Bala
Deshpande
Carlos
Probability and Statistics for Center for Data
2 Fernandez-
Science in NYU
1st edition, 2017
Data Science Granda
Avrim Blum,
John
Cambridge University
3 Foundations of Data Science Hopcroft,
Press
1st edition, 2020
and Ravi
Kannan
James D.
4 Statistics For Data Science Packt Publishing 1st edition, 2019
Miller
Michael J.
Probability and Statistics - Evans and
5 University of Toronto 1st edition, 2009
The Science of Uncertainty Jeffrey S.
Rosenthal
chrome-
An Introduction to the extension://efaidnbmn
Joseph C. Preliminary
6 Science of Statistics: From nnibpcajpcglclefindm
Edition.
Watkins kaj/https://www.math.
Theory to Implementation
arizo
 Video Links (NPTEL, SWAYAM…)
Module No. Link ID
https://archive.nptel.ac.in/courses/106/106/106106198/
1
https://archive.nptel.ac.in/courses/106/106/106106198/
2 https://ocw.mit.edu/courses/18-06-linear-algebra-spring-2010/resources/lecture-29-singular-
value-decomposition/
https://ocw.mit.edu/courses/18-650-statistics-for-applications-fall-2016/resources/lecture-19-
3
video/
4 https://archive.nptel.ac.in/courses/106/106/106106198/
 SEMESTER S3

ECONOMICS FOR ENGINEERS

(Common to All Branches)

Course Code UCHUT346 CIE Marks 50

Teaching Hours/Week
2:0:0:0 ESE Marks 50
(L: T:P: R)

Credits 2 Exam Hours 2 Hrs. 30 Min.

Prerequisites (if any) None Course Type Theory

Course Objectives:

1. Understanding of finance and costing for engineering operation, budgetary planning and
control
2. Provide fundamental concept of micro and macroeconomics related to engineering industry
3. Deliver the basic concepts of Value Engineering.

SYLLABUS

Module Contact
Syllabus Description
No. Hours
Basic Economics Concepts - Basic economic problems – Production
Possibility Curve – Utility – Law of diminishing marginal utility – Law
of Demand - Law of supply – Elasticity - measurement of elasticity and

1 its applications – Equilibrium- Changes in demand and supply and its 6
effects

Production function - Law of variable proportion – Economies of Scale –
Internal and External Economies – Cobb-Douglas Production Function

Cost concepts – Social cost, private cost – Explicit and implicit cost – Sunk
cost - Opportunity cost - short run cost curves - Revenue concepts

2 Firms and their objectives – Types of firms – Markets - Perfect 6
Competition – Monopoly - Monopolistic Competition - Oligopoly
(features and equilibrium of a firm)
 Monetary System – Money – Functions - Central Banking –Inflation -
Causes and Effects – Measures to Control Inflation - Monetary and Fiscal
policies – Deflation

Taxation – Direct and Indirect taxes (merits and demerits) - GST
3 6
National income – Concepts - Circular Flow – Methods of Estimation and
Difficulties - Stock Market – Functions- Problems faced by the Indian
stock market-Demat Account and Trading Account – Stock market
Indicators- SENSEX and NIFTY
Value Analysis and value Engineering - Cost Value, Exchange Value, Use
Value, Esteem Value - Aims, Advantages and Application areas of Value
4 6
Engineering - Value Engineering Procedure - Break-even Analysis - Cost-
Benefit Analysis - Capital Budgeting - Process planning

Course Assessment Method
(CIE: 40 marks, ESE: 60 marks)

Continuous Internal Evaluation Marks (CIE):

Assignment/ Internal Internal
Attendance Case study/ Examination-1 Examination- 2 Total
Micro project (Written) (Written )

10 15 12.5 12.5 50

End Semester Examination Marks (ESE)

In Part A, all questions need to be answered and in Part B, each student can choose any one
full question out of two questions

Part A Part B Total
 Minimum 1 and  2 questions will be given from each module, out
Maximum 2 Questions of which 1 question should be answered.
from each module.  Each question can have a maximum of 2 sub
 Total of 6 Questions, divisions. 50
each carrying 3 marks  Each question carries 8 marks.
(6x3 =18marks) (4x8 = 32 marks)
 Course Outcomes (COs)

At the end of the course students should be able to:

Bloom’s
Course Outcome Knowledge
Level (KL)
Understand the fundamentals of various economic issues using laws and K2
CO1
learn the concepts of demand, supply, elasticity and production function.
Develop decision making capability by applying concepts relating to K3

CO2 costs and revenue, and acquire knowledge regarding the functioning of
firms in different market situations.
Outline the macroeconomic principles of monetary and fiscal systems, K2
CO3
national income and stock market.
Make use of the possibilities of value analysis and engineering, and K3

CO4 solve simple business problems using break even analysis, cost benefit
analysis and capital budgeting techniques.
Note: K1- Remember, K2- Understand, K3- Apply, K4- Analyse, K5- Evaluate, K6- Create

CO-PO Mapping Table:

PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10 PO11 PO12
CO1 - - - - - 1 - - - - 1 -

CO2 - - - - - 1 1 - - - 1 -

CO3 - - - - 1 - - - - - 2 -

CO4 - - - - 1 1 - - - - 2 -

Text Books

Name of the Edition
Sl. No Title of the Book Name of the Author/s
Publisher and Year
Geetika, Piyali Ghosh and
1 Managerial Economics Tata McGraw Hill, 2015
Chodhury
H. G. Thuesen, W. J.
2 Engineering Economy PHI 1966
Fabrycky
3 Engineering Economics R. Paneerselvam PHI 2012
 Reference Books
Name of the Edition
Sl. No Title of the Book Name of the Author/s
Publisher and Year
Leland Blank P.E,
1 Engineering Economy Mc Graw Hill 7TH Edition
Anthony Tarquin P. E.
2 Indian Financial System Khan M. Y. Tata McGraw Hill 2011
Engineering Economics and Donald G. Newman,
3 Engg. Press, Texas 2002
analysis Jerome P. Lavelle
Contemporary Engineering Prentice Hall of India
4 Chan S. Park 2001
Economics Ltd
 SEMESTER S3/S4

ENGINEERING ETHICS AND SUSTAINABLE DEVELOPMENT
Course Code UCHUT347 CIE Marks 50

Teaching Hours/Week 2:0:0:0
ESE Marks 50
(L: T:P: R)

Credits 2 Exam Hours 2 Hrs. 30 Min.

Prerequisites (if any) None Course Type Theory

Course Objectives:

1. Equip with the knowledge and skills to make ethical decisions and implement gender-
sensitive practices in their professional lives.
2. Develop a holistic and comprehensive interdisciplinary approach to understanding
engineering ethics principles from a perspective of environment protection and sustainable
development.
3. Develop the ability to find strategies for implementing sustainable engineering solutions.
SYLLABUS

Module Contact
Syllabus Description
No. Hours
Fundamentals of ethics - Personal vs. professional ethics, Civic Virtue,
Respect for others, Profession and Professionalism, Ingenuity, diligence
and responsibility, Integrity in design, development, and research domains,
Plagiarism, a balanced outlook on law - challenges - case studies,
Technology and digital revolution-Data, information, and knowledge,
Cybertrust and cybersecurity, Data collection & management, High
1 technologies: connecting people and places-accessibility and social 6
impacts, Managing conflict, Collective bargaining, Confidentiality, Role of
confidentiality in moral integrity, Codes of Ethics.

Basic concepts in Gender Studies - sex, gender, sexuality, gender spectrum:
beyond the binary, gender identity, gender expression, gender stereotypes,
Gender disparity and discrimination in education, employment and
everyday life, History of women in Science & Technology, Gendered
 technologies & innovations, Ethical values and practices in connection with
gender - equity, diversity & gender justice, Gender policy and
women/transgender empowerment initiatives.

Introduction to Environmental Ethics: Definition, importance and
historical development of environmental ethics, key philosophical theories
(anthropocentrism, biocentrism, ecocentrism). Sustainable Engineering
Principles: Definition and scope, triple bottom line (economic, social and
environmental sustainability), life cycle analysis and sustainability metrics.
2 Ecosystems and Biodiversity: Basics of ecosystems and their functions, 6
Importance of biodiversity and its conservation, Human impact on ecosystems
and biodiversity loss, An overview of various ecosystems in Kerala/India, and
its significance. Landscape and Urban Ecology: Principles of landscape
ecology, Urbanization and its environmental impact, Sustainable urban
planning and green infrastructure.

Hydrology and Water Management: Basics of hydrology and water cycle,
Water scarcity and pollution issues, Sustainable water management practices,
Environmental flow, disruptions and disasters. Zero Waste Concepts and
Practices: Definition of zero waste and its principles, Strategies for waste
reduction, reuse, reduce and recycling, Case studies of successful zero waste
initiatives. Circular Economy and Degrowth: Introduction to the circular
3 economy model, Differences between linear and circular economies, degrowth 6
principles, Strategies for implementing circular economy practices and
degrowth principles in engineering. Mobility and Sustainable
Transportation: Impacts of transportation on the environment and climate,
Basic tenets of a Sustainable Transportation design, Sustainable urban
mobility solutions, Integrated mobility systems, E-Mobility, Existing and
upcoming models of sustainable mobility solutions.

Renewable Energy and Sustainable Technologies: Overview of renewable
energy sources (solar, wind, hydro, biomass), Sustainable technologies in
energy production and consumption, Challenges and opportunities in
renewable energy adoption. Climate Change and Engineering Solutions:
4 6
Basics of climate change science, Impact of climate change on natural and
human systems, Kerala/India and the Climate crisis, Engineering solutions to
mitigate, adapt and build resilience to climate change. Environmental
Policies and Regulations: Overview of key environmental policies and
 regulations (national and international), Role of engineers in policy
implementation and compliance, Ethical considerations in environmental
policy-making. Case Studies and Future Directions: Analysis of real-world
case studies, Emerging trends and future directions in environmental ethics
and sustainability, Discussion on the role of engineers in promoting a
sustainable future.

Course Assessment Method
(CIE: 50 marks , ESE: 50)
Continuous Internal Evaluation Marks (CIE):
Continuous internal evaluation will be based on individual and group activities undertaken throughout
the course and the portfolio created documenting their work and learning. The portfolio will include
reflections, project reports, case studies, and all other relevant materials.

The students should be grouped into groups of size 4 to 6 at the beginning of the semester.
These groups can be the same ones they have formed in the previous semester.
Activities are to be distributed between 2 class hours and 3 Self-study hours.
The portfolio and reflective journal should be carried forward and displayed during the 7th
Semester Seminar course as a part of the experience sharing regarding the skills developed
through various courses.

Sl. Item Particulars Group/ Mark
No. Individ s
ual
(G/I)

1 Reflective Weekly entries reflecting on what was learned, personal I 5
Journal insights, and how it can be applied to local contexts.

2 Micro project 1 a) Perform an Engineering Ethics Case Study analysis G 8
and prepare a report

1 b) Conduct a literature survey on ‘Code of Ethics for
(Detailed Engineers’ and prepare a sample code of ethics
documentation
of the project, 2. Listen to a TED talk on a Gender-related topic, do a G 5
including literature survey on that topic and make a report citing
methodologies, the relevant papers with a specific analysis of the
findings, and Kerala context
reflections)
3. Undertake a project study based on the concepts of G 12
sustainable development* - Module II, Module III &
Module IV
 3 Activities 2. One activity* each from Module II, Module III & G 15
Module IV

4 Final A comprehensive presentation summarising the key G 5
Presentation takeaways from the course, personal reflections, and
proposed future actions based on the learnings.

Total Marks 50

*Can be taken from the given sample activities/projects

Evaluation Criteria:
Depth of Analysis: Quality and depth of reflections and analysis in project reports and case
studies.
Application of Concepts: Ability to apply course concepts to real-world problems and
local contexts.
Creativity: Innovative approaches and creative solutions proposed in projects and reflections.
Presentation Skills: Clarity, coherence, and professionalism in the final presentation.
Course Outcomes (COs)

At the end of the course students should be able to:

Bloom’s
Course Outcome Knowledge
Level (KL)

Develop the ability to apply the principles of engineering ethics in their K3
CO1
professional life.

Develop the ability to exercise gender-sensitive practices in their K4
CO2
professional lives

Develop the ability to explore contemporary environmental issues and K5
CO3
sustainable practices.

Develop the ability to analyse the role of engineers in promoting K4
CO4
sustainability and climate resilience.

Develop interest and skills in addressing pertinent environmental and K3
CO5
climate-related challenges through a sustainable engineering approach.

Note: K1- Remember, K2- Understand, K3- Apply, K4- Analyse, K5- Evaluate, K6- Create
 CO-PO Mapping Table:

PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10 PO11 PO12

CO1 3 2 3 3 2 2

CO2 1 3 2 3 3 2 2

CO3 3 3 2 3 2 2

CO4 1 3 3 2 3 2 2

CO5 3 3 2 3 2 2

Reference Books

Name of the Edition
Sl. No Title of the Book Name of the Author/s
Publisher and Year

2nd edition
Ethics in Engineering Practice Cambridge University
1 Caroline Whitbeck & August
and Research Press & Assessment
2011

Cambridge University November
2 Virtue Ethics and Professional Justin Oakley
Roles Press & Assessment 2006

2nd edition
Cambridge University &
3 Bert J. M. de Vries
Sustainability Science Press & Assessment December
2023

Sustainable Engineering Cambridge University
4 Bhavik R. Bakshi, 2019
Press & Assessmen
Principles and Practice
M Govindarajan, S
PHI Learning Private
5 Natarajan and V S 2012
Engineering Ethics Ltd, New Delhi
Senthil Kumar

New age international
6 Professional ethics and human RS Naagarazan 2006.
values (P) limited New Delhi

Tata McGraw Hill
Mike W Martin and 4" edition,
7 Publishing Company
Ethics in Engineering Roland Schinzinger, 2014
Pvt Ltd, New Delhi
 Suggested Activities/Projects:
Module-II
Write a reflection on a local environmental issue (e.g., plastic waste in Kerala backwaters or oceans)
from different ethical perspectives (anthropocentric, biocentric, ecocentric).
Write a life cycle analysis report of a common product used in Kerala (e.g., a coconut, bamboo or
rubber-based product) and present findings on its sustainability.
Create a sustainability report for a local business, assessing its environmental, social, and economic
impacts
Presentation on biodiversity in a nearby area (e.g., a local park, a wetland, mangroves, college campus
etc) and propose conservation strategies to protect it.
Develop a conservation plan for an endangered species found in Kerala.
Analyze the green spaces in a local urban area and propose a plan to enhance urban ecology using native
plants and sustainable design.
Create a model of a sustainable urban landscape for a chosen locality in Kerala.

Module-III
Study a local water body (e.g., a river or lake) for signs of pollution or natural flow disruption and
suggest sustainable management and restoration practices.
Analyse the effectiveness of water management in the college campus and propose improvements -
calculate the water footprint, how to reduce the footprint, how to increase supply through rainwater
harvesting, and how to decrease the supply-demand ratio
Implement a zero waste initiative on the college campus for one week and document the challenges and
outcomes.
Develop a waste audit report for the campus. Suggest a plan for a zero-waste approach.
Create a circular economy model for a common product used in Kerala (e.g., coconut oil, cloth etc).
Design a product or service based on circular economy and degrowth principles and present a business
plan.
Develop a plan to improve pedestrian and cycling infrastructure in a chosen locality in Kerala
Module-IV
Evaluate the potential for installing solar panels on the college campus including cost-benefit analysis
and feasibility study.
Analyse the energy consumption patterns of the college campus and propose sustainable alternatives to
reduce consumption - What gadgets are being used? How can we reduce demand using energy-saving
gadgets?
Analyse a local infrastructure project for its climate resilience and suggest improvements.
Analyse a specific environmental regulation in India (e.g., Coastal Regulation Zone) and its impact on
local communities and ecosystems.
 Research and present a case study of a successful sustainable engineering project in Kerala/India (e.g.,
sustainable building design, water management project, infrastructure project).
Research and present a case study of an unsustainable engineering project in Kerala/India highlighting
design and implementation faults and possible corrections/alternatives (e.g., a housing complex with
water logging, a water management project causing frequent floods, infrastructure project that affects
surrounding landscapes or ecosystems).
 SEMESTER S3

SURVEY LAB

Course Code PCCEL307 CIE Marks 50

Teaching Hours/Week
0:0:3:0 ESE Marks 50
(L: T:P: R)

Credits 2 Exam Hours 2 Hrs. 30 Min.

Prerequisites (if any) GCESL106 /Equivalent Course Type Lab

Course Objectives:

1. Demonstrate proficiency in chain and compass surveying for practical applications.
2. Execute various levelling and theodolite surveying techniques effectively.
3. Utilize advanced surveying equipment such as total stations, levels, and GPS
4. Employ total station for field surveying, perform contouring, and set out curves.
Demonstrate the use of lidar and GNSS surveying

Expt.
Experiments
No.
Conventional surveying

1 a. Chain/ tape surveying
b. Compass surveying
Levelling
2
Differential levelling

3 Fly levelling

4 Profile Levelling and Cross sectioning

5 Distance between inaccessible points (horizontal angle)

6 Level difference between points (vertical angle)

7 Tangential tacheometry (vertical angle)
Traversing - Balancing the traverse using Bowditch’s rule, Transit rule and graphical
8
method
Total station survey
9
Heights and distances
Area computation
10
Contouring
 11 Setting out of curve- simple curve

12 Setting out of curve - Compound curve using angular methods only
Study of instruments
a. Automatic level
13
b. Digital level
c. Handled GPS

14 Lidar Surveying

15 GNSS Surveying

16 Distance between inaccessible points (horizontal angle)

* A minimum of 12 experiments is mandatory

Course Assessment Method
(CIE: 50 marks, ESE: 50 marks)

Continuous Internal Evaluation Marks (CIE):

Preparation/Pre-Lab Work experiments,
Viva and Timely Internal
Attendance Total
completion of Lab Reports / Record Examination
(Continuous Assessment)

5 25 20 50

End Semester Examination Marks (ESE):

Procedure/ Conduct of experiment/ Result with valid
Preparatory Execution of work/ inference/ Viva
Record Total
work/Design/ troubleshooting/ Quality of voce
Algorithm Programming Output
10 15 10 10 5 50

Submission of Record: Students shall be allowed for the end semester examination only upon
submitting the duly certified record.

Endorsement by External Examiner: The external examiner shall endorse the record
 Course Outcomes (COs)
At the end of the course students should be able to:

Bloom’s
Course Outcome Knowledge
Level (KL)
CO1 Demonstrate proficiency in conventional surveying for practical applications. K3

CO2 Execute various levelling and theodolite surveying techniques effectively. K3

CO3 Utilize advanced surveying equipment such as total stations, Lidar, GPS etc. K3
Employ total station for field surveying, perform contouring, and set out K3
CO4
curves.
Note: K1- Remember, K2- Understand, K3- Apply, K4- Analyse, K5- Evaluate, K6- Create

CO- PO Mapping (Mapping of Course Outcomes with Program Outcomes)

PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10 PO11 PO12
CO1 3 2 2

CO2 3 2 2

CO3 3 2 3 2 3

CO4 3 2 3 2 2
1: Slight (Low), 2: Moderate (Medium), 3: Substantial (High), -: No Correlation

Text Books
Name of the Edition
Sl. No Title of the Book Name of the Author/s
Publisher and Year
B.C. Punmia, Ashok
1 Seventh,
Surveying-Vol 1 Kumar Jain & Arun Laxmi Publications
2016
Kumar Jain
2 Second,
Textbook of surveying Venkataramaiah C. University Press
2011
3 T.P.Kenetkar & Pune Vidyarthi Griha Second,
Surveying and Levelling
S.V.Kulkarni Prakashan 2004
4 Satheesh Gopi, R Second,
Advanced Surveying Pearson Education
Santhikumar, N Madhu 2008
 Reference Books
Name of the Edition
Sl. No Title of the Book Name of the Author/s
Publisher and Year
1 Reprint
Surveying Vol. I S. K. Duggal Tata McGraw Hill Ltd
2015
2 A Text book of Surveying and
R. Agor Khanna Publishers 2005
Levelling
3 GPS and GNSS for Land
Jan Van Sickle CRC Press First, 2023
Surveyors
Topographic Laser Ranging
4 and Scanning Charles K. Toth, Jie Shan CRC Press 2009
Principles and Processing

Video Links (NPTEL, SWAYAM…)

Sl. No. Link ID

1 https://sl-iitr.vlabs.ac.in/

Continuous Assessment (25 Marks)

1. Preparation and Pre-Lab Work (7 Marks)
 Pre-Lab Assignments: Assessment of pre-lab assignments or quizzes that test
understanding of the upcoming experiment.
 Understanding of Theory: Evaluation based on students’ preparation and understanding
of the theoretical background related to the experiments.
2. Conduct of Experiments (7 Marks)
 Procedure and Execution: Adherence to correct procedures, accurate execution of
experiments, and following safety protocols.
 Skill Proficiency: Proficiency in handling equipment, accuracy in observations, and
troubleshooting skills during the experiments.
 Teamwork: Collaboration and participation in group experiments.
3. Lab Reports and Record Keeping (6 Marks)
 Quality of Reports: Clarity, completeness and accuracy of lab reports. Proper
documentation of experiments, data analysis and conclusions.
 Timely Submission: Adhering to deadlines for submitting lab reports/rough record and
maintaining a well-organized fair record.
 4. Viva Voce (5 Marks)
 Oral Examination: Ability to explain the experiment, results and underlying
principles during a viva voce session.

Final Marks Averaging: The final marks for preparation, conduct of experiments, viva, and
record are the average of all the specified experiments in the syllabus.

Evaluation Pattern for End Semester Examination (50 Marks)

1. Procedure/Preliminary Work/Design/Algorithm (10 Marks)
 Procedure Understanding and Description: Clarity in explaining the procedure and
understanding each step involved.
 Preliminary Work and Planning: Thoroughness in planning and organizing
materials/equipment.
 Algorithm Development: Correctness and efficiency of the algorithm related to the
experiment.
 Creativity and logic in algorithm or experimental design.

2. Conduct of Experiment/Execution of Work/Programming (15 Marks)
 Setup and Execution: Proper setup and accurate execution of the experiment or
programming task.
3. Result with Valid Inference/Quality of Output (10 Marks)
 Accuracy of Results: Precision and correctness of the obtained results.
 Analysis and Interpretation: Validity of inferences drawn from the experiment or
quality of program output.

4. Viva Voce (10 Marks)
 Ability to explain the experiment, procedure results and answer related questions
 Proficiency in answering questions related to theoretical and practical aspects of the
subject.

5. Record (5 Marks)
 Completeness, clarity, and accuracy of the lab record submitted
 SEMESTER S3

FLUID MECHANICS LAB

Course Code PCCEL308 CIE Marks 50

Teaching Hours/Week
0-0-3-0 ESE Marks 50
(L: T:P: R)

Credits 2 Exam Hours 2 Hrs. 30 Min.

Prerequisites (if any) None Course Type Lab

Course Objectives:

1. To familiarize and understand the different flow measurement equipments, pumps and turbines
and the laboratory procedures of experimentation with them.
2. To develop the necessary skills of experimentation techniques for the study of flow phenomena
in channels/pipes

Expt.
Experiments
No.
1 Study of taps, valves, pipe fittings, gauges, Pitot tubes, water meters and current meters
2 Calibration of Pressure gauges
3 Determination of metacentric height and radius of gyration of floating bodies.
4 Verification of Bernoulli’s theorem
Hydraulic coefficients of orifices and mouth pieces under constant head method and time
5
of emptying method.
6 Calibration of Venturi meter
7 Calibration of Orifice meter
8 Calibration of water meter..