←Civil Engineering

3L + 0T + 0P Unit 1.0- Atomic and Molecular Structure 8 hrs Electromagnetic radiations, Dual nature of electron and Heisenberg uncertainty Principle. Photoelectric effect, Planck's theory. Principles for the combination of atomic orbitals to form a molecular diagram of molecular orbitals. Bent's rule, VSEPR theory (typical example) co- ordination numbers and geometries. Isomerism in transition metal compounds. Metal Carbonyls; Synthesis and Structure. Unit 2.0- Spectroscopy 6 hrs Principle of rotational and vibrational spectroscopy, selection rule for application in diatomic molecules, elementary idea of electronic spectroscopy, UV-VIS spectroscopy with related to rules and its applications. Basic Principle of nuclear Magnetic resonance spectroscopy with applications. Unit 3.0 -Electrochemistry and Fuels 6 hrs Nernst equation, EMF and electrochemical cell, the introduction of corrosion, corrosion mechanism, types of corrosion, water line corrosion, stress corrosion, pitting corrosion, Lead acid storage cell, leclanche cell. Calorific value of fuels, proximate and ultimate analysis of coals, fuel cells, Bio fuels. Unit 4.0- Water Chemistry 8 hrs Hardness of water, estimation of water hardness by EDTA and Alkalinity method. Removal of the hardness of water- soda lime process, zeolite process, Ion exchange process, Boiler problem, sludge, and scale formation, priming and foaming, Boiler corrosion, and Caustic embrittlement. Unit 5.0 - Polymer and Plastics 8 hrs Polymerization techniques (free radical, ionic, and co-ordination mechanism)Preparation properties, and technical application of phenol-formaldehyde resins, elastomers, synthetic rubbers (Buna-S, Buna-N, neoprene). Inorganic polymers, Silicones, adhesives, epoxy resins. the structural difference between thermoplastic and thermosetting Plastics, the Importance of commercially important thermoplastics and thermosets; Poly ethylene, Polyvinyl chloride, Polystyrene. Unit 6.0- Organic Reactions and Synthesis of A Drug Molecule 6 hrs Introduction to intermediate and reaction involving Substitution, addition, elimination, oxidation-reduction. Diels Elder cyclization and epoxide ring opening reactions, synthesis of commonly used drug molecules like aspirin.

3L + 1T + 0P Unit- 1.0: Linear Algebra-I 7 hrs Elementary Row operations, Gauss -Jordan Method for finding the inverse of Matrix, Complex Matrix : Hermitian , Skew Hermitian and Unitary Matrix, Vector space, Sub Spaces, Linear dependence and Independences of Vectors, Linear Span, Basis, Dimension, Extension of basis of subspace, The rank of a matrix, Row and column space, Solvability of system of linear equations. Unit- 2.0: Linear Algebra-II 7 hrs Linear Transformations, Kernel and Range of linear transformation, Matrix Representation of a linear transformation, Rank-Nullity Theorem, Eigen Value and Eigen Vectors, Properties of Eigen vectors, Eigen Bases, Orthogonal Transformation, Similarity Transformation, Matrix Diagonalization, Cayley- Hamilton Theorem. Unit- 3.0: Calculus for single variable 7 hrs Inderminate form, L’Hospital Rule, Rolle’s Theorem, Mean Value Theorem, Expansion of function (single variable), Taylor and Maclaurin Series, Riemann Integration, Riemann Sum, Improper Integrals, Beta and Gamma function and their properties. Unit- 4.0 : Multivariable Calculus (Differentiation) 7 hrs Function with two or more variable, Limit, continuity and Partial differentiation, Total Differentiation Taylor’s series and Maclaurin’s series for function with two variable, Jacobian, Maxima and Minima, Method of Lagrange’s multiplier. Unit-5.0: Multivariable Calculus (Integration) 7 hrs Double Integral, change of order of integration, Triple integral, Change of Variable in a Double and Triple Integrals, Change to polar coordinate, Change to cylindrical coordinate, Change to spherical polar coordinate, Application to area and volume using double and triple integral Unit- 6.0: Vector Calculus 7 hrs Scalar and vector fields, Gradient, Directional derivative, Divergence, Curl and their properties, Line integral, Green’s theorem in plane (without proof), Surface integral, Stoke’s theorem (without proof), Volume Integral, Gauss-Divergence’ theorem (without proof).

3L + 0T + 0P Unit-1.0: Vocabulary Building 7 hrs Nature of Word Formation; Root Word and Morpheme; Prefix and Suffix; Foreign Expressions in English; Synonym and Antonym; Homophone and Homograph; Abbreviation and Acronym. Unit-2.0: Basic Writing Skills 7 hrs Parts of Speech: Types of Words; Structures of Sentence; Kind of Sentence; Phrase and Clause; Punctuation Marks; Capitalization; Tenses: Present, Past and Future; Voices: Active and Passive; Formation of Questions using Primary Auxiliaries, Modals and Wh-Words. Unit-3.0: Common Errors in English 7 hrs Articles; Prepositions; Modifiers; Subject-Verb Agreement; Noun-Pronoun agreement; Redundancies; Cliches; Spelling Error. Unit-4.0: Principles of Appropriate Writi 7 hrs Defining: Describing, Classifying and Exemplifying; Introduction, Body, and Conclusion; References, Quotations and Illustrations; Organizing the Paragraphs in a Document; 7Cs of the Professional Writing: Clear, Concise, Concrete, Correct, Coherent, Complete and Courteous. Unit-5.0: Practices of Formal Writing 7 hrs Formal Letter: Cover-Letter and Application; Resume Writing; Report Writing; Minutes of Meeting; Memorandum; Notice; Essay Writing: Personal and Impersonal; Email Writing Etiquettes; Article Writing; Writing for Current Social Media. Unit-6.0: Comprehension of Written English 7 hrs Of Studies (Essay) by Sir Francis Bacon; The Sun Rising (Poem) by John Donne; The Last Leaf (Story) by O Henry; Unseen/Untaught Passage.

1L + 0T + 0P Unit- 1.0: Introduction to Engineering Drawing 7hrs Principles of Engineering Graphics and Their Significance, Usage of Drawing Instruments, Lettering, Conic Sections including the Rectangular Hyperbola (General Method Only); Cycloid, Epicycloid, Hypocycloid and Involute; Scales Plain, Diagonal and Vernier Scales Unit- 2.0 Orthographic Projections 7hrs Principles of Orthographic Projections - Conventions -Projections of Points and Lines Inclined to Both Planes; Projections of Planes Inclined Planes Auxiliary Planes. Unit- 3.0 Projections of Regular Solids 7hrs Types of Solids, Projects of Solids (Prism, pyramids, cone, and cylinder): Inclined to Both the Planes- Auxiliary Views; Draw Simple Annotation, Dimensioning and Scale. Unit- 4.0 Sections and Sectional Views of Right Angular Solids 7hrs Section of Solids (Prism, Cylinder, Pyramid, Cone), Auxiliary Views; Development of Surfaces Of Right Regular Solids- Prism, Pyramid, Cylinder And Cone; Draw The Sectional Orthographic Views of Geometrical Solids, Objects From Industry And Dwellings (Foundation To Slab Only). Unit- 5.0 Isometric Projections 7hrs Isometric Views, Compound Solids; Principles of Isometric Projection Isometric Scale, Conventions; Isometric Views of Lines, Planes, Simple and Conversion of Isometric Views toOrthographic Views And Vice-Versa, Conventions. Unit- 6.0 Overview of Computer Graphics 7hrs Listing the Computer Technologies that Impact on Graphical Communication, Demonstrating Knowledge of the Theory of CAD Software [Such As: The Menu System, Toolbars (Standard, Object Properties, Draw, Modify And Dimension), Drawing Area (Background, Crosshairs, Coordinate System), Dialog Boxes And Windows, Shortcut Menus (Button Bars), The Command Line (Where Applicable), The Status Bar, Different Methods of Zoom as Used in CAD, Select and Erase Objects.; Isometric Views of Lines, Planes, Simple And Compound Solids.

3L + 0T + 0P Unit- 1.0: Fundamentals of Mechanics 7hrs Overview of engineering mechanics. Vector and scalar quantities. Units of physical quantities. Dimensions of physical quantities. Units and Dimensions. Dimensional analysis. Unit- 2.0: Force Systems and Equilibrium 7hrs Force Systems Basic Concepts, Particle Equilibrium in 2-D & 3-D, Rigid Body Equilibrium, System of Forces: oplanar Concurrent Forces, Components in Space, Resultant and Moment of Forces and its Application, Couples and Resultant of Force System, Free Body Diagrams, Equations of Equilibrium of Coplanar Systems and Spatial Systems. Unit- 3.0: Friction and Structural Analysis 7hrs Types of Friction: Limiting, Static, and Dynamic, Laws of Friction, Motion of Bodies and Wedge Friction, Equilibrium in Three Dimensions, Method of Sections and Method of Joints, Tension and Compression in Members, Simple Trusses, Zero Force Members, Beams, Types of Beams, Frames and Machines. Unit- 4.0: Centroid, Centre of Gravity, and Moment of Inertia 7hrs Centroid of Simple Figures from First Principle, Centroid of Composite Sections, Centre of Gravity and Its Implications, Area Moment of Inertia: Definition and Theorems Moment of Inertia of Plane Sections, Standard Sections, and Composite Sections, Mass Moment Inertia of Circular Plate, Cylinder, Cone, Sphere, Hook. Unit- 5.0: Virtual Work, Energy Method, and Particle Dynamics 7hrs Virtual Displacements and Principle of Virtual Work, Degrees of Freedom and Active Force Diagram, Conservative Forces and Potential Energy, Energy Equation for Equilibrium, Applications of Energy Method for Equilibrium, Stability of Equilibrium, Review of Particle Dynamics: Rectilinear and Plane Curvilinear Motion, Relative and Constrained Motion, Newton’s 2nd Law Work-Kinetic Energy, Power, Potential Energy Impulse-Momentum and Impact. Unit- 6.0: Kinetics of Rigid Bodies 7hrs Introduction to Kinetics of Rigid Bodies Basic Terms and General Principles in Dynamics Types of Motion and Instantaneous Centre of Rotation in Plane Motion Simple Problems D’Alembert’s Principle and Its Applications in Plane Motion and Connected Bodies Work- Energy Principle and Its Application in Plane Motion of Connected Bodies Kinetics of Rigid Body Rotation.

0L + 0T + 2P Course Objectives: (a) Encouraging creativity and innovation: The course could aim to foster a culture of creativity and innovation among engineering students. It could provide opportunities for students to generate and develop new ideas, think critically, and come up with innovative solutions to real-worldproblems. This objective could be achieved through brainstorming sessions, design thinking exercises, and hands-on projects. (b) Enhancing problem-solving skills: The course could focus on enhancing the problem- solving skills of engineering students. It could provide training on various problem-solving techniques, such as root cause analysis, critical thinking, and decision-making. Students may learn how to identify and analyse complex problems, develop feasible solutions, and implement them effectively. (c) Developing project management skills: The course could aim to develop project management skills among engineering students. It could cover topics such as project planning, scheduling, budgeting, and risk management. Students may learn how to manage resources, communicate effectively, and work collaboratively in a project-based environment. (d) Promoting interdisciplinary collaboration: The course could encourage interdisciplinary collaboration among engineering students. It could provide opportunities for students from different engineering disciplines to work together on innovative projects. This could foster cross-disciplinary learning, encourage diverse perspectives, and promote teamwork and collaboration skills. (e) Facilitating practical application of engineering concepts: The course could focus on the practical application of engineering concepts and principles. It could provide students with opportunities to apply their theoretical knowledge to real-world projects, prototypes, or simulations. Students may learn how to translate engineering theories into practical solutions and develop hands-on experience in implementing innovative projects. Pre-requisite: Nil Course Outcome: 1. Developed innovative projects: Students may have successfully developed innovative projects that demonstrate their creativity, problem-solving skills, and technical competence. These projects could be prototypes, models, simulations, or practical solutions to real-world problems, showcasing their ability to apply engineering concepts in a creative and innovative manner. 2. Improved critical thinking and problem-solving skills: Students may have honed their critical thinking and problem-solving skills through various course activities, such as brainstorming, design thinking, and project development. They may have learned to analyse complex problems, identify viable solutions, and make informed decisions based on technical, economic, and social considerations. 3. Enhanced project management and teamwork skills: Students may have gained practical experience in managing projects, including planning, scheduling, budgeting, and risk management. They may have learned how to work effectively in a team, collaborate with diverse team members, and communicate project progress and results professionally. 4. Increased interdisciplinary knowledge and collaboration: Students may have gained exposure to interdisciplinary concepts and collaborated with peers from different engineering disciplines. They may have learned to appreciate diverse perspectives, leverage interdisciplinary knowledge, and work collaboratively to develop innovative solutions that integrate multiple domains of engineering. 5. Cultivated a mindset of innovation and entrepreneurship: Students may have developed a mindset of innovation and entrepreneurship, recognizing the importance of creativity, adaptability, and continuous improvement in engineering practice. They may have learned to identify opportunities, think critically, and take risks to develop and implement innovative projects with commercial or societal potential. List of Reports: Any topics related to innovative project.

0L + 0T + 2P Perform any 10 Experiments 1. To estimate hardness of water by alkalinity method 2. To estimate hardness of water by EDTA method 3. To remove hardness of water by ion exchange method 4. Determination of pH of a given acid solution using a standard sodium hydroxide solution 5. Determination of surface tension and viscosity 6. Chemical analysis of salt (Acid radical and basic radical) 7. Adsorption of acetic acid by charcoal 8. Test of adulteration of fat butter, sugar, turmeric powder, chilli powder and pepper 9. Saponification/ acid value of an oil 10. Identification of organic substances and their functional groups 11. Potentiometric determination of redox potentials and emf 12. Synthesis of drug/ polymer like ASPRIN/ Urea- formaldehyde resin 13. Thin layer chromatography 14. Analysis of flue gas by orsat apparatus

0L + 0T + 2P Perform any 10 Experiments Introduction: Language Lab of English includes Listening Comprehension, Reading Comprehension, Speaking Skills: Phonetics, International Phonetic Alphabet Symbols (IPAS), Sounds: Vowels and Consonants, Pronunciation, Intonation, Stress and Rhythm, Just A Minute Technique (JAM), Communication: Verbal and Non-Verbal; Ethical Usage of Artificial Intelligence, Self-Introduction: Social, Academic and Professional; Interview: Brainstorming Vocabulary Activities. 1. Listening Comprehension and Speed (Software) 2. Reading Comprehension and Speed (Software) 3. Pronunciation: Learning and Test (Software) 4. Self-Introduction: Social, Academic and Professional 5. English Typing: Microsoft Word Document (MS Word), and Microsoft Power Point Presentation (PPT) 6. Oral Presentation 7. Interview: Online and Offline 8. Just A Minute Technique (JAM) and Extempore 9. Debate 10. Group Discussion 11. Activities: Role Play, Peer Activities, and Group Activities 12. Anchoring and Addressing: an Assembly, a Meeting, a Seminar, a Party

0L + 0T + 4P Perform any 10 Experiments 1. (Which includes dimensioning methods, different types of line, construction of different polygon, divide the line and angle in parts, use of stencil) 2. Construction of Plane, Diagonal & Vernier Scales. 3. Construction of Ellipses, Parabolas, and Hyperbolas using the general method. 4. Construction of cycloid, epicycloid, hypocycloid, and involute of a circle. 5. Projection of Points and Lines inclined to both planes. 6. Projections of Planes (e.g., rectangular, triangular) in inclined positions. 7. Projection of Solids (prisms,pyramids, cones, and cylinders) 8. Drawing of Sections of Prisms, Cylinders, Pyramids, and Cones. 9. Development of Surfaces for prisms, pyramids, cylinders, and cones. 10. Construction of Isometric views of lines, planes, and simple solids. 11. Introduction to CAD Software. 12. Use of CAD software to draw basic geometric shapes, apply dimensions, and modify objects.

0L + 0T + 2P Perform any 10 Experiments 1. Practical based on mechanical advantage of different machines. 2. Verification of triangle law & parallelogram law of forces. 3. Verification of polygon law of forces. 4. Determination of moment of inertia of a flywheel. 5. Crank Lever apparatus. 6. Verification of support reactions of a simply supported beam. 7. Verification of condition of equilibrium of a system of forces. 8. Verification of axial forces in the members of a truss. 9. Verification of equilibrium of three dimensional forces. 10. Determination of coefficient of friction between two surfaces. 11. Verification of centroid of different laminae. 12. Verification of Newton’s laws of motion.