Download lesson plan engineering physics theory

FT/GN/68/00/21.04.15
SRI VENKATESWARA COLLEGE OF ENGINEERING
COURSE DELIVERY PLAN - THEORY
Page 1 of 15
LP: PH6151
Department of APPLIED PHYSICS
B.E/B.Tech/M.E/M.Tech : Common to All Branches
PG Specialisation
Rev. No: 00
Regulation:2013
Date:
: _________________________
Sub. Code / Sub. Name : PH6151 / ENGINEERING PHYSICS-I
Unit
: I-CRYSTAL PHYSICS
CRYSTAL PHYSICS
(9)
Lattice – Unit cell – Bravais lattice – Lattice planes – Miller indices – d spacing in cubic lattice – Calculation of number
of atoms per unit cell – Atomic radius – Coordination number – Packing factor for SC, BCC, FCC and HCP structures –
Diamond and graphite structures (qualitative treatment)- Crystal growth techniques –solution, melt (Bridgman and
Czochralski) and vapour growth techniques (qualitative)
Objective: At the end of this unit, the students understand about the structure identification of engineering materials.
Session
Topics to be covered
Ref
Teaching
No *
Aids
1
8-ch. 1; Pg.1.1- PPT
Introduction
Classification of solids- crystalline solids (or) Amorphous solids, Differences
1.7
between crystalline and amorphous materials….
Concepts of Elementary Crystallography
Unit Cell- Space Lattice-How is a crystal formed?
2
8-ch. 1; Pg.1.8- PPT
Crystallography
Lattice parameters-Bravais lattices
1.14,1.39-1.46
Lattice Planes-Miller Indices
Procedure for finding Miller Indices-Important features of Miller Indicesprocedure for drawing the plane for given Miller Indices (hkl)
3
8-ch. 1;
PPT
Inter planar d spacing in a Cubic Lattice -Problems
Pg.1.47-1.51
4
Simple Crystal Structures
Simple cubic structure (SC)- Body centred Cubic structure (BCC)-Face
Centred Cubic Structure (FCC)- (HCP)
HCP- axial ratio (c/a ratio)-Packing Density
8-ch. 1;
Pg.1.17-1.28
PPT
8-ch. 1;
Pg.1.29-1.33
PPT
6
Diamond and Graphite Structures
Diamond-Graphite
8-ch. 1;
Pg.1.33-1.37
PPT
7
Introduction to Crystal Growth
Solution Growth –Low temperature solution growth
Crystal Growth from Melt (High Temperature Solution Growth)
Bridgman techniques-Czochralski method
8-ch. 1;
Pg.1.52-1.57
PPT
8
Vapour Growth techniques
Physical Vapour Deposition (PVD)-Chemical Vapour Deposition (CVD)
6-ch. 1;
Pg.1.47-1.50
PPT
5
Content beyond syllabus covered (if any):
Characteristics of NaCl Unit Cell.
Manufacturing of Microchip.
Working knowledge of fundamental physics and basic engineering
principles to include advanced knowledge in one or more engineering disciplines
Course Outcome 1:
* Session duration: 50 minutes
FT/GN/68/00/21.04.15
SRI VENKATESWARA COLLEGE OF ENGINEERING
COURSE DELIVERY PLAN - THEORY
Page 2 of 15
Sub. Code / Sub. Name: PH6151 / ENGINEERING PHYSICS-I
Unit : II - PROPERTIES
OF MATTER AND THERMAL PHYSICS
PROPERTIES OF MATTER AND THERMAL PHYSICS
(9)
Elasticity- Hooke’s law - Relationship between three moduli of elasticity (qualitative) – stress -strain diagram –
Poisson’s ratio –Factors affecting elasticity –Bending moment – Depression of a cantilever –Young’s modulus
by uniform bending- I-shaped girders
Modes of heat transfer- thermal conductivity- Newton’s law of cooling - Linear heat flow – Lee’s disc method
– Radial heat flow – Rubber tube method – conduction through compound media (series and parallel)
Objective: At the end of this unit, the students understand about the Physical and thermal properties of the
materials.
Session
No *
Topics to be covered
PROPERTIES OF MATTER
1
2
3
4
5
6
7
8
9
Introduction Elasticity-stress and strain-Elastic moduli-The Young’s modulus (E)-The
Bulk Modulus(K)-The rigidity modulus or shear modulus(G)- relation
between the three moduli of elasticity E, K, and G
The variation of Stress and Strain (stress -strain diagram)
Poisson’s ratio –Factors affecting elasticity
Bending Moment-Free end of a Cantilever -Theory
Expression for bending moment-Bending of a Cantilever -experiment
Uniform Bending-Theory- Girders
Uniform bending-Experiment-I-Shaped Girders
THERMAL PHYSICS
Introduction –Modes of Transfer-Conduction-convection-radiation
Newton’s law of cooling-Derivation of Newton’s law of coolingExperimental verification of Newton’s law of cooling
The Mechanism of Conduction in solids
Thermal conductivity-Theory of Linear Heat Flow through a Rod
Determination of Thermal Conductivity
Theory of thermal conductivity of poor conductors- Lee’s Disc method
Radiation Flow of Heat
Radial flow of Heat through the sides of a tube-Thermal conductivity of
rubber
Thermal Conduction through Compound Media
Bodies in series-Bodies in parallel
Ref
4-Ch.2 ; Pg.2.12.4,2.7-2.12
PPT
4-Ch.2 ; Pg.2.42.6
4-Ch.2 ;
Pg.2.25-2.34
4-Ch.2 ;
Pg.2.35-2.43
4-Ch.3 ; Pg.3.13.10
PPT
4-Ch.3;Pg.3.113.16
4-Ch.3 ;
Pg.3.21-3.25
4-Ch.3 ;
Pg.3.25-3.30
PPT
4-Ch.3 ;
Pg.3.17-3.21
PPT
Content beyond syllabus covered (if any):
Practical Applications of conduction of heat-Davy’s Safety lamp
Course Outcome 2: The ability to formulate, conduct, analyzes, and interprets experiments in
engineering physics.
* Session duration: 50 mins
Teaching
Aids
PPT
PPT
PPT
PPT
PPT
FT/GN/68/00/21.04.15
SRI VENKATESWARA COLLEGE OF ENGINEERING
COURSE DELIVERY PLAN - THEORY
Page 3 of 15
Sub. Code / Sub. Name: PH6151 / ENGINEERING PHYSICS-I
Unit : III- QUANTUM PHYSICS
QUANTUM PHYSICS
(9)
Black body radiation – Planck’s theory (derivation) – Deduction of Wien’s displacement law and Rayleigh – Jeans’ Law
from Planck’s theory – Compton Effect-Theory and experimental verification – Properties of Matter waves – G.P
Thomson experiment -Schrödinger’s wave equation – Time independent and time dependent equations – Physical
significance of wave function – Particle in a one dimensional box - Electron microscope - Scanning electron microscope Transmission electron microscope.
Objective: The students understand about the physical significance of wave function and various types of microscope and
its applications.
Session
No *
1
2
3
4
5
6
7
8
Topics to be covered
Introduction
What is meant by quantum physics?
Concept of a Black Body
What is a perfect black body?- construction of a black body
Ref
6-Ch.4 ;
Pg.4.1-4.3
PPT
6-Ch.4 ;
Theory of Black Body Radiation
Stefan’s –Boltzmann’s law-Wien’s displacement law-Rayleigh-Jean’s law- Pg.4.4-4.9
Planck’s quantum theory-deduction of weins’s displacement lawDeduction of Rayleigh – Jean’s law
6-Ch.4 ;
The Compton Effect-Theory
Pg.4.9Experimental verification of Compton’s theory
4.15
Matter waves-De Broglie wavelength
De Broglie wavelength associated with electrons-characteristics of matter
waves
Experimental Study of Matter Wave
G.P.Thomson Experiment
Schröedinger wave equation
Schrödinger’s wave equation – Time independent and time dependent
equations- physical significance of wave function- Particle in a one
dimensional box
Electron Microscope
Principle-Construction and working-uses-limitations
Scanning Electron Microscope (SEM)
Construction and working of a typical SEM
Specimen interaction-Applications
Transmission Electron Microscopy (TEM)
Constructing and working of a typical TEM-Thin specimen
interactions used in TEM-Applications-Limitations of Transmission
electron microscope
PROBLEMS
Content beyond syllabus covered (if any):STEM
Course Outcome 3: To understand and to compute problems in Quantum Physics
* Session duration: 50 mins
Teaching
Aids
6-Ch.4 ;
Pg.4.184.23
6-Ch.4 ;
Pg.4.284.36
6-Ch.4 ;
Pg.4.394.41
PPT
PPT
PPT
PPT
PPT
8-Ch.4 ;
Pg.4.414.49
PPT
8-Ch.4
FT/GN/68/00/21.04.15
SRI VENKATESWARA COLLEGE OF ENGINEERING
COURSE DELIVERY PLAN - THEORY
Page 4 of 15
Sub. Code / Sub. Name: PH6151 / ENGINEERING PHYSICS-I
Unit : IV-
ACOUSTICS AND ULTRASONICS
ACOUSTICS AND ULTRASONICS
(9)
Classification of Sound- decibel- Weber–Fechner law – Sabine’s formula- derivation using growth and decay
method – Absorption Coefficient and its determination –factors affecting acoustics of buildings and their
remedies.
Production of ultrasonics by magnetostriction and piezoelectric methods - acoustic grating –Non Destructive
Testing – pulse echo system through transmission and reflection modes - A,B and C –scan displays, Medical
applications - Sonogram
Objective: At the end of this unit, the students will understand about the production and detection of ultrasonic
waves and its application in various fields.
Session
No *
Topics to be covered
ACOUSTICS
1
2
3
4
5
6
Introduction
Classification of sound-Musical sound-Noise
Characteristics of Musical Sounds
Pitch or frequency-Loudness or Intensity-Measurement of Intensity leveldecibel-Physical significance of 1 decibel change-Weber-Fechner lawQuality or timbre
Sound intensity in a room
Reverberation-Reverberation time-Absorption coefficient
Sabines’s Formula (Growth and Decay Method) -Measurement of Sound
Absorption CoefficientFactors affecting the Architectural Acoustics and their RemediesApplications of Acoustics
ULTRASONICS
Introduction-Ultrasonic Production-Magnetostriction Method
Piezoelectric method
Piezo electric effect-Inverse Piezo electric effect-Piezoelectric materialspiezoelectric oscillator -Properties of Ultrasonic waves-Acoustic Grating
Formation
Applications of Ultrasonic waves
Non Destructive Testing –ultrasonic inspection-Ultrasonic flaw
detector –pulse echo system
Ref
Teaching
Aids
6-Ch.5 ;
Pg.5.1-5.8
PPT
5-Ch.1 ;
Pg.1.14-1.20
PPT
5-Ch.1 ;
Pg.1.22-1.26
6-Ch.6 ;
Pg.6.1-6.6
PPT
6-Ch.6 ;
Pg.6.6-6.14
PPT
6-Ch.6 ;
Pg.6.14-6.19
PPT
PPT
Scan Displays
A-Scan Display-B-Scan Display-C-Scan Display-Comparison
8-Ch.6 ;
Pg.6.16-6.18
PPT
7
Applications of Ultrasaonic NDT
Advantages of Ultrasonics, NDT, Limitations of ultrasonic NDT
6-Ch.6 ;
Pg.6.23-6.25
PPT
8
Medical Applications of Ultrasonic waves
Sonogram
8-Ch.6 ;
Pg.6.19-6.21
PPT
9
Content beyond syllabus covered (if any): Underwater Acoustics-Ultrasonics-Applications –SONAR-Material
Processing
Course Outcome 4: Use modern engineering physics techniques and tools.
* Session duration: 50 mins
FT/GN/68/00/21.04.15
SRI VENKATESWARA COLLEGE OF ENGINEERING
COURSE DELIVERY PLAN - THEORY
Page 5 of 15
Sub. Code / Sub. Name: PH6151 / ENGINEERING PHYSICS-I
PHOTONICS AND FIBRE OPTICS
PHOTONICS AND FIBRE OPTICS
(9)
Spontaneous and stimulated emission- Population inversion -Einstein’s A and B coefficients - derivation. Types
of lasers – Nd: YAG, CO2 , Semiconductor lasers (homojunction & heterojunction)- Industrial and Medical
Applications.
Principle and propagation of light in optical fibres – Numerical aperture and Acceptance angle - Types of
optical fibres (material, refractive index, mode) – attenuation, dispersion, bending – Fibre Optical
Communication system (Block diagram) - Active and passive fibre sensors- Endoscope.
Objective: This unit enhances the knowledge of students in knowing more about the types of laser and its
applications and gains the basic knowledge in optical fibers.
Unit : V-
Session
No *
Topics to be covered
PHOTONICS
Introduction
1
2
Optical Resonator- Characteristics of Laser –Laser systems (Types of
Lasers)- Nd-YAG Laser
CO2 , Semiconductor lasers (homojunction & heterojunction)
5
6
PPT
1-Ch.7 ;
Pg.7.5,7.9-7.11
2,6-Ch.31,7 ;
Pg.31.731.8,7.26-7.31
Industrial applications of LASERS
Lasers in metrology-Lasers in material processing (Manufacturing
industry)- Medical Applications of Lasers
6-Ch.7 ;
Pg.7.32-7.38
FIBRE OPTICS
1-Ch.8 ; Pg.8.28.6
Introduction
Structure of optical Fibre-Concept of Total Internal ReflectionAcceptance Angle - Numerical Aperture –NA in terms of Δ
Types of optical Fibers
Based on material-modes-Single and Multimode fibers-refractive indexStep index fiber-Propagation of light in step index fiber-Graded index
fiber-Propagation of light in graded index fiber-Formation of modes in
optical fibers
Teaching
Aids
2-Ch.31 ;
Pg.31.1-31.4
Spontaneous and stimulated emission of Radiation- Einstein’s A
and B coefficients- Population inversion-creation of Population
inversion –Pumping Mechanisms
3
4
Ref
PPT
PPT
PPT
PPT
8-Ch.8; Pg.8.88.15
PPT
7
Fibre Optic Communication System(Block Diagram)-SensorsDisplacement & Temperature Sensor
8-Ch.8; Pg.8.198.23
PPT
8
Dispersion
Attenuation (Losses in Fibers)-Fiber optic Medical Endoscopy-Some
applications of fiber-Optic endoscopy.
8-Ch.8 ;
Pg.8.158.18,8.23-8.25
PPT
Problems
8-Ch.8
9
Content beyond syllabus covered (if any): Application of Laser-Holography
Course Outcome 5: To enhance knowledge about photonics and optical fiber communication system.
FT/GN/68/00/21.04.15
SRI VENKATESWARA COLLEGE OF ENGINEERING
COURSE DELIVERY PLAN - THEORY
Page 6 of 15
* Session duration: 50 mins
Sub. Code / Sub. Name: PH6151/Engineering Physics-I
Course Outcomes:
Course Outcome 1: Working knowledge of fundamental physics and basic engineering principles to include
advanced knowledge in one or more engineering disciplines
Course Outcome 2: The ability to formulate, conduct, analyzes, and interprets experiments in engineering
physics.
Course Outcome 3: To understand and to compute problems in Quantum Physics
Course Outcome 4: Use modern engineering physics techniques and tools.
Course Outcome 5: To enhance knowledge about photonics and optical fiber communication system.
Programme Outcomes: [CH]
Programme Outcome 1: To apply the knowledge of mathematics, science and engineering fundamentals
Programme Outcome 2: To design and conduct experiments and interpret the experimental results.
Programme Outcome 3: To identify, formulate and solve chemical engineering problems.
Programme Outcome 4: To design the system component and the process conforming to safety, economical,
energy efficient and environmental norms.
Programme Outcome 5: To have an understanding of the professional responsibilities and ethical values.
Programme Outcome 6: To apply engineering solutions in global, economic and societal context.
Programme Outcome 7: To recognize the need for and have the ability to engage in lifelong learning.
Programme Outcome 8: To communicate effectively.
Programme Outcome 9: To apply technical knowledge on contemporary issues.
Programme Outcome 10: To use techniques, skills and modern engineering tools necessary for engineering
practices.
Mapping – CO – PO :
PO1
PO2
PO3
PO4
PO5
PO6
PO7
PO8
PO9
PO10
CO1
A
A
C
B
B
B
B
B
B
B
CO2
A
A
B
B
B
B
B
C
B
B
CO3
A
B
C
B
B
B
C
A
C
C
CO4
A
B
B
B
B
B
B
B
C
B
CO5
A
B
B
C
B
C
B
B
A
B
A – Excellent; B – Good; C – Average
FT/GN/68/00/21.04.15
SRI VENKATESWARA COLLEGE OF ENGINEERING
COURSE DELIVERY PLAN - THEORY
Page 7 of 15
Sub. Code / Sub. Name: PH6151/Engineering Physics-I
Course Outcomes:
Course Outcome 1: Working knowledge of fundamental physics and basic engineering principles to
include advanced knowledge in one or more engineering disciplines
Course Outcome 2: The ability to formulate, conduct, analyzes, and interprets experiments in
engineering physics.
Course Outcome 3: To understand and to compute problems in Quantum Physics
Course Outcome 4: Use modern engineering physics techniques and tools.
Course Outcome 5: To enhance knowledge about photonics and optical fiber communication system.
Programme Outcomes: [CE]
Programme Outcome 1: Knowledge in mathematics, science and engineering.
Programme Outcome 2: Graduates will demonstrate the ability to design and conduct experiments, interpret and
analyze data, and report results.
Programme Outcome 3: Graduates will demonstrate the ability to design of Civil Engineering systems or a process
that meets desired specifications and requirements related to all fields of Civil Engineering
Programme Outcome 4: Graduates will demonstrate the ability to function on engineering and science laboratory
teams, as well as on multidisciplinary design teams.
Programme Outcome 5: Graduates will demonstrate the ability to identify, formulate and solve Civil engineering
problems.
Programme Outcome 6: Graduates will demonstrate an understanding of their professional and ethical
Responsibilities.
Programme Outcome 7: Graduates will be able to communicate effectively in both verbal and written forms.
Programme Outcome 8: Graduates will have the confidence to apply engineering solutions in global and societal
contexts.
Programme Outcome 9: Graduates should be capable of self-education and clearly understand the value of lifelong
learning.
Programme Outcome 10: Graduates will be broadly educated and will have an understanding of the impact of
engineering on society and demonstrate awareness of contemporary issues.
Programme Outcome 11: Graduates will be familiar with modern engineering software tools and equipment to
Analyze Civil engineering problems.
Mapping – CO – PO :
PO1
PO2
PO3
PO4
PO5
PO6
PO7
PO8
PO9
PO10
PO11
CO1
A
A
B
B
A
B
B
B
C
B
B
CO2
A
A
B
B
B
B
C
B
B
C
B
CO3
A
B
B
B
B
B
A
C
B
B
B
CO4
A
B
B
B
B
B
B
B
B
B
B
CO5
A
B
B
B
B
B
B
B
B
A
B
A – Excellent; B – Good; C – Average
FT/GN/68/00/21.04.15
SRI VENKATESWARA COLLEGE OF ENGINEERING
COURSE DELIVERY PLAN - THEORY
Page 8 of 15
Sub. Code / Sub. Name: PH6151/Engineering Physics-I
Course Outcomes:
Course Outcome 1: Working knowledge of fundamental physics and basic engineering principles to
include advanced knowledge in one or more engineering disciplines
Course Outcome 2: The ability to formulate, conduct, analyzes, and interprets experiments in
engineering physics.
Course Outcome 3: To understand and to compute problems in Quantum Physics
Course Outcome 4: Use modern engineering physics techniques and tools, including software and
laboratory instrumentation.
Course Outcome 5: To enhance knowledge about photonics and optical fiber communication system.
Programme Outcomes: [CS]
Programme Outcome 1:An ability to apply knowledge of mathematics, science, and engineering
Programme Outcome 2: An ability to design and conduct experiments, as well as to analyze and interpret
data
Programme Outcome 3: An ability to design a system, component, or process to meet desired needs within
realistic constraints such as economic, environmental, social, political, ethical, health and safety,
manufacturability, and sustainability.
Programme Outcome 4: An ability to function on multidisciplinary teams
Programme Outcome 5: An ability to identify, formulate, and solve engineering problems
Programme Outcome 6: An understanding of professional and ethical responsibility
Programme Outcome 7: An ability to communicate effectively
Programme Outcome 8: The broad education necessary to understand the impact of engineering solutions
in a global, economic, environmental, and societal context
Programme Outcome 9: A recognition of the need for, and an ability to engage in life-long learning
Programme Outcome 10: A knowledge of contemporary issues
Programme Outcome 11: An ability to use the techniques, skills, and modern engineering tools necessary
for engineering practice.
Mapping – CO – PO :
PO1
PO2
PO3
PO4
PO5
PO6
PO7
PO8
PO9
PO10
PO11
CO1
A
A
B
B
A
B
B
B
C
B
B
CO2
A
A
B
B
B
B
C
B
B
C
B
CO3
A
B
B
B
B
B
A
C
B
B
B
CO4
A
B
B
B
B
B
B
B
B
B
B
CO5
A
B
B
B
B
B
B
B
B
A
B
A – Excellent; B – Good; C – Average
FT/GN/68/00/21.04.15
SRI VENKATESWARA COLLEGE OF ENGINEERING
COURSE DELIVERY PLAN - THEORY
Page 9 of 15
Sub. Code / Sub. Name: PH6151/Engineering Physics-I
Course Outcomes:
Course Outcome 1: Working knowledge of fundamental physics and basic engineering principles to
include advanced knowledge in one or more engineering disciplines
Course Outcome 2: The ability to formulate, conduct, analyzes, and interprets experiments in
engineering physics.
Course Outcome 3: To understand and to compute problems in Quantum Physics
Course Outcome 4: Use modern engineering physics techniques and tool.
Course Outcome 5: To enhance knowledge about photonics and optical fiber communication system.
Programme Outcomes: [EE]
Programme Outcome 1: An ability to apply knowledge of mathematics, science, and engineering
Programme Outcome 2: An ability to identify, formulate and analyze, electrical and electronics engineering
problems
Programme Outcome 3: An ability to design/develop solutions for complex problems related to electrical
and electronics engineering applications
Programme Outcome 4: Ability to conduct investigations of complex engineering problems, be a part of
novel research, and provide valid conclusions.
Programme Outcome 5: An ability to use the modern engineering techniques and tools to model complex
engineering activities.
Programme Outcome 6: An ability to apply engineering expertise to approach and assess societal, health,
safety issues and environmental needs.
Programme Outcome 7: An understanding of professional and ethical responsibility.
Programme Outcome 8: Ability to work individually, and in multidisciplinary teams with the skill to
organize and lead.
Programme Outcome 9: An ability to communicate effectively.
Programme Outcome 10: A recognition of the need for and an ability to engage in life - long learning.
Mapping – CO – PO :
PO1
PO2
PO3
PO4
PO5
PO6
PO7
PO8
PO9
PO10
CO1
A
A
B
B
B
B
B
B
B
B
CO2
A
A
B
C
C
B
B
B
B
B
CO3
A
B
B
B
B
B
B
B
A
B
CO4
A
B
B
B
A
B
B
B
B
B
CO5
A
B
B
B
B
A
B
B
B
B
A – Excellent; B – Good; C – Average
FT/GN/68/00/21.04.15
SRI VENKATESWARA COLLEGE OF ENGINEERING
COURSE DELIVERY PLAN - THEORY
Page 10 of 15
Sub. Code / Sub. Name: PH6151/Engineering Physics-I
Course Outcomes:
Course Outcome 1: Working knowledge of fundamental physics and basic engineering principles to
include advanced knowledge in one or more engineering disciplines
Course Outcome 2: The ability to formulate, conduct, analyzes, and interprets experiments in
engineering physics.
Course Outcome 3: To understand and to compute problems in Quantum Physics
Course Outcome 4: Use modern engineering physics techniques and tools.
Course Outcome 5: To enhance knowledge about photonics and optical fiber communication system.
Programme Outcomes: [EC]
Programme Outcome 1: To impart fundamental knowledge of mathematics, applied science and concepts of
Electronics & Communication engineering for modeling and solving engineering problems.
Programme Outcome 2: To inculcate an ability to analyze Electronics and Communications Engineering
problems by applying the knowledge of mathematics and core engineering subjects.
Programme Outcome 3: To design Electronics & Communication systems with specifications based on
societal and environmental considerations.
Programme Outcome 4: impart an ability to design and conduct experiments as well as to analyze and
interpret data in the areas of Computer hardware, Digital signal processing, and VLSI and Communication
systems.
Programme Outcome 5: To teach the use of modern engineering tools, techniques, equipments, software and
programming language skills necessary for designing and testing Electronics and Communication Engineering
systems.
Programme Outcome 6: To make the students understand the impact of the engineering solutions in a global,
economic, environmental and societal context.
Programme Outcome 7: To impart an Awareness of innovativeness, entrepreneurship and sustainable
development.
Programme Outcome 8: To inculcate an ability to understand professional and ethical responsibilities.
Programme Outcome 9: To create an ability to work effectively in multidisciplinary and multi-cultural
teams.
Programme Outcome 10: To improve oral and written communication skills
Programme Outcome 11: To impart management principles for applying in own work, team work and to
manage projects.
Programme Outcome 12: To impart an ability to engage in life-long learning and to keep abreast with current
developments in the field of Electronics and Communication engineering.
Mapping – CO – PO :
PO1
PO2
PO3
PO4
PO5
PO6
PO7
PO8
PO9
PO10
PO11
PO12
CO1
A
A
B
C
B
B
C
B
B
B
B
B
CO2
A
B
B
B
B
B
B
C
B
B
B
B
CO3
A
B
B
B
B
B
B
B
B
A
B
C
CO4
A
B
B
B
A
B
B
B
B
C
B
B
B
A
B
B
B
B
B
CO5
A
B
B
B
B
A – Excellent; B – Good; C – Average
FT/GN/68/00/21.04.15
SRI VENKATESWARA COLLEGE OF ENGINEERING
COURSE DELIVERY PLAN - THEORY
Page 11 of 15
Sub. Code / Sub. Name: PH6151/Engineering Physics-I
Course Outcomes:
Course Outcome 1: Working knowledge of fundamental physics and basic engineering principles to
include advanced knowledge in one or more engineering disciplines
Course Outcome 2: The ability to formulate, conduct, analyzes, and interprets experiments in
Engineering physics.
Course Outcome 3: To understand and to compute problems in Quantum Physics
Course Outcome 4: Use modern engineering physics techniques and tools.
Course Outcome 5: To enhance knowledge about photonics and optical fiber communication system.
Programme Outcomes: [IT]
Programme Outcome 1: Apply Engineering knowledge to solve problems in different areas of Information
Technology.
Programme Outcome 2: Identify, hypothesize and construct software Requirement Specification using various
concepts and techniques in the field of IT.
Programme Outcome 3: Design and develop solutions for complex systems to meet the needs of society and IT
industry.
Programme Outcome 4: Ability to conduct research in diversified field of Mobile Communication, Web
technology Data Mining, Cryptography, Network Security etc to obtain valid conclusions for challenging problems.
Programme Outcome 5: Develop programming skills to use sophisticated and advanced software tools of IT.
Programme Outcome 6: Develop ability to perform best engineering and technical practices that benefit the
corporate society and industry.
Programme Outcome 7: Develop projects using software tools for satisfying the needs of end users.
Programme Outcome 8: Learn and follow the ethical principles involved in IT research and industrial practices.
Programme Outcome 9: Ability to work as an individual based on interest and also in multidisciplinary team of
Information Technology.
Programme Outcome 10: Develop effective communication and technical writing in IT research and industrial
practices.
Programme Outcome 11: Develop management skills to work in IT industry and also to become an entrepreneur in
the field of Information Technology.
Programme Outcome 12: Engage in lifelong learning process by updating the knowledge of individual with the
upcoming software tools and techniques.
Mapping – CO – PO :
PO1
PO2
PO3
PO4
PO5
PO6
PO7
PO8
PO9
PO10
PO11 PO12
CO1
A
C
B
C
C
A
C
B
B
B
B
B
CO2
A
C
C
C
B
B
C
B
B
B
C
C
CO3
A
C
C
C
B
B
C
B
B
A
B
B
CO4
A
B
B
B
B
B
A
B
B
B
B
B
B
B
B
A
B
B
B
CO5
A
B
B
B
A – Excellent; B – Good; C – Average
B
FT/GN/68/00/21.04.15
SRI VENKATESWARA COLLEGE OF ENGINEERING
COURSE DELIVERY PLAN - THEORY
Page 12 of 15
Sub. Code / Sub. Name: PH6151/Engineering Physics-I
Course Outcomes:
Course Outcome 1: Working knowledge of fundamental physics and basic engineering principles to
include advanced knowledge in one or more engineering disciplines
Course Outcome 2: The ability to formulate, conduct, analyzes, and interprets experiments in
engineering physics.
Course Outcome 3: To understand and to compute problems in Quantum Physics
Course Outcome 4: Use modern engineering physics techniques and tools.
Course Outcome 5: To enhance knowledge about photonics and optical fiber communication system.
Programme Outcomes: [ME]
Programme Outcome 1: Applying the engineering knowledge to solve problems in different areas of
Mechanical Engineering.
Programme Outcome 2: Identification, hypothesizing and conducting experiments using various theories
of Mechanical Engineering.
Programme Outcome 3:
Designing and developing the solutions for complex processes in Mechanical
Engineering to meet the need of the society.
Programme Outcome 4: Developing the ability to conduct research in diversified field of Mechanical to
obtain valid conclusions for challenging problems.
Programme Outcome 5: Developing the skills to use modern and advanced tools of Mechanical
Engineering.
Programme Outcome 6: Developing the ability to perform good Mechanical practices that benefit the
society.
Programme Outcome 7: Developing the projects using Mechanical tools for environmental conservation
and sustainable development.
Programme Outcome 8: Learning and following the Management principles involved in Mechanical
research and industrial practices.
Programme Outcome 9: Developing the ability to work as an individual based on interest and also in
multi-disciplinary team of Mechanical engineering.
Programme Outcome 10: Developing the effective communication and scientific writing in Mechanical
research and industrial practices.
Programme Outcome 11: Developing the management skills to work in Mechanical industry and also to
become an entrepreneur in Mechanical Field.
Programme Outcome 12: Engaging in life-long learning towards the area of specialization in Mechanical
Engineering.
Mapping – CO – PO :
PO1
PO2
PO3
PO4
PO5
PO6
PO7
PO8
PO9
PO10
CO1
A
A
B
B
C
B
B
C
B
B
B
B
CO2
A
A
C
B
B
B
B
C
B
B
B
B
CO3
A
C
C
B
B
B
C
C
B
A
B
B
CO4
A
B
B
B
A
B
B
B
B
B
B
B
B
B
B
B
B
B
B
B
CO5
A
B
B
B
A – Excellent; B – Good; C – Average
PO11 PO12
FT/GN/68/00/21.04.15
SRI VENKATESWARA COLLEGE OF ENGINEERING
COURSE DELIVERY PLAN - THEORY
Page 13 of 15
Sub. Code / Sub. Name: PH6151/Engineering Physics-I
Course Outcomes:
Course Outcome 1: Working knowledge of fundamental physics and basic engineering principles to
include advanced knowledge in one or more engineering disciplines
Course Outcome 2: The ability to formulate, conduct, analyzes, and interprets experiments in
engineering physics.
Course Outcome 3: To understand and to compute problems in Quantum Physics
Course Outcome 4: Use modern engineering physics techniques and tools.
Course Outcome 5: To enhance knowledge about photonics and optical fiber communication system.
Programme Outcomes: [AE]
Programme Outcome 1: Ability to apply knowledge mathematics, science and engineering
Programme Outcome 2: Ability to design and conduct experiments, interpret and analyze data and
report results
Programme Outcome 3: Ability to design an automotive system or a process that meets desired
specifications and requirements.
Programme Outcome 4: Ability to function on engineering and science laboratory teams, as well as on
multidisciplinary design teams.
Programme Outcome 5: Ability to identify, formulate and solve automobile engineering problems.
Programme Outcome 6: Understanding of their professional and ethical responsibilities
Programme Outcome 7: Ability to communicate effectively in both verbal and written forms.
Programme Outcome 8: Ability to apply engineering solutions in global and societal contexts.
Programme Outcome 9: Attain broad education and will have an understanding of the impact of
engineering on society and demonstrate awareness of contemporary issues.
Programme Outcome 10: Attain the capability of self learning and clearly understand the value of
lifelong learning.
Programme Outcome 11: Familiar with modern engineering software tools and equipment to analyze
automobile engineering problems
Mapping – CO – PO :
PO1
PO2
PO3
PO4
PO5
PO6
PO7
PO8
PO9
PO10
CO1
A
A
B
B
C
B
B
C
B
B
B
B
CO2
A
A
C
B
B
B
B
C
B
B
B
B
CO3
A
C
C
B
B
B
C
C
B
A
B
B
CO4
A
B
B
B
A
B
B
B
B
B
B
B
CO5
A
B
B
B
B
B
B
B
B
B
B
B
A – Excellent; B – Good; C – Average
PO11 PO12
FT/GN/68/00/21.04.15
SRI VENKATESWARA COLLEGE OF ENGINEERING
COURSE DELIVERY PLAN - THEORY
Page 14 of 15
Sub. Code / Sub. Name: PH6151/Engineering Physics-I
Course Outcomes:
Course Outcome 1: Working knowledge of fundamental physics and basic engineering principles to
include advanced knowledge in one or more engineering disciplines
Course Outcome 2: The ability to formulate, conduct, analyzes, and interprets experiments in
engineering physics.
Course Outcome 3: To understand and to compute problems in Quantum Physics
Course Outcome 4: Use modern engineering physics techniques and tools.
Course Outcome 5: To enhance knowledge about photonics and optical fiber communication system.
Programme Outcomes:[BT]
Programme Outcome 1: Applying the engineering knowledge to solve problems in different areas of Biotechnology
Programme Outcome 2: Identification, hypothesizing and conducting experiments using various theories of life
sciences and engineering.
Programme Outcome 3: Designing and developing the solutions for complex processes in Biotechnology to meet the
need of the society.
Programme Outcome 4: Developing the ability to conduct research in diversified field of Biotechnology to obtain
valid conclusions for challenging problems.
Programme Outcome 5: Developing the skills to use modern and advanced tools of Biotechnology.
Programme Outcome 6: Developing the ability to perform good Biotechnological practices that benefit the society.
Programme Outcome 7: Developing the projects using Biotechnological tools for environmental conservation and
sustainable development.
Programme Outcome 8: Learning and following the ethical principles involved in Biotechnology research and
industrial practices.
Programme Outcome 9: Developing the ability to work as an individual based on interest and also in disciplinary
team of Biotechnology.
Programme Outcome 10: Developing the effective communication and scientific writing in Biotechnology research
and industrial practices.
Programme Outcome 11: Developing the management skills to work in Biotechnology industry and also to become
an entrepreneur in Biotechnology
Programme Outcome 12: Engaging in life-long learning towards the area of specialization in Biotechnology.
Mapping – CO – PO :
PO1
PO2
PO3
PO4
PO5
PO6
PO7
PO8
PO9
PO10
PO11 PO12
CO1
A
A
C
B
B
B
B
B
B
B
B
B
CO2
A
A
B
B
B
B
B
C
B
B
B
B
CO3
A
B
C
B
B
B
C
A
C
C
B
B
CO4
A
B
B
B
B
B
B
B
C
B
B
B
CO5
A
B
B
C
B
C
B
B
A
B
C
B
A – Excellent; B – Good; C – Average
FT/GN/68/00/21.04.15
SRI VENKATESWARA COLLEGE OF ENGINEERING
COURSE DELIVERY PLAN - THEORY
Page 15 of 15
TEXT BOOKS:
1. Arumugam M. Engineering Physics. Anuradha publishers, 2010
2. Gaur R.K. and Gupta S.L. Engineering Physics. Dhanpat Rai publishers, 2009
REFERENCES:
3. Searls and Zemansky. University Physics, 2009
4. Mani P. Engineering Physics I. Dhanam Publications, 2011
5. Marikani A. Engineering Physics. PHI Learning Pvt., India, 2009
6. Palanisamy P.K. Engineering Physics. SCITECH Publications, 2011
7. Rajagopal K. Engineering Physics. PHI, New Delhi, 2011
8. Senthilkumar G. Engineering Physics I. VRB Publishers, 2011
Prepared by
Approved by
Name
Ms.G.Bharathy
Dr.S.SampathKrishnan
Designation
Asst.Professor
Professor
02.07.2015
02.07.2015
Signature
Date
Remarks *:
Remarks *:
* If the same lesson plan is followed in the subsequent semester/year it should be mentioned and signed by the
Faculty and the HOD