b.sc (physics) programe outcome · ps01 b.sc (physics) programe outcome po1: to enhance the...

PS01

B.Sc (PHYSICS)

PROGRAME OUTCOME

PO1: To enhance the student’s academic abilities, personal qualities and transferable skills which

will give them an opportunity to develop as responsible citizens.

PO2: To define the basic laws involved in Physics

PO3: To understand the concepts and significance of the various physical phenomena.

PO4 : To carry out experiments to understand the laws and concepts of Physics.

PO5 : To apply the theories learnt and the skills acquired to solve real time problems.

PO6 : To acquire a wide range of problem solving skills, both analytical and computational and to

apply them.

PROGRAMME EDUCATION OBJECTIVES

• To produce graduates who excel in the competencies and values required for leadership to

serve a rapidly evolving global community

• To motivate the students to pursue PG courses in reputed institutes

• To kindle the interest for research in students

• To acquire placement in educational institutions, engineering and industrial firms.

• To endow the students with creative and analytical skills; this will equip them to become

entrepreneurs.

PS02

. S. G. R. KRISHNAMMAL COLLEGE FOR WOMEN, COIMBATORE-641004

(Autonomous and Affiliated to Bharathiar University)

(Re - Accredited with A Grade by NAAC)

(An ISO 9001:2008 Certified Institution)

Programme and Branch: B.Sc. PHYSICS Branch III

Scheme of Examination

(Applicable to Students admitted during the academic year 2017-2018 onwards)

Se

m

Part Subject

Code

Title of the Paper Instruc

tion

Hours/

week

Total

conta

ct

hours

Tuto

rials

Durat-

ion

of

exam

(In

hrs)

Maximum Marks Credits

CA ES

E

Total

I

I

TAM1701/

HIN1701/

FRE1701

Language T/H/F Paper I

6

86

4

3

40

60

100

3

II

ENG1701/

ENG17F1

English Paper I/Functional English

6

86

4

3

40

60

100

3

III

PS17C01

Core Physics Paper I

Properties of Matter and Sound

6

86

4

3

40

60

100

5

PS16CP1

Core Physics Practical I

3

-

-

-

-

-

CE16A01/

TH16A01

Allied Chemistry Paper –I*/

Mathematical Statistics- I*

4

56

4

3

40

60

100

4

CE16AP1/ Allied Chemistry Practicals/

3 - - - - -

IV NME16B1/

NME16A1/

NME12WS/

NME12GS/

NME12AS

Basic Tamil I/

Advanced Tamil II/

Women Studies/

Gandhian Studies/

Ambedhkar Studies

2

27

3

3

50

50

100

50

50

100

100

2

II

I

TAM1702/

HIN1702/

FRE1702

Language T/H/F Paper II

6

86

4

3

40

60

100

3

II

ENG1702/

ENG17F2

Part II – English Paper II /Functional

English

6

86

4

3

40

60

100

3

III

PS17C02

Core Physics Paper II

Heat and Thermodynamics

5

71

4

3

40

60

100

4

PS16CP1

Core Physics Practicals – I

3

3

40

60

100

4

CE16A02/

TH16A05

Allied Chemistry Paper –II*/

Mathematical Statistics –II*

5

71

4

3

40

60

100

4

CE16AP1 Allied Chemistry Practicals

3 3 20 30 50 2

IV NME16B2

NME16A2

Basic Tamil II **/

Advanced Tamil II**

2

50

50

100

2

PS03

OPS1601

Open Course(Self Study online courses)

-

-

-

2

Personality development program

2

-

-

-

-

-

100

2

VI

NM11GAW

General Awareness

Self

Study

-

-

Grade

-

III I

TAM1703/

HIN1703/

FRE1703

Language T/H/F Paper III

6

86

4

3

25

75

100

3

II

ENG1703

ENG17F3

Language Through Literature - Level

III/ Language Through Literature -

Functional Level III

5

71

4

3

25

75

100

3

III

PS17C03

Core Physics Paper III

Mechanics and Relativity

4

56

4

3

25

75

100

4

PS16CP2

Core Physics Practical – II

3

-

-

-

-

-

TH16A12

PL16A01

AS16A01

Allied Mathematics for Physics - I

Allied Botany Paper- I

Allied Zoology Paper I

7

4

4

101 4 3

3

3

25

20

20

75

55

55

100

75

75

5

4

4

IV

SB17PC01 Skill Based Elective - Theory

Programming in C

1

SB17PCP1 Skill Based Elective Practicals

Programming in C

2

NM11VRH

Value Education and Human Rights

2

27

3

3

25

75

100

2

VI Job Oriented Course

PCB Fabrication Techniques

After

12.50

PM

3

-

-

Grade

-

IV

I

TAM1704/

HIN1704/

FRE1704

Part I Language T/H/F Paper IV

5

71

4

3

25

75

100

3

II

ENG1704/

ENG17F4

Language Through Literature - Level IV

/ Language Through Literature -

Functional Level IV

6

86

4

3

25

75

100

3

III

PS17C04

Core Physics Paper IV

Electricity and Magnetism

4

56

4

3

25

75

100

4

PS16CP2

Core Physics Practicals – II

3

3

40

60

100

4

PS04

TH16A13

PL16A02

AS16A02

Allied Mathematics for Physics - II

Allied Botany Paper- II

Allied Zoology Paper II

7

4

4

101 4 3

3

3

25

20

20

75

55

55

100

75

75

5

4

4

PL16AP1

AS16AP1 Allied Botany Practicals

Allied Zoology Practicals

3

3

3

3

20

20

30

30

50

50

2

2

IV

SB17PC01 Skill Based Elective - Theory

Programming in C

2

2 25 75 100 3

SB17PCP1 Skill Based Elective Practicals

Programming in C

1 2 40 60 100 2

NM08EVS Environmental Studies 2 27 3 3 25 75 100 2

Internship

(4 Weeks)

- - - 100 100 2

V

NSS/NCC/ /YRC/ SPORTS&GAMES

-

- - 100 100 1

V

III

PS16C05

Core Paper V

Electronics

6

86

4

3

40

60

100

5

PS16C06

Core Paper VI

Solid state physics

6

86

4

3

40

60

100

5

PS16E01

PS16E02

PS16E03

Elective :

1.Programming in ‘C’

2. Materials Science – I

3. Bio medical Instrumentation -I

4

56

4

3

40

60

100

5

NM12IS2 Information Security 2 27 3

PS16PR0J

Project

3

45

Viva

25

75

100

5

PS16AC1

#Advanced Learners’ Course I –

Energy Physics- I

-

3

-

100

100*

*5

PS16AC2

#Advanced Learners’ Course I –

Experimental techniques and data

Analysis - I

-

3

-

100

100*

*5

SB11MD02

SB11BS02

SB11BA02

SB11AC02

SB11WD02

Skill Based Elective

Multimedia and DTP software-Level II

Basics Of Computer Application

Business Application Software Level II

Business Automation- Level II

Applications with C- Level II

Basics of web designing- Level II

3

4

PS05

SB11MDP2

SB11BAP2

SB11BSP2

SB11ACP1

SB11WDP1

Skill Based Elective Practicals

Multimedia and DTP software- Level II

Practical II

Accounting package- Level II Practical

II

Business Application Software Level II

Practical– II

Applications with C Level II Practical

II

Basics of web designing Level I

practical II

2

PS16CP3

Core Physics Practicals – III

6

86

4

3

40

60

100

4

PS16CE Comprehensive Exam - 2

On line

- - - Grade

VI

Supportive Course

-

-

-

-

Submis

sion of

certific

ate

VI

III

PS16C07

Core Paper VII

Optics and Spectroscopy

5

71

4

3

25

75

100

5

PS16C11

Core Paper VIII

Quantum Mechanics and Relativity

5

71

4

3

25

75

100

5

PS16C09

Core Paper IX

Atomic and Nuclear Physics

5

71

4

3

25

75

100

5

PS16E04

PS16E05

PS16E06

Elective :

1 Microprocessor

2. Materials Science - II

3. Bio medical Instrumentation -II

6

86

4

3

25

75

100

5

PS16AC3

#Advanced Learners’ Course II -

Energy Physics- II

-

3

-

100

100*

*5

PS16AC4

#Advanced Learners’ Course II –

Experimental techniques and data

Analysis - II

-

3

-

-

100*

*5

PS16CP4

Core Physics Practicals- IV

6

86

4

3

40

60

100

4

SB09MD02

SB11BC02

SB11BA02

SB11AC02

Skill Based Elective

Multimedia and DTP software –Level II

Basics Of Computer Application

Business Application Software – II

BUSINESS AUTOMATION

Internet and e-commerce

APPLICATIONS WITH C C with Graphics

3 3 25 75 100 4

PS06

SB09MDP2

SB11BCP2

SB11BAP2

SB11ACP2

Skill Based Elective Practicals

Multimedia and DTP software-Practical

II

Basics Of Computer Application Business Application Practicals– II

BUSINESS AUTOMATION

Tally and Internet

C with Graphics practicals-II

3

40

60 100 2

GRAND TOTAL 3800 140+10#

* Not considered for Grand Total and CGPA

PS07

Category L T P Credit

86 4 5

Preamble

To stimulate thekey concepts underpinning the physical interpretations ofdifferent properties of matter and

apply themin real world problems

Course Outcomes

On the successful completion of the course, students will be able to

Mapping with Programme Outcomes

COs PO1 PO2 PO3 PO4 PO5 PO6

CO1. S S

S S S S

CO2. S S

S S S M

CO3. S S S M

S S

CO4. S S S S

M S

CO5. S S M S

S S

S- Strong; M-Medium; L-Low

PS17C01 PROPERTIES OF MATTER AND SOUND

CO Number

CO Statement Knowledge

Level

CO1. Learning the basics concepts of elasticity, surface tension, gravitation, viscosity

and sound K1

CO2. Understand the concepts of properties of matter and to recognise their

applications in various real problems K2

CO3. Describe the key evidence for the breakdown of the classical description of the

properties of matter K3

CO4. Recall the principles and basic equations and apply them to unseen problems K4

CO5. Formulate the equations for unique cases in the diverse categories of material

systems K5

PS08

Syllabus

Unit – I: Elasticity 18 hrs

Three types of elastic moduli – Poisson’s ratio – Bending of beams – Expression for bending

moment – Depression of the loaded end of a Cantilever – uniform – non uniform bending – theory –

experiment - pin and microscope method – work done in uniform bending – Koenig’s method – non-

uniform bending - theory - expression for couple per unit twist - determination of rigidity modulus -

Static torsion method with scale and telescope - Rigidity modulus by torsion pendulum with mass.

Unit – II: Gravitation 17 hrs

Newton’s law of gravitation - Kepler’s Law of Planetary motion – Boy’s method for G –

Gravitational potential – Gravitational potential and field at a point due to spherical shell –

Gravitational potential and field at a point due to solid sphere - Variation of ‘g’ with latitude, altitude

and depth – The compound pendulum and determination of g.

Unit- III: Viscosity 17 hrs

Coefficient of critical velocity – Poiseulli’s formula for coefficient of viscosity and its

correction - determination of coefficient of viscosity by capillary flow method - comparison of

viscosities Oswald's viscometer - viscosity of a highly viscous liquid - Stoke's method for the

Coefficient of a highly viscous liquid - variations of viscosity with temperature and pressure -

viscosity of gases - Mayer's formula for the rate of flow of a gas through a capillary tube - Rankine's

method for the determination of viscosity of a gas.

Unit – IV: Surface tension and Osmosis 17 hrs

Surface energy - angle of contact and its determination - excess of pressure inside curved

surface - formation of drops - Experimental study of variation of Surface tension with temperature -

drop weight method of determining surface tension and interfacial surface tension - angle of contact

of mercury - Quincke's method - surface tension and vapour pressure osmosis - experimental

determination of osmotic pressure - Laws of osmosis pressure - osmotic and vapour pressure of a

solution.

Unit-V: Sound 17 hrs

Different methods for determination of frequency – direct and graphical – by chronography –

stroboscopic methods – strobosconne- phonic wheel method – resonance method – Sonometer –

Helmholtz resonator – method of beats – Siren – means of Lissajous figures.

Ultrasonics

Ultrasonics –Properties - Production –detection and applications.

PS09

Text Book

S.No Authors Title of the Book Publishers Year of

Publication

Edition

1 R.Murugesan Properties of Matter S.Chand and

Company Pvt Ltd

2013

11th

edition

2 Saighal.R.L Textbook of Sound S.Chand &Co Ltd 1998 2nd

Edition

eference Books


Publication

Edition

1 D.S.Mathur Elements of Properties

of Matter

Shyam Lal

Charitable

Trust

2003 11th

Edition

,

2 Brijlal

Subramanyam

Properties of Matter S.Chand and

Company Pvt

Ltd

1995 3rd

Edition

3 Murugesan. R Properties of matter,

Sound and thermal

physics

S. Chand &

Co Ltd

2011 1st Edition

4 Brijlal

Subramanyam

Sound Vikas

Publishing

House Pvt

Ltd

1999 2nd

Edition

Pedagogy

Chalk and Talk, ppt, group discussion, seminar, Interaction, problem solving

Course Designers:

1. Mrs. N. Priyadharsini,

PS010


71 5 - 5

Preamble

The aim of this course is to acquire knowledge in heat transfer, entropy, production of low

temperature and liquefaction of gases, thermal radiation and statistical thermodynamics

Course Outcomes


CO

Number CO Statement Knowledge

Level

CO1. Listing the basic ideas on heat. K1

CO2. Understand the central concepts and basic formalisms of specific heat,

entropy, quantum theory of radiation; K2

CO3. Use of tools needed to formulate problems in the thermodynamics of gases. K2

CO4. Solving problems based on heat transfer, entropy and thermal radiation K3

CO5. Finding applications of the physical quantities. K3



CO1 S S M M M S

CO2 S S S S S M

CO3 S S S S M S

CO4 S S S S S S

CO5 S S S S M S


Syllabus

Unit I 14 Hrs

Kinetic theory of gases:

PS17C02 HEAT AND THERMODYNAMICS

PS011

Kinetic theory of gases - pressure exerted by a perfect gas- rms velocity – derivation of gas equation-

derivation of gas laws- Brownian motion - Langevins theory of Brownian motion - Einsteins theory

of Brownian motion–degrees of freedom- adiabatic expansion of ideal gas - Vander Waal’s equation

of state – critical constants –experimental determination of critical constants.

Quantum Theory of Specific Heat

Specific heat of solids - Dulong and Petits law and the deduction – failure of Dulong and

Petit’s law – Einstein’s theory and its limitation – Debye theory of specific heat of solids – specific

heat of gases – Variation of specific heat of diatomic gases with temperature.

Unit II 14 Hrs

Production of Low Temperature and Liquefaction of Gases

Methods of production of low temperatures – Joule Thomson effect – Porous plug

experiment – its theory and result – Joule Thomson effect for perfect and real gases – *superfludity –

Helium I and Helium II -Lamda point* – adiabatic demagnetization

Thermal Radiation

Quantum theory of radiation- Planck’s hypothesis – average energy of Planck’s oscillator – Plank’s

radiation law and its experimental verification – *Wein’s law -Rayleigh- Jean’s in relation to Planks

law – Stefan’s constant and Wein’s constant from Plank’s law *

Unit III

Laws of Thermodynamics 14 Hrs

First law of thermodynamics – Applications of first law of thermodynamics - Isothermal and

Adiabatic process –Work done on isothermal and adiabatic process – Reversible and irreversible

process- Determination of g by Clement and Desorme’s method – second law of thermodynamics –

Carnot’s engine- Working efficiency – Carnot’s refrigerator – Carnot’s Theorem.

Unit IV 14 Hrs

Entropy

Concept of entropy - change of entropy in reversible cycle - Principle of increase of entropy;

change of entropy in irreversible process - temperature – entropy diagram – physical significance of

entropy - entropy of a perfect gas- Thermo dynamic potentials- internal energy (U)- Helmtzholtz

function (F)- Gibb’s function (G) and enthalpy (h) – significance of thermodynamic potentials -

Maxwell’s thermodynamics relation – the (T-dS) equation – Clapeyron’s latent heat equation using

Maxwell’s thermodynamics relation

Unit V 15 Hrs

Statistical Thermodynamics

Probability- Basic rules of probability theorem – Macro state and micro state –

thermodynamic probability – constraints on a system – static and dynamic states Most probable state

– Life time of a macro and micro state – concept of a cell in a compartment - Statistical equilibrium –

Probability theorem in statistical thermodynamics– Maxwell’s Boltzmann distribution law-

Maxwell’s Boltzmann distribution in terms of temperature – Maxwell quantum statistics – phase

PS012

space – Fermi- dirac distribution law – Bose Einstein distribution law –*Comparison of three

statistics*.

Text Book


Publication

Edition

1 Brijlal N

Subrahmanyam

P.S.Hemne

Heat Thermodynamics

and Statistical Physics

and applications

S. Chand 2012 3rd

edition

2 R.Murugeshan

Er. Kiruthiga

Sivaprasath

Thermal Physics S.Chand 2012 3rd

edition

Reference Books

S.

No

Authors Title of the Book Publishers Year of

Publication

Edition

1 A.B Gupta

H.P. Roy

Thermal Physics Arunabha

Sen

2005 1st edition

2 Agrawal

Prakash

Thermal Physics Pragati

Prakashan

2015 27th

edition

3 Agrawal

Prakash

Thermodynamics and

Statistical Physics

Pragati

Prakashan

2015 27th

edition

Pedagogy

Chalk and talk, PPT, Seminar, Group discussion, Interaction

Course Designers:

1. Mrs. M. Lavanya

PS013

Preamble

This course introduces students to the methods of experimental physics. Emphasis will be given on

laboratory techniques such as accuracy of measurements and data analysis. The concepts that are

learnt in the lecture sessions will be translated to the laboratory sessions thus providing a hands-on

learning experience such as in measuring the basic concepts in properties of matter, Sound, Heat,

Optics, Electricity and Magnetism.

Course Outcomes


CO


Level

CO1. Apply knowledge of mathematics and physics fundamentals and an

instrumentation to arrive solution for various problems. K1

CO2. Understand the usage of basic laws and theories to determine various

properties of the materials given. K2

CO3. Understand the application side of the experiments K2

CO4. Use standard methods to calibrate the given low range voltmeter and

ammeter and to measure resistance of the given coil and various physical

quantities.

K3

CO5. Use of basic laws to study the spectral properties and optical properties of

the given prism. K3



CO1. S S L L L L

CO2. S S

S S M M

CO3. S S

S S M M

CO4. S S S S

M M

CO5. S S

S S M M


PS16CP1 CORE PRACTICALS I Category L T P Credit

- - 82 4

PS014

Syllabus

List of Experiments

1. Young’s Modulus- Non Uniform bending- Optic lever

2. Young’s Modulus- Uniform bending – pin and microscope.

3. Rigidity modulus- Static torsion

4. Rigidity modulus and moment of inertia – Torsion pendulum.

5. A.C. Frequency- Sonometer.

6. Acceleration due to gravity – Compound pendulum

7. Co-efficient of thermal conductivity- Lee’s disc method

8. Refractive index of a solid prism- Spectrometer

9. Refractive index of a liquid prism- Spectrometer

10. Wavelength of a spectral lines – grating – minimum deviation method using Spectrometer

11. Calibration of a low range voltmeter- Potentiometer

12. Calibration of a low range ammeter- Potentiometer

13. Resistance by Potentiometer

14. Moment of a magnet - deflection magnetometer –Tan C method.

15. Moment of a magnet – Circular coil- deflection magnetometer

16. Temperature co-efficient of resistance of a Thermistor

Pedagogy:

Demonstration and practical sessions

Course Designers:

1. Dr. G. Praveena

2. Dr. P. Meena

PS015


56 4 - 4

Preamble

This paper introduces the students to the basic concepts of Elasticity, Rotational motion, Heat and

thermodynamics, Sound, Optics, Atomic and Nuclear Physics

Course Outcomes




CO1. S S

S M L L

CO2. S M

S M S L

CO3. S M S L

M S

CO4. S M S S

S S

CO5. S M S M

S M


Syllabus

PS16A01/PS16A03 ALLIED PHYSICS PAPER- I

CO


Level

CO1. Explore the fundamental concepts of physics K1

CO2. Import knowledge about the importance of material properties, heat,

sound, optics, atomic and nuclear physics. K2

CO3. Understand the energy involved in nuclear reaction K2

CO4. Carry out the practical by applying these concepts K3

CO5. Get depth knowledge of physics in day today life K3

PS016

Unit – I

11 Hrs

Properties of Matter

Elasticity: Elastic moduli- bending moment-expression – Young’s modulus by uniform and non-

uniform bending-theory and experiment- I–section girders-Torsion pendulum-couple per unit twist-

work done in twisting –determination of the rigidity modulus of the material of the wire.

Unit - II 11 Hrs

Transmission Of Heat

Conduction process: Thermal conductivity- Rectilinear field along a bar- Measurement of

Thermal conductivity of a bad conductor by Lee’s disc method

Convection process: Lapse rate-stability of atmosphere- Green house effect

Radiation process: Solar constant- Pyroheliometer- solar energy and its applications (flat plate

collector & solar cooker)

Unit - III 11 Hrs

Thermodynamics, Sound:

Thermodynamics: Second law of thermodynamics-explanation-Carnot’s theorem-entropy- change

of entropy in reversible and irreversible processes-change of entropy of a perfect gas

Ultrasonics: Production by piezo electric method-detection-Applications

Unit - IV 11 Hrs

Optics:

Dispersion: Dispersive power-combination of prisms to produce (i) deviation without dispersion

(ii) dispersion without deviation-direct vision spectroscope.

Interference: Air wedge-determination of diameter of a wire-Newton’s rings-determination of

refractive of a liquid

Polarisation: Production, detection and analysis of plane, circularly, elliptically polarized light-

quarter and half wave plates

Unit - V 12Hrs

Atomic Physics: Vector atom model -electron, spin quantum numbers-Pauli’s exclusion principle-

excitation and ionization potential-experimental determination-Franck and Hertz method

Nuclear Physics: Mass defect-binding energy- Liquid drop model - Radioactivity-nature of ά, β &

γ,rays-Nuclear Fission – Energy released in a fission- atom bomb-Nuclear fusion- thermonuclear

reaction.

Text Book

PS017

1. Brijlal Subramanium, Heat and thermodynamics, S.Chand and Co, 2012, 16th

Edition

2. Brijlal Subramanium & Hemne.P.S, Heat thermodynamics and Statistical Physics, S.Chand and

Co., 2011, 12th

edition

3. Brijlal Subramanium, Optics , S.Chand and Co, 2012, 21st Edition.

4. Murugeshan R, Allied Physics, S.Chand and Co, 1998, 1st Edition.

Reference Books

1. Jayaprakash. N, Ancillary Physics, Volume I, J.P.Publications ,1994, 1st Edition.

2. Mathur D.S, Properties of matter , S.Chand and Co, 1970, 2nd

Edition .

3. Murugesan R, Modern Physics , S.Chand and Co , 2013, 9th

edition.

Pedagogy

Chalk & Talk, Group Discussion, Demonstration, Problem solving, Seminar, PPT and Assignment

Course Designers:

1. Dr. S. Shanmuga Sundari

2. Mrs. T. Poongodi

PS018


56 4 - 4

Preamble

This paper introduces the student to the basic concepts of current electricity, electronics and digital

electronics

Course Outcomes




CO1. S S

S M M S

CO2. S S

S S L M

CO3. S S L L

S S

CO4. S M M S

S M

CO5. S S L S

M S


Syllabus

Unit - I 11Hrs

Static Electricity:

PS16A02/PS16A04 ALLIED PHYSICS PAPER- II

CO


Level

CO1. Acquire knowledge on elementary ideas of electricity and magnetism K1

CO2. Emphasize the significance of laws involved in electric circuits K1

CO3. Understand the basics of operational amplifier K2

CO4. Apply the principles of electronics in day to life K3

CO5. Apply the characteristics of electronic devices in practicals. K3

PS019

Gauss theorem and its proof- field due to uniformly charged sphere –intensity due to a

plane sheet of charge-Coulomb’s theorem-Principle of a capacitor-capacity of a parallel plate and

spherical capacitor-energy stored in a capacitor-loss energy due to sharing of charges

Unit - II 11Hrs

Current Electricity and electromagnetism:

Kirchoff’s laws-explanation- Wheatstone’s network-Potentiometer-calibration of voltmeter-

calibration of ammeter-comparison of resistances-Biot-Savart’s law –force on a conductor carrying

current in a magnetic field-Ballistic galvanometer- correction for damping-measurement of

capacity of a condenser using B.G.

Unit – III 11Hrs

Alternating currents:

Mean and RMS values of AC -Series and parallel resonant circuits-Power factor- power

factor of an ac circuit containing resistance, inductance and capacitance -Transformer-construction-

working-losses.

Unit – IV 11Hrs

Electronic devices, circuitry and communication:

Zener diode- V-I characteristics-its application in voltage regulation-Transistors-working

characteristic (CE, CB, CC mode)-Biasing-potential divider method-Single stage amplifier (CE)-

frequency response-feedback principle-Barkhausen criterion for sustained oscillations-Hartley

oscillator

Unit – V 12Hrs

Digital Electronics:

Boolean algebra-DeMorgan’s theorem-OR, AND, NOT, XOR NOR and NAND gates-NOR and

NAND gates as universal building blocks-half adder, full adder-RS flip flop-JK flip flop

Operational amplifier: Characteristics-virtual ground-summing point-inverting and non inverting

amplifier-adder-subtractor.

Text Book

1. R. Murugeshan, Electricity and Magnetism, S.Chand and Co, 2013, 9th

Edition.

2. R. Murugeshan, Allied Physics, S.Chand and Co, 2005, 1th

edition.

Reference Books

1. V.K. Metha, Principles of electronics, S. Chand, 1980, 1st Edition

2. V. Vijayendran, Introduction to Integrated Electronics, Viswanathan Publishers, 2005, 1st

Edition

Pedagogy

PS020

Chalk& Talk, Group Discussion, Demonstration, Problem solving, Seminar, PPT and Assignment

Course Designers:


2. Mrs. T. Poongodi


- - - 82 3

Preamble

To enable the student to gain practical knowledge

Course Outcomes



CO1. PO1 PO2 PO3 PO4 PO5 PO6

CO2. S S S S M S

CO3. S S S S S S

CO4. S M S M M M

CO5. S M M S M S


PS16AP1

ALLIED PHYSICS PRACTICALS

SEMESTERS I & II

CO


Level

CO1. Gain knowledge in the scientific methods and learn the process of

measuring different Physical variables K1

CO2. Educate The Basics Of Instrumentation, Data Acquisition And

Interpretation of Results K2

CO3. Enhance The Students Understand The Concepts In Materials Properties K2

CO4. Have a deep knowledge of fundamentals of optics, electric circuits,

magnetism and sound K3

PS021

Syllabus

List of Experiments

Any Eighteen

1. Young’s Modulus –Non- Uniform bending –Pin and Microscope

2. Young’s Modulus – Uniform bending – Optic lever

3. Rigidity modulus - Static torsion

4. Rigidity Modulus - torsional pendulum

5. Moment of inertia - torsional pendulum

6. Acceleration due to gravity - compound pendulum

7. Thermal conductivity of a bad conductor – Lee’s disc method

8. AC frequency - Sonometer

9. Refractive index of solid prism - spectrometer

10. Refractive index of liquid-Hollow prism - spectrometer

11. Wave length- Grating - Minimum deviation method - Spectrometer

12. Low range Ammeter Calibration - Potentiometer

13. Low range Voltmeter Calibration - Potentiometer

14. Moment of a magnet in the Tan C position

15. Volt-Ampere characteristic of a p-n junction diode in the forward and reverse directions

16. Logic gates - Verification of the truth table

17. Characteristics of Zener diode

18. Closed loop gain of Operational Amplifier in Inverting mode

19. Closed loop gain of Operational Amplifier in Non Inverting mode.

Pedagogy

Demonstration

Course Designers:

1. Mrs. T. Poongodi



56 4 - 4

Preamble

To give the students fundamental ideas on conservation laws, rotational and vibrational motion of

rigid bodies, projectiles, relativity, and basics on classical approach of Lagrangian mechanics.

Course Outcomes


PS17C03 MECHANICS AND RELATIVITY

PS022



CO1. S

S M S M L

CO2. S

M S S M S

CO3. S M S

S S S

CO4. S M M

S S S

CO5. S M M

S S S


Syllabus

Unit I 11 Hrs

Conservation Law – Collision- Impulse of a force – Fundamental principle of impact-Oblique

impact of a smooth sphere on a fixed smooth plane – Direct impact of two smooth spheres- loss of

K.E due to direct impact of two smooth spheres- oblique impact of two smooth spheres and loss of

K.E due to oblique impact – friction – Laws of friction – angle of friction –cone of friction –

Experimental method for determining co-efficient of friction between two surfaces-Equilibrium of

a body on a rough inclined plane acted upon by an External force.

Unit II 11 Hrs

Rigid Body Dynamics:

Rigid body – rotational and vibrational motion – Torque – moment of inertia – radius of

gyration- kinetic energy of rotation- M.I. of a fly wheel- Experimental determination – Precession

– The gyrostat – gyrostatic applications – M.I. of a diatomic molecule – its rotational energy states.

Unit III

CO


Level

CO1. Understand and define the laws involved in mechanics K1

CO2. Gain deeper understanding of mechanics and its fundamental concepts K2

CO3. Explain the notion of degrees of freedom and identify them for a given

mechanical system. K3

CO4. Provide the students with an idea of relativity which are essential tools

in problem solving. K3

CO5. Provide elementary ideas on classical mechanics and will be able to

write equations for real time problems using classical mechanics. K3

PS023

Projectiles: 11 Hrs

Vertical motion under gravity- motion of particle projected horizontally from a point above

the earth- particle projected in any direction-path of projectile is a parabola- range of projectile on a

plane inclined to the horizontal maximum range on the inclined plane- angle of projection for a

particular range- velocity at a point in the path of a projectile- enveloping parabola.

Unit IV 12 Hrs

Elementary Principles of classical mechanics

Constraints and degrees of freedom – Generalized co-ordinates – Generalized

displacement- velocity – acceleration – momentum – force – potential D’Alembert’s principle

Lagrangian mechanics

Lagrangian differential equation from D’Alembert’s principle – Applications of Lagrange’s

equation of motion to linear harmonic oscillator – simple pendulum compound pendulum

Unit V

Relativity 11 Hrs Frames of reference - Galilean transformation equations- Michelson Morley experiment –

explanation of negative result – postulates of special theory of relativity- Lorentz transformation

equation – Length contraction and time dilation – Twin paradox-addition of velocities – variation

of mass with velocity –Mass energy equivalence.

Books for study:

S.No

Authors Title of the

Book

Publishers Year of

Publication

Edition

1 Murugeshan.R Mechanics

and

Mathematical

Methods

S.Chand &

Co Ltd, New

Delhi

2006 Reprint

2 Mathur D.S Mechanics S. Chand

&Co Ltd,

New Delh

2012

2nd

Edition

3 Narayanamurthi. M

and Nagarathinam.M

Dynamics National

Publishing

Company

1988 Revised Edition

4 Gupta, Kumar &

Sharma

Classical

Mechanics

Pragati

Prakashan

2010 19th

edition

5 R.Murugesan Modern

Physics

S. Chand &

Co Ltd

2001 Ninth revised

edition

Books for Reference:

S.No Authors Title of the Publishers Year of Edition

PS024

Book Publication

1 Bhargava& Sharma A Text Book

of Mechanics

Ratan

Prakshan

Mandir

1990

7th

edition

2 Arthur Beiser Concepts of

Modern

Physics

TMH- 2003 6th

edition.

Pedagogy

Chalk and Talk lectures, Group Discussion, Seminar, Interaction, power point presentation

Course Designer

1.Mrs.C.Sharmila


56 4 - 4

Preamble

The aim of this course is i) to acquire in-depth knowledge in electrostatics and magnetostatics so

that students would apply theories of static and moving charges and extend its applications to

instruments involving electric and magnetic fields and ii) to give idea on the fundamentals of

electromagnetic conduction and electromagnetic waves.

Course Outcomes


CO


Level

CO6. Recognize basic terms in electricity and magnetism K1

CO7. Understand the laws of electrostatics and magnetostatics K2

CO8. Apply theorems to construct and solve electrical circuits. K3

CO9. Ability to design and conduct experiments as well as to analyze and

interpret data K4

CO10. Build up strong problem solving skills by effectively formulate a circuit problem

into a mathematical problem using circuit laws and theorems K5


PS17C04 ELECTRICITY AND MAGNETISM

PS025


CO6. S S M L L L

CO7. S S

S S S M

CO8. S S

S S M S

CO9. S S S S

M M

CO10. S S

S S M M


Syllabus

UNIT I 12 Hrs

Electrostatics and Capacitors:

Gauss theorem and its applications:

Gauss’s law, application of Gauss law - Electric field due to uniformly charged sphere,

Electric filed due to an isolated uniformly charged conducting sphere, Electric filed due to uniform

infinite cylindrical charge, Electric filed due to an infinite plane sheet of charge, Field due to two

parallel sheets of charge, Coulomb’s theorem, energy stored in unit volume of an electric field.

Capacitors:

Spherical capacitor, cylindrical capacitor, force of attraction between charged plates of a capacitor,

change in the energy of a parallel plate capacitor when the distance between the plates is altered

and when a dielectric slab is introduced between the plates.

UNIT II 11 Hrs

Alternating currents AC Circuits:

Alternating current relation between current and voltage in pure R,C and L vector diagrams-

Analysis of the AC circuits (with vector diagrams) containing (i) resistance and inductance, (ii)

*capacitance and resistance* and (iii) resistance, inductance and capacitance - LCR series

resonance circuit- Parallel LCR Circuit - Characteristics of LCR Circuit: (1) Resonance, (2)

Quality Factor, (3) Band Width and (4) Sharpness of Resonance - power consumed by the above

circuits.

UNIT III 11 Hrs

Magnetostatics:

Magnetic Vector Potential - Scalar Potential - Magnetic Shell - Potential at any point due to

a magnetic shell - Magnetic Potential and Field at a Point on the axis of a Flat Circular Magnetic

Shell - Equivalence of a Magnetic Shell and Current Circuit – Hall Effect – Magnetic Induction -

Magnetization - Relation between B, H and M - Magnetic susceptibility - Magnetic Permeability -

Properties of Diamagnetic, Paramagnetic, Ferromagnetic Materials.

PS026

UNIT IV 11 Hrs

Magnetic Properties of Matter:

Biot-Savart’s Law – Magnetic Induction at a point due to a straight conductor and circular

coil carrying current – Force between two parallel current carrying conductors – Moving Coil of

Ballistic Galvanometers (BG) – uses - Figure of Merit of BG – Absolute Capacitance of a

Capacitor. Comparison of two Capacitances of BG – Comparison of emf’s of two cells using BG –

Ampere’s circuital Law – Differential Form of Ampere’s Law.

UNIT V 11 Hrs

Electromagnetic induction and Electromagnetic waves Electromagnetic induction:

Faraday’s law (Differential and Integral forms). Lenz’s Law. Self and Mutual Induction.

transformer –Construction, working, energy losses and efficiency. Energy stored in a Magnetic

Field.

Electromagnetic waves:

Types of currents – Displacement current – Significance of displacement current -

Maxwell’s equations in differential form – Maxwell’s wave equation, plane electromagnetic waves

– Transverse nature of electromagnetic waves, Poynting theorem, production of electromagnetic

waves (Hertz experiment)

Books for Study:


Publication

Edition

1 Dr. K. K. Tewari Electricity and

Magnetism

S. Chand & Co

Pvt Ltd

2011 Revised

Edition

2 Brijlal and N.

Subrahmanyam

Electricity and

Magnetism

S. Chand & Co

Pvt Ltd

1990 18th

Edition

3 R. Murugesan Electricity and

Magnetism

S. Chand & Co

Pvt Ltd

2013 5th

Edition

Books for References:


Publication

Edition

1 D C Tayal Electricity and

Magnetism

Himalaya

Publishing

House

1988 2nd

edition

2 Sehgal, Chopra,

Sehgal

Electricity and

Magnetism

S.Chand and

sons

2010 2nd

edition

PS027

3 A S Mahajan, A

A Rangwala

Electricity and

Magnetism

S.Chand and

sons

2007 6th

edition

4 C L Arora Simplified Course

in Electricity and

Magnetism

S.Chand and

sons

1999

1st edition

5 D N Vasudeva Fundamentals of

Electricity and

Magnetism

Tata McGraw-

Hill Publishing

company

1983 2nd

edition

Pedagogy

Chalk and Talk lectures, Group Discussion, Seminar, Interaction and Power Point Presentation

Course Designers:

1. Mrs.N.Priyadharsini


- - 82 4

Preamble

This course introduces students to the methods of experimental physics. Emphasis will be given on

laboratory techniques such as accuracy of measurements and data analysis. The concepts that are

learnt in the lecture sessions will be translated to the laboratory sessions thus providing a hands-on

learning experience such as in measuring the basic concepts in properties of matter, heat, optics,

electricity and electronics.

Course Outcomes


CO


Level

CO6. Understand the usage of basic laws and theories to determine various

properties of the materials given. K1,K2

CO7. Understand the application side of the experiments. K2

CO8. Apply knowledge of mathematics and physics fundamentals and an

instrumentation to arrive solution for various problems. K3

CO9. Use standard methods to calibrate the given high range voltmeter and

ammeter and to measure the elasticity and thickness of the given material. K3

CO10. Use of basic laws to study the spectral properties and optical properties of

the given prism and grating. K3


PS16CP2 CORE PRACTICALS II

PS028


CO6. S S L L L L

CO7. S S S S M M

CO8. S S S S M M

CO9. S S S S M M

CO10. S S S S M M


Syllabus

List of Experiments

1. Young’s Modulus – Uniform Bending – Koenig’s Method

2. i-d curve- μ of the prism- Spectrometer

3. Dispersive Power of Grating – Spectrometer- Wave length of Mercury Spectral Lines by

minimum deviation method

4. Refractive index (μ) of lens – Newton’s rings method

5. Calibration of High Range Voltmeter – Potentiometer

6. i) Verification of Truth Tables of IC Gates: OR, AND, NOT, XOR, NOR, and NAND

ii) Verification of Demorgan’s theorem using Logic Gates

7. Verification of Truth Table of Half and Full Adders

8. Wave length of Mercury Spectral Lines – Grating - Normal Incidence – Spectrometer

9. Young’s Modulus –Non-Uniform Bending – Koenig’s Method

10. Thickness of a thin wire – Air Wedge method

11. EMF of thermocouple – Potentiometer

12. High resistance by i) Charging

ii) Leakage using Ballistic Galvanometer

13. Comparison of Mutual Inductance’s – Ballistic Galvanometer

14. Verification of NAND as a Universal Block

15. Verification of NOR as a Universal Block

16. Verification of Truth Tables of Half and Full Subtractor

Pedagogy:


Course Designers:

1. Dr. G. Praveena

2. Mrs. N. Priyadharsini

PS029


86 6 5

Preamble

This course helps the students to gain basic ideas of the construction and working of electronic

devices and circuits and to understand the fundamentals of communication systems.

Course Outcomes

On the successful completion of the course, students will



CO1. S M S M S M

CO2. S S M S S M

CO3. S S S S S S

CO4. S S S S S S

CO5. S S S S S S


Syllabus

Unit I

Electronic Devices: 17 Hrs

PS16C05 ELECTRONICS

CO


Level

CO1. Be familiar with the basic concepts of construction and working of

electronic devices and optical fibers K1

CO2. Apply the knowledge to understand the working of amplifiers, oscillators

and multivibrators K3

CO3. Understand the principles of modulation and demodulation K2

CO4. Apply the knowledge to understand the working of special types of

diodes K3

CO5. Apply the principles of feedback in amplifiers and oscillators K3

PS030

Kirchoff laws- Network Theorem: Thevenin’s and Nortons theorem -PN junction- formation –

properties - applying voltage-current flow VI characteristics- breakdown voltage and knee voltage.

Zener diode-equivalent circuit-Voltage stabilizer-Bipolar junction Transistor-Characteristics (CE

mode) –graphical analysis of CE configuration- Collector Leakage current- commonly used

transistor Connection- Transistors as an amplifier in CE arrangement – Transistor load line

analysis- Operating point – Field effect transistor- Principle ,working and Schematic symbol –

comparison with bipolar transistor – VI characteristics – Expression for drain current – FET

parameters- Relation among FET parameters –JFET biasing – self bias for JFET –SCR Basic ideas

– Characteristics –SCR in normal operation – SCR as a switch – SCR switching – Unijunction

transistor- Construction – Operation – Equivalent circuit of UJT – Advantages of UJT – UJT

relaxation oscillator.LED voltage and current – advantages – applications - Photo diode-

characteristics-applications-Tunnel Diode.

Unit II 17 Hrs

Amplifiers:

Multistage transistor amplifiers-Role of Capacitors in Transistor Amplifiers-Gain frequency and

bandwidth- Properties of decibel gain- RC coupled amplifier -Transformer coupled amplifier.

Amplifiers with negative feedback-Principles of negative voltage feedback-gain-Advantages of

negative voltage feedback- Principle of negative current feedback-gain-Effects of negative current

feedback- emitter follower.

Operational amplifier: Basic concepts- Ideal Operational Amplifier- Inverting OP-AMP - Non

inverting OP-AMP-Characteristics- CMRR- Applications of OPAMP- inverting amplifier as adder-

Subtractor-differentiator-integrator.

Unit III 17Hrs

Oscillators and Multivibrators

Barkhausen criteria for self sustained oscillations-Hartley oscillator –frequency and

condition for sustained oscillations -Colpitt’s oscillator –frequency and condition for sustained

oscillations-crystal oscillator-Phase shift oscillators-Analysis - Wien bridge oscillator – Analysis.

Astable, monostable and bistable Multivibrators

Unit IV 17Hrs

Modulation & Demodulation

Radio Broadcasting, Transmission and Reception-Modulation-Need for modulation-Types

of Modulation-Amplitude Modulation-Modulation factor-Analysis of Amplitude Modulated wave-

Sideband frequencies in AM waves-Transistor AM modulator-Superheterodyne AM Receiver -

Frequency modulation (FM)- Theory of Frequency modulation – Comparison of FM and AM-

Demodulation-Essentials in demodulation-Phase modulation (PM)-definition–analysis-comparison

of AM, FM and PM -

Unit V 18Hrs

Fiber Optic Communication and special purpose diodes

Fiber construction- Application of Fiber cables. - Propagation of light waves in an optical

fibre – Acceptance angle and Acceptance cone of a fibre – Numerical Aperture (NA) – NA of a

graded Index Fibre – Classification of Optical fibers –Step index Fiber- Step index Monomode

Fiber- Graded index Multimode Fiber

PS031

Tunnel diode- LED-Structures of LED-LED materials - semiconductor Laser diode LED – The

process involved in LEDS – Modulation bandwidth and Spectral Emission of LEDS-PIN photo

detector.

Books for Study:


Publication

Edition

1 MehtaV.K &

Rohit Mehta

Principles of

Electronics

( Unit I,II&III)

Tata McGraw

Hill Publishing

Company

Limited New

Delhi

2012 11th

Edition

2 B.LTheraja Basic Electronics-

Solid State (Unit I and

II)

S.Chand &

Company Ltd

2009 5th

Edition

3 Gupta Kumar Handbook of

Electronics(Unit II)

Pragati

Prakashan

2007 34th

Revised

Edition

3 Dennis Roddy

&John Coolen

Electronic

Communication

(Unit IV)

PHI 1995 4th

edition

2 George

Kennedy &

Bernard Devis

Electronic

Communication

systems (Unit IV)

Tata McGraw-

Hill

2005 28th

Reprint

3 Millman and

Halkias

Integrated Electronics

(Unit II)

Tata Mc Graw

Hill

2005 41st

Reprint

6 Subir Kumar

Sarkar

Optical Fibers and

Fiber Optic

Communication

Systems ( Unit V)

S.Chand &Co 2001 2nd

edition



Publication

Edition

1 Bernard Grob -Basic electronics Tata McGraw-

Hill

2007 2nd

Edition

2 R S Sedha Applied

Electronics

S.Chand 2004 24th

reprint

PS032

Pedagogy


Course Designer

1. Dr. P. Meena

PS033

Preamble

The objective of this paper is to enable the students to have a physical understanding of matter

from an atomic view point. Topics covered include the structure, super conductivity and electrical

properties of matter and its applications.

Course Outcome

On successful completion of the course the students will be able to

CO

number

Statement Knowledge

Level

CO 1 Outline the importance of solid state physics in the

modern society K1

CO 2 Explore the relationships between chemical

bonding & crystal structure and their defects K2

CO 3

Understand the basic properties of metals,

insulators and semiconductors and their

technological applications

K2

CO 4

Extend their knowledge in theoretical

fundamentals of electron theory and super

conductivity

K3

CO 5

Transfer their knowledge level from theoretical

physical subjects towards the understanding of

basic properties of solid state matter

K2 & K3

Mapping with programming outcomes


CO 1 S S S S S S

CO 2 S S S M S S

CO 3 S S S M S M

CO 4 S M S L M S

CO 5 S S S S S S


Syllabus

Unit I 18Hrs

Elementary Crystallography

Introduction- Lattice parameters of an unit cell-Primitive cell- Bravais lattices- crystal structures of

important engineering materials and stacking sequences- coordination number- -density of

PS16C06

SOLID STATE PHYSICS


86 6 - 5

PS034

packing- sc, bcc , fcc and hcc structures- diamond cubic structure-Zinc blend structure-Sodium

Chloride structure- Caesium Chloride structure- Polymorphism and Allotropy

Crystal Planes in Crystals

ntroduction –Nomenclature of crystal directions - Nomenclature of crystal planes-–Miller indices –

Important features of Miller indices of crystal planes – Procedure for finding Miller indices

Perpendicular distance between two parallel planes in a cubic crystal lattice-Important features of

Miller Indices- Crystal imperfections and defects (elementary ideas only)

Unit II

Electron Theory of Metals: 17 Hrs

Introduction, - the Classical Free electron theory – Electrical conductivity of a metal based on

Drude Lorentz theory - Electrical conductivity before steady state- Relaxation Time, Collision time

and mean free path-success of free electron theory-Breakdown of classical theory-The quantum

free electron theory-Electron energies in metals-– Electrical conductivity of a metal from quantum

free electron theory - Fermi-Dirac distribution function and its variation with temperature-Density

of states-Band theory of solids-Electron in a periodic potential - Kronig Penney model of periodic

potential Effective mass of electron and concept of hole--factors affecting conductivity of

conductors-Derivation of Ohm’s law – Thermal Conductivity- Derivation of Coefficient of

Thermal Conductivity due to Conduction electrons-Wiedemann Franz law.

Unit III 17 Hrs

Dielectric Properties

Introduction- Fundamental definitions in dielectrics-Different types of electric

polarization-frequency and temperature effects on polarization-Dielectric loss-Frequency

dependence of dielectric constant-local; field or internal field-Clausius Mossoti relation-

Determination of dielectric constant and dipole moment of a dielectric material-Dielectric

breakdown-Different types of dielectrics-Essential requirements of a good insulating material-

Classification of insulating materials-Applications of insulating and dielectric materials

Unit IV 17 Hrs

Magnetic Properties

Introduction – Different types of magnetic materials – classical theory of dia magnetism (Langevin

theory)- Langevin theory of para magnetism- Weiss theory of para magnetism – Weiss theory of

ferromagnetism (molecular field theory on field magnetism)- Heisenberg interpretation on internal

field and quantum theory of ferromagnetism – domain theory of ferromagnetism – hard and soft

materials

Unit V 17 Hrs

Superconductivity

Introduction – Explanation for the occurrence of superconductivity – General properties of

superconductors-Meissner effect-Type I and Type II superconductors- London equations and

penetration depth- energy gap in superconductors –Supercondutors in A.C fields Thermodynamics

of superconductors –BCS theory - Quantum tunneling- Josephson tunneling – D.C and A.C

Josephson’s effect - Applications of superconductors

PS035

Books for study:


Publication

Edition

1 M. Arumugam Solid state Physics

(Units I to III)

Anuradha agencies 2009 1st

Edition

2 Pillai .S.O Solid state Physics

(Unit IV &V)

New age

International

Private Limited

2011 6th

Edition



Publication

Edition

1 Kittel Solid state

Physics

Wiley student

edition

2007 8th

Edition

2 Gupta and

Kumar

Solid state

Physics

K.Nath & Co 1992 8th

edition

3 Arthur Beiser Concepts of

Modern Physics

Tata McGrew

Hill

2008 6th

edition

4 Dekker Solid state

Physics

Macmillan & Co

limited

1967 1st edition

Pedagogy


Course Designer



56 5 - 5

Preamble

The main objective of this course is to i) train the students to the basic concepts of programming

language ii) to provide exposure to problem solving through programming iii) also create

foundation for students to learn other complex programming languages like C++, Java, etc.,

Course Outcomes


PS16E01 PROGRAMMING IN C

PS036

CO

Number CO Statement

Knowledge

Level

CO1 Understand the fundamentals of C programming K1

CO2 Understand the concepts of operators and arrays K2

CO3 Understand the role of structure and pointers in the program. K2

CO4 Develop a greater understanding of the issues involved in

programming language design and implementation K3

CO5 Write C program for simple applications of real life using

structures K3



CO11. S M M M M M

CO12. S S M M M S

CO13. S S M S S M

CO14. M S S S M M

CO15. S M S M S M


Syllabus

Unit I 11Hrs

Introduction to C

Overview of C - C character set - C tokens - Key words and identifiers-constants- variables

- date types and sizes- declaration of variables –Assigning valued to the variables –Defining

symbolic constants.

Unit II 11 Hrs

Operators and Expressions

Arithmetic operators - relational and logical operators-assignment operators - increment and

decrement operator-Conditional operator-Bit wise and Special operator - Arithmetic expression-

Evaluation of expression – Precedence of arithmetic operations-Type conversion in expressions-

Operator precedence and some computational problems.

Unit III

Statements and Loops 11 Hrs

IF Statement – IF ELSE Statement- Nesting IF ELSE Statements- Switch Statements- the?:

Operator- GOTO Statements-While Statements – DO statements – For Statements- Jumps in loops

PS037

Unit IV 11 Hrs

Arrays and Structures:

One Dimensional array- Two dimensional Array- Initializing two-dimensional Array-

Multidimensional arrays- Dynamic Arrays. Structure definition – Giving values to members-

Structure initialization – Comparison of structure variables- Arrays of Structures – Arrays within

Structure – Structure with in Structures- Structures and Functions

Unit V 12Hrs

Pointers in C

Understanding Pointers-Accessing the address of a variable- Declaring and Initializing

Pointers- Accessing a variable through its pointer- Chain of pointers -Pointer expressions – Pointer

increments and Scale factor-Pointers and Arrays-Pointers and Character Strings- Pointers to

Functions- Pointers and Structures.

Book for Study

Reference Books

S. No Authors Title of the Book Publishers Year of

Publication

1 E. Balagurusamy Programming In

ANSI C

Tata Mc Graw Hill, 6th

Edition. 2012


Publication

1 Byran gottfried Programming with C Tata McGraw Hill, 3

rd

Edition. 2013

2 V.Rajaraman Computer

Programming in C

Prentice Hall of India Pvt

Ltd, 1st Edition.

2004

3 Smarajit Ghosh Programming in C Prentice Hall of India Pvt

Ltd, 1st Edition.

2004

4 Yeswanth

Kanethkar Let us C

BPB Publications, 13th

Edition. 2014

PS038

Pedagogy

Chalk and talk, PPT, Discussion, Assignment, Quiz, Seminar.

Course Designer

1. Mrs. M. Lavanya

5 Martin J

Gentile

An Easy Guide to

Programming in C

Create Space Independent

Publishing Platform, 2nd

Edition

2012

PS039


56 4 - 5

Preamble

The aim of this course is to introduce the students to electron theory of solids and different types of

materials based on their properties.

Course Outcomes


CO


Level

CO11. List the basic concepts of conductors ,dielectric K1

CO12. Understand the basic laws of magnetism K2

CO13. Provide the students with an idea of dielectric and magnetism which are

essential tools in problem solving. K2

CO14. Solve problems based on electron theory of solids and for different

materials K3

CO15. Find applications of the superconductors. K3



CO1. S S S M S L

CO2. S S

S S S M

CO3. S S

S S S S

CO4. S M M S

S S

CO5. S M

S S S S


Syllabus

Unit I

Electron Theory of Solids 11 Hrs

Introduction-the classical free electron theory and the quantum free electron theory-

Electron energy in metals and Fermi energy- density of states- anti-symmetric nature of the wave

functions of the Fermi system – explanation of covalent bonding in crystals- electron in a periodic

potential- energy bands in solids- Brillouin zones – distinction between metals, insulators and

semiconductors- effect mss of electron and concept of hole – the Hall effect.

PS16E02

MATERIALS SCIENCE PAPER I

PS040

Unit II 11 Hrs

Conducting Properties of materials

Introduction- atomic interpretation of ohms law- relaxation time and electrical conductivity

– relaxation time – collision time- mean free path- heat developed in a current carrying conductor-

sources of resistivity of metals and alloys- thermal conductivity- Wiedemann Franz law- thermal

expansion- electrical conductivity at high frequencies- geometrical and magnetic field effects on

electrical conductivity- variation of electrical resistivity due to mechanical stress (strain gauge)-

different types of conducting materials.

Unit III 11 Hrs

Dielectric Properties of materials

Introduction- fundamental definition in dielectric – different types of electric polarization-

frequency and temperature effects on polarization- dielectric loss- local field or internal field –

Clausius- Mossotti relation – determination of dielectric constant – dielectric break down-

properties and different types on insulating materials – Ferro electric materials

Unit IV 11 Hrs

Magnetic Properties of materials

Introduction- different type soft magnetic materials – classical theory of dia magnetism

(Langevin theory)- Langevin theory of para magnetism- Weiss theory of para magnetism- Weiss of

Ferro magnetism (molecular field theory on field magnetism) – Heisenberg interpretation on

internal field and quantum theory of ferromagnetism- domain theory of Ferro magnetism- hard and

soft materials

Unit V 12 Hrs

Superconducting materials

Introduction- explanation for the occurrence of super conductivity – general properties of

super conductors- other general observations- types of superconductors- applications of

superconductors.

Books for Study:


Publication

Edition

1 Arumugam. M Material Science Anuradha

agencies-

Kumbakonam

Revised

1990

1st edition



Publication

Edition

PS041

1 Raghavan Materials and

engineering

Prentice Hall of

India

1990 3rd

edition

2 Vijaya &

Rangarajan

Materials Science Tata McGraw

Hill Publishing

Company Ltd

2005 1st edition

3 Raghavan Materials Science Prentice Hall 1990 13th

edition

Pedagogy :


Course Designer:

1. Ms.A.Anshy Tom Dhanya

PS042

Preamble

The objective of this paper is to introduce the students the basic knowledge of transducers,

recorders and other bio medical instruments and devices.

Course Outcomes



CO1. S M S L L L

CO2. S S

S S M M

CO3. S S

S S M M

CO4. S S S S

S M

CO5. S S

S S S S


Syllabus

Unit I 11 hrs

Electrodes and transducers

Transducers for medical applications-Active transducers-Passive transducers-Electrode

theory-Components of biomedical instrument system-electrodes- microelectrodes-chemical

electrodes

PS16E03

BIO MEDICAL INSTRUMENTATION -

PAPER I


56 4 - 5

CO


Level

CO1. Recognize the technical vocabulary associated with biomedical

Instrumentation. K1

CO2. Understand the uses of various instruments in medicine. K2

CO3. Understand the canonical structure of biomedical instrumentation

systems. K2

CO4. Review the static and dynamic performance characteristics for

instrumentation systems. K3

CO5. Understand the problem and the ability to identify the necessity of

equipment to a specific problem. K4

PS043

Unit II 11 hrs

Different types of transducers-Magnetic induction type-piezoelectric type-thermoelectric type-

capacitive transducers-inductive transducers- linear variable differential transformer

Unit III 11 hrs

Biopotential Recorders-I

Cardiovascular instrumentation-characteristics of recording system-electrocardiography- origin of

cardiac potentials-P,R,T,S-T,Q waves-ECG lead configurations-ECG recording set up-Practical

considerations for ECG recording-

Unit IV 11 hrs

Biopotential Recorders-II

Analysis of ECG signals-Phonocardiography-Heart sounds-Physical characteristics of heart

sounds-Recording set up-Relationship between the heart sounds and function of the cardiovascular

system-Medical applications-special; applications of phonocardiogram

Electroencephalograph(EEG) -recording of evoked potentials-electromyograph

Unit V 12hrs

Physiological Assist devices

Pacemakers-Pacemaker batteries-Artificial heart valves-Defibrillators-Nerve and muscle

stimulators-Heart lung machine-Kidney machine.

BOOKS FOR STUDY


Publication

Edition

1 Arumugam. M Biomedical

Instrumentation

(units II,III, IV&

V)

Anuradha

Publications

2007 1st Edition

2 James Cameron Medical Physics

(Units III , IV& V)

Wiley

publications

1978 1st Edition

BOOKS FOR REFERENCES


Publication

Edition

PS044

1 Leslie Cromwell,

Fred J Weibell

and Erich

A.Pfeiffer

Biomedical

Instrumentation

and Measurements

Prentice Hall

of India

1992 2nd

Edition

Pedagogy


Course Designer:

1. Mrs.S.Sowmya


- - 82 4

Preamble

This course helps the student to acquire practical knowledge to design the basic electrical circuits

using diodes, transistors, etc., The concepts that are learnt in the lecture sessions will be translated

to the laboratory sessions thus providing a hands-on learning experience to design the circuits. It

also provides them to understand the applications of solar cells, qualitative and quantitative

analysis of Chlorophyll II, carbohydrates, proteins, etc.,

Course Outcomes


CO


Level

CO1. Basic laws and theories involving diodes, transistors, solar cells, etc., K1

CO2. Understand the given concepts and its physical significance K2

CO3. Apply the theory to design the basic electrical circuits K3

CO4. Analyze the response of these devices using the circuits constructed.

Qualitative and quantitative analysis of chlorophyll, proteins, etc.,

K4,K5

CO5. Use of these basic circuits to create amplifier circuits, oscillator, regulated

power supplies etc., K6


PS16CP3 CORE PRACTICALS III

PS045


CO1. S S S L L L

CO2. S S S M M L

CO3. S S M S M M

CO4. S S M S S S

CO5. S S M S S S


Syllabus

List of Experiments (Any 16)

1. Determination of Absolute Mutual Inductance – Ballistic Galvanometer

2. Determination of Absolute Capacity- Ballistic Galvanometer

3. Cauchy’s Constants using Spectrometer

4. Dispersive power of a prism using Spectrometer

5. of a prism – Stokes formula – Spectrometer

6. Characteristics of Junction Diode

7. Characteristics of Zener Diode

8. Transistor Characteristics - Common Emitter Configuration

9. Characteristics of FET

10. Characteristics of UJT

11. R-C Coupled Amplifier – Single Stage

12. Emitter Follower

13. Voltage Doubler

14. Regulated low Range power supply

15. Hartley Oscillator - Solid State

16. Colpitt’s Oscillator – Solid State

17. Closed loop Gain Op Amp (Inverting & Non inverting)

18. Op Amp as adder in inverting mode & Subtractor

19. Op Amp as Differentiator & Integrator

20. Op Amp - Astable Multivibrator

21. Characteristics of laser diodes

22. Study of characteristics of photodiode(solar cell)

23. Determination of efficiency of solar cells

24. Qualitative and Quantitative study of Chlorophyll II, Carbohydrates, proteins and Heavy

metal ions.

Pedagogy:


Course Designers:

PS046

1. Dr. G. Praveena


PROJECT

Hours: 45 Subject Code: PS16PR0J

Credits: 5

Objectives:

To make the students understand the importance of experimental and theoretical analysis.

To make the students develop a Scientific approach in solving problems related to physics.

To educate and train the students to write scientific papers.

Project and Viva Voce

Topics in Physics will be assigned to each group of students by the staff coordinator

guiding the project. The project work is to be carried out at the department or any other

organization approved by the staff coordinator and the HoD. Review meeting will be conducted

once in a month. Viva Voce presentation will be conducted by the HoD, internal examiner and the

staff coordinator guiding the project.

Methodology

Each project should contain the following details

Introduction

Literature Survey

Theory / Experimental details

Results and Discussion

Conclusion

Bibliography

The dissertation submitted should have a minimum of 40 pages.

PS047


71 5 - 5

Preamble

This course provides students with a working knowledge of optical physics, including diffraction,

interference, polarisation and spectroscopy, laser physics. This paper aims to impart a detailed

knowledge in Optics & Spectroscopy.

Course Outcomes


CO


Level

CO1. List the basic ideas in image formation and the defects involved. K1

CO2. Understand the central concepts and basic formalisms of interference,

diffraction, polarisation and basics of spectroscopy. K2

CO3. Use of tools needed to formulate problems in optics and spectroscopy. K3

CO4. Gain Fundamental knowledge in lasers, holography and Raman effect. K2,K3

CO5. To impart knowledge related to the concepts of spectroscopy. K3



CO1. S S S L L L

CO2. S M

S S M M

CO3. M S

M S S S

CO4. S S S S

M M

CO5. S M

M S M M


Syllabus

PS16C07 OPTICS AND SPECTROSCOPY

PS048

Unit I 14 Hrs

Geometrical Optics

Spherical aberration in lenses – reducing spherical aberration –Coma – Aplanatic lens- Oil

immersion objective- Astigmatism –Curvature – Distortion – Dispersion – Angular and Chromatic

dispersion – Combination of prisms to produce (i) dispersion – without deviation (ii) deviation

without dispersion – Achromatism in lenses – Achromatic combination of lenses –(i) in contact (ii)

and separated by a distance –Eye pieces-Ramsden’s and Huygen’s eyepiece.

Unit II

Interference 14 Hrs

Interference in thin films due to reflected and transmitted light – Fringes due to wedge

shaped films – Newton’s rings- Determination of wavelength of light- Refractive index of liquid –

Michelson’s interferometer- Applications – Determination of Wavelength, Thickness of a thin

transparent films, Refractive index of gases – Fabry-Perot Interferometer – Antireflection coatings

– Interference filters

Unit III 14 Hrs

Diffraction

Rectilinear propagation of light- Zone plate- action and construction- comparison with

convex lens-Fraunhofer diffraction – Diffraction at single slit, double slit, Diffraction grating

Polarization

Double refraction – Huygen’s explanation in uniaxial crystals – production and detection of

plane, circular and elliptically polarized light – Optical activity – Fresnel’s explanation – Laurent’s

half shade polarimeter.

Unit IV 14 Hrs

Quantum Optics

Lasers

Spontaneous and Stimulated emission – Einstein’s A & B coefficients, Population Inversion

- Metastable states - Optical pumping- Modes of resonators and coherence length, Ruby & He –

Neon lasers

Holography

Basic principle-Making a Hologram-Reconstruction of the image from the Hologram-

Mathematical theory-Applications of Holography-Holographic Interferometry & Microscopy

Unit V 15 Hrs

Spectroscopy

Photoelectric effect-Laws of Photoelectric Emission-Einstein’s photoelectric equation -

Compton effect - X ray spectra- Continuous and Characteristic spectra – Moseley’s law –

Application – Molecular spectra – Spectra of diatomic molecules – Pure rotation spectra-

Vibration, rotation spectra- Selection rules- Raman effect – Experimental study – Raman effect in

solids and gases Explanation of Raman effect – Application of Raman effect in a molecular

spectra

Books for Study

PS049


Publication

Edition

1 Brijlal and

Subramaniam

A Text Book of

Optics

(Units I , II & III)

S. Chand &

Co

2006 23rd

Edition

2 Murugesan. R Modern Physics

(Unit IV & V)

S. Chand

&Co

2013 17th

edition

3 P.K. Chakrabarti Geometrical and

Physical Optics

(Unit V)

New Central

Book Agency

2005 3rd

edition

Books for Reference

S. No Authors Title of the

Book

Publishers Year of

Publication

Edition

1 R. Murugesan Optics and

Spectroscopy

S. Chand &

Co

2012 8th

edition

Pedagogy

Chalk and Talk lectures, Group Discussion, Seminar, Interaction, Power Point Presentation

Course Designer

1. Mrs. S. Subanya

PS050


71 5 - 5

Preamble

The aim of this course is to acquire sufficient knowledge in Properties of matter waves, Wave

equation, Schrodinger equation and applications, Operator formalism and Relativity.

Course Outcomes


CO


Level

CO1. Recognize basic terms in Quantum Mechanics. K1

CO2. Understand the basic principles of quantum particles. K2

CO3. Apply basics to construct and solve one particle

equation. K3

CO4. Ability to design and construct particle equation in the

free and bound states as well as to analyze and interpret

the results.

K4

CO5. To understand the fundamentals and concepts in the

special theory of relativity K5



CO1. S S M L L L

CO2. S S

S S S M

CO3. S S

S S M S

CO4. S S S S

M M

CO5. S S

S S M M


PS16C08 QUANTUM MECHANICS AND

RELATIVITY

PS051

Syllabus

Unit I 14 Hrs

Wave Properties

Dual nature of matter – De Broglie’s concept of, matter waves- Expression for De-Broglie’s

wavelength – Wave pocket – Expression for phase velocity and group velocity and relation

between them – G.P.Thomson experiment – Heisenberg’s uncertainty principal- physical

significance of uncertainty relation – Elementary proof of uncertainty principle - Gamma ray

microscope – Electron diffraction at a slit - Applications – Non-Existence of electrons in the

nucleus – Radius of Bohr’s first orbit of H2 atom and energy in the ground state.

Unit II 14 Hrs

Wave Equation

Wave function for a free particle – Physical interpretation of wave function –

derivation of one dimensional time dependent and time independent Schrodinger’s wave equation-

Orthogonal and normalized wave functions – Eigen functions, Eigen value and Eigen value

equation – Orthogonality of Eigen function – Expectations value – probability current density –

Ehrenfest’s theorem – postulates of quantum mechanics

Unit III 14 Hrs

Operator Formalism

Linear operator –commuting and non-commuting operators –operators for momentum,

kinetic energy and total energy –Hamiltonian operator-commutation relation between position and

momentum and between Hamiltonian and momentum – Hermitian operator and their properties-

Angular momentum operator – commutation relation between Lx, Ly, Lz and L - Ladder operator L+

and L- - Commutation relation between L and position.

Unit IV 14 Hrs

Application of Schrodinger equation

Free states – free particle – rectangular potential barrier – E<V0- reflection and transmission

coefficients- decay – bound states – particle in an infinitely deep one- dimensional potential well-

particle in a rectangular three dimensional box – particle in a one dimensional well of finite depth –

linear harmonic oscillator

Unit V 15 Hrs

PS052

Relativity

General theory of relativity-Frames of reference- inertial frames of reference- Galilean

transformation equations- Michelson Morley experiment – explanation of negative result –

postulates of special theory of relativity- Lorentz transformation equation – Length contraction and

time dilation – addition of velocities – variation of mass with velocity – Einstein’s mass energy

equivalence- relativity of simultaneity- Minkowski’s space time continuum

Books for Study


Publication

Edition

1 S.P. Singh,

M.K. Bagde and

Kamal Singh

Quantum

Mechanics

S. Chand &

Co.

1983 2nd

Edition

2 Sathya Prakash

and Kamal

Singh

Quantum

Mechanics

Kedarnath &

Ramnath Co

2007 New

Edition

3 R. Shankar Principles of

Quantum

Mechanics

Springer 2010 2nd

edition

4 G. Aruldhas Quantum

Mechanics

PHI 2013 2nd

Edition

5 R. Murugeshan Modern Physics S.Chand and

Co

2013 17th

edition

Books for Reference


Publication

Edition

1 R.Eisberg & R.

Resnick

Quantum Physics

Of Atom,

Molecules,

Solids, Nuclei &

Particles

John Wiley 2006 2nd

edition

2 Keith Gibbs Advanced Physics Cambridge

University

Press

1991 2nd

Edition

3 K A I L

Wijewardena

Gamalath –

Landau, L.D.,

Introduction to

Vector spaces in

Physics

Pergamon,

NY

1974 1st

edition

PS053

and Lifshitz

E.M.,

4 R. Shankar Principles of

Quantum

Mechanics

Springer 2010 2nd

edition

5 F. Schwabl, Quantum

Mechanics

Springer 1995 4th

edition

Pedagogy


Course Designer:

1. Dr.G.Praveena

PS054


71 5 - 5

Preamble

The aim of this course is to provide a coherent and concise coverage of traditional atomic and

nuclear physics.

Course Outcomes


CO


Level

CO1. Acquire knowledge of the fundamental physics underpinning atomic and

nuclear physics K1

CO2. Understand the concepts and potential applications of atomic and nuclear

physics K2

CO3. Apply general considerations of quantum physics to atomic and nuclear

system K3

CO4. Analyse production and decay reactions for fundamental particles K4

CO5. Expand and evaluate the theoretical predictions for nuclear reactions. K5



CO1. S S S S L L

CO2. S S

S S S M

CO3. S S

S S M S

CO4. S S S S

L M

CO5. S S

S S M M


PS16C09

ATOMIC AND NUCLEAR PHYSICS

PS055

Syllabus

Unit I : Atomic structure: 14 Hrs

Rutherford’s experiment on scattering of alpha particles-theory of alpha particle scattering-

Experimental verification- Bohr model of the atom-Effect of nuclear motion on atomic spectra -

evidences in favour of Bohr s theory-critical potentials-atomic excitation – Experimental

determination of critical potential : Frank and Hertz experiment- Sommerfeld’s relativistic atom

model – Vector atom model- Quantum numbers associated with the Vector atom model, Coupling

Schemes.

Unit II : Optical Spectra and electronic structure: 15 Hrs

Pauli’s exclusion principle - Some examples of electronic configuration with their modern

symbolic representation - Magnetic moment due to orbital and spin motion – Stern Gerlach

Experiment – Optical spectra- Fine structure of sodium D line- Zeeman effect- Experimental

arrangement, Expression for Zeeman Shift- Quantum mechanical explanation of the normal

Zeeman effect-Anomalous Zeeman effect- Stark effect.

Unit III 15 Hrs

Nuclear Models

Introduction to nucleus - Models of Nuclear structure - Liquid Drop model, Semi empirical

mass formula, Shell model, Magic Nos.

Particle accelerators and detectors

Linear accelerators, Cyclotron, Betatron, GM counter, Ionisation chamber

Radioactivity

Natural radioactivity- properties of alpha, beta and gamma rays, Geiger – Nuttal Law,

Gamow’s theory of α- decay, β- ray spectra, magnetic Spectrograph, origin of line and continuous

spectra, Neutrino theory of β – decay, k- electron capture, Gamma ray – introduction, Origin,

nuclear isomerism, internal conversion, Mossbauer effect.

Unit IV 14 Hrs

Artificial Transmutation of Elements

Discovery of Artificial Transmutation – Rutherford’s Experiment , Bohr’s theory of nuclear

disintegration, Q – value equation- nuclear reactions, energy balance in nuclear reactions.

Nuclear Transmutation

Transmutation by (i) Alpha Particles (ii) Protons (iii) Deutrons (V) Neutrons, Scattering

cross section, and its determination.

Artificial radioactivity

Discovery-preparation of radio elements-applications of radio isotopes.

Unit V 13 Hrs

Nuclear fission and fusion

PS056

Nuclear fission , energy released in fission,chain reaction, Atom bomb, nuclear reactor ,

Breeder reactor, Nuclear fusion , Source of Stellar energy ,thermonuclear reactions, transuranic

elements.

Elementary Particles:

Introduction , classification of elementary particles, four fundamental interactions,

Elementary particle quantum numbers , conservation laws & Symmetry ,Quark model.

Books for Study


Publication

Edition

1 Murugesan R Modern Physics S.Chand &

Co

1994 9th

Edition

Books for References


Publication

Edition

1 H.Semat and

J.R.Albright

Introduction to

Atomic and

Nuclear Physics

Chapman and

Hall Ltd

1972 5th

Edition

2 S.N. Ghoshal Atomic and

Nuclear Physics

S. Chand &

company

1900 1st edition

3 C.L.Arora Atomic and

Molecular

Physics

S Chand &

company Ltd

1999 1st edition

4 Beiser Concepts of

Modern Physics

Tata McGraw

Hill

Publishers

2002 6th

Edition

5 Roy R.R&

Nigam

Nuclear physics Wiley

Eastern Ltd

2017 5th

edition

6 Kenneth S

Krane

Modern Physics John Wiley

and Sons,

2012 3rd

Edition

Pedagogy


Course Designers:

1. Mrs. R. Kasthuri

PS057


86 4 - 5

Preamble

This course deals with the basic concepts of microprocessor, programming instructions and

interfacing concepts.

Course Outcomes


CO


Level

CO1. Basic ideas on microprocessor, memory and I/O devices K1

CO2. Be familiar with the basic concepts of microprocessor architecture and

interfacing K2

CO3. To impart skills in the programming instruction sets of microprocessor K2

CO4. Apply the programming instructions to perform simple programs using

microprocessor K3

CO5. Finding solution for real time applications K4



CO1. S S S S M M

CO2. S S

S S M M

CO3. S S

S S S S

CO4. S M M S

S S

CO5. S M

M S S S


Syllabus

Unit I 17 Hrs

Microprocessors – Microprocessor instruction set and Computer Languages – Microprocessor

Architecture and its operations – Memory – Input and Output devices – Review: Logic devices for

interfacing – 8085 MPU – Memory Interfacing.

PS16E04

MICROPROCESSOR

PS058

Unit II 17 Hrs

The 8085 Programming Model – Instruction Classification – Instruction and Data format - How to

write, Assemble and Execute a simple program – Overview of 8085 instruction Set- Addressing

modes.

Unit III 17 Hrs

Programming Techniques: Looping , counting and indexing – Additional data transfer and 16 bit

Arithmetic instructions – Logical Operations: Rotate and Compare – Stack and Subroutines- BCD

to binary –binary to BCD conversion-binary to ASCII and ASCII to Binary code conversion.

Unit IV 17 Hrs

8085 interrupts – 8255A Programmable peripheral interface –Block diagram – Mode 0: Simple

Input or Output – BSR Mode – Mode1: Input or Output with Handshake – Mode2: Bidirectional

Data transfer- Interfacing keyboard and Seven segment display – 8254 programmable interval

timer – Block diagram – Programming the 8254 – 8254 as a counter - Modes.

Unit V 18 Hrs

8259A programmable interrupt controller – Block diagram – Interrupt operations –Priority

modes and other features - DMA Controller – Basic concepts in serial I/O – Software controlled

asynchronous serial I/O – 8251A Programmable Communication Interface.

Books for Study:


Publication

Edition

1 Ramesh

S.Gaonkar

Microprocessor

Architecture,

Programming and

Applications with

the 8085

Penram

International

Publications

2000 4th

Edition



Publication

Edition

1 Douglas V. Hall Microprocessors

and digital systems

McGraw Hill 1983 1st edition

2 Mohammad

Refiguzzaman

Microprocessor and

microcomputer

based system

Design

Universal

bookstall

1990 2nd

edition

PS059

Pedagogy


Course Designer

1. Dr.J.Balavijayalakshmi


86 4 - 5

Preamble

The aim of this course is to make the students learn the mechanical behavior of materials, testing

methods and different types of modern materials.

Course Outcomes


CO


Level

CO1. List out the different kinds of mechanical behavior of materials K1

CO2. Classify the different types of semiconducting materials K2

CO3. Compare the various non destructive methods of testing materials K2

CO4. Identify the factors affecting mechanical properties of materials. K3

CO5. Identify the various modern engineering materials K3



CO1. S S S L M L

CO2. S S S M M S

CO3. S M M M S S

CO4. M M S L M M

CO5. M M M M L L


PS16E05 MATERIALS SCIENCE PAPER II

PS060

Syllabus

Unit I

Mechanical behavior of Materials 17 Hrs

Introduction – different mechanical properties of engineering materials – creep- factors

influencing creep resistance – theories of creep- fracture- mechanism of brittle facture- ductile

fracture – mechanism of ductile fracture- difference between brittle and ductile fracture- fatigue

fracture- mechanism of fatigue fracture- creep fracture- mechanism of creep fracture – factors

affecting mechanical properties of materials.

Unit II

Semi conducting materials 17 Hrs

Introduction- chemical bond in semi conductors like germanium and silicon- Intrinsic and

extrinsic semiconductors- carrier concentration- carrier concentration in intrinsic semi conductors-

carrier concentration in N type semiconductor- carrier concentration in P type semiconductor-

variation of carrier concentration with temperature in n type semiconductor- conductivity of

extrinsic semiconductors.

Unit – III 17 Hrs

Engineering materials

Introduction- Polymers-ceramics-Super strong materials- Cermets – High temperature

materials – Thermoelectric materials – Electrets – Nuclear engineering materials.

Unit – IV 18 Hrs

Modern materials

Introduction – Metallic glasses – Fiber reinforced plastics – metal matrix composites –

optical materials – Materials for optical sources – Fibre optic materials – Display materials –

acoustic materials and their applications-SAW materials-bio materials-high temperature

superconductors.

Unit – V

Non Destructive Testing 17 Hrs

Introduction – Radiographic methods – Photo elastic methods- Magnetic methods –

Electrical methods – Ultrasonic methods- Visual and other optical methods – Thermal methods –

Surface defect detection – NDT –Equipments used in non destructive testing- metallurgical

microscope- Electron microscope- Coolidge x ray tube – Production of ultrasonic waves –

Magnetostriction ultrasonic generator- Piezoelectric ultrasonic generator.

Books for study


Publication

Edition

PS061

1 M.Arumugam Materials Science Anuradha

agencies-

Kumbakonam

Revised 1990 1st

edition

1987



Publication

Edition

1 S.O.Pillai Solid state Physics New age

International

Private

Limited

2011 6th

Edition

2 Khurmi Sedha Material Science S. Chand &

Co.

2001 4th

edition

Pedagogy

Chalk and Talk lectures, Group Discussion, Seminar, Interaction, Power Point Presentation

Course Designer

1. Dr. Mrs.J.Leona

PS062


86 5 - 5

Preamble

The aim of this course is to acquire knowledge in Mechanical behaviour of Materials, principles of

Diagnostic, therapeutic and other specialized bio medical equipments.

Course Outcomes


CO


Level

CO1. List the basic ideas on X- rays, radiation, sensors, and microwaves and so

on. K1

CO2. Understand the central concepts of X-ray production, infrared radiation,

and biomedical computer applications. K2

CO3. Evaluate the facts about ultrasounds and Anaesthesia, intensive care

monitoring. K2

CO4. Examine the uses of radiation detectors, counters and various other

instruments measuring biological parameters. K3

CO5. Finding, practical applications of equipments in biological fields. K3



CO1. M S S S M M

CO2. M S S S S M

CO3. M M S S S M

CO4. M S S S M M

CO5. S S S S M S


Syllabus

Unit I 17 Hrs

Basics of Diagnostic radiology

Nature of X-rays-production of X-ray-stationary anode tube- X-ray machine- Medical

ultrasound-basic pulse-echo apparatus-pulse repetition frequency generators-transmitter-receiver-

biological effects of ultrasound.

PS16E06

BIO MEDICAL INSTRUMENTATION -

PAPER II

PS063

Unit II

Operation theatre equipment 17 Hrs

Surgical diathermy- Shortwave diathermy-Microwave diathermy-Ultrasonic diathermy-

Therapeutic effect o heat-Range and area of irritation of different diathermy techniques-

Ventilators-Anesthesia Machine-Blood flow meters-Cardiac output measurements-Pulmonary

function analysers-Gas analysers-Blood Gas analysers-Oxymeters-Elements of intensive care

monitoring

Unit III 17 Hrs

Therapeutic equipments Medical

thermography- physics of thermography-infrared radiation- infrared detectors-thermographic

equipment- Physiotherapy equipments: High frequency heat therapy-short wave diatherapy-

diapulse therapy-microwave diatherapy-ultrasonic therapy

Unit IV 17 Hrs

Specialised Medical Equipment

Blood cell counter-Electron Microscope-Radiation detectors-Photo detectors and Colorimeters-

digital thermometer-Audiometers-X-ray tube-X-ray machine-Radiography and fluoroscopy-Image

intensifiers-Angiography-Applications of X-ray examination

Bio telemetry- radiotelemetry systems- problems in implant telemetry-uses.

Unit V 18 Hrs

Computers in Biomedical Instrumentation

The digital computer-Microprocessors-Interfacing the computer with medical instrumentation and

other equipment-Biomedical computer applications

Books for Study:

S.No Authors Title of the

Book

Publishers Year of

Publication

Edition

1 M.Arumugam Biomedical

Instrumentation

(Unit III)

Anuradha

agencies-

Kumbakonam

2007 1st edition


S.No Authors Title of the

Book

Publishers Year of

Publication

Edition

1 James Cameron Medical

Physics (Units

II)

Wiley publications 1978 1st edition

PS064

2 Khandpur R.S Handbook of

Biomedical

Instrumentatio

n

(Unit I)

TMH, Delhi

Publications

2008 1st edition

3 Leslie Cromwell,

Fred J Weibell and

Erich A.Pfeiffer

Biomedical

Instrumentatio

n

and

measurements

Unit IV, V

Prentice Hall of

India

1992 2nd

Edition

Pedagogy


Course Designer:

1. Ms.B.Veena


- - 82 4

Preamble

This course helps the student to acquire practical knowledge in making use of the 8085 ALP and its

logical operation, also develops the program writing skills using C language. The concepts that are

learnt in the lecture sessions will be translated to the laboratory sessions, thus providing a hands-on

learning experience.

Course Outcomes


CO


Level

CO11. Defining the primary functions of 8085 ALP and basic principles of C

programming K1

CO12. Understand the given concepts and its physical significance K2

CO13. Apply the theory to find the solutions of practical problems K3

CO14. Analyze the problem studied through analytical calculation K4,K5

CO15. Acquire problem solving skills and to create more problems based on

physical concepts K6

PS16CP4 CORE PRACTICALS IV

PS065



CO11. S S L L L L

CO12. S S S S M M

CO13. S S S S M M

CO14. S S S S S S

CO15. S S S S S S


Syllabus

List of Experiments

(Any 16)

1. 8085 ALP for 8 bit addition using Memory and register

2. 8085 ALP for 8 bit subtraction using Memory and register

3. 8085 ALP for 8 bit multiplication and division

4. 8085 ALP using control instructions (Increment/Decrement & Rotate)

5. 8085 ALP for finding the biggest and smallest element in the array

6. 8085 ALP to sort the array in ascending and descending order

7. 8085 ALP for BCD to Binary conversion

8. 8085 ALP for Binary to BCD conversion

9. 8085 ALP for Binary to ASCII conversion

10. 8085 ALP for ASCII to Binary conversion.

11. Write a Program that inputs three integers from the key board and prints SUM, AVERAGE,

PRODUCT, SMALLEST and LARGEST of THREE NUMBERS

12. Write a program to arrange a set of numbers in ascending order using SELECTION SORT

13. A palindrome is a string that is spelled the same way forwards and backwards. An example

is “RADAR”. Write a Recursive function to test palindrome and the function return TRUE

if the given string is palindrome and FALSE otherwise. The function should ignore spaces

and punctuation in the string.

14. Write a C program to perform Matrix Addition

15. Write a C program to perform Matrix Multiplication

16. Write a C program to find the number of days elapsed between two dates

17. (a) Write a C program to convert integer in the range 1 to 100 into words

(b) Write a program to find the solution of the given quadratic equation.

18. Write a C program to find the solution for the ground state of hydrogen atom

19. Write a C program to calculate the De Broglie’s wave length

p

h

PS066

20. Write a C program to prove Heisenberg’s Uncertainty Principle

Pedagogy:


Course Designers:

1. Dr. G. Praveena


b.sc (physics) programe outcome · ps01 b.sc (physics) programe outcome po1: to enhance the...

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