rayat shikshan sanstha’s karmaveer bhaurao patil college ... · each paper shall consist of four...

Rayat Shikshan Sanstha’s

Karmaveer Bhaurao Patil College, Vashi, Navi Mumbai

Autonomous College

[University of Mumbai]

Syllabus for Approval

Sr.

No. Heading Particulars

1 Title of Course S.Y.B.Sc. Physics

2 Eligibility for Admission F.Y.B.Sc. [of any recognized

University]

3 Passing marks

4 Ordinances/Regulations

(if any)

5 No. of Years / Semesters One Year / Two Semesters

6 Level U.G.

7 Pattern Semester

8 Status New

9 To be implemented from

Academic year 2019-2020

AC – 02 / 03 / 2019

Item No – 2.41

Rayat Shikshan Sanstha’s KARMAVEER BHAURAO PATIL COLLEGE, VASHI.

NAVI MUMBAI (AUTONOMOUS COLLEGE)

Sector-15- A, Vashi, Navi Mumbai - 400 703

Syllabus for S.Y.B.Sc. In Physics

Program: B.Sc. Physics

Course: S.Y.B.Sc. Physics

(Choice Based Credit, Grading and Semester System

with effect from the academic year 2019-2020)

Preamble of the Syllabus:

This is a part of the undergraduate programme (Six Semesters) in Physics, to be taught in Semester III

& IV from the academic year 2019-20 onwards.

Developing Curriculum that is progressive and purposeful to create positive improvement in the

education system is the logic behind this revision.

All three courses in each Semester are devoted to core Physics, catering to Mechanics, Waves and

Oscillations, Electromagnetism and Optics, Analog Electronics, Thermodynamics and Materials

Science, Wave Mechanics and Digital Electronics. These have been tailored to fit in with the existing

FYBSc syllabus (Sem I and Sem II) in terms of continuity and to ensure delivery of quality content to

the learner.

The science of Physics has diversified immensely in recent times and numerous new fields in Physics,

such as Laser and Fiber Optics, Instrumentation and Radio Communication, Geo-Physics, Biophysics,

and Radiation Physics, Materials Science etc. have come into existence. The fundamentals and the

generality of many principles of Physics are common to all these specialized diverse fields. Most

problems in applied areas have been discussed intensely in academic conferences and journals, but

have not found their place in regular curriculum.

By considering scope and challenges of interdisciplinary and application- oriented courses will be

designed in each semester and those will be supplementary to the main curriculum. In future, we will be

providing the choice / option as far as these supplementary courses are concerned, so that the learners

across various subjects and streams can offer these courses as per their choice. These courses will

seek to foster a spirit of multidisciplinary approach in learning.

The 'practical' component in these supplementary courses will be seen as a combination of laboratory

sessions, a visit to a Research Institute / Industry, mini project, an assignment on a relevant topic etc.

For the various units, experts will guide as 'Resource Persons' and their laboratories/ departments

could serve as Resource Centers. Faculty members/Teachers can avail of their expertise to train

themselves in the delivery of these courses whenever required.

SYLLABUS FOR S. Y. B. Sc. PHYSICS (THEORY & PRACTICAL)

Course code Title

Credits

Semester III

UGPH301 Mechanics, Oscillations and Sound

2

UGPH302 Electromagnetism and optics

2

UGPH303 Analog Electronics

2

UGPHP03 Practical – III

3

Total = 09

Semester IV

UGPH401 Thermodynamics and Materials Science

2

UGPH402 Wave Mechanics

2

UGPH403 Digital Electronics

2

UGPHP04 Practical – IV

3

Total = 09

SCHEME OF EXAMINATION (THEORY COURSES) FOR EACH SEMESTER Continuous Internal Assessment: 40 Marks

(Unit Test - 20 Marks & 20 Marks for- Assignment, Oral, Open Book Test, Poster, Conf / Sem / WS, Visit to Res. Institute etc.)

Semester End Examination: 60 Marks (2 hrs duration) will be as follows:

I. Theory:

Each theory paper shall be of TWO Hours duration.

Each paper shall consist of FOUR questions. All questions are compulsory and will have internal options.

Q – I : is from Unit – I (15 Marks)

Q – II : is from Unit – II (15 Marks)

Q – III : is from Unit – III (15 Marks)

Q – IV : will consist of questions from all the THREE Units with equal weightage of marks allotted to each Unit. (15 Marks)

II. Practicals:

The External examination per practical course will be conducted as per the following scheme.

Sr. No.

Particulars of External Practical Examination Marks%

1 Laboratory Work ( 3 Expts to be performed) 120

2 Journal 15

3 Viva 15

TOTAL 150

A candidate will be allowed to appear for the practical examination only if the candidate submits

a certified journal of SYBSc Physics or a certificate from the Head of the Department to the

effect that the candidate has completed the practical course of SYBSc Physics as per the

minimum requirements.

Program Outcomes: Students having an academic background of science at 10+2 level can pursue

B.Sc programme in various branches. After the completion of the B.Sc degree there are various options

available for the science students, they can pursue master degree in Science i.e. M.Sc, work in

research related fields and can even look for professional job oriented courses. Often, in some reputed

universities or colleges the students are recruited directly by MNC’s after the completion of the course.

The student is also eligible for the job of a Medical Representative. The student after graduating will be

eligible for various government exams conducted by UPSC, MPSC, IBPS, SSC etc.

Program Specific Outcomes: After successful completion of B.Sc.(Hons.) Physics program, students

will be able to:

understand the in depth knowledge of various subjects of Physics.

demonstrate skills and competencies to conduct wide range of scientific experiments.

identify their area of interest in academics, research and development

perform job in various fields’ viz. science, engineering, education, banking, business and public

service, etc. with precision, analytical mind, innovative thinking, clarity of thought and

expression, systematic approach.

SEMESTER - III

Name of the Duration Semester Subject

Program

B.Sc.in Physics Six semesters I Physics

Course Code Title Credits

UGPH301 Mechanics, Oscillations

and Sound 2

Course Outcomes: On successful completion of this course, Students will be able to:

articulate and describe the relative motion, Inertial and non-inertial reference frames.

understand the dynamics of system of particles.

understand the concept of Centre of mass and inertia of mechanical systems.

understand the elastic property of the materials.

understand SHM and its superposition

understand the un-damped oscillations and damped oscillations.

demonstrate Doppler Effect in sound and light.

understand the basics of acoustics of the buildings.

PAPER ‐ 1: Mechanics, Oscillations and Sound COURSE NO.: UGPH301: (45 lectures, 2 credits)

Unit - I Mechanics and properties of matter (13 Lect. + 02 Tutorials)

Dynamics of system of particles: Concept of rigid bodies, C-M co-ordinates, motion of a centre of mass and linear momentum, angular momentum and torque, angular momentum of a system of cm. conservation of angular momentum.

Bending of beams: bending moment, basic assumptions for theory of bending, cantilever and beam supported at its ends and loaded in the middle, i-section girders, determination of y by bending, determination of elastic constants by Searle’s method.

Unit -II Waves and Oscillations (13 Lect. + 02 Tutorials)

SHM: Linear S.H.M., composition of two collinear S.H.M., superposition of two mutually perpendicular S H M, Lissajous figures. Compound pendulum: Expression for period, maximum and minimum time periods, centres of suspension and oscillations, reversible compound pendulum, kater’s reversible pendulum,advantages of a compound pendulum over a simple pendulum. Damped oscillations: Introduction, differential equation of damped harmonic oscillator and its solution,

logarithmic decrement, energy equation of damped oscillations, power dissipation and quality factor,

application to LCR circuit.

Unit -III Sound and acoustics of building (13 Lect. + 02 Tutorials)

Doppler effect, expression for apparent frequency in different cases, asymmetric nature of doppler effect,

doppler effect in light, symmetric nature of doppler effect in light , applications: red shift, violet shift, radar.

Reverberation, sabine’s formula (without derivation) absorption coefficient, acoustics of buildings, factors

affecting acoustics of buildings, sound distribution in an auditorium.

Assignments: should be based on numerical problems related to the syllabus.

References:

1. Resnick and Halliday : Physics – I

2. Mechanics – H. S. Hans and S. P. Puri, Tata McGraw Hill (2nd ED.)

3. Modern Physics Concept and Applications – Sanjeev Puri, Narosa Publication.

4. Properties of matter and Acoustics – R Murugeshan and K. Shivaprasath, S Chand & Co.Ltd. (2005-

Ed)

5. Mechanics and Electrodynamics, Brijlal and Subramanayan and Jeevan Seshan, Rev Edn. 2005.

SEMESTER-III


Programme

B.Sc.in Physics Six semesters III Physics


UGPH302

Electromagnetism

and Optics 2

Course Outcomes: On successful completion of this course students will be able to:

understand the basic laws of electro-statics and magneto-statics

make use of the basic knowledge of e-s and e-m in related applications and be able to perform

calculations using them.

demonstrate quantitative problem solving skills in all the topics covered.

understand the interference, diffraction, polarization and resolving power (of any optical

instruments) processes and applications of them in physical situations.

understand the applications of interference in know the design and working of interferometers.

understand the resolving power and the limitations therein of different optical instruments.


PAPER ‐ 2: Electromagnetism and Optics COURSE NO.: UGPH302: (45 lectures, 2 credits) Unit - I Electromagnetism (13 Lect.+ 02 Tutorials)

Motion of charged particles in uniform electric and magnetic fields: kinetic energy of a charged particle in an

electric field, motion of a charged particle in a constant electric field, charged particle in an alternating

electric field, force on a charge in a magnetic field, charged particle in a uniform and constant magnetic field,

the cyclotron, motion of charged particles in combined electric and magnetic fields.

Unit -II Diffraction (13 Lect.+ 02 Tutorials)

1. Fresnel’s diffraction: Introduction, huygens’s - fresnel’s theory, fresnel’s assumptions, distinction between interference and diffraction, fresnel and fraunhoffer types of diffraction, diffraction due to (a) Straight edge, (b) narrow slit, (c) narrow wire, position of maximum and minimum intensity, intensity at a point inside a geometrical shadow.

2.Fraunhoffer diffraction: Introduction, fraunhoffer diffraction due to (a) a single slit, (b) double slit,

distinction between single slit and double slit diffraction patterns, plane diffraction grating, theory of plane

transmission grating, prism and grating spectra.

Unit -III Polarization and R. P. of Optical Instruments (13 Lect.+ 02 Tutorials)

Review of Interference, Michelson’s Interferometer and its application to determine wavelength of a source.

Polarization: Introduction, the wire grid polarizer and a polaroid, polarization by reflection, polarization by double refraction, malus’ law, superposition of two disturbances, the phenomenon of double refraction, quarter wave plates and half wave plates.

Resolving power of optical instruments: Definition, Rayleigh’s criterion about the limit of resolution. R.P. of (a) telescope, (b) prism, (c) grating.


References:

1. Introduction to Electrodynamics 3rd Ed by D.J. Griffith

2. A Text Book Of Optics By: Dr. N. Subrahmanyam, Brijlal, Dr. M. N. Avadhaanulu (S.Chand, 25th

Revised edition2012 Reprint 2013)

3. Ajoy Ghatak: Optics (5th

Edition)

SEMESTER - III


Program

B.Sc.in Physics Six semesters III Physics


UGPH303 Analog Electronics 2

Course Outcomes: On completion of this, it is expected that the students should be able to …

understand the basics of differential and operational amplifiers and their applications.

understand the basic concepts of oscillators and be able to perform calculations using them.

use IC 555 timer for various timing applications.

design the oscillator circuits using discrete transistors and IC 555.

differentiate between oscillators and multivibrators

understand the basics of filter circuits and their applications in general.

PAPER ‐ 3: Analog Elelctronics COURSE NO.: UGPH303: (45 lectures, 2 credits)

Unit - I Amplifiers and Oscillators (13 Lect. + 02 Tutorials)

Amplifiers: General amplifier characteristics: Concept of amplification, amplifier notations, current gain,voltage gain, power gain, input resistance, output resistance, general theory of feedback, reasons for negative feedback, loop gain, phase reversal, frequency response, decibel gain and band width.

Oscillators: Introduction, effect of positive feedback, requirements for oscillations, phase shift oscillator,

Wien bridge oscillator, Colpitt’s oscillator, Hartley oscillator

Unit -II Operational Amplifier (13 Lect. + 02 Tutorials)

Differential Amplifier: DC and AC analysis of a differential amplifier, Input characteristic-effect of input bias,

offset current and input offset voltage on output, common mode gain, CMRR.

Operational Amplifiers: Introduction, schematic symbol of OPAMP, bandwidth of an OPAMP, slew rate,

frequency response of an OPAMP, OPAMP with negative feedback, inverting amplifier, non-inverting

amplifier, voltage follower, summing amplifier, applications of summing amplifier, OPAMP integrator,

differentiator and comparator.

Unit -III Multivibrators and Active Filters (13 Lect. + 02 Tutorials)

Transistor multivibrators: Astable, Monostable and Bistable multivibrators and Schmitt trigger.

IC555 Timer: Internal block diagram, use of IC555 as an Astable and Monostable Multivibrator.

Active Filter Circuits: Types of filter circuits, first order low pass butterworth filter, first order high pass

butterworth filter, first order butterworth band pass filter and first order butterworth band stop filter


References:

1. Principles of Electronics – V. K. Mehta and Rohit Mehta. (S. Chand – Multicoloured illustrative edition).

2. Electronic devices and circuits – An introduction Allan Mottershead (PHI Pvt. Ltd.– EEE – Reprint –

2013).

3. Electronic Devices And Circuit Theory: Robert Boylestad and Louis Nashelsky (7th/8th Edition Prentice Hall) .

4. Electronic Principles : A. P. Malvino and D.J. Bates (7th Ed.) – (TMH).

SEMESTER - III

Name of the Duration Semester Subject Programme

B.Sc.in Physics

Six semesters

III Physics

Course Code

Title

Credits

UGPHP03 Practical - I 3


understand & practice the skills while performing experiments.

understand the use of apparatus and their use without fear & hesitation.

correlate the physics theory concepts to practical application.

understand the concept of errors and their estimation.

Note: Exemption of two experiments from section A and / or B and / or C may be given if

student carries out any one of the following activity.

collect the information of at least five Physicists with their work or any three events on physics,

report that in journal.

execute a mini project to the satisfaction of teacher in-charge of practical.

participate in a study tour or visit & submit a study tour report.

Regular Experiments: (Min.15 – At Least 04 from each group)

Sr. No. Particulars

GROUP – A 1 Y by bending. 2 Y by vibration

3 Flat spiral spring (n)

4 Helmholtz resonator

5 Optical Lever: determination of μ

6 Coupled oscillations and resonance pendulum

7 Charging and discharging of capacitor

8 Lissajous figures using CRO

GROUP – B 1 LCR series resonance. 2 Figure of merit of a mirror galvanometer

3 Laser beam profile

4 Cylindrical obstacle: determination of λ

5 De Sauty’s bridge

6 Couchy’s constants

7 Polarimeter

8 R.P. of telescope

GROUP – C 1 Opamp: Inverting amplifier with different gains 2 Opamp: Non-inverting amplifier and voltage follower

3 CE amplifier: determination of bandwidth

4 Phase shift oscillator (Transistorised)

5 Wien bridge oscillator (Transistorised)

6 Astable multivibrator (Transistorised)

7 IC555 astablemultivibrator

8 Passive low / high pass filters

Skill Experiments: (All are compulsory)

Sr. No. Particulars

1. Soldering technique

2. Component testing, colour code of resistors, capacitors etc.

3. Use of DMM

4. Travelling microscope ( radius of capillary)

5. Spectrometer: optical leveling and Shuster’s method

Demonstration Experiments: (Min 03)

1. Error analysis of a given experiment

2. Use of CRO

3. Transformer and its types

4. Study of passive band pass filter circuit

5. Audio frequency generator

6. PC Simulation

Minimum 15 experiments (at least 04 from each group) from the list should be completed in the first semester.

All skill experiments and minimum 03 demo experiments are to be reported in journal. Certified journal is must to

be eligible to appear for the semester end practical examination. The scheme of examination for the revised

course in Physics at the Second Year B.Sc. Semester end examination will be as follows.

SEMESTER END PRACTICAL EXAMINATION (There will be no internal assessment for practicals)

For practical examinations, the learner will be examined in three experiments (one from each

group).

Each experiment will be of three hours' duration.

A Minimum 04 from each group and in all minimum 15 experiments must be reported in journal.

All the skill experiments and minimum 03 demo experiments are required to be completed

compulsorily. Students are required to report all these experiments in the journal. Evaluation in

viva voce will be based on regular experiments and skill experiments.

A learner will be allowed to appear for the semester and practical examination only if he

submits a certified journal of Physics or a certificate that the learner has completed the practical

course of Physics Semester III as per the minimum requirements.

SEMESTER - IV


Programme

B.Sc.in Physics Six semesters IV Physics


UGPH401 Thermodynamics and

Materials Science 2


understand the basic concepts of thermodynamics and its applications in physical situations.

get the idea about low temperature physics.


know about the different materials and their classification

know the possible applications of Optical properties of the materials

appreciate the role of Physics in 'interdisciplinary’ areas related to materials.

PAPER ‐ 1: Thermodynamics and Materials Science COURSE NO.: UGPH401: (45 lectures, 2 credits)

Unit - I Thermodynamics I (13 Lect. + 02 Tutorials)

Reversible and irreversible process, Heat engines, definition of efficiency, Carnot’s ideal heat engine,

Carnot’s cycle, effective way to increase efficiency, Carnot’s engines and refrigerator, coefficient of

performance, second law of thermodynamics, Carnot’s theorem, Clapeyron’s latent heat equation using

Carnot’s cycle and its applications

Steam engine, Otto engine, petrol engine, diesel engine.

Unit -II Thermodynamics II (13 Lect. + 02 Tutorials)

Concept of entropy, Change in entropy in adiabatic process, Change in entropy in reversible cycle, Principle

of increase of entropy, Change in entropy in irreversible process.

T-S diagram, Physical significance of Entropy, Entropy of a perfect gas, Kelvin’s thermodynamic scale of

temperature, (Omit alternative method using Carnot cycle), The size of a degree, Zero of absolute scale,

Identity of a perfect gas scale and absolute scale.

Third law of thermodynamics, Zero point energy, Negative temperatures (not possible), Heat death of the

universe.

Unit -III Materials Science (13 Lect. + 02 Tutorials)

Introduction to materials, classification of materials based on structures and their functionality. Types of Materials Metals and alloys, Ceramics, Polymers and Composites, Thin Films, Nanomaterials.

Applications (Optical materials): LEDs, OLEDs, LCDs, Flat Panel Displays, optical fibers Dielectric materials:Piezoelectric, ferroelectric and pyroelectric materials.


References:

1. Thermal Physics, AB Gupta and H. Roy, Book and Allied (P) Ltd, Reprint 2008, 2009.

2. Heat Thermodynamics and Statistical Physics, Brijlal, N.Subramanyam, P.S. Hemne, S. Chand, edition 2007.

3. Materials Science and Engineering: A First Course by V. Raghavan

4. Electronic Properties of Materials, Rolf E Hummel

SEMESTER IV




UGPH402 Wave Mechanics 2


know the limitations of classical mechanics

understand the postulates quantum mechanics

bridge the gap between classical mechanics and quantum mechanics

understand the importance of quantum mechanics in explaining significant phenomena in

Physics.

demonstrate quantitative problem solving skills in all the topics covered

PAPER ‐ 2: Wave Mechanics COURSE NO.: UGPH402: (45 lectures, 2 credits)

Unit - I The Schrodinger wave equation (13 Lect. + 02 Tutorials)

Background Reading (Review): Origin of Quantum Mechanics: 1. Review of Black body radiation, b) Review of photoelectric effects. 2. Matter waves-De Broglie hypothesis. 3. Davisson and Germer experiment. 4. Wave particle duality 5. Concept of wave packet, phase velocity, group velocity and relation between them 6. Heisenberg’s uncertainty principle with thought experiment, different forms of uncertainty. The Schrodinger wave equation

1. Concept of wave function,Born interpretation of wave function.

2. Concepts of operator in quantum mechanics examples – position, momentum and energy operators.

3. Eigenvalue equations, expectation values of operators.

4. Schrodinger equation.

5. Postulates of Quantum Mechanics.

6. Analogy between Wave equation and Schrodinger equation.

7. Time dependent and time independent (Steady State) Schrodinger equation, Stationary State

8. Superposition principle.

9. Probability current density, Equation of continuity and its physical significance.

Unit -II Applications of Schrodinger steady state equation - I (13 Lect. + 02 Tutorials)

1. Free particle. 2. Particle in infinitely deep potential well (one - dimension). 3. Particle in finitely deep potential well (one - dimension). 4. Step potential. 5. Particle in three dimension rigid box, degeneracy of energy state.

Unit -III Applications of Schrodinger steady state equation –II (13 Lect. + 02 Tutorials)

1. Potential barrier (Finite height and width) penetration and tunneling effect (derivation of approximate transmission probability) 2. Theory of alpha particle decay from radioactive nucleus. 3. Harmonic oscillator (one-dimension), correspondence principle.


References:

1. Concepts of Modern Physics – A. Beiser (6th Ed.) Tata McGraw Hill.

2. Quantum Mechanics – S P Singh, M K Bagade, Kamal Singh, - S. Chand : 2004 Ed.

3. Introduction to Quantum Mechanics. - By D. Griffiths Published by Prentice Hall.

4. Quantum Mechanics. - By Ghatak and Lokanathan Published by Mc. Millan.

5. Quantum Mechanics. - By L. I. Schiff.

6. Quantum Mechanics. - By Powell and Crasemann, Addison-Wesley Pub. Co.

SEMESTER - IV




UGPH403 Digital Electronics 2

Course Outcome: On completion of this, it is expected that the students should be able to:

understand the basics of number systems and their inter conversion

understand the basic concepts of combinational and sequential logic families

use of IC 555 timer as a clock and its various timing applications.

understand the basics of flip-flops and various applications of counters and registers.

PAPER ‐ 3: Digital Electronics COURSE NO.: UGPH403: (45 lectures, 2 credits)

Unit - I Number System (13 Lect. + 02 Tutorials)

Binary number system, Binary to Decimal, Decimal to binary, Hexadecimal number, Hexadecimal to decimal

Conversion, Decimal to hexadecimal conversion, Hexadecimal to binary conversion, Binary to hexadecimal

conversion, Binary addition, Unsigned binary numbers, Sign magnitude numbers, 1's complement, 2's

complement , Converting to and from 2's complement representation , 2's complement arithmetic, The adder-

subtractor.

Unit -II Flip-Flops and Data processing circuits (13 Lect. + 02 Tutorials)

Clock: waveforms, TTL clock.

Flip-Flops: RS Flip-Flops, Gated Flip – Flops, Edge triggered R-S FF, Edge triggered D Flip-Flop, J-K Flip-

Flop, JK Master- Slave Flip-Flops, Bounce elimination switch.

Data processing circuits: Multiplexer, de-multiplexer, encoder and decoder.

Unit -III Counters and Registers (13 Lect. + 02 Tutorials)

Counters: Asynchronous counter -3 bit (ignore IC specific diagrams), Synchronous counter only mod 8,

Decade Counters Mod 5 and Mod10.

Registers: Types of registers - Serial in – Serial out, Serial in – Parallel out, Parallel in – Serial out and

Parallel in – Parallel out.


References:

1. Digital Principles and Applications: Donald Leach, A Malvino , Goutam Saha ( 13th Edition) (McGraw Hill Publication).

2. Digital Fundamentals by Thomas L Floyd 10th

edn.

3. Modern Digital Electronics by R P Jain 4th

edn.

SEMESTER - IV


B.Sc.in Physics

Six semesters

IV Physics

Course Code

Title

Credits

UGPHP04 Practical - IV 3


understand & practice the skills while performing experiments.

understand the use of apparatus and their use without fear & hesitation.

correlate the physics theory concepts to practical application.

understand the concept of errors and their estimation.

Note: Exemption of two experiments from section A and / or B and / or C may be given if

student carries out any one of the following activity.

collect the information of at least five Physicists with their work or any three events on physics,

report that in journal.

execute a mini project to the satisfaction of teacher in-charge of practical.

participate in a study tour or visit & submit a study tour report.

Regular Experiments: (Min.15 – At Least 04 from each group)

Sr. No. Particulars

GROUP – A 1 Verification of Stefan’s law ( electrical method) 2 Laser experiments: ruler grating

3 Op-amp integrator / differentiator circuit

4 First order low pass filter circuit

5 LCR parallel resonance

6 Determination of R.I. of liquid by laser

7 μ by total internal reflection

8 Determination of dielectric constant of a material

GROUP – B

1 Transistorized monostable multivibrator 2 IC 555 as monostablemultivibrator

3 Op—amp as astable multivibrator

4 Op-amp as square wave generator

5 Op-amp as a Schmitt’s trigger

6 First order active low pass filter

7 First order active high pass filter

8 First order narrow band pass filter circuit

GROUP – C 1 Half adder and full adder (7486, 7408) 2 Study of multiplexer

3 Study of de-multiplexer

4 Study of encoder / decoder

5 Study of R-S flip flop

6 Study of J-K flip flop

7 Counters 2,5,10

8 Shift registers

Skill experiments (All are compulsory)

Sr. No. Particulars

1 Wiring of a simple circuit using bread board

2 Use of oscilloscope

3 Spectrometer: mean μ of yellow doublet of mercury source

4 Drawing of graph on semi logarithmic / logarithmic scale

5 Radius of ball bearings (single pan balance)

Demonstration experiments (Min. 03)

Sr. No.

Particulars

1 First order active wide band pass / narrow band reject filter circuit

2 Unregulated power supply

3 Regulated power supply

4 Function generator

5 Digital CRO

Minimum 15 experiments (at least 04 from each group) from the list should be completed in the first semester. All

skill experiments and minimum 03 demo experiments are to be reported in journal. Certified journal is must to be

eligible to appear for the semester end practical examination. The scheme of examination for the revised course

in Physics at the Second Year B.Sc. Semester end examination will be as follows.

SEMESTER END PRACTICAL EXAMINATION (There will be no internal assessment for practicals)

For practical examinations, the learner will be examined in three experiments (one from each

group).

Each experiment will be of three hours' duration.

A Minimum 04 from each group and in all minimum 15 experiments must be reported in journal.

All the skill experiments and minimum 03 demo experiments are required to be completed

compulsorily. Students are required to report all these experiments in the journal. Evaluation in

viva voce will be based on regular experiments and skill experiments.

A learner will be allowed to appear for the semester and practical examination only if he

submits a certified journal of Physics or a certificate that the learner has completed the practical

course of Physics Semester III as per the minimum requirements.

rayat shikshan sanstha’s karmaveer bhaurao patil college ... · each paper shall consist of four...

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