18MET-203F: Applied Physics Syllabus for Metallurgical Engineering 2nd Sem C18 Curriculum TSSBTET

Applied Physics detailed Syllabus for Metallurgical Engineering (DMET), C18 curriculum has been taken from the TSSBTET official website and presented for the diploma students. For Course Code, Course Name, Lectures, Tutorial, Practical/Drawing, Internal Marks, Max Marks, Total Marks, Min Marks and other information, do visit full semester subjects post given below.

For all other Diploma in Metallurgical Engineering (DMET) Syllabus for 2nd Sem C18 Curriculum TSSBTET, do visit Diploma in Metallurgical Engineering (DMET) Syllabus for 2nd Sem C18 Curriculum TSSBTET Subjects. The detailed Syllabus for applied physics is as follows.

Prerequisites:

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Course Objective:

After studying this course, the student will be able to understand and appreciate the role of Engineering Physics in different areas of engineering and technology.

Course Outcome:

On successful completion of the course, the student will have the ability to attain below

1. Apply knowledge of waves and sound in engineering problems.
2. Apply knowledge of Simple Harmonic Motion to solve engineering problems
3. Use modern instruments in engineering
4. Use various magnetic materials in engineering equipments
5. Use various electrical measuring instruments as tools in engineering
6. Apply Electronics principles in engineering problems

Unit – 1 Waves and Sound

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Unit – 2 Simple Harmonic Motion

Periodic motion – Simple Harmonic Motion (SHM)- definition – examples – Conditions for SHM – Projection of circular motion on any diameter of a circle is SHM -Expressions for Displacement, Velocity and Acceleration of a particle executing SHM -derivations – Time period, frequency, amplitude and phase of particle in SHM – Ideal simple pendulum – time period of simple pendulum – derivation – laws of simple pendulum -Seconds pendulum – problems.

Unit – 3 Modern Physics

Photo electric effect – Einsteins photo electric equation – Work function and threshold frequency – laws of photo electric effect – applications of photo electric effect – photo cell – concept of Refraction of light – critical angle and total internal reflection – principle of Optical fiber – Applications of optical fiber – LASER – definition and characteristics -principle of LASER – spontaneous and stimulated emission-population inversionexamples of LASER – Uses.

Unit – 4 Magnetism

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Unit – 5 Electricity and Measuring Instruments

Ohms law -Ohmic and non ohmic conductors – examples – Temperature dependence of resistance – coefficients of resistance with examples – Specific resistance – units -conductance- moving coil galvanometer – conversion of galvanometer into ammeter and voltmeter with diagram (qualitatively) – Kirchhoffs current and voltage laws in electricity – Expression for balancing condition of Wheatstones bridge – derivation -Meter bridge -working with neat diagram -Superconductivity-definition-superconductors-definition and examples-applications- related problems.

Unit – 6 Electronics

Solids – definition – energy bands in solids- valence band, conduction band and forbidden band – Energy band diagram of conductors, insulators and semiconductors -concept of Fermi level – Intrinsic semiconductors – examples – Concept of holes in semiconductors – Doping – Extrinsic semiconductor – P-type and N-type semiconductors -PN Junction diode – Forward Bias and Reverse Bias – Applications of PN diode – Diode as rectifier – principle – principle of Light Emitting Diode and solar cell.

References:

For the complete Syllabus, results, class timetable, and many other features kindly download the iStudy App
It is a lightweight, easy to use, no images, and no pdfs platform to make students’s lives easier.
.

Course Outcome:

Upon completion of the course the student shall be able to

Know the Concept of Waves and Sound

• Define wave. Explain the characteristics of wave (frequency, wavelength, amplitude)
• Explain audibility range of sound.
• Define infrasonic and ultrasonic sounds.
• Define longitudinal and transverse wave motion. Write examples for each. Distinguish between them.
• Derive the relation between wavelength, frequency and velocity of wave (v = n/)
• Define stationary waves.
• Explain the phenomenon of beats. List the applications of beats.
• Explain Doppler Effect. List the applications of Doppler Effect.
• Application of Doppler Effect in medicine and engineering – ultrasound and radar.
• Define echo. List the applications of echo.
• Derive the relation between time of echo and distance of obstacle.
• Explain Reverberation and time of reverberation.
• Write Sabines formula and explain the terms.
• Define free and forced vibrations.
• Define resonance with examples.
• State the conditions of a good auditorium.
• Define noise pollution.
• List the effects and methods to minimize noise pollution.
• Solve related numerical problems.

Know the Concept of Simple Harmonic Motion

• Define periodic motion
• Define Simple Harmonic Motion (SHM)
• List the examples of SHM.
• State the conditions of simple harmonic motion
• Projection of circular motion on any diameter of a circle is SHM.
• Derive the expressions for Displacement, Velocity and Acceleration of a particle executing SHM.
• Define the terms time period, frequency, amplitude and phase of particle in SHM
• Define Ideal simple pendulum and derive the expression for time period of simple pendulum.
• State the laws of simple pendulum.
• Define seconds pendulum.
• Solve related numerical problems.

Know the Concept of Modern Physics

• Explain Photo electric effect.
• State Einsteins photo electric equation.
• Define terms work function and threshold frequency.
• State laws of photo electric effect.
• List the applications of photo electric effect.
• Define critical angle.
• Define Total internal reflection.
• State conditions for Total internal reflection
• What is Optical fiber? and explain working principle of optical fiber
• List the applications of optical fiber.
• Explain the principle of LASER.
• Define spontaneous and stimulated emission.
• Define population inversion.
• List the examples of LASER.
• List the uses of LASER.

Know the Concept of Magnetism

• Define magnetic field.
• Define magnetic lines of force.
• State the properties of magnetic lines of force.
• Define Uniform and Non-uniform magnetic field.
• Define the terms magnetic length and pole strength of a bar magnet.
• Define magnetic induction field strength.
• State and explain Coulombs inverse square law of magnetism.
• Derive the expression for moment of couple on a bar magnet placed in a uniform magnetic field.
• Derive the formula for magnetic induction field strength at a point on the axial line of a bar magnet.
• Define Dia, Para and Ferro magnetic materials with examples.
• Solve related numerical problems.

Know the Concept of Electricity and Measuring Instruments

• State Ohms law – Define ohmic and non ohmic conductors with examples
• Explain temperature dependence of resistance – types of temperature coefficients with examples
• Define specific resistance. Write its units.
• Define conductance.
• Write the formulae for effective resistance in series and parallel combination of resistors.
• State and explain Kirchhoffs current and voltage laws in electricity.
• Explain moving coil galvanometer.
• How a galvanometer is converted to ammeter and voltmeter?
• Derive an expression for balancing condition of Wheatstones bridge with legible sketch.
• Explain briefly Meter Bridge with neat diagram.
• Define superconductivity.
• Define superconductor. Give examples.
• List the applications of superconductors.
• Solve related numerical problems.

Know the Concepts of Electronics and Applications

• Define solid.
• Define valence band, conduction band and forbidden band.
• Explain conductors, insulators and semiconductors on the basis of energy band diagram.
• Explain the concept of Fermi level.
• Define intrinsic semiconductors.
• List the examples for intrinsic semiconductors.
• Explain the concept of hole in semiconductors.
• Define doping
• Define extrinsic semiconductors.
• Explain P-type and N-type semiconductors.
• Explain PN Junction Diode (formation only).
• Explain forward and reverse bias of PN diode (biasing and flow of majority and minority carriers with diagram only)
• List applications of PN Diode.
• Explain the principle of diode as a rectifier.
• Explain working principle of Light Emitting Diode (LED)
• Explain the working principle of solar cell.

Suggested Student Activities

1. Student visits Library to refer Text books, reference books and manuals to find their specifications.
2. Student inspects the available equipment in the Physics Lab to familiarize with them.
3. Quiz
4. Seminar
5. Group discussion
6. Surprise test

Course Outcome:

On successful completion of the course, the students will have ability to attain below

1. Understand and explain the different metallurgical processes, alloys and applications of alloys
2. Understand and explain corrosion and preventive methods of corrosion
3. List out the different methods of preparation and industrial uses of plastics, rubber and fibers. vulcanization of rubber and its applications
4. Classify the fuels and explain basic terms of fuel, outline the composition and industrial use of gaseous fuels
5. Under stand and Explain Galvanic cell, emf of cell – electro chemical series-Applications of Galvanic cells, batteries and cells and distinguish the Galvanic and electrolytic cell
6. Explain the causes, effects and controlling methods of air and water pollutions.

For detail Syllabus of all other subjects of Metallurgical Engineering, C18 curriculum do visit Diploma In Metallurgical Engineering 2nd Sem Syllabus for C18 curriculum.

For all Metallurgical Engineering results, visit TSSBTET DMET all semester results direct links.