Course Outcomes (COs) of Engineering : Physics (BESI-2T)
Sr. No. | Unit No. | CO mapped |
---|---|---|
1 |
Wave Optics |
CO1 |
2 |
Quantum Mechanics |
CO2 |
3 |
Crystal structure |
CO3 |
4 |
Optical Fibre |
CO4 |
5 |
Electron Optics |
CO5 |
Apply concepts in interference and diffraction to solve relevant numerical problems and to relate to relevant engineering applications.
Learn the basic concepts of dual nature of matter and wave packet and apply them to analyze various relevant phenomenon and to solve related numerical problem.
Recall the basic concepts of crystal structure and apply them in solving numerical problems based on them in relating to applications for determination of crystal structure.
Relate the basic idea of total internal reflection to the propagation of light in an optical fiber and make use of the fiber concepts to solve numerical problems and relate to applications in engineering.
Find how to extend the basic concepts of motion of charged particles in electric magnetic fields to solve numerical problems and to relate to applications to electron optic device and CRO.
COURSE OUTCOMES (COS) OF: ADVANCED ENGINEERING MATERIALS (BSEII-2T)
Sr. No. | Unit No. | CO mapped |
---|---|---|
1 | Band theory of Solids |
CO1 |
2 | Semiconductor Devices |
CO2 |
3 | Magnetic and Superconducting Materials |
CO3 |
4 | Lasers |
CO4 |
5 | Nanoscience and Nanomaterials |
CO5 |
Learn the concept of formation of energy bands and to classify solids on its basis.
Identify and explain different types of diodes, transistors and its applications
Learn the concepts of magnetism and superconductivity, classify and analyze various types of magnetic and superconducting materials.
Learn and explain quantum transitions and apply it to working of lasers
Learn the concept of nano materials and compare its properties with those of bulk materials.
COURSE OUTCOMES (COS) OF: Physics CE-BS-102 T
Sr. No. | Unit No. | CO mapped |
---|---|---|
1 | Quantum Mechanics |
CO1 |
2 | Basic Semiconductors |
CO2 |
3 | Lasers |
CO3 |
4 | Optical Fibre |
CO4 |
Recall basic concepts in Quantum mechanics and extend them to interprete Compton effect and Davission and Germer’s experiment, wave packet and Schrodinger’s equation and to solve numerical problems related to it.
Learn the basic concepts of Semiconductors physics and relate them to devices such as diodes and transistors and their technological applications.
Extend the basic concepts of quantum transitions to explain the characteristics, working and applications of different Lasers and to solve relevant numerical problems.
Relate the basic idea of total internal reflection to the propagation of light in an Optical fibre and make use of the fibre concept to solve numerical problems and relate to applications in engineering and technology.
COURSE OUTCOMES (COS) OF: Properties of Matter CE-BS 202 T
Sr. No. | Unit No. | CO mapped |
---|---|---|
1 | Viscosity |
CO1 |
2 | Surface tension |
CO2 |
3 | Crystal structure and X-rays |
CO3 |
4 | Interference of light |
CO4 |
To understand and apply the basic concepts of Viscosity and technological applications related to viscosity. Also apply it to solve relevant numerical problems.
To develop the basic concepts and apply it to solve numerical problems of Surface tension and their applications to technology.
To recall the basic concepts of Crystal structure, X-rays and apply them in solving numerical problems based on them and in relating to applications for determination of crystal structure.
Apply basic concepts of Interference of light and to solve relevant numerical problems and to apply it to technology such as thin film interference, in industry.
COURSE OUTCOMES (COS) OF: Material Science CE -GES-304 T (BGE)
Sr. No. | Unit No. | CO mapped |
---|---|---|
1 |
Bonding in Materials |
CO1 |
2 |
Crystal structure of materials |
CO2 |
3 |
Defects in solids |
CO3 |
4 |
Strength of Materials |
CO4 |
5 |
Biomaterials |
CO5 |
Various bonding between atoms, thermal expansion, elastic modulus and melting point of materials & role of materials selection in design.
Miller Indices, packing of atoms, close-packed structure, ionic solids, glass and polymers.
Different imperfections, impurities, dislocations, defects, and stacking faults.
Different structure and strength of materials, strain behaviour of metals, ceramics and polymers.
Amorphous materials, Polymer nano-composite materials and Environmental Degradation.