Program Specific Outcomes / Course Outcomes
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Department of Physics & Electronics
Program Specific Outcomes Course Outcome
Program Specific Outcomes
M.P.Cs | PSO1 | Acquire strong foundation from fundamental concepts to advanced areas of Mathematics, Physics and Computer science; attain global competency exhibiting analytical, logical, programming and research abilities. |
PSO2 | Develop proficiency in different laboratory techniques and drive zeal to apply the same to the real-world situation. | |
PSO3 | Gain employable skills through interdisciplinary and multidisciplinary knowledge, hands-on coding & computing abilities and inculcate a spirit of lifelong learning adapting to the new demands from industry. | |
M.E.Cs | PSO1 | Acquire strong foundation from fundamental concepts to advanced areas of Mathematics, Electronics and Computer science; attain global competency exhibiting analytical, logical, programming and research abilities. |
PSO2 | Develop proficiency in computing, simulation, and laboratory techniques cultivating thirst for knowledge on emerging technologies in becoming empowered women. | |
PSO3 | Derive employable skills through interdisciplinary and multidisciplinary knowledge, industry exposure for hands-on skills leading to gainful employment. |
Semester 1
PHY101: Mechanics and Waves and Oscillations
At the end of the course, the student would be able to
CO1 | Understand the concepts of Vectors and Newton’s Laws |
CO2 | Understand the concepts of rigid bodies , Apply to rotational motion |
CO3 | Analyze the frames of references, relativity ,length contraction and time dilation. |
CO4 | Apply the wave motion to obtain the equations of motion under different conditions.Create Lissajous patterns |
PHY111: Mechanics and Waves and Oscillations Lab
CO1 | Understand the characteristics of wave motion |
CO2 | Apply to various types of bodies to deduce the time period and also other physical properties |
Semester 2
PHY202: Thermal Physics
At the end of the course, the student would be able to
CO1 | Understand the concepts of thermodynamics and kinetic theory of gasses |
CO2 | Remember the thermodynamic potentials and solve Maxwell’s equations. |
CO3 | Apply the thermodynamic laws to Low temperature Physics and Cryogenics |
CO4 | Understand the Quantum theory and Statistical Mechanics |
PHY212:Thermal Physics Lab
CO1 | Apply the wave properties of light and determine the refractive Index of a liquid, wavelength of a Laser |
CO2 | Evaluate the thermal conductivity of a bad conductor, efficiency of electric Kettle. |
Semester 3
PHY303: Electromagnetic Theory
At the end of the course, the student will be able to
CO1: Understand and Remember the concept of Electric Field, Magnetic Field, Maxwell’s equations, growth and decay of current in various circuits |
CO2: Explain nature of electric field, magnetic field, Ampere’s law, Lenz’s Law, Maxwell’s equations |
CO3: Implement the concepts of electric, magnetic field for various cases |
CO4:Examine and experiment the behavior of different circuits |
PHY313: Electromagnetic Theory
At the end of the course the student will be able to
CO1 | Experiment different Network theorems |
CO2 | Determine time constant etc for LCR Series/Parallel circuits, LR, RC, Circuits |
Semester 4
PHY404: Waves and Optics
At the end of the course, the student will be able to
CO1: Understand concepts of longitudinal and transverse waves, Interference, Diffraction and Polarisation |
CO2: Explain the formation of waves, interference pattern , diffraction pattern and Polarisation effects under different conditions |
CO3: Implement the understanding of various waves and optical concepts for different cases |
CO4:Examine and experiment different interference and diffraction patterns, polarization effects and transverse and longitudinal effects. |
PHY414: Waves and Optics Lab
At the end of the course the student will be able to
CO1 | Experiment the formation of interference and diffraction patterns |
CO2 | Determine the wavelength of the given source of light with the help of interference and diffraction patterns formed |
Semester 5
PHY505: Modern Physics
At the end of the course, the student would be able to
CO1:Understand and Remember Atomic spectra, Molecular spectra, Matter waves, Schrodinger equations, Nuclear and crystal structure |
CO2: Explain different experiments, and experimental effects |
CO3: Implement the experimental understanding to practical applications like, Schrodinger equation etc |
CO4: Examine and Experiment the understanding of various theoretical concepts |
PHY515: Modern Physics lab
At the end of the course the student will be able to
CO1 | Experiment Photoelectric effect, GM Counter |
CO2 | Determine planck’s constant |
Semester- 6
PHY606: Basic Electronics
At the end of the course the student will be able to
CO1: Understand the concept of AC,D C, kirchoff’s laws, Resonance, Network theorems and solve the simple networks using kirchoff laws. |
CO2: Design the transistor Hybrid model circuit and calculate the h parameters |
CO3: Study the V-I characteristics of different semiconductor devices and calculate their parameters |
CO4: Construct basic gates using Universal gates |
PHY616: Basic Electronics
At the end of the course the student will be able to
CO1 | Draw the V-I characteristics of different semiconductor devices and calculate their parameters. |
CO2 | Construct basic gates using Universal gates |
PHY101 Oscillations & Waves
MPCS | PSO1 | PSO2 | PSO3 |
| academic excellence global competency | proficiency in different laboratory techniques Research | lifelong learning employable skill Inter-Multidisciplinary |
CO1 | Understand the concepts of vectors and their significance in various physical phenomena To obtain knowledge of Newton’s laws in translatory motion along with Applications | Implement Time period experiments for simple pendulum and Compound pendulum for the “g” calculations Determination of Moment of Inertia of a rigid body Apply Perpendicular axes theorem on a laminar bi fiar pendulum |
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CO2 | Analyzing the Rigid body motion and rotational dynamics. Understand Euler’s equations and tensor representation Apply Euler’s equations to conservation energy and angular momentum | Investigate the oscillations in a Torsional pendulum and calculate the material’s rigidity modulus |
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CO3 | Analyze Central forces and their conservative nature. Discuss the theory of Relativity and length contraction and time dilation leading to Astronomical applications |
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CO4 | Implement the knowledge of wave motion and wave equations for damped oscillators, applications in real world | Examine the damping phenomena in various types of oscillations and Lissajous patterns for unknown frequency Correlate the damping factors and study the viscosity of a fluid |
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PHY202 Thermal Physics
MPCS | PSO1 | PSO2 | PSO3 |
| academic excellence global competency | proficiency in different laboratory techniques Research | lifelong learning employable skill Inter-Multidisciplinary |
CO1 | Understand the concepts of Heat and Thermodynamics and its significance in radiation physics To remember the Laws of thermodynamics and study the Maxwell’s equations To apply the knowledge of transport phenomena in gases |
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CO2 | Deduce Maxwell’s thermodynamic potentials, understand Entropy and its significance | To investigate the Thermal conductivity of a Bad conductor and Cooling curve in heat transfer experiments |
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CO3 | To Analyze the Low temperature cryogenics and refrigeration process To explore the cooling phenomena of helium gas through different techniques | To evaluate the specific rotatory power of an optically active substance through Polarization experiment |
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CO4 | To implement the basic knowledge of statistics to various ensembles and analyze the distribution of energy of gas molecules | Understand the Laser fundamentals and apply for diffraction phenomena Evaluate the resolving power of a telescope |
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PHY303- Electromagnetic Theory
MPCS | PSO1 | PSO2 | PSO3 |
| academic excellence global competency | proficiency in different laboratory techniques Research | lifelong learning employable skill Inter-Multidisciplinary |
CO1 | Understand the concept of Electric Field, Magnetic Field
Remember Faraday’s Laws, Lenz’s Laws and Maxwell’s Equations
Discuss and describe the growth and decay of currents in various circuits |
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CO2 | Sketch the nature of Electric Field and Electric Potential
Implement Ampere’s law for straight, circular and solenoidal currents
Execute Maxwell’s equations in vacuum and dielectric medium
Solve relation between current and voltage in pure components |
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CO3 |
| Question and Test the working of Ballistic Galvanometer
Investigate the transverse nature of Electromagnetic Waves
Construct ac circuits to determine power |
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CO4 |
| Solve the calculation of electric field from electric potential
Examine transfer of energy with Poynting Theorem
Describe AC and DC motors |
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PHY404- Waves and Optics
MPCS | PSO1 | PSO2 | PSO3 |
| academic excellence global competency | proficiency in different laboratory techniques Research | lifelong learning employable skill Inter-Multidisciplinary |
CO1 | Describe the fundamentals of Waves
Define Interference, Diffraction and Polarisation |
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CO2 |
| Experiment the formation of Interference Fringes
Examine the arrangement and formation of Diffraction Fringes
Formulate and analyze the formation of Polarized light
Investigate the propagation of Transverse and longitudinal waves
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CO3 | Discuss different polarization techniques
| Investigate the formation of Newton’s rings using different liquids
Distinguish between Fresnel and Fraunhofer Diffraction
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CO4 |
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ELECTRONICS
Circuit Analysis ELE101
MECS | PSO1 | PSO2 | PSO3 |
| academic excellence global competency | proficiency in different laboratory techniques Leadership empowerment | lifelong learning employable skill Inter-Multidisciplinary |
CO1 | Understand the concept of AC,DC,kirchoff’s laws,Resonance,Network theorems,working of CRO, Design and study working of Filters, integrator , differentiator and resonance circuits. |
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CO2 |
| Design and simulate filter,differentiator and Integrator circuits |
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CO3 |
| Solve the networks using kirchoff’s laws,network theorems, node analysis and mesh analysis |
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CO4 |
| Examine the different AC waveforms using CRO and calculate the time period and frequency of a wave |
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Electronic Devices ELE202
MECS | PSO1 | PSO2 | PSO3 |
| academic excellence global competency | proficiency in different laboratory techniques Leadership empowerment | lifelong learning employable skill Inter-Multidisciplinary |
CO1 | Understand the concept of semiconductors,working of different semiconductor devices |
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|
CO2 |
| Design the transistor Hybrid model circuit and calculate the h parameters |
|
CO3 |
| Study the V-I characteristics of different semiconductor devices and calculate their parameters |
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CO4 |
| Different semiconductor devices applications in daily life |
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Analog Circuits ELE303
MECS | PSO1 | PSO2 | PSO3 |
| academic excellence global competency | proficiency in different laboratory techniques Leadership empowerment | lifelong learning employable skill Inter-Multidisciplinary |
CO1 | Understand the working of different types of rectifiers, regulated power supply and filter circuits,Design and study the working of amplifier circuits |
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CO2 |
| Design a regulated power supply , Amplifier and oscillator circuits. Simulation of circuits |
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CO3 |
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| Implementing simple projects |
CO4 |
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| Sensitizing on the design of energy saving devices |
Linear Integrated circuits & Basics of Communication ELE404
MECS | PSO1 | PSO2 | PSO3 |
| academic excellence global competency | proficiency in different laboratory techniques Leadership empowerment | lifelong learning employable skill Inter-Multidisciplinary |
CO1 | Analysing the block diagram of op amp,IC Timer circuits and applications. |
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CO2 |
| Develop op-amp based projects |
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CO3 |
| Solve numerical problems to compare the different limits of modulation.Compare the analog and digital modulation techniques. |
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CO4 |
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| Real world applications of Electronic modulation |
Digital Electronics & Communications ELE505
MECS | PSO1 | PSO2 | PSO3 |
| academic excellence global competency | proficiency in different laboratory techniques Leadership empowerment | lifelong learning employable skill Inter-Multidisciplinary |
CO1 | Understand the different logic gates , Construction and working of Basic Logic gates. NAND/NOR as universal gates Simplifying Boolean expressions using Boolean identities and DeMorgan’s laws. K-map – Product of sums and Sum of products.working of different types of memories . |
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CO2 |
| Construction and working of flip flops,counters ,shift registers |
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CO3 |
| Develop projects in daily life using the logic gates |
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CO4 |
| Simulation of electronic circuits . |
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Embedded Systems and Microcontrollers ELE607
MECS | PSO1 | PSO2 | PSO3 |
| academic excellence global competency | proficiency in different laboratory techniques Leadership empowerment | lifelong learning employable skill Inter-Multidisciplinary |
CO1 | Understand the Shanon’s theorem , analyze different signals, compare different modulation techniques . |
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CO2 |
| Different modulation techniques – comparison |
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CO3 |
| Solve the errors in the transmission systems with the help of different detection techniques |
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CO4 |
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| Different modulation techniques – comparison |
M.P.Cs | PSO1 | Acquire strong foundation from fundamental concepts to advanced areas of Mathematics, Physics and Computer science; attain global competency exhibiting analytical, logical, programming and research abilities. |
PSO2 | Develop proficiency in different laboratory techniques and drive zeal to apply the same to the real-world situation. | |
PSO3 | Gain employable skills through interdisciplinary and multidisciplinary knowledge, hands-on coding & computing abilities and inculcate a spirit of lifelong learning adapting to the new demands from industry. | |
M.E.Cs | PSO1 | Acquire strong foundation from fundamental concepts to advanced areas of Mathematics, Electronics and Computer science; attain global competency exhibiting analytical, logical, programming and research abilities. |
PSO2 | Develop proficiency in computing, simulation, and laboratory techniques cultivating thirst for knowledge on emerging technologies in becoming empowered women. | |
PSO3 | Derive employable skills through interdisciplinary and multidisciplinary knowledge, industry exposure for hands-on skills leading to gainful employment. |
Course Outcome
B.Sc Electronics
Semester- I
Circuit Analysis ELE101
At the end of the course the student will be able to
CO1: Understand the concept of AC,D C, kirchoff’s laws, Resonance, Network theorems, working of CRO, Design and study working of Filters, integrator , differentiator and resonance circuits.
CO2:Design and simulate filter, differentiator and Integrator circuits.
CO3:Solve the networks using kirchoff’s laws, network theorems, node analysis and mesh analysis
CO4:Examine the different AC waveforms using CRO and calculate the time period and frequency of a wave
Circuit Analysis ELE111
At the end of the course the student will be able to
CO1: Solve the network theorems using complicated networks and prove the kirchoff laws
CO2: Design and simulate the filters,integrator ,differentiator circuits and calculate the resonant frequency of resonant circuits.
Semester- II
Electronic Devices ELE202
At the end of the course the student will be able to
CO1:Understand the concept of semiconductors,working of different semiconductor devices
CO2:Design the transistor Hybrid model circuit and calculate the h parameters
CO3:Study the V-I characteristics of different semiconductor devices and calculate their parameters
CO4:Apply different semiconductor devices in daily life.
Electronic Devices ELE212
At the end of the course the student will be able to
CO1: Understand the V-I characteristics of different semiconductor devices and calculate their parameters.
CO2:Design and Simulate the voltage regulator circuit.
Semester- III
Analog Circuits ELE303
At the end of the course the student will be able to
CO1:Understand the working of different types of rectifiers, regulated power supply and filter circuits,Design and study the working of amplifier circuits
CO2:Design a regulated power supply , Amplifier and oscillator circuits. Simulation of circuits
CO3:Implement simple projects
CO4:Create energy saving devices
Analog Circuits Lab ELE313
At the end of the course the student will be able to
CO1: Create a regulated power supply
CO2: Design and analyze the oscillators.
Semester – IV
Linear Integrated circuits and Basics of Communication ELE404
At the end of the course the student will be able to
CO1: Analyze the block diagram of op amp,IC Timer circuits and applications.
CO2: Develop op-amp-based projects
CO3: Solve numerical problems to compare the different limits of modulation
CO4:Compare the analog and digital modulation techniques.
Linear Integrated circuits and Basics of Communication lab ELE414
At the end of the course the student will be able to
CO1:Develop projects using timers.
CO2:Conceptualize the modulation technologies
Semester – V
Digital Electronics & Communications ELE505
At the end of the course the student will be able to
CO1: Understand daily life applications of Basic Logic gates
CO2: Analyze the steps to simplify the circuit construction and minimalistic hardware.
CO3: Evaluate flip flops and develop working projects
CO4: Create display counters.
Digital Electronics & Communications Lab ELE515
At the end of the course the student will be able to
CO1: Create basic gates using Universal gates, Apply minimalistic hardware.
CO2: Evaluate Sequential Circuits and Create display counters.
Semester – VI
Embedded Systems and Microcontrollers ELE606
At the end of the course the student will be able to
CO1: Understand the fundamentals of microcontrollers
CO2: Analyze the steps involved in an Embedded Product Development Lifecycle
CO3: Develop Programming skills in Embedded Systems for various sensor based applications
CO4: Create modules for real time projects
Embedded systems and Microcontrollers Lab ELE616
At the end of the course the student will be able to
CO1: Create program for the hardware implementation as per real time requirements
CO2: Evaluate the functionality of the hardware as per the developed program
BSc Physics
Semester 1
PHY101 Mechanics and Waves and Oscillations
At the end of the course, the student would be able to
CO1:Understand the concepts of Vectors and Newton’s Laws
CO2:Understand the concepts of rigid bodies , Apply to rotational motion
CO3:Analyze the frames of references, relativity ,length contraction and time dilation.
CO4:Apply the wave motion to obtain the equations of motion under different conditions.Create Lissajous patterns
PHY111: Mechanics and Waves and Oscillations
CO1:Understand the characteristics of wave motion
CO2:Apply to various types of bodies to deduce the time period and also other physical properties
Semester 2
PHY202: Thermal Physics
At the end of the course, the student would be able to
CO1:Understand the concepts of thermodynamics and kinetic theory of gasses
CO2: Remember the thermodynamic potentials and solve Maxwell’s equations.
CO3: Apply the thermodynamic laws to Low temperature Physics and Cryogenics
CO4:Understand the Quantum theory and Statistical Mechanics
PHY212:Thermal Physics Lab
CO1:Apply the wave properties of light and determine the refractive Index of a liquid, wavelength of a Laser
CO2:Evaluate the thermal conductivity of a bad conductor, efficiency of electric Kettle.
Semester 3
PHY303: Electromagnetic Theory
At the end of the course, the student will be able to
CO1: Understand and Remember the concept of Electric Field, Magnetic Field, Maxwell’s equations, growth and decay of current in various circuits
CO2: Explain nature of electric field, magnetic field, Ampere’s law, Lenz’s Law, Maxwell’s equations
CO3: Implement the concepts of electric, magnetic field for various cases
CO4:Examine and experiment the behavior of different circuits
PHY313 Electromagnetic Theory
At the end of the course the student will be able to
CO1:Experiment different Network theorems
CO2:Determine time constant etc for LCR Series/Parallel circuits, LR, RC, Circuits
Semester 4
PHY404: Waves and Optics
At the end of the course, the student will be able to
CO1: Understand concepts of longitudinal and transverse waves, Interference, Diffraction and Polarisation
CO2: Explain the formation of waves, interference pattern , diffraction pattern and Polarisation effects under different conditions
CO3: Implement the understanding of various waves and optical concepts for different cases
CO4:Examine and experiment different interference and diffraction patterns, polarization effects and transverse and longitudinal effects.
Waves and Optics Lab PHY414
At the end of the course the student will be able to
CO1:Experiment the formation of interference and diffraction patterns
CO2:Determine the wavelength of the given source of light with the help of interference and diffraction patterns formed
Semester 5
PHY505: Modern Physics
At the end of the course, the student would be able to
CO1:Understand and Remember Atomic spectra, Molecular spectra, Matter waves, Schrodinger equations, Nuclear and crystal structure
CO2: Explain different experiments, and experimental effects
CO3: Implement the experimental understanding to practical applications like, Schrodinger equation etc
CO4: Examine and Experiment the understanding of various theoretical concepts
Modern Physics lab PHY515
At the end of the course the student will be able to
CO1:Experiment Photoelectric effect, GM Counter
CO2:Determine planck’s constant
Semester- VI
Basic Electronics PHY606
At the end of the course the student will be able to
CO1: Understand the concept of AC,D C, kirchoff’s laws, Resonance, Network theorems and solve the simple networks using kirchoff laws.
CO2: Design the transistor Hybrid model circuit and calculate the h parameters
CO3: Study the V-I characteristics of different semiconductor devices and calculate their parameters
CO4: Construct basic gates using Universal gates
Basic Electronics PHY616
At the end of the course the student will be able to
CO1: Draw the V-I characteristics of different semiconductor devices and calculate their parameters.
CO2: Construct basic gates using Universal gates