CO-PO Mapping
Course Outcomes: Mechanics of solid I (3rd Semester)
COs |
Mechanics of solid I(MEC-203A) |
CO1 |
Explain the basic concepts of Engineering Mechanics, simple stresses and strains in simple and compound members and to evaluate the M.O.I. of different shapes. |
CO2 |
Illustrate the concept of stresses on the inclined planes in the body and to evaluate the variations of shear force and bending moment in different kinds of beams subjected to different loading conditions. |
CO3 |
Evaluate the shear stress and angle of deflection in a shaft subjected to torque. |
CO4 |
Evaluate Bending and shear stresses in different shaped channels. |
CO5 |
Determine the buckling in the columns using different theories and to analyze the slope and deflection in the beams |
CO-PO Mapping
CO |
PO1 |
PO2 |
PO3 |
PO4 |
PO5 |
PO6 |
PO7 |
PO8 |
PO9 |
PO10 |
PO11 |
PO12 |
PSO1 |
PSO2 |
CO1 |
3 |
3 |
β |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO2 |
3 |
3 |
β |
2 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO3 |
3 |
3 |
β |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO4 |
3 |
3 |
2 |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO5 |
3 |
3 |
3 |
2 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
AVG |
3 |
3 |
2.5 |
2.6 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
Course Outcomes: Theory of Machine (3rd Semester)
COs |
Theory of Machine (MEC-201A) |
CO1 |
Illustrate the student conversant with commonly used mechanism for industrial application. |
CO2 |
Analyze the velocity and acceleration of a mechanisms analytically and synthesis of problems. |
CO3 |
Construct the cam profile and analyze effect of friction in different mechanisms. |
CO4 |
Determine the static and dynamic forces for mechanical systems and flywheels |
CO5 |
Design of belt and chain drive system |
CO6 |
Design gear mechanisms for a given motion or a given input/output motion or force relationship |
CO-PO Mapping
CO |
PO1 |
PO2 |
PO3 |
PO4 |
PO5 |
PO6 |
PO7 |
PO8 |
PO9 |
PO10 |
PO11 |
PO12 |
PSO1 |
PSO2 |
CO1 |
3 |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO2 |
3 |
3 |
2 |
2 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO3 |
3 |
3 |
2 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO4 |
3 |
2 |
2 |
2 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO5 |
3 |
3 |
3 |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO6 |
3 |
2 |
3 |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
AVG |
3 |
2.7 |
2.4 |
2.5 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
Course Outcomes: Thermodynamics (3rd Semester)
COs |
Thermodynamics (MEC-205A) |
CO1 |
Analyze the work and heat interactions associated with a prescribed process path |
CO2 |
Criticize a different operations on steady flow energy equation |
CO3 |
Define the fundamentals of the first and second laws of thermodynamics and explain their significance to a wide range of systems. |
CO4 |
Evaluate entropy changes in a wide range of processes and determine the reversibility or irreversibility of a process from such calculations. |
CO5 |
Analyze the problems related to Steam and plot the processes on H-S and T-S diagram. |
CO6 |
Understand thermodynamics relations and Maxwell relations. |
CO-PO Mapping
CO |
PO1 |
PO2 |
PO3 |
PO4 |
PO5 |
PO6 |
PO7 |
PO8 |
PO9 |
PO10 |
PO11 |
PO12 |
PSO1 |
PSO2 |
CO1 |
3 |
3 |
β |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO2 |
3 |
3 |
β |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO3 |
3 |
2 |
β |
2 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO4 |
3 |
3 |
3 |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO5 |
3 |
3 |
3 |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO6 |
3 |
2 |
β |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
AVG |
3 |
2.7 |
3 |
2.8 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
Course Outcomes: Wave and optics (3rd Semester)
COs |
Wave and optics (BS-201A) |
CO1 |
Recall the basic phenomenon used in waves and optics. |
CO2 |
Illustration of the concepts of Interference, Diffraction and Polarization and their applications. |
CO3 |
Apply the concepts of wave optics to understand the importance of Laser in Technology. |
CO4 |
Simplify the problems based on the concepts of waveβs optics. |
CO5 |
Summarize of the theoretical knowledge through the experimental results. |
CO6 |
Develop the basic knowledge to create the models and projects. |
CO-PO Mapping
CO |
PO1 |
PO2 |
PO3 |
PO4 |
PO5 |
PO6 |
PO7 |
PO8 |
PO9 |
PO10 |
PO11 |
PO12 |
PSO1 |
PSO2 |
CO1 |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO2 |
3 |
β |
β |
2 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO3 |
3 |
2 |
2 |
2 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO4 |
3 |
2 |
2 |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO5 |
3 |
3 |
3 |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO6 |
3 |
3 |
3 |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
3 |
AVG |
3 |
2.5 |
2.5 |
2.6 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
3 |
Course Outcomes: Higher Engineering Math (3rd Semester)
COs |
Higher Engineering Math (BS-204A) |
CO1 |
Interpret the Laplace Transform of basic functions using the definition |
CO2 |
Apply Laplace Transforms to find solutions of initial value problems for linear ODEs |
CO3 |
Solve Partial Differential Equations, its formation and solutions for muti variable differential equations originated from real world problems |
CO4 |
Explain the theoretical and practical aspects of the use of numerical methods. |
CO5 |
Derive numerical methods for various mathematical operations and tasks, such as interpolation, differentiation, integration, |
CO6 |
Classify with essential tool of Numerical differentiation and Integration needed in approximate solutions for Ordinary differential equations |
CO-PO Mapping
CO |
PO1 |
PO2 |
PO3 |
PO4 |
PO5 |
PO6 |
PO7 |
PO8 |
PO9 |
PO10 |
PO11 |
PO12 |
PSO1 |
PSO2 |
CO1 |
3 |
3 |
β |
2 |
2 |
_ |
_ |
_ |
_ |
_ |
_ |
_ |
3 |
_ |
CO2 |
3 |
3 |
2 |
3 |
2 |
_ |
_ |
_ |
_ |
_ |
_ |
_ |
2 |
_ |
CO3 |
3 |
3 |
2 |
3 |
3 |
_ |
_ |
_ |
_ |
_ |
_ |
_ |
3 |
_ |
CO4 |
3 |
2 |
2 |
2 |
3 |
_ |
_ |
_ |
_ |
_ |
_ |
_ |
3 |
_ |
CO5 |
3 |
3 |
3 |
3 |
3 |
_ |
_ |
_ |
_ |
_ |
_ |
_ |
3 |
_ |
CO6 |
3 |
3 |
3 |
3 |
2 |
_ |
_ |
_ |
_ |
_ |
_ |
_ |
2 |
_ |
AVG |
3 |
2.8 |
2.4 |
2.7 |
2.5 |
_ |
_ |
_ |
_ |
_ |
_ |
_ |
2.7 |
_ |
Course Outcomes: Basic of Electronics Engineering (3rd Semester)
COs |
Basic of Electronics Engineering (ES-203A) |
CO1 |
Understand operation of diodes, transistors, OP-AMP in order to design basic circuits |
CO2 |
Analyze output in different operating modes of different semiconductor devices |
CO3 |
To analyze the different RC and LC oscillator circuits to determine the frequency of oscillation |
CO4 |
To understand the effects of negative feedback on amplifier circuits. |
CO5 |
Acquire knowledge on basic digital electronic gates, Combinational and Sequential Circuits |
CO6 |
Classify with Basic Electronic Communication System. |
CO-PO Mapping
CO |
PO1 |
PO2 |
PO3 |
PO4 |
PO5 |
PO6 |
PO7 |
PO8 |
PO9 |
PO10 |
PO11 |
PO12 |
PSO1 |
PSO2 |
CO1 |
3 |
2 |
3 |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO2 |
3 |
3 |
2 |
2 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO3 |
3 |
3 |
2 |
2 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO4 |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO5 |
3 |
3 |
β |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO6 |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
AVG |
3 |
2.75 |
2.3 |
2.5 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
Course Outcomes: Environmental Science (3rd Semester)
COs |
Environmental Science (MC-901A) |
CO1 |
Β Understand the importance of natural resources. |
CO2 |
Β Illustrate the theoretical and practical aspects of eco system. |
CO3 |
Β Interpret the basic concepts of conservation of biodiversity. |
CO4 |
Β Understand the basic concept of sustainable development. |
CO5 |
Β Understand the transnational character of environmental problems and ways of addressing them, including interactions across local to global scales. |
CO6 |
Β Develop an integrative approach to environmental issues with a focus on sustainability. |
CO-PO Mapping
CO |
PO1 |
PO2 |
PO3 |
PO4 |
PO5 |
PO6 |
PO7 |
PO8 |
PO9 |
PO10 |
PO11 |
PO12 |
PSO1 |
PSO2 |
CO1 |
β |
β |
β |
β |
β |
3 |
3 |
β |
β |
β |
β |
β |
β |
β |
CO2 |
β |
β |
β |
β |
β |
3 |
3 |
β |
β |
β |
β |
β |
β |
β |
CO3 |
β |
β |
β |
β |
β |
2 |
3 |
β |
β |
β |
β |
β |
β |
β |
CO4 |
β |
β |
β |
β |
β |
3 |
3 |
β |
β |
β |
β |
β |
β |
β |
CO5 |
β |
β |
β |
β |
β |
3 |
3 |
β |
β |
β |
β |
β |
β |
β |
CO6 |
β |
β |
β |
β |
β |
2 |
3 |
β |
β |
β |
β |
β |
β |
β |
AVG |
β |
β |
β |
β |
β |
2.7 |
3 |
β |
β |
β |
β |
β |
β |
β |
Course Outcomes: Theory of Machines Lab (3rd Semester)
COs |
Theory of Machines Lab(MEC-207LA) |
CO1 |
Understand different types of mechanisms and their inversions with applications in different machines. |
CO2 |
Analyze of static and dynamic forces on different components of single slider cranks mechanism. |
CO3 |
Determine the moment of inertia of a flywheel. |
CO4 |
Find gyroscopic couple of a motorized gyroscope experimentally. |
CO5 |
Understand design and working of various gear, gear trains, steering systems, belt drives, brakes and dynamometers. |
CO-PO Mapping
CO |
PO1 |
PO2 |
PO3 |
PO4 |
PO5 |
PO6 |
PO7 |
PO8 |
PO9 |
PO10 |
PO11 |
PO12 |
PSO1 |
PSO2 |
CO1 |
3 |
β |
β |
β |
β |
β |
β |
β |
2 |
3 |
β |
β |
β |
β |
CO2 |
3 |
3 |
2 |
3 |
β |
β |
β |
β |
3 |
2 |
β |
β |
β |
β |
CO3 |
3 |
3 |
β |
3 |
β |
β |
β |
β |
3 |
2 |
β |
β |
β |
β |
CO4 |
3 |
2 |
β |
3 |
β |
β |
β |
β |
3 |
2 |
β |
β |
β |
β |
CO5 |
3 |
3 |
2 |
2 |
β |
β |
β |
β |
2 |
3 |
β |
β |
β |
β |
AVG |
3 |
2.75 |
2 |
2.75 |
β |
β |
β |
β |
2.6 |
2.4 |
β |
β |
β |
β |
Course Outcomes: Mechanics of Solids Lab (3rd Semester)
COs |
Mechanics of Solids Lab (MEC-209LA) |
CO1 |
Design and conduct experiments, acquire data, analyse and interpret data |
CO2 |
Determine the behaviour of ferrous metals subjected to normal and shear stresses by meansΒ of experiments. |
CO3 |
Determine the behaviour of structural elements, such as bars subjected to tension, compression, shear, bending, and torsion by means of experiments. |
CO4 |
Physical insight into the behaviour materials and structural elements, including distribution of stresses and strains, deformations and failure modes. |
CO5 |
Write individual and group reports: present objectives, describe test procedures and results, synthesize and discuss the test results. |
CO-PO Mapping
CO |
PO1 |
PO2 |
PO3 |
PO4 |
PO5 |
PO6 |
PO7 |
PO8 |
PO9 |
PO10 |
PO11 |
PO12 |
PSO1 |
PSO2 |
CO1 |
3 |
3 |
3 |
3 |
β |
β |
β |
β |
3 |
2 |
β |
β |
3 |
2 |
CO2 |
3 |
3 |
β |
2 |
β |
β |
β |
β |
2 |
3 |
β |
β |
β |
β |
CO3 |
3 |
2 |
β |
2 |
β |
β |
β |
β |
2 |
3 |
β |
β |
β |
β |
CO4 |
3 |
3 |
β |
2 |
β |
β |
β |
β |
3 |
2 |
β |
β |
β |
β |
CO5 |
3 |
3 |
β |
β |
β |
β |
β |
β |
2 |
3 |
β |
β |
β |
3 |
AVG |
3 |
2.8 |
3 |
2.2 |
β |
β |
β |
β |
2.4 |
2.6 |
β |
β |
3 |
2.5 |
Course Outcomes: Mechanics of solid II (4th Semester)
COs |
Mechanics of solid II(MEC-206A) |
CO1 |
Interpreting and understanding the strain energy in different loading conditions and explain different theories of failure. |
CO2 |
Interpreting the stresses developed in pressure vessel subjected to internal pressure and learns to design the same. |
CO3 |
Understand and interpreting the stresses developed in the rotating elements and design of different kinds of springs. |
CO4 |
Implementation of design analysis in interpreting the stresses in crane hook and understanding the procedure of finding the stresses in different sections subjected to unsymmetrical bending. |
CO5 |
Understand and implement the design analysis in different shaped elements to interpret the magnitude the nature of stresses. |
CO-PO Mapping
CO |
PO1 |
PO2 |
PO3 |
PO4 |
PO5 |
PO6 |
PO7 |
PO8 |
PO9 |
PO10 |
PO11 |
PO12 |
PSO1 |
PSO2 |
CO1 |
3 |
2 |
β |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO2 |
3 |
2 |
β |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO3 |
3 |
3 |
β |
2 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO4 |
3 |
3 |
3 |
2 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO5 |
3 |
2 |
3 |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
AVG |
3 |
2.4 |
3 |
2.6 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
Course Outcomes: Applied Thermodynamics (4th Semester)
COs |
Applied Thermodynamics(MEC-202A) |
CO1 |
Understand and analyze the concept of fire tube and water tube boilers itsΒ mountings and accessories to find the boiler efficiency |
CO2 |
Understand the concept of draught and design the Chimney |
CO3 |
Understand the concept of Carnot cycle, Rankine cycle and steam engine how to modify the Rankin cycle |
CO4 |
Understand and analyze the concept of steam nozzle andΒ type of condenser |
CO5 |
Understand and analyze the concept of condensers |
CO6 |
Understand and analyze the concept of Steam Turbine |
CO-PO Mapping
CO |
PO1 |
PO2 |
PO3 |
PO4 |
PO5 |
PO6 |
PO7 |
PO8 |
PO9 |
PO10 |
PO11 |
PO12 |
PSO1 |
PSO2 |
CO1 |
3 |
3 |
β |
2 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO2 |
3 |
2 |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO3 |
3 |
2 |
β |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO4 |
3 |
3 |
β |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO5 |
3 |
3 |
β |
2 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO6 |
3 |
3 |
β |
2 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
AVG |
3 |
2.7 |
3 |
2.4 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
Course Outcomes: Instrumentation and Control (4th Semester)
COs |
Instrumentation and Control (MEC-208A) |
CO1 |
Understand about instruments performance characteristics and statistical error analysis. |
CO2 |
Understand the importance and classification of sensors and transducers used in measurements. |
CO3 |
Analyze force, torque, shaft power, speed and Acceleration of mechanical components. |
CO4 |
Apply pressure, temperature and to flow of engineering materials. |
CO5 |
Analyze humidity, viscosity and density of mechanical quantities |
CO6 |
Understand basic knowledge of process monitoring and control |
CO-PO Mapping
COPO1PO2PO3PO4PO5PO6PO7PO8PO9PO10PO11PO12PSO1PSO2CO13βββββββββββββCO23βββββββββββββCO33333ββββββββββCO43222ββββββββββCO53332ββββββββββCO63βββββββββββββAVG32.72.72.3ββββββββββ
Course Outcomes: Fluid Mechanics & Machines (4th Semester)
COs |
Fluid Mechanics & Machines (MEC-204A) |
CO1 |
Understand the basic concept of fluid and properties of fluid. |
CO2 |
Analyze the basic concepts of fluid-statics, kinematics and dynamics withΒ Β their applications. |
CO3 |
Understand and the implementation of continuity equation, discharge of flow in major and minor losses through pipes and to learn the hydraulic gradient energy. |
CO4 |
Implement the fluid concept in viscous and turbulent flow. |
CO5 |
Analyze and evaluate the performance of pumps and turbine. |
CO6 |
Analyze the performance curve and Cavitation in Pumps and Turbine |
CO-PO Mapping
CO |
PO1 |
PO2 |
PO3 |
PO4 |
PO5 |
PO6 |
PO7 |
PO8 |
PO9 |
PO10 |
PO11 |
PO12 |
PSO1 |
PSO2 |
CO1 |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO2 |
3 |
3 |
3 |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO3 |
3 |
2 |
β |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO4 |
3 |
2 |
β |
2 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO5 |
3 |
3 |
2 |
2 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO6 |
3 |
3 |
2 |
2 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
AVG |
3 |
2.6 |
2.3 |
2.4 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
Course Outcomes: Material Engineering (4th Semester)
COs |
Material Engineering (ES-204 A) |
CO1 |
Understand the Crystal structures and deformation mechanism in various materials. |
CO2 |
Analyze various types of phase diagrams, TTT curve and Iron carbon diagram. |
CO3 |
Understand about different heat treatment processes. |
CO4 |
Understand about the failure mechanisms like Creep and Fatigue and designation of materials. |
CO5 |
Understand basics of metallography and processes of the metallography. |
CO6 |
Understand Basic Principle involved in the working of various types of Material characterization techniques |
CO-PO Mapping
CO |
PO1 |
PO2 |
PO3 |
PO4 |
PO5 |
PO6 |
PO7 |
PO8 |
PO9 |
PO10 |
PO11 |
PO12 |
PSO1 |
PSO2 |
CO1 |
3 |
2 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO2 |
3 |
2 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO3 |
3 |
3 |
β |
β |
β |
β |
3 |
β |
β |
β |
β |
β |
β |
β |
CO4 |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO5 |
3 |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO6 |
3 |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
AVG |
3 |
2.6 |
β |
β |
β |
β |
3 |
β |
β |
β |
β |
β |
β |
β |
Course Outcomes: Constitution of India (4th Semester)
COs |
Constitution of IndiaΒ (MC-902A) |
CO1 |
Understand the basic features of Constitution of India |
CO2 |
Understand about salient features of the Constitution of India. |
CO3 |
Understand fundamental duties and federal structure of Constitution of India. |
CO4 |
Understand about emergency provisions in Constitution of India. |
CO5 |
Understand about fundamental rights under constitution of India. |
CO-PO Mapping
CO |
PO1 |
PO2 |
PO3 |
PO4 |
PO5 |
PO6 |
PO7 |
PO8 |
PO9 |
PO10 |
PO11 |
PO12 |
PSO1 |
PSO2 |
CO1 |
β |
β |
β |
β |
β |
3 |
β |
3 |
β |
β |
β |
β |
β |
β |
CO2 |
β |
β |
β |
β |
β |
3 |
β |
3 |
β |
β |
β |
β |
β |
β |
CO3 |
β |
β |
β |
β |
β |
3 |
β |
2 |
β |
β |
β |
β |
β |
β |
CO4 |
β |
β |
β |
β |
β |
3 |
β |
3 |
β |
β |
β |
β |
β |
β |
CO5 |
β |
β |
β |
β |
β |
3 |
β |
3 |
β |
β |
β |
β |
β |
β |
AVG |
β |
β |
β |
β |
β |
3 |
β |
2.8 |
β |
β |
β |
β |
β |
β |
Course Outcomes: Materials Engineering Lab (4th Semester)
COs |
Materials Engineering Lab(ES-206LA) |
CO1 |
Design and conduct experiments, acquire data, analyze and interpret data |
CO2 |
Determine the grain size and microstructure in different Ferrous alloys by means of experiments. |
CO3 |
Learn about microstructures of different Non-Ferrous alloys by means of experiments. |
CO4 |
Understand heat treatment processes through experiments. |
CO5 |
Analyze microstructure of Heat-treated specimens and perform Fatigue and creep test on different materials. |
CO-PO Mapping
CO |
PO1 |
PO2 |
PO3 |
PO4 |
PO5 |
PO6 |
PO7 |
PO8 |
PO9 |
PO10 |
PO11 |
PO12 |
PSO1 |
PSO2 |
CO1 |
3 |
3 |
3 |
3 |
β |
β |
β |
β |
3 |
2 |
β |
β |
2 |
3 |
CO2 |
3 |
2 |
β |
β |
β |
β |
β |
β |
3 |
3 |
β |
β |
β |
β |
CO3 |
3 |
β |
β |
β |
β |
β |
β |
β |
2 |
3 |
β |
β |
β |
β |
CO4 |
3 |
β |
β |
3 |
β |
β |
β |
β |
3 |
3 |
β |
β |
β |
β |
CO5 |
3 |
3 |
β |
β |
β |
β |
β |
β |
3 |
2 |
β |
β |
β |
β |
AVG |
3 |
2.7 |
3 |
3 |
β |
β |
β |
β |
2.8 |
2.6 |
β |
β |
2 |
3 |
Course Outcomes: Fluid Mechanics & Fluid Machines Lab (4th Semester)
COs |
Fluid Mechanics & Fluid Machines Lab (MEC-210LA) |
CO1 |
Operate fluid flow equipment and instrumentation. |
CO2 |
Analyze data using fluid mechanics principles and experimentation methods. |
CO3 |
Determine the coefficient of discharge for various flow measurement devices. |
CO4 |
Calculate flow characteristics such as Reynolds number, friction factor from laboratory measurements. |
CO5 |
Analyze the performance characteristics of hydraulic pumps. |
CO6 |
Analyze the performance characteristics of hydraulic turbines. |
CO-PO Mapping
CO |
PO1 |
PO2 |
PO3 |
PO4 |
PO5 |
PO6 |
PO7 |
PO8 |
PO9 |
PO10 |
PO11 |
PO12 |
PSO1 |
PSO2 |
CO1 |
3 |
β |
β |
β |
β |
β |
β |
β |
2 |
3 |
β |
β |
β |
β |
CO2 |
3 |
2 |
2 |
3 |
β |
β |
β |
β |
3 |
2 |
β |
β |
β |
β |
CO3 |
3 |
2 |
β |
3 |
β |
β |
β |
β |
2 |
3 |
β |
β |
β |
β |
CO4 |
3 |
3 |
β |
3 |
β |
β |
β |
β |
3 |
2 |
β |
β |
β |
β |
CO5 |
3 |
2 |
2 |
2 |
β |
β |
β |
β |
3 |
2 |
β |
β |
β |
β |
CO6 |
3 |
3 |
3 |
3 |
β |
β |
β |
β |
3 |
2 |
β |
β |
β |
β |
AVG |
3 |
2.4 |
2.3 |
2.8 |
β |
β |
β |
β |
2.7 |
2.3 |
β |
β |
β |
β |
Course Outcomes: Entrepreneurship (5th Semester)
COs |
Entrepreneurship (HM-905A) |
CO1 |
Understand entrepreneurs and what competences needed |
CO2 |
Explain insights into the management, opportunity search, identification of a product, market flexibility studies, project finalization etc. required for small business enterprise. |
CO3 |
Explain a report and do oral presentation on the topics such as product identification, business ideas, export marketing etc. |
CO4 |
Summarize the different financial and other assistance available for establishing small industrial units. |
CO5 |
Understand the role OS support institutions |
CO6 |
Distinguish the importance of Legal issues in Entrepreneurship |
CO-PO Mapping
CO |
PO1 |
PO2 |
PO3 |
PO4 |
PO5 |
PO6 |
PO7 |
PO8 |
PO9 |
PO10 |
PO11 |
PO12 |
PSO1 |
PSO2 |
CO1 |
3 |
β |
β |
β |
β |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
CO2 |
2 |
β |
β |
β |
β |
2 |
β |
β |
β |
3 |
β |
β |
β |
β |
CO3 |
3 |
β |
β |
β |
β |
3 |
β |
β |
β |
3 |
β |
β |
β |
β |
CO4 |
3 |
2 |
β |
β |
β |
2 |
β |
β |
β |
2 |
β |
β |
β |
β |
CO5 |
3 |
β |
β |
β |
β |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
CO6 |
3 |
3 |
β |
β |
β |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
AVG |
2.8 |
2.5 |
β |
β |
β |
2.7 |
β |
β |
β |
2.7 |
β |
β |
β |
β |
Course Outcomes: Heat Transfer (5th Semester)
COs |
Heat Transfer (MEC-301 A) |
CO1 |
Explain the basic modes and laws of heat transfer. |
CO2 |
Develop and analyze general conduction equation in Cartesian, cylindrical and spherical coordinates. |
CO3 |
Develop and analyze temperature distribution and heat dissipation rate equations for different type of fins. |
CO4 |
Illustrate the concept of free and forced convection and discuss the dimensional analysis. |
CO5 |
Classify the concept of boundary layer and develop the related equations. |
CO6 |
Summarize the laws of thermal radiation and the concept of black body. |
CO7 |
Explain the types of heat exchangers and discuss LMTD and NTU approaches for the design of heat exchangers. |
CO-PO Mapping
CO |
PO1 |
PO2 |
PO3 |
PO4 |
PO5 |
PO6 |
PO7 |
PO8 |
PO9 |
PO10 |
PO11 |
PO12 |
PSO1 |
PSO2 |
CO1 |
3 |
2 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO2 |
3 |
3 |
2 |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
2 |
β |
CO3 |
3 |
3 |
2 |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO4 |
3 |
3 |
β |
2 |
β |
β |
β |
β |
β |
β |
β |
β |
2 |
β |
CO5 |
3 |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO6 |
3 |
2 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO7 |
3 |
3 |
3 |
2 |
β |
β |
β |
β |
β |
β |
β |
β |
3 |
β |
AVG |
3 |
2.7 |
2.3 |
2.5 |
β |
β |
β |
β |
β |
β |
Β Β Β β |
β |
2.3 |
β |
Course Outcomes: Production Technology (5th Semester)
COs |
Production Technology (MEC-303 A) |
CO1 |
Understand the concept of machining, various machine tool and analyze the various forces acting during machining |
CO2 |
Study the various tool materials, cutting fluids and concept of tool life used in machining operations. |
CO3 |
Understand the concept of metrology, inspection tools with their applications. |
CO4 |
Understand the various methods used to make threads and study of different jigs and fixtures used in machine tools with their materials. |
CO5 |
Explain about different gear generation and production processes and gear finishing processes used in Industries. |
CO6 |
Classify the various computer numerical control (CNC) machines, its working structure and programming of CNC machines. |
CO-PO Mapping
CO |
PO1 |
PO2 |
PO3 |
PO4 |
PO5 |
PO6 |
PO7 |
PO8 |
PO9 |
PO10 |
PO11 |
PO12 |
PSO1 |
PSO2 |
CO1 |
3 |
2 |
β |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO2 |
3 |
2 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO3 |
3 |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO4 |
3 |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO5 |
3 |
2 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO6 |
3 |
3 |
2 |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
2 |
3 |
AVG |
3 |
2.5 |
2 |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
2 |
3 |
Course Outcomes: Mechanical Vibrations and Tribology (5th Semester)
COs |
Mechanical Vibrations and Tribology (MEC-305 A) |
CO1 |
Understand the fundamentals of mechanical vibrations. |
CO2 |
Ability to apply different methods for formulating the equation of motion for free and damped vibratory system and their solution cases. |
CO3 |
Analyze the response of rotating imbalance and harmonic excitations, and applications in vibration isolations. |
CO4 |
To learn various methods for calculating influence coefficients and principle modes of vibrations. |
CO5 |
Understand the different modes of vibrations and applications of numerical methods. |
CO6 |
Understand the basic concept of Tribology in design and the various theories of lubrication, friction and wears. |
CO-PO Mapping
CO |
PO1 |
PO2 |
PO3 |
PO4 |
PO5 |
PO6 |
PO7 |
PO8 |
PO9 |
PO10 |
PO11 |
PO12 |
PSO1 |
PSO2 |
CO1 |
2 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO2 |
2 |
3 |
2 |
2 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO3 |
3 |
3 |
3 |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO4 |
3 |
2 |
β |
2 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO5 |
2 |
2 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO6 |
3 |
3 |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
AVG |
2.5 |
2.6 |
2.7 |
2.3 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
Course Outcomes: Essence of Indian Traditional Knowledge (5th Semester)
COs |
Essence of Indian Traditional KnowledgeΒ (MC-903A) |
CO1 |
Understand the basic structure of Indian knowledge system. |
CO2 |
Explain basic principles of thought process. |
CO3 |
Understand the basic concept of reasoning and inferencing. |
CO4 |
Understand the basic concept of Indian traditional knowledge in modern Scientific perspective. |
CO5 |
Practice Yoga and understand about holistic health care. |
CO-PO Mapping
CO |
PO1 |
PO2 |
PO3 |
PO4 |
PO5 |
PO6 |
PO7 |
PO8 |
PO9 |
PO10 |
PO11 |
PO12 |
PSO1 |
PSO2 |
CO1 |
β |
β |
β |
β |
β |
2 |
β |
β |
β |
β |
β |
β |
β |
β |
CO2 |
β |
β |
β |
β |
β |
2 |
β |
3 |
β |
2 |
β |
β |
β |
β |
CO3 |
β |
β |
β |
β |
β |
3 |
β |
3 |
β |
3 |
β |
β |
β |
β |
CO4 |
β |
β |
β |
β |
β |
3 |
β |
β |
β |
3 |
β |
β |
β |
β |
CO5 |
β |
β |
β |
β |
β |
3 |
β |
3 |
β |
β |
β |
β |
β |
β |
AVG |
β |
β |
β |
β |
β |
2.6 |
β |
3 |
β |
2.7 |
β |
β |
β |
β |
Course Outcomes: Heat Transfer lab (5th Semester)
COs |
Heat Transfer lab (MEC-307LA) |
CO1 |
Design and conduct experiments, acquire data, analyze and interpret data. |
CO2 |
Measure the thermal conductivity of metal rod, insulating material and liquids. |
CO3 |
Understand the concept of composite wall and determine its thermal resistance. |
CO4 |
Plot the temperature profile in free and forced convection. |
CO5 |
Measure the performance of a heat exchanger. |
CO6 |
Understand the concept of solar heating and measure the performance of solar equipment. |
CO-PO Mapping
CO |
PO1 |
PO2 |
PO3 |
PO4 |
PO5 |
PO6 |
PO7 |
PO8 |
PO9 |
PO10 |
PO11 |
PO12 |
PSO1 |
PSO2 |
CO1 |
3 |
2 |
3 |
3 |
β |
β |
β |
β |
3 |
2 |
β |
β |
β |
β |
CO2 |
3 |
2 |
β |
β |
β |
β |
β |
β |
3 |
3 |
β |
β |
β |
β |
CO3 |
3 |
2 |
β |
β |
β |
β |
β |
β |
2 |
3 |
β |
β |
β |
β |
CO4 |
3 |
3 |
β |
β |
β |
β |
β |
β |
3 |
2 |
β |
β |
β |
β |
CO5 |
3 |
3 |
β |
β |
β |
β |
β |
β |
2 |
3 |
β |
β |
β |
β |
CO6 |
3 |
2 |
β |
β |
β |
β |
β |
β |
2 |
3 |
β |
β |
β |
3 |
AVG |
3 |
2.3 |
3 |
3 |
β |
β |
β |
β |
2.5 |
2.8 |
β |
β |
β |
3 |
Course Outcomes: Production Technology Lab (5th Semester)
COs |
Production Technology Lab (MEC-309LA) |
CO1 |
Understand the concept of various measuring devices used in Industries and concept of tolerances and fits. |
CO2 |
Understand and gain the practical knowledge of different measuring instruments used in machining operations. |
CO3 |
Perform different machining operations for the preparation of a job. |
CO4 |
Prepare various jobs using TIG/MIG welding. |
CO5 |
Perform various works on CNC lathe and CNC milling. |
CO-PO Mapping
CO |
PO1 |
PO2 |
PO3 |
PO4 |
PO5 |
PO6 |
PO7 |
PO8 |
PO9 |
PO10 |
PO11 |
PO12 |
PSO1 |
PSO2 |
CO1 |
3 |
β |
β |
β |
β |
β |
β |
β |
2 |
3 |
β |
β |
β |
β |
CO2 |
3 |
β |
β |
β |
β |
β |
β |
β |
2 |
3 |
β |
β |
β |
β |
CO3 |
3 |
3 |
3 |
3 |
β |
β |
β |
β |
3 |
2 |
β |
β |
β |
β |
CO4 |
3 |
3 |
2 |
β |
β |
β |
β |
β |
3 |
2 |
β |
β |
β |
β |
CO5 |
3 |
3 |
3 |
3 |
β |
β |
β |
β |
3 |
2 |
β |
β |
2 |
3 |
AVG |
3 |
3 |
2.7 |
3 |
β |
β |
β |
β |
2.6 |
2.4 |
β |
β |
2 |
3 |
Course Outcomes: Mechanical Vibrations and Tribology Lab (5th Semester)
COs |
Mechanical Vibrations and Tribology Lab (MEC-311LA) |
CO1 |
Understanding the vibration fundamentals for a single degree of freedom (D.O.F.) system under free and damped vibrations. |
CO2 |
Analyze different types of forced vibration system in single degree of freedom (D.O.F.) and damped, undamped, free and forced systems with two D.O.F. |
CO3 |
Understand the principal modes of vibrations using different methods for various combinations of spring-mass and rotor-shaft systems. |
CO4 |
Understand transverse, longitudinal and torsional vibration for beams, bars and shafts respectively. |
CO5 |
Understand the fundamentals of tribology, lubrication, friction and wear. |
CO-PO Mapping
CO |
PO1 |
PO2 |
PO3 |
PO4 |
PO5 |
PO6 |
PO7 |
PO8 |
PO9 |
PO10 |
PO11 |
PO12 |
PSO1 |
PSO2 |
CO1 |
3 |
β |
β |
β |
β |
β |
β |
β |
2 |
3 |
β |
β |
β |
β |
CO2 |
3 |
3 |
2 |
3 |
β |
β |
β |
β |
3 |
2 |
β |
β |
β |
β |
CO3 |
3 |
3 |
β |
2 |
β |
β |
β |
β |
2 |
3 |
β |
β |
β |
β |
CO4 |
3 |
β |
β |
β |
β |
β |
β |
β |
2 |
3 |
β |
β |
β |
β |
CO5 |
3 |
β |
β |
β |
β |
β |
β |
β |
2 |
3 |
β |
β |
β |
β |
AVG |
3 |
3 |
2 |
2.5 |
β |
β |
β |
β |
2.2 |
2.8 |
β |
β |
β |
β |
Course Outcomes: Refrigeration and air conditioning (6th Semester)
COs |
Refrigeration and air conditioning (MEP-310 A) |
CO1 |
Understand the concept of different refrigeration processes. |
CO2 |
Understand and apply the concept of air-conditioning system in aircraft. |
CO3 |
Learn about refrigerants, their properties and evaluate the COP of VCR and VAR systems. |
CO4 |
Understand the basics of Psychometry and its implementation in air conditioning systems. |
CO5 |
Understand of standards for human comforts. |
CO6 |
Implement the knowledge of air conditioning systems in different heating load calculations. |
CO-PO Mapping
CO |
PO1 |
PO2 |
PO3 |
PO4 |
PO5 |
PO6 |
PO7 |
PO8 |
PO9 |
PO10 |
PO11 |
PO12 |
PSO1 |
PSO2 |
CO1 |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO2 |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO3 |
3 |
3 |
β |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO4 |
3 |
3 |
β |
2 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO5 |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO6 |
3 |
2 |
3 |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
AVG |
3 |
2.7 |
3 |
2.7 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
Course Outcomes: Design of Machine element (6th Semester)
COs |
Design of Machine element (MEC-304 A) |
CO1 |
Explain the design procedures and methods, properties of engineering materials and their selection, design against static and fluctuating loads. |
CO2 |
Solve the design problems of different types of joints i.e. bolted, riveted joint and welded joint under different loading conditions. |
CO3 |
Analyse the design problems related to the design of springs under different loading conditions. |
CO4 |
Analyse the transmission shafts and keys under different loading conditions. |
CO5 |
Design problems related to clutches, brakes and selection of bearings from manufacturerβs catalogue. |
CO-PO Mapping
CO |
PO1 |
PO2 |
PO3 |
PO4 |
PO5 |
PO6 |
PO7 |
PO8 |
PO9 |
PO10 |
PO11 |
PO12 |
PSO1 |
PSO2 |
CO1 |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO2 |
3 |
2 |
2 |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO3 |
3 |
3 |
2 |
2 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO4 |
3 |
3 |
3 |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO5 |
3 |
3 |
3 |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
AVG |
3 |
2.75 |
2.5 |
2.75 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
Course Outcomes: Organizational Behaviour (6th Semester)
COs |
Organizational BehaviourΒ (HM-901A) |
CO1 |
Overview about organizational behaviour as a discipline and understanding the concept of individual behaviour. |
CO2 |
Understand the concept and importance of personality, emotions and its importance in decision making and effective leadership. |
CO3 |
Enabling the students to know about the importance of effective motivation. |
CO4 |
Enabling the students to know about the importance of group dynamics and resolving conflicts. |
CO5 |
Understand how to overcome organizational stress by maintaining proper organizational culture. |
CO6 |
Understand how to overcome organizational stress by maintaining effective communication. |
CO-PO Mapping
CO |
PO1 |
PO2 |
PO3 |
PO4 |
PO5 |
PO6 |
PO7 |
PO8 |
PO9 |
PO10 |
PO11 |
PO12 |
PSO1 |
PSO2 |
CO1 |
β |
β |
|
β |
β |
2 |
β |
2 |
β |
β |
β |
β |
β |
β |
CO2 |
β |
β |
β |
β |
β |
3 |
β |
2 |
β |
β |
β |
β |
β |
β |
CO3 |
β |
β |
β |
β |
β |
2 |
β |
3 |
β |
β |
β |
β |
β |
β |
CO4 |
β |
3 |
β |
β |
β |
2 |
β |
2 |
β |
β |
β |
β |
β |
β |
CO5 |
β |
β |
β |
β |
β |
3 |
β |
2 |
β |
β |
β |
β |
β |
β |
CO6 |
β |
β |
β |
β |
β |
2 |
β |
1 |
β |
β |
β |
β |
β |
β |
AVG |
|
3 |
β |
β |
β |
2.3 |
β |
2 |
β |
β |
β |
β |
β |
β |
Course Outcomes: Manufacturing Technology (6th Semester)
COs |
Manufacturing TechnologyΒ (MEC-302 A) |
CO1 |
Explain the fundamentals of casting processes and evaluate design parameters |
CO2 |
Describe different metal forming processes and analysis |
CO3 |
Study different type of cutting processes |
CO4 |
Understand different welding processes with their applications |
CO5 |
Evaluate design parameters of powder metallurgy processes and explain different powder metallurgy |
CO6 |
Understand different plastic shaping processes |
CO-PO Mapping
CO |
PO1 |
PO2 |
PO3 |
PO4 |
PO5 |
PO6 |
PO7 |
PO8 |
PO9 |
PO10 |
PO11 |
PO12 |
PSO1 |
PSO2 |
CO1 |
3 |
2 |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO2 |
3 |
3 |
β |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO3 |
3 |
β |
β |
2 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO4 |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO5 |
3 |
3 |
β |
2 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO6 |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
AVG |
3 |
2.7 |
3 |
2.3 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
Course Outcomes: Internal Combustion Engine (6th Semester)
COs |
Internal Combustion EngineΒ (MEP-302 A) |
CO1 |
Introduction to heat engines and understand various cycles of operations of Internal combustion engines |
CO2 |
Discuss the mixture requirement and fuel injection system in IC engines |
CO3 |
Understand the concept of knocking and fuel ignition system in various engines |
CO4 |
Describe the lubrication system of engine and evaluate its performance parameters. |
CO5 |
Analyze the current scenario on the pollution and illustrate methods of emission control |
Β Β CO6 |
Understand and evaluate the factor affecting the efficiency of compressor and gas turbines. |
CO-PO Mapping
CO |
PO1 |
PO2 |
PO3 |
PO4 |
PO5 |
PO6 |
PO7 |
PO8 |
PO9 |
PO10 |
PO11 |
PO12 |
PSO1 |
PSO2 |
CO1 |
3 |
3 |
β |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO2 |
3 |
3 |
β |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO3 |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO4 |
3 |
3 |
β |
2 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO5 |
3 |
3 |
β |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
3 |
CO6 |
3 |
3 |
β |
2 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
AVG |
3 |
3 |
β |
2.6 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
3 |
Course Outcomes: Refrigeration and Air conditioning Lab (6th Semester)
COs |
Refrigeration and Air conditioning Lab (MEC-310LA) |
CO1 |
Understand about the basics and working principle of water cooler. |
CO2 |
Understand about the basics and working principle of cooling tower |
CO3 |
Identify the different cycle of operation in air-conditioning |
CO4 |
Analyze the humidity measurement and its importance in air-conditioning |
CO5 |
Learn about the various control devices and parts of refrigeration and air-conditioning systems |
CO6 |
Learn about the various parts of refrigeration and air-conditioning systems |
CO-PO Mapping
CO |
PO1 |
PO2 |
PO3 |
PO4 |
PO5 |
PO6 |
PO7 |
PO8 |
PO9 |
PO10 |
PO11 |
PO12 |
PSO1 |
PSO2 |
CO1 |
3 |
β |
β |
β |
β |
β |
β |
β |
2 |
3 |
β |
β |
β |
β |
CO2 |
3 |
β |
β |
β |
β |
β |
β |
β |
2 |
3 |
β |
β |
β |
β |
CO3 |
3 |
3 |
β |
2 |
β |
β |
β |
β |
3 |
2 |
β |
β |
β |
β |
CO4 |
3 |
3 |
2 |
3 |
β |
β |
β |
β |
3 |
2 |
β |
β |
β |
β |
CO5 |
3 |
β |
β |
β |
β |
β |
β |
β |
2 |
3 |
β |
β |
β |
β |
CO6 |
3 |
β |
β |
β |
β |
β |
β |
β |
2 |
3 |
β |
β |
β |
β |
AVG |
3 |
3 |
2 |
2.5 |
β |
β |
β |
β |
2.3 |
2.7 |
β |
β |
β |
β |
Course Outcomes: Mechanical Engineering Lab I (6th Semester)
COs |
Mechanical Engineering Lab I (MEC-306 LA) |
CO1 |
Determine the IHP, BHP, SFC and make balance sheet of 4 Stroke Diesel Engine |
CO2 |
Determine the IHP, BHP, SFC and make balance sheet of 4 Stroke Petrol Engine |
CO3 |
Evaluate the efficiency of two stage reciprocating air compressor and air blower |
CO4 |
Understand the concept of fuel injection system, lubrication and cooling system. |
CO5 |
Discuss about cooling tower and carburettor |
CO-PO Mapping
CO |
PO1 |
PO2 |
PO3 |
PO4 |
PO5 |
PO6 |
PO7 |
PO8 |
PO9 |
PO10 |
PO11 |
PO12 |
PSO1 |
PSO2 |
CO1 |
3 |
3 |
β |
2 |
β |
β |
β |
β |
3 |
2 |
β |
β |
β |
β |
CO2 |
3 |
3 |
β |
2 |
β |
β |
β |
β |
3 |
2 |
β |
β |
β |
β |
CO3 |
3 |
2 |
β |
3 |
β |
β |
β |
β |
3 |
2 |
β |
β |
β |
β |
CO4 |
3 |
β |
β |
β |
β |
β |
β |
β |
3 |
3 |
β |
β |
β |
β |
CO5 |
3 |
β |
β |
β |
β |
β |
β |
β |
2 |
3 |
β |
β |
β |
β |
AVG |
3 |
2.7 |
β |
2.3 |
β |
β |
β |
β |
2.8 |
2.4 |
β |
β |
β |
β |
Course Outcomes: SMART MATERIALS (7th Semester)
COs |
SMART MATERIALSΒ (MEO-401A) |
CO1 |
Understand and classification of smart materials and various functions of intelligent materials. |
CO2 |
Categorize the various types of smart structure systems, actuators and sensors. |
CO3 |
Describe the various typesβ batteries, such as lithium ion batteries. |
CO4 |
Describe the various types of SMA based hybrid composites and smart battery materials. |
CO5 |
Understand the structure and properties of various types of nano tubes. |
Β Β CO6 |
Describe the mechanical, physical and elastic properties of nano tubes |
CO-PO Mapping
CO |
PO1 |
PO2 |
PO3 |
PO4 |
PO5 |
PO6 |
PO7 |
PO8 |
PO9 |
PO10 |
PO11 |
PO12 |
PSO1 |
PSO2 |
CO1 |
3 |
3 |
β |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO2 |
3 |
3 |
β |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO3 |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO4 |
2 |
3 |
β |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO5 |
3 |
3 |
β |
2 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
3 |
CO6 |
3 |
3 |
β |
2 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
AVG |
2.8 |
3 |
β |
2.6 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
3 |
Course Outcomes: MANUFACTURING COST ESTIMATION (7th Semester)
COs |
MANUFACTURING COST ESTIMATION (MEO-407A) |
CO1 |
Understand the concept of cost estimation & cost reduction techniques. |
CO2 |
Establish staff and organization for cost estimation. |
CO3 |
Summarize components of costing and Determine material cost of simple machine components. |
CO4 |
Analyze to estimate the costs for different machining and casting processes. |
CO5 |
Analyze to estimate the various costs for different joining processes. |
Β Β CO6 |
Analyze to estimate the various costs for surface finishing processes. |
CO-PO Mapping
CO |
PO1 |
PO2 |
PO3 |
PO4 |
PO5 |
PO6 |
PO7 |
PO8 |
PO9 |
PO10 |
PO11 |
PO12 |
PSO1 |
PSO2 |
CO1 |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO2 |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
3 |
β |
CO3 |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO4 |
3 |
3 |
β |
2 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO5 |
3 |
2 |
β |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO6 |
3 |
3 |
β |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
AVG |
3 |
2.7 |
β |
2.7 |
β |
β |
β |
β |
β |
β |
β |
β |
3 |
β |
Course Outcomes: Computer aided design (7th Semester)
COs |
Computer aided design (MEP-401A) |
CO1 |
Understand the basics of CAD/CAM, CIM and Computer Aided Quality Control. |
CO2 |
Construct model of different types of curves, surfaces and solids. |
CO3 |
Understand the concept of group technology, transformation of points and lines in computer aided software. |
CO4 |
Understand and implement the coding. |
CO5 |
Β Apply computer aided process planning. |
CO-PO Mapping
CO |
PO1 |
PO2 |
PO3 |
PO4 |
PO5 |
PO6 |
PO7 |
PO8 |
PO9 |
PO10 |
PO11 |
PO12 |
PSO1 |
PSO2 |
CO1 |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
2 |
3 |
CO2 |
3 |
2 |
2 |
2 |
3 |
β |
β |
β |
β |
β |
β |
β |
2 |
3 |
CO3 |
3 |
β |
2 |
β |
2 |
β |
β |
β |
β |
β |
β |
β |
3 |
3 |
CO4 |
3 |
2 |
3 |
3 |
3 |
β |
β |
β |
β |
β |
β |
β |
3 |
3 |
CO5 |
3 |
β |
β |
β |
3 |
β |
β |
β |
β |
β |
β |
β |
3 |
3 |
AVG |
3 |
2 |
2.3 |
2.5 |
2.7 |
β |
β |
β |
β |
β |
β |
β |
2.6 |
3 |
Course Outcomes: Mechatronic (7th Semester)
COs |
Mechatronic (MEP-407A) |
CO1 |
Understand number system and able to convert number systems from one system to another |
CO2 |
Identify the suitable sensor and actuator for a Mechatronics system |
CO3 |
Understand the Pneumatic and Hydraulic system components along with their symbols |
CO4 |
Explain Architecture of Microprocessor |
CO5 |
Explain Integrate, Mechanical , Electronics,Β Control and Computer Engineering in the design of Mechatronics system |
CO6 |
Design a Mechatronics System |
CO-PO Mapping
CO |
PO1 |
PO2 |
PO3 |
PO4 |
PO5 |
PO6 |
PO7 |
PO8 |
PO9 |
PO10 |
PO11 |
PO12 |
PSO1 |
PSO2 |
CO1 |
3 |
2 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO2 |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
3 |
CO3 |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO4 |
3 |
2 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO5 |
3 |
3 |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
2 |
CO6 |
3 |
β |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
3 |
3 |
AVG |
3 |
2.3 |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
3 |
2.7 |
Course Outcomes: Mechatronic (7th Semester)
COs |
Mechatronic (MEP-407A) |
CO1 |
Understand number system and able to convert number systems from one system to another |
CO2 |
Identify the suitable sensor and actuator for a Mechatronics system |
CO3 |
Understand the Pneumatic and Hydraulic system components along with their symbols |
CO4 |
Explain Architecture of Microprocessor |
CO5 |
Explain Integrate, Mechanical , Electronics,Β Control and Computer Engineering in the design of Mechatronics system |
CO6 |
Design a Mechatronics System |
CO-PO Mapping
CO |
PO1 |
PO2 |
PO3 |
PO4 |
PO5 |
PO6 |
PO7 |
PO8 |
PO9 |
PO10 |
PO11 |
PO12 |
PSO1 |
PSO2 |
CO1 |
3 |
2 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO2 |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
3 |
CO3 |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO4 |
3 |
2 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO5 |
3 |
3 |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
2 |
CO6 |
3 |
β |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
3 |
3 |
AVG |
3 |
2.3 |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
3 |
2.7 |
Course Outcomes: Automation in Manufacturing (7th Semester)
COs |
Automation in Manufacturing (MEC-401A) |
CO1 |
Explain the role of automation in manufacturing and robotics industry. |
CO2 |
Describe the group technology and flexible manufacturing techniques in the automated production line and manufacturing system. |
CO3 |
Understand the computer aided process planning and shop floor manufacturing activities. |
CO4 |
Develop CNC programs and apply in industry for manufacturing. |
CO5 |
Understand the concept automated guided vehicle and automated storage system in material handling. |
CO-PO Mapping
CO |
PO1 |
PO2 |
PO3 |
PO4 |
PO5 |
PO6 |
PO7 |
PO8 |
PO9 |
PO10 |
PO11 |
PO12 |
PSO1 |
PSO2 |
CO1 |
3 |
2 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
2 |
CO2 |
3 |
3 |
2 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
3 |
CO3 |
3 |
3 |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
3 |
CO4 |
3 |
2 |
3 |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
3 |
3 |
CO5 |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
3 |
AVG |
3 |
2.5 |
2.7 |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
3 |
2.8 |
Course Outcomes: Computer Aided Design Lab (7th Semester)
COs |
Computer Aided Design (MEC-403LA) |
CO1 |
Understand and perform about the 2D drawing and modelling. |
CO2 |
Apply 3D software in part designing. |
CO3 |
Create various parts assembly design by using software |
CO4 |
Understand about G Codes and M codes. |
CO5 |
Understand and apply NC part programming and OPTIZE method. |
CO-PO Mapping
CO |
PO1 |
PO2 |
PO3 |
PO4 |
PO5 |
PO6 |
PO7 |
PO8 |
PO9 |
PO10 |
PO11 |
PO12 |
PSO1 |
PSO2 |
CO1 |
3 |
β |
3 |
3 |
2 |
β |
β |
β |
2 |
3 |
β |
β |
β |
3 |
CO2 |
3 |
2 |
2 |
2 |
3 |
β |
β |
β |
3 |
2 |
β |
β |
3 |
3 |
CO3 |
3 |
2 |
3 |
3 |
2 |
β |
β |
β |
3 |
2 |
β |
β |
2 |
3 |
CO4 |
3 |
2 |
3 |
2 |
3 |
β |
β |
β |
2 |
3 |
β |
β |
3 |
3 |
CO5 |
3 |
2 |
2 |
2 |
3 |
β |
β |
β |
3 |
2 |
β |
β |
3 |
3 |
AVG |
3 |
2 |
2.6 |
2.4 |
2.6 |
β |
β |
β |
2.6 |
2.4 |
β |
β |
2.7 |
3 |
Course Outcomes: Foundry Engineering (8th Semester)
COs |
Foundry Engineering (ME-422 N) |
CO1 |
Understand the conceptual knowledge of casting such as casting methods, pattern and pattern allowances. |
CO2 |
Understand the concept of moulding, core makingΒ and comparison of different moulding procedures |
CO3 |
Understand the gating system and casting method to rise ring practices |
CO4 |
Learn the casting defects their causes and remedies |
CO5 |
Understand the conceptual and procedural knowledge to produce the economical and defect free castings. |
CO-PO Mapping
CO |
PO1 |
PO2 |
PO3 |
PO4 |
PO5 |
PO6 |
PO7 |
PO8 |
PO9 |
PO10 |
PO11 |
PO12 |
PSO1 |
PSO2 |
CO1 |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO2 |
3 |
2 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO3 |
3 |
3 |
2 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO4 |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO5 |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
AVG |
3 |
2.5 |
2 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
Course Outcomes: Quality Assurance & Reliability (8th Semester)
COs |
Quality Assurance & Reliability (ME-406 N) |
CO1 |
Understand the conceptual knowledge of quality, quality assurance and management. |
CO2 |
UnderstandΒ Β factual and Procedural knowledge of X & R chart and Process capability. |
CO3 |
Learn to use sampling & the Errors in Making Inferences from Control Charts. |
CO4 |
Learn the concept of Reliability, Failure rate, Failure data analysis & Probability of failure |
CO5 |
Learn about the concept of quality, reliability and attributes and variable control charts. |
CO-PO Mapping
CO |
PO1 |
PO2 |
PO3 |
PO4 |
PO5 |
PO6 |
PO7 |
PO8 |
PO9 |
PO10 |
PO11 |
PO12 |
PSO1 |
PSO2 |
CO1 |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO2 |
3 |
2 |
β |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO3 |
3 |
3 |
β |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO4 |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO5 |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
AVG |
3 |
2.5 |
β |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
Course Outcomes: Automobile Engineering (8th Semester)
COs |
Automobile Engineering (ME-402 N) |
CO1 |
Understand the working of common automobile component, single and multi-cylinder engines, valve operating and fuel injection systems. |
CO2 |
Understand the working principles of clutches and their types. |
CO3 |
Understand the working principles of gearbox and their types. |
CO4 |
Understand the working principles of propeller shaft, differential and their types. |
CO5 |
Understand the working principles of brakes and their types. |
CO6 |
Understand the working principle of suspension systems like interconnected suspension system, air and liquid suspension system, independent and dependent suspension system and its components like dampers and springs. |
CO-PO Mapping
CO |
PO1 |
PO2 |
PO3 |
PO4 |
PO5 |
PO6 |
PO7 |
PO8 |
PO9 |
PO10 |
PO11 |
PO12 |
PSO1 |
PSO2 |
CO1 |
3 |
β |
β |
β |
2 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO2 |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO3 |
3 |
β |
β |
β |
2 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO4 |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO5 |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO6 |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
AVG |
3 |
β |
β |
β |
2 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
Course Outcomes: Power Plant Engineering (8th Semester)
COs |
Power Plant Engineering(ME-404N) |
CO1 |
Know about the different energy sources and power generation. |
CO2 |
Understand the concept of hydrology and details about the hydroelectric power plant. |
CO3 |
Ability to analyze steam cycle and learn about different handling systems used in steam power generators. |
CO4 |
Understand the environmental norms and standards in thermal power generation. |
CO5 |
Β Learn about combined cycles for power generation and diesel engine power plants. |
CO6 |
Understand the conceptual knowledge of nuclear energy, its resources and the economics of power generation. |
CO-PO Mapping
CO |
PO1 |
PO2 |
PO3 |
PO4 |
PO5 |
PO6 |
PO7 |
PO8 |
PO9 |
PO10 |
PO11 |
PO12 |
PSO1 |
PSO2 |
CO1 |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO2 |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO3 |
3 |
3 |
β |
2 |
β |
β |
3 |
β |
β |
β |
β |
β |
β |
β |
CO4 |
3 |
β |
β |
β |
β |
β |
3 |
β |
β |
β |
β |
β |
β |
β |
CO5 |
3 |
2 |
β |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO6 |
3 |
β |
β |
β |
β |
β |
2 |
β |
β |
β |
β |
β |
β |
β |
AVG |
3 |
2.5 |
β |
2.5 |
β |
β |
2.7 |
β |
β |
β |
β |
β |
β |
β |
Course Outcomes: Material Management (8th Semester)
COs |
Material Management (ME-426N) |
CO1 |
Understand the functional and conceptual aspects of production & operation management. |
CO2 |
Learn about theΒ practical knowledge of plant location andΒ different types ofΒ plant layout |
CO3 |
Understand the functional and managerial knowledge ofΒ material handling and management |
CO4 |
Understand theoretical and operational knowledge ofΒ Waste Management & Automation |
CO5 |
Understand the functional and conceptual aspects of material management and material handling |
CO-PO Mapping
CO |
PO1 |
PO2 |
PO3 |
PO4 |
PO5 |
PO6 |
PO7 |
PO8 |
PO9 |
PO10 |
PO11 |
PO12 |
PSO1 |
PSO2 |
CO1 |
3 |
2 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO2 |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO3 |
3 |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
CO4 |
3 |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
3 |
CO5 |
3 |
3 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
AVG |
3 |
2.75 |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
β |
3 |
Course Outcomes: Automobile Engineering Lab (8th Semester)
COs |
Automobile Engineering Lab( ME-408N) |
CO1 |
Understand construction details and working of various parts of automotive system |
CO2 |
Understand constructional details and working of Cylinder, Ignition System and Injection System of I C Engine. |
CO3 |
Summarize constructional details of Automotive Clutches, Automotive Transmission Systems Automotive Drive Lines & Differentials. |
CO4 |
Understand about design and constructional details of Automotive Suspension Systems and Automotive Suspension Systems. |
CO5 |
Understand about design and constructional details Automotive Tyres& wheels Automotive Brake Systems Automotive Emission / Pollution control systems. |
CO-PO Mapping
CO |
PO1 |
PO2 |
PO3 |
PO4 |
PO5 |
PO6 |
PO7 |
PO8 |
PO9 |
PO10 |
PO11 |
PO12 |
PSO1 |
PSO2 |
CO1 |
3 |
– |
– |
– |
– |
– |
– |
– |
2 |
3 |
– |
– |
– |
– |
CO2 |
3 |
3 |
– |
– |
– |
– |
– |
– |
3 |
3 |
– |
– |
– |
– |
CO3 |
3 |
2 |
– |
– |
– |
– |
– |
– |
2 |
2 |
– |
– |
– |
– |
CO4 |
3 |
2 |
3 |
3 |
– |
– |
– |
– |
3 |
3 |
– |
– |
– |
– |
CO5 |
3 |
2 |
3 |
2 |
– |
– |
– |
– |
3 |
3 |
– |
– |
– |
3 |
AVG |
3 |
2.25 |
3 |
2.5 |
– |
– |
– |
– |
2.6 |
2.8 |
– |
– |
– |
3 |