Master's program in Mechanical Engineering
*Program Overview*
- *Credits*: 30–36 credits (varies by institution).
- *Specializations*: Robotics, Aerospace, Energy Systems, Advanced Manufacturing, Automotive Engineering, Biomechanics, Materials Science, or Thermofluids.
*Core Courses (Fundamental Subjects)*
1. *Advanced Mathematics for Engineers*
- Numerical methods, linear algebra, partial differential equations, optimization techniques.
- Applications in modelling and simulations.
2. *Advanced Thermodynamics*
- Combustion theory, energy systems, entropy analysis, refrigeration cycles, and renewable energy integration.
3. *Computational Fluid Dynamics (CFD)*
- Finite volume methods, turbulence modelling, meshing techniques, and software tools (ANSYS, OpenFOAM).
4. *Advanced Mechanics of Materials*
- Stress-strain analysis, fracture mechanics, composite materials, and fatigue failure.
5. *Heat and Mass Transfer*
- Conduction, convection, radiation, phase change, and applications in thermal systems.
6. *Dynamics and Vibrations*
- Multibody dynamics, nonlinear vibrations, rotor dynamics, and control of mechanical systems.
7. *Advanced Control Systems*
- PID control, state-space modeling, robotics control, and AI/ML applications in automation.
8. *Finite Element Analysis (FEA)*
- Structural analysis, modal analysis, and software tools (ABAQUS, COMSOL).
*Elective Courses (Specialization-Based)*
*Robotics & Automation*
- Mechatronics
- Robot Dynamics and Control
- Autonomous Systems and AI
*Energy & Sustainability*
- Renewable Energy Systems (solar, wind, hydrogen)
- Energy Storage Technologies
- Sustainable Design and Lifecycle Analysis
*Aerospace Engineering*
- Aerodynamics
- Propulsion Systems
- Spacecraft Dynamics
*Advanced Manufacturing*
- Additive Manufacturing (3D printing)
- Smart Manufacturing (Industry 4.0, IoT)
- Precision Engineering
*Materials Science*
- Nanomaterials and Nanotechnology
- Composite Materials
- Corrosion and Surface Engineering
*Biomechanics*
- Biomedical Device Design
- Prosthetics and Orthotics
- Computational Biomechanics
*Automotive Engineering*
- Vehicle Dynamics
- Hybrid/Electric Vehicle Systems
- Crashworthiness and Safety
*Research/Thesis Component*
- *Thesis Proposal*: Literature review, problem statement, methodology.
- *Independent Research*: 6–12 months of lab/experimental work.
- *Dissertation Defence*: Presentation and evaluation.
- *Capstone Project* (non-thesis track): Industry-sponsored or applied research project.
*Laboratory/Practical Work*
- *CFD/FEA Labs*: Simulation-based projects.
- *Advanced Materials Testing*: SEM, XRD, mechanical testing.
- *Robotics and Automation Labs*: ROS (Robot Operating System), PLC programming.
- *Thermal Systems Lab*: Heat exchanger design, refrigeration cycles.
*Additional Components*
- *Seminars/Workshops*: Research ethics, technical writing, patent filing.
- *Internships/Industry Collaboration*: Optional for applied programs.
- *Professional Development*: Courses in project management, entrepreneurship.
*Sample Semester-wise Structure*
| *Semester 1* | *Semester 2* |
|------------------------------------|------------------------------------|
| - Advanced Thermodynamics | - Computational Fluid Dynamics |
| - Finite Element Analysis | - Advanced Control Systems |
| - Mechanics of Composite Materials | - Elective 1 (Specialization) |
| - Research Methodology | - Elective 2 |
| *Semester 3* | *Semester 4* |
|------------------------------------|------------------------------------|
| - Elective 3 | - Thesis/Capstone Project Completion |
| - Thesis Work (Proposal + Initial Research) | - Dissertation Defense |
*Key Skills Developed*
- Computational modelling (ANSYS, MATLAB, Python).
- Advanced design and simulation.
- Experimental and analytical problem-solving.
- Cross-disciplinary collaboration.
Master's in Engineering