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B-TECH in Mechatronics Engineering at SRM Institute of Science and Technology (Deemed to be University)
Chengalpattu, Tamil Nadu
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About the Specialization
What is Mechatronics Engineering at SRM Institute of Science and Technology (Deemed to be University) Chengalpattu?
This Mechatronics Engineering program at Sri Ramaswamy Memorial Institute of Science and Technology focuses on an interdisciplinary blend of mechanical, electrical, computer, and control engineering. It equips students with the skills to design, develop, and implement smart systems, robotics, and automation solutions. With India''''s rapid industrialization and emphasis on smart manufacturing, this program is highly relevant, preparing graduates for cutting-edge roles in diverse industries.
Who Should Apply?
This program is ideal for aspiring engineers who possess a strong foundation in science and mathematics, along with a keen interest in integrated systems and automation. It suits fresh 10+2 graduates looking to enter dynamic fields like robotics, automotive, and smart manufacturing. Working professionals seeking to upskill in AI, IoT, or advanced automation will also find value. A prerequisite background in Physics, Chemistry, and Mathematics is generally expected.
Why Choose This Course?
Graduates of this program can expect diverse career paths in India''''s growing automation, automotive, aerospace, and defense sectors. Roles include Robotics Engineer, Automation Engineer, Embedded Systems Developer, and Design Engineer with competitive starting salaries often ranging from INR 4-8 LPA for freshers, growing significantly with experience. The curriculum aligns with industry demands, fostering skills crucial for roles in companies driving India''''s technological advancements.
Student Success Practices
Foundation Stage
Build Strong Engineering Fundamentals- (Semester 1-2)
Focus intensely on core subjects like Engineering Mathematics, Physics, Chemistry, and Electrical/Electronics. These form the bedrock for advanced Mechatronics concepts. Actively participate in lab sessions to gain practical understanding of basic circuits and mechanics. Join peer study groups to clarify doubts and reinforce learning.
Tools & Resources
NPTEL courses for foundational subjects, Khan Academy for concept clarity, College''''s physics/chemistry/electrical labs
Career Connection
A solid foundation is crucial for understanding complex systems later, leading to better problem-solving skills valued in engineering roles and competitive exams.
Master Programming and Data Structures- (Semester 1-2)
Develop strong programming skills in C/C++ by solving problems regularly. Understand data structures deeply as they are essential for embedded systems, robotics, and AI. Participate in coding contests and online judge platforms to improve logical thinking.
Tools & Resources
CodeChef, HackerRank, GeeksforGeeks, Online C/C++ tutorials
Career Connection
Proficiency in programming is a core skill for Mechatronics, enabling work in embedded systems, automation, and AI/ML, boosting employability in tech and core engineering companies.
Engage in Mechatronics Workshop Activities- (Semester 1-2)
Actively participate in the Mechatronics Workshop to gain hands-on experience with tools, electrical wiring, and basic sensor/actuator integration. This practical exposure builds confidence and bridges the gap between theory and application, fostering an engineering mindset early on.
Tools & Resources
College workshop facilities, Basic electronics kits, DIY projects with Arduino/Raspberry Pi
Career Connection
Practical skills are highly valued by employers for roles requiring hardware-software integration, enhancing readiness for internships and junior engineering positions.
Intermediate Stage
Undertake Mini Projects and Design Challenges- (Semester 3-5)
Apply theoretical knowledge by working on mini-projects involving sensors, microcontrollers, and actuators. Participate in design challenges or competitions (e.g., Robotics competitions, Hackathons) to enhance problem-solving, teamwork, and practical application skills.
Tools & Resources
Arduino/ESP32 development boards, SolidWorks/Fusion 360 for CAD, Matlab/Simulink for control simulation
Career Connection
Projects demonstrate initiative and technical competence, making your resume stand out for internships and job applications in automation and robotics firms.
Deep Dive into Control Systems and Embedded Programming- (Semester 3-5)
Master Control Systems Engineering and Microprocessors/Embedded Systems. These are central to Mechatronics. Practice designing and implementing control algorithms and embedded code for various applications. Explore RTOS (Real-Time Operating Systems) and advanced microcontroller families.
Tools & Resources
LabVIEW, Proteus/Multisim for circuit simulation, PIC/ARM microcontrollers and development kits, Code Composer Studio
Career Connection
Strong expertise in these areas opens doors to specialized roles in automotive embedded systems, industrial automation, and smart device development, commanding higher salaries.
Seek Industry Exposure and Networking- (Semester 3-5)
Attend industry seminars, workshops, and guest lectures to understand current trends and technologies. Network with professionals and alumni in the Mechatronics field. Explore internship opportunities even for short durations to gain a glimpse into corporate environments.
Tools & Resources
LinkedIn for professional networking, Industry magazines and journals, Career fairs and college placement cells
Career Connection
Networking often leads to internship and job opportunities. Industry exposure helps align your skills with market demands, making you a more desirable candidate.
Advanced Stage
Focus on Specialization and Advanced Projects- (Semester 6-8)
Choose professional electives wisely based on your career interests (e.g., Advanced Robotics, AI for Mechatronics, IoT). Engage deeply in your final year project, aiming for innovative solutions and possibly publishing your work. Collaborate with faculty on research initiatives.
Tools & Resources
ROS (Robot Operating System), OpenCV for Machine Vision, TensorFlow/PyTorch for AI/ML, High-performance microcontrollers
Career Connection
A strong final year project and specialized knowledge are critical for securing roles in R&D, product development, or pursuing higher studies (M.Tech/MS) in niche Mechatronics areas.
Undergo Comprehensive Placement Preparation- (Semester 6-8)
Actively participate in campus placement training programs, focusing on aptitude tests, technical interviews, and group discussions. Prepare a compelling resume and portfolio showcasing projects and skills. Practice mock interviews regularly to refine communication and technical articulation.
Tools & Resources
Placement cell workshops, Online aptitude platforms, InterviewBit/LeetCode for interview prep
Career Connection
Thorough preparation directly translates to successful placements in top-tier companies, securing competitive starting packages and a strong career launchpad.
Pursue Industry Internships and Certifications- (Semester 6-8)
Secure a meaningful industry internship in your area of interest (e.g., automation, robotics, embedded systems). Complement your degree with relevant certifications (e.g., Certified LabVIEW Developer, PLC Programming, IoT Developer, Robotics certification) to validate specialized skills.
Tools & Resources
NPTEL online certifications, Coursera/edX specialized courses, Industry-recognized certification bodies (e.g., Siemens, Rockwell Automation)
Career Connection
Internships provide invaluable real-world experience and often lead to pre-placement offers. Certifications enhance your resume, making you a more attractive candidate for specialized roles in the Indian job market.
Program Structure and Curriculum
Eligibility:
- Passed 10+2 or its equivalent with Physics, Chemistry, Mathematics (or Biology/Biotechnology/Computer Science/Informatics Practices/Interdisciplinary Vocational Course) with English as a compulsory subject from a recognized board, with a minimum of 50% aggregate marks.
Duration: 4 years / 8 semesters
Credits: 155 Credits
Assessment: Internal: 50%, External: 50%
Semester-wise Curriculum Table
Semester 1
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| U23MEE101T | Engineering Mathematics - I | Core | 3 | Matrices and Eigenvalue problems, Vector Calculus and its applications, Ordinary Differential Equations, Laplace Transforms, Applications in engineering |
| U23MEE102T | Engineering Physics | Core | 3 | Quantum Physics and Nanomaterials, Lasers and Fiber Optics, Crystal Physics and X-ray Diffraction, Modern Engineering Materials, Wave Optics and Interference |
| U23MEE103T | Engineering Chemistry | Core | 3 | Water Technology and Treatment, Electrochemistry and Batteries, Corrosion and its Control, Fuel Technology and Combustion, Polymer Chemistry and Composites |
| U23EAC101T | Professional English | Core | 3 | Basic Grammar and Sentence Structure, Reading Comprehension and Vocabulary, Writing Skills for academic purposes, Listening and Speaking for effective communication, Presentation Skills and Public Speaking |
| U23MEE104T | Basic Electrical and Electronics Engineering | Core | 3 | DC and AC Circuits fundamentals, Semiconductor Devices and Junction Diodes, Bipolar Junction Transistors (BJTs), Introduction to Logic Gates, Operational Amplifiers applications |
| U23MEE105P | Engineering Graphics & Design | Practical | 2 | Orthographic Projections, Isometric Projections, Sectional Views and Developments, Computer Aided Design (CAD) Software Basics, Assembly Drawings and Detailing |
| U23MEE106P | Basic Electrical and Electronics Engineering Laboratory | Practical | 1 | Verification of Ohm''''s Law and KVL/KCL, Characteristics of PN Junction Diode, Transistor Amplifier circuits, Verification of Logic Gates, Op-Amp based circuits |
| U23MEE107P | Engineering Physics and Chemistry Laboratory | Practical | 1 | Spectrometer experiments, Laser diffraction and interference, Viscosity and surface tension measurements, pH Metry and Conductometry, Water hardness determination |
| U23EAE101T | Environmental Science & Engineering | Ability Enhancement | 2 | Ecosystems and Biodiversity, Environmental Pollution and Control, Solid Waste Management, Natural Resources and Conservation, Environmental Ethics and Policies |
| U23EAS101T | Indian Constitution and Human Rights | Ability Enhancement | 1 | Preamble and Basic Structure of Constitution, Fundamental Rights and Duties, Directive Principles of State Policy, Union and State Governments, Human Rights and International Law |
Semester 2
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| U23MEE201T | Engineering Mathematics - II | Core | 3 | Multivariable Calculus, Vector Integration theorems, Complex Numbers and functions, Analytic Functions and conformal mapping, Sequences and Series |
| U23EAC201T | Technical English | Core | 3 | Technical Report Writing, Professional Correspondence and Email Etiquette, Job Application and Resume Writing, Group Discussions and Interview Skills, Technical Presentation techniques |
| U23MEE202T | Engineering Mechanics | Core | 3 | Force Systems and Equilibrium, Friction and its applications, Kinematics of Particles and Rigid Bodies, Dynamics of Particles and Rigid Bodies, Work, Energy, and Power |
| U23MEE203T | Manufacturing Processes | Core | 3 | Casting processes and defects, Forming operations (rolling, forging), Machining processes (turning, milling), Welding techniques and metallurgy, Introduction to Additive Manufacturing |
| U23MEE204T | C Programming and Data Structures | Core | 3 | C Language Fundamentals, Arrays, Pointers, and Strings, Functions and Recursion, Stacks, Queues, and Linked Lists, Searching and Sorting Algorithms |
| U23MEE205P | Manufacturing Processes Laboratory | Practical | 1 | Lathe and Milling Machine operations, Arc and Gas Welding practices, Foundry processes and sand molding, Sheet metal working operations, Introduction to 3D Printing |
| U23MEE206P | C Programming and Data Structures Laboratory | Practical | 1 | Implementation of arrays and pointers, Functions and recursive solutions, Stack and Queue implementations, Linked List operations, Searching and Sorting algorithm implementation |
| U23EAC202T | Engineering Ethics | Ability Enhancement | 1 | Ethical Theories and Dilemmas, Engineering as a Social Experiment, Professional Codes of Conduct, Safety, Rights, and Responsibility, Global Issues and Computer Ethics |
| U23MEE207P | Mechatronics Workshop | Practical | 2 | Basic Hand Tools and Measuring Instruments, Electrical Wiring and Safety, Sensor Integration basics, Actuator Control principles, Mechanical Assembly and Disassembly |
Semester 3
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| U23MEE301T | Engineering Mathematics - III | Core | 3 | Fourier Series and Transforms, Partial Differential Equations, Z-Transforms and Difference Equations, Numerical Methods for Engineering, Probability and Statistics |
| U23MEE302T | Strength of Materials | Core | 3 | Stress, Strain, and Elastic Constants, Torsion of Circular Shafts, Bending Moments and Shear Forces, Deflection of Beams, Columns and Struts |
| U23MEE303T | Digital Electronics and Microcontrollers | Core | 3 | Logic Families and Boolean Algebra, Combinational Logic Circuits, Sequential Logic Circuits (Flip-flops, Counters), Microcontroller Architecture (e.g., PIC/Arduino), Microcontroller Programming |
| U23MEE304T | Fluid Mechanics and Machinery | Core | 3 | Fluid Properties and Classification, Fluid Statics and Buoyancy, Fluid Dynamics and Bernoulli''''s Equation, Flow through Pipes and Open Channels, Hydraulic Turbines and Pumps |
| U23MEE305T | Object Oriented Programming with C++ | Core | 3 | Classes and Objects, Inheritance and Polymorphism, Encapsulation and Abstraction, Constructors and Destructors, File Handling and Exception Handling |
| U23MEE306P | Digital Electronics and Microcontrollers Laboratory | Practical | 1 | Implementation of Logic Gates, Design of Combinational Circuits, Design of Sequential Circuits (Counters), Interfacing ADC/DAC with Microcontroller, Microcontroller I/O Programming |
| U23MEE307P | Object Oriented Programming with C++ Laboratory | Practical | 1 | Class and Object implementation, Inheritance and Polymorphism examples, Operator Overloading, File I/O operations, Template programming |
| U23MEE308P | Mechatronics Design and Simulation Laboratory | Practical | 2 | CAD Modeling of Mechanical Components, Finite Element Analysis (FEA) basics, Kinematic analysis of mechanisms, Dynamic simulation of mechatronic systems, Multibody Dynamics software usage |
Semester 4
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| U23MEE401T | Sensors and Instrumentation | Core | 3 | Principles of Measurement and Transducers, Resistive, Inductive, and Capacitive Sensors, Optical and Temperature Sensors, Signal Conditioning and Data Acquisition, Smart Sensors and their applications |
| U23MEE402T | Theory of Machines | Core | 3 | Kinematics of Mechanisms, Dynamics of Machines and Inertia Forces, Cams and Followers, Gears and Gear Trains, Vibrations and Balancing |
| U23MEE403T | Microprocessors and Embedded Systems | Core | 3 | Microprocessor Architecture (e.g., 8085/8086), Assembly Language Programming, Memory and I/O Interfacing, Interrupts and Timers, Introduction to Embedded C Programming |
| U23MEE404T | Control Systems Engineering | Core | 3 | System Modeling and Transfer Functions, Block Diagram and Signal Flow Graph, Time Domain Analysis of Control Systems, Stability Analysis (Routh-Hurwitz, Root Locus), Frequency Domain Analysis (Bode, Nyquist) |
| U23MEE405T | Industrial Robotics | Core | 3 | Robot Kinematics (Forward and Inverse), Robot Dynamics and Control, Robot Programming Languages (e.g., VAL), End Effectors and Grippers, Industrial Robot Applications |
| U23MEE406P | Sensors and Instrumentation Laboratory | Practical | 1 | Calibration of various sensors (LVDT, Strain Gauge), Temperature measurement using Thermocouple, RTD, Pressure and Flow Measurement techniques, Data Acquisition System interfacing, Characteristics of different transducers |
| U23MEE407P | Microprocessors and Embedded Systems Laboratory | Practical | 1 | Assembly Language programming exercises, Interfacing I/O devices (LED, LCD), Timer/Counter programming, Serial Communication (UART), Introduction to Embedded System projects |
| U23MEE408P | Control Systems Engineering Laboratory | Practical | 1 | Open-loop and Closed-loop control systems, PID Controller tuning techniques, Lead-Lag Compensator design, Frequency response analysis experiments, Stability analysis using software tools |
Semester 5
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| U23MEE501T | Actuators and Drives | Core | 3 | DC and AC Motors and their control, Stepper Motors and Servo Motors, Hydraulic Actuators and Circuits, Pneumatic Actuators and Circuits, Motor Drives and their applications |
| U23MEE502T | Industrial Automation and PLC | Core | 3 | Fundamentals of Industrial Automation, Programmable Logic Controller (PLC) architecture, Ladder Logic Programming, SCADA Systems and HMI, Industrial Communication Protocols |
| U23MEE503T | Machine Vision and Image Processing | Core | 3 | Image Acquisition and Representation, Image Preprocessing and Filtering, Feature Extraction and Segmentation, Object Recognition and Classification, Machine Vision Applications in Industry |
| U23MEE504T | Artificial Intelligence and Machine Learning for Mechatronics | Core | 3 | Introduction to AI and ML, Supervised Learning (Regression, Classification), Unsupervised Learning (Clustering), Neural Networks and Deep Learning basics, Reinforcement Learning principles |
| U23MEE505P | Actuators and Drives Laboratory | Practical | 1 | Control of DC and AC motors, Stepper and Servo motor control, Hydraulic and Pneumatic system experiments, PID control of actuators, Drive selection and tuning |
| U23MEE506P | Industrial Automation and PLC Laboratory | Practical | 1 | PLC ladder logic programming exercises, Sensor and Actuator interfacing with PLC, HMI development for industrial processes, SCADA system simulation, Troubleshooting automation systems |
| U23MEE507P | Machine Vision and Image Processing Laboratory | Practical | 1 | Image acquisition and enhancement, Edge detection and segmentation algorithms, Object recognition techniques, Machine vision system calibration, Applications in quality control |
| U23MEOXXX | Open Elective - I | Open Elective | 3 | Selected from a pool of university-wide general subjects, Focus on interdisciplinary knowledge, Broadening academic interests, Developing complementary skills, Exploring diverse fields |
| U23MEEEXX | Professional Elective - I | Professional Elective | 3 | Selected from a pool of specialized subjects within Mechatronics, Deepening knowledge in a specific area, Advanced concepts in robotics or automation, Specialized sensor/actuator technologies, Emerging trends in Mechatronics |
| U23MEMXXX | Mandatory Course | Mandatory | 1 | Often includes Value Education, Soft Skills, or NSS, Developing personal and professional ethics, Enhancing communication and interpersonal skills, Promoting social responsibility, Holistic personality development |
Semester 6
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| U23MEE601T | Product Design and Development | Core | 3 | Product Life Cycle and Management, Design Thinking Process, Concept Generation and Selection, Prototyping and Testing, Design for Manufacturability and Assembly |
| U23MEE602T | Additive Manufacturing and Advanced Materials | Core | 3 | Principles of 3D Printing Technologies, Materials for Additive Manufacturing, Post-Processing Techniques, Design for Additive Manufacturing, Introduction to Advanced Composites |
| U23MEE603T | Internet of Things (IoT) for Mechatronics | Core | 3 | IoT Architecture and Protocols, Sensor Nodes and Gateways, Cloud Platforms for IoT, Edge Computing in IoT, IoT Applications in Industrial Automation |
| U23MEEEXX | Professional Elective - II | Professional Elective | 3 | Selected from a pool of specialized subjects within Mechatronics, Advanced robotics or control systems, Embedded system design, Industrial automation techniques, AI applications in Mechatronics |
| U23MEEEXX | Professional Elective - III | Professional Elective | 3 | Selected from a pool of specialized subjects within Mechatronics, Advanced manufacturing processes, MEMS and NEMS technology, Human-Robot Interaction, Automotive Mechatronics |
| U23MEOXXX | Open Elective - II | Open Elective | 3 | Selected from a pool of university-wide general subjects, Enhancing interdisciplinary perspectives, Developing soft skills and humanities knowledge, Exploring entrepreneurship or management, Cultural and societal aspects |
| U23MEE604P | Mini Project | Project | 2 | Problem Identification and Scope Definition, System Design and Component Selection, Prototype Development and Implementation, Testing, Debugging, and Evaluation, Technical Report Writing and Presentation |
| U23MEE605P | Industry Internship/Industrial Training | Internship | 2 | On-the-job training in industrial settings, Exposure to real-world engineering problems, Application of theoretical knowledge, Developing professional and teamwork skills, Industrial Report and Presentation |
Semester 7
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| U23MEE701T | CAD/CAM/CAE | Core | 3 | Advanced CAD Software Techniques, CAM Programming for CNC Machining, Computer Aided Engineering (CAE) for Simulation, Geometric Dimensioning and Tolerancing (GD&T), Product Lifecycle Management (PLM) |
| U23MEE702T | Micro-Electro-Mechanical Systems (MEMS) | Core | 3 | MEMS Fabrication Processes, Micro-sensors and their working principles, Micro-actuators and their applications, Micro-fluidics and Bio-MEMS, Introduction to Nano-Electro-Mechanical Systems (NEMS) |
| U23MEEEXX | Professional Elective - IV | Professional Elective | 3 | Selected from a pool of specialized subjects within Mechatronics, Advanced topics in control systems, Robotic vision and perception, Smart factories and Industry 4.0, Autonomous systems |
| U23MEEEXX | Professional Elective - V | Professional Elective | 3 | Selected from a pool of specialized subjects within Mechatronics, Advanced materials for mechatronic applications, Biomedical instrumentation and robotics, Renewable energy systems, Human-computer interaction |
| U23MEMXXX | Mandatory Course | Mandatory | 1 | Often includes advanced professional ethics or societal impact, Developing leadership and management skills, Entrepreneurship and innovation, Intercultural communication, Legal aspects of engineering |
| U23MEE703P | Project Work - Phase I | Project | 6 | Extensive Literature Survey and Research, Problem Identification and Formulation, Project Planning and Scheduling, Preliminary Design and Methodology Development, Proposal Writing and Presentation |
Semester 8
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| U23MEEEXX | Professional Elective - VI | Professional Elective | 3 | Selected from a pool of specialized subjects within Mechatronics, Advanced topics in IoT and Cyber-Physical Systems, Robotic process automation, Data analytics for manufacturing, Virtual and augmented reality in engineering |
| U23MEE801P | Project Work - Phase II | Project | 10 | System Implementation and Development, Extensive Testing and Validation, Data Collection and Analysis, Final Project Report Writing, Project Demonstration and Viva-Voce |
