B-TECH-LATERAL-ENTRY in Electronics And Instrumentation Engineering at Manipal Institute of Technology
Udupi, Karnataka
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About the Specialization
What is Electronics and Instrumentation Engineering at Manipal Institute of Technology Udupi?
This Electronics and Instrumentation Engineering program at Manipal Institute of Technology focuses on the design, development, and maintenance of advanced electronic systems and precision instruments. It addresses the growing need for automation and control in Indian industries like manufacturing, healthcare, and energy, equipping students with interdisciplinary skills crucial for modern industrial applications and technological innovation.
Who Should Apply?
This program is ideal for diploma holders seeking direct entry into advanced engineering studies, fresh graduates aiming for careers in automation and control, and working professionals looking to specialize in instrumentation, smart systems, or embedded technologies. Candidates with a strong foundation in electronics, physics, and mathematics are particularly well-suited.
Why Choose This Course?
Graduates can expect diverse career paths in core industries, R&D, and IT sectors across India. Roles include Instrumentation Engineer, Control System Engineer, Automation Specialist, and Embedded System Designer. Entry-level salaries typically range from INR 4-7 LPA, with experienced professionals earning significantly more. The program prepares students for leadership in industrial automation and cutting-edge sensor technology.
Student Success Practices
Foundation Stage
Build Strong Core Engineering Fundamentals- (Semester 1-2 (or first 2 semesters for lateral entry if foundational gaps exist))
Focus on mastering core concepts in mathematics, physics, and basic electrical/electronics. Utilize online resources like NPTEL and Khan Academy for supplementary learning and problem-solving. Join peer study groups to clarify doubts and reinforce understanding.
Tools & Resources
NPTEL, Khan Academy, MAHE e-learning portal, Dedicated MAHE faculty office hours
Career Connection
A solid foundation is crucial for understanding advanced engineering subjects and excelling in technical interviews for core engineering roles and competitive exams like GATE.
Develop Practical Problem-Solving Skills- (Semester 1-2 (or first 2 semesters for lateral entry if foundational gaps exist))
Actively participate in all laboratory sessions, ensuring a thorough understanding of experimental setups, data analysis, and reporting. Learn basic programming (C/Python) through competitive programming platforms and apply it to simple engineering problems.
Tools & Resources
Lab manuals, Coding platforms like HackerRank, LeetCode, Departmental workshops on programming
Career Connection
Hands-on experience and coding proficiency are highly valued by recruiters for roles in software development, data analysis, and R&D within the EIE domain.
Engage in Departmental and Technical Clubs- (Semester 1-2 (or first 2 semesters for lateral entry if foundational gaps exist))
Join clubs like the EIE student association or robotics club. Participate in technical workshops, mini-projects, and inter-collegiate competitions. This helps in networking, learning from seniors, and applying theoretical knowledge.
Tools & Resources
EIE Departmental Club, Robotics Club, MIT Innovation Centre, Inter-college tech fests
Career Connection
Builds teamwork, leadership, and practical skills. Creates a portfolio of projects, enhancing resume and interview performance for internships and placements.
Intermediate Stage
Master Instrumentation and Control Concepts- (Semester 3-5 (or semesters 1-3 for lateral entry))
Deep dive into subjects like Sensors and Transducers, Control Systems, and Microcontrollers. Apply theoretical knowledge by designing and simulating control loops and embedded systems using industry-standard software. Seek projects mentored by faculty focusing on these areas.
Tools & Resources
MATLAB/Simulink, LabVIEW, Proteus, NI Multisim, Departmental labs
Career Connection
Directly prepares students for core instrumentation, automation, and control engineering roles in manufacturing, process industries, and R&D.
Pursue Industry-Relevant Certifications and Workshops- (Semester 3-5 (or semesters 1-3 for lateral entry))
Enroll in online courses or workshops for PLCs, SCADA, industrial automation, or specific sensor technologies. These certifications add significant value, demonstrating practical skills beyond the curriculum.
Tools & Resources
Coursera, Udemy, NPTEL advanced modules, Local industry training centers, Vendor-specific certifications from Siemens, Rockwell
Career Connection
Makes students highly competitive for internships and entry-level positions in automation companies and enhances their profile for specialized roles.
Network with Professionals and Alumni- (Semester 3-5 (or semesters 1-3 for lateral entry))
Attend industry seminars, guest lectures, and career fairs. Actively connect with EIE alumni on LinkedIn for mentorship, internship leads, and career advice. Participate in departmental industry visits to understand real-world applications.
Tools & Resources
LinkedIn, Industry conferences, MAHE alumni network, Department career guidance cell
Career Connection
Opens doors to internship opportunities, valuable industry insights, and potential job referrals, significantly aiding placement efforts.
Advanced Stage
Undertake Comprehensive Major Projects and Internships- (Semester 6-8 (or semesters 4-6 for lateral entry))
Dedicate significant effort to major projects, ensuring they address real-world problems. Secure an industry internship for 4-6 months to gain practical experience, apply learned skills, and understand corporate work culture.
Tools & Resources
MAHE Project Labs, MIT Innovation Center, Company R&D departments, Industry mentors
Career Connection
Internships often lead to pre-placement offers (PPOs). Strong projects are excellent talking points in interviews and demonstrate problem-solving capabilities to potential employers.
Specialize Through Electives and Advanced Learning- (Semester 6-8 (or semesters 4-6 for lateral entry))
Strategically choose electives that align with career interests (e.g., Biomedical Instrumentation, VLSI Design, IoT). Pursue advanced topics through self-study, research papers, and participation in departmental research groups.
Tools & Resources
IEEE Xplore, Scopus, Research lab facilities, Faculty research mentors, Advanced NPTEL courses
Career Connection
Develops specialized expertise, making students prime candidates for niche roles, higher studies (M.Tech/MS), and research positions in specific EIE domains.
Prepare Holistically for Placements and Higher Education- (Semester 6-8 (or semesters 4-6 for lateral entry))
Start early with rigorous aptitude training, technical interview preparation, and resume building. Practice mock interviews. For higher education aspirations, prepare for competitive exams like GATE, GRE, or IELTS and work on Statement of Purpose (SOPs).
Tools & Resources
MAHE Placement Cell, Career counseling services, Online aptitude test platforms, Previous year question papers
Career Connection
Maximizes chances of securing desirable placements in top companies or gaining admission to prestigious national/international universities for postgraduate studies.
Program Structure and Curriculum
Eligibility:
- Passed 3-year diploma in an appropriate branch of Engineering / Technology with minimum 50% aggregate marks or equivalent grade from any recognized board of examination.
Duration: 4 years / 8 semesters (Lateral entry students typically join in 3rd or 5th semester, completing in 3 or 2 years respectively)
Credits: 160 Credits
Assessment: Internal: 50%, External: 50%
Semester-wise Curriculum Table
Semester 1
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| UCL1001 | Communicative English | Skill Based | 2 | Communication Skills, Written Communication, Oral Communication, Presentation Skills, Group Discussion |
| MAC1001 | Engineering Mathematics – I | Core | 4 | Differential Calculus, Integral Calculus, Multivariable Calculus, Vector Calculus, Differential Equations |
| PHL1001 | Engineering Physics | Core | 4 | Optics, Modern Physics, Quantum Mechanics, Solid State Physics, Electromagnetism |
| PHL1002 | Engineering Physics Lab | Lab | 1 | Experiments on Optics, Electricity, Magnetism, Modern Physics |
| CYL1001 | Engineering Chemistry | Core | 4 | Electrochemistry, Corrosion, Water Technology, Polymer Chemistry, Nanomaterials |
| CYL1002 | Engineering Chemistry Lab | Lab | 1 | Volumetric Analysis, Instrumental Analysis, Chemical Synthesis, Water Quality Testing |
| EEL1001 | Basic Electrical and Electronics Engineering | Core | 4 | DC Circuits, AC Circuits, Transformers, Diodes, Transistors |
| CSL1001 | Problem Solving using C | Core | 3 | C Programming Basics, Data Types, Control Structures, Functions, Arrays, Pointers |
| CSL1002 | Problem Solving using C Lab | Lab | 1 | C Programming Practice, Debugging, Algorithm Implementation |
| MEL1001 | Engineering Graphics | Core | 2 | Orthographic Projections, Isometric Projections, Sections, Development of Surfaces, CAD Basics |
| VEL1001 | Value Engineering | Core | 1 | Values, Ethics, Self-exploration, Human-human relationship, Professional ethics |
Semester 2
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| MAC1002 | Engineering Mathematics – II | Core | 4 | Linear Algebra, Vector Spaces, Eigenvalues, Numerical Methods, Laplace Transforms |
| MEC1001 | Engineering Mechanics | Core | 4 | Statics, Dynamics, Kinematics, Kinetics, Work and Energy |
| EEC1002 | Introduction to Electrical and Electronics Lab | Lab | 1 | Verification of Circuit Laws, Diode Characteristics, Transistor Characteristics, Logic Gates |
| CSL1003 | Object Oriented Programming using Python | Core | 3 | Python Fundamentals, Object-Oriented Concepts, Classes, Objects, Inheritance, Polymorphism |
| CSL1004 | Object Oriented Programming using Python Lab | Lab | 1 | Python Programming Practice, OOP Implementation, Data Structures in Python |
| MEL1002 | Manufacturing Process | Core | 2 | Foundry, Welding, Machining, Sheet Metal Operations, Additive Manufacturing |
| EEL1003 | Environmental Studies | Core | 2 | Ecosystems, Biodiversity, Environmental Pollution, Natural Resources, Sustainable Development |
| HUL1001 | Indian Constitution | Core | 1 | Preamble, Fundamental Rights, Directive Principles, Union and State Government, Judiciary |
| HUL1002 | Indian Traditional Knowledge | Core | 1 | Traditional Indian Science, Art and Architecture, Literature, Yoga, Medicine |
| UEL1001 | Universal Human Values | Skill Based | 1 | Human Values, Ethics in Profession, Self-Awareness, Right Understanding |
Semester 3
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| EIC2001 | Engineering Mathematics III | Core | 4 | Complex Variables, Fourier Series, Partial Differential Equations, Probability, Statistics |
| EIC2002 | Network Theory | Core | 4 | Network Theorems, AC Circuits, Resonance, Two-Port Networks, Transient Analysis |
| EIC2003 | Digital Electronics | Core | 4 | Logic Gates, Boolean Algebra, Combinational Circuits, Sequential Circuits, Memories |
| EIC2004 | Analog Electronic Circuits | Core | 4 | Diode Circuits, BJT Amplifiers, FET Amplifiers, Feedback Amplifiers, Oscillators |
| EIC2005 | Electronic Measurement and Instrumentation | Core | 4 | Measurement Systems, Transducers, Analog Meters, Digital Meters, Oscilloscopes |
| EIE2001 | Digital Electronics Lab | Lab | 1 | Logic Gates Implementation, Combinational Circuit Design, Sequential Circuit Design |
| EIE2002 | Analog Electronic Circuits Lab | Lab | 1 | Diode Characteristics, BJT Amplifier Design, FET Characteristics, Op-Amp Applications |
| EIE2003 | Electronic Measurement and Instrumentation Lab | Lab | 1 | Transducer Characterization, Bridge Circuits, Measurement of Electrical Quantities |
| EIC2006 | Universal Human Values 2 | Core | 1 | Harmony in the Family, Harmony in Society, Harmony in Nature, Holistic Understanding, Professional Ethics |
Semester 4
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| EIC2051 | Sensors and Transducers | Core | 4 | Sensor Principles, Resistive Transducers, Inductive Transducers, Capacitive Transducers, Optical Sensors |
| EIC2052 | Control Systems | Core | 4 | System Modeling, Block Diagram Reduction, Time Domain Analysis, Frequency Domain Analysis, Stability Analysis |
| EIC2053 | Linear Integrated Circuits | Core | 4 | Op-Amp Basics, Op-Amp Applications, Active Filters, Timers, Voltage Regulators |
| EIC2054 | Electrical Measurement and Instrumentation | Core | 4 | AC Bridges, DC Bridges, Potentiometers, Instrument Transformers, Energy Meters |
| CSL2055 | Data Structures and Algorithms | Core | 3 | Arrays, Linked Lists, Stacks, Queues, Trees, Graphs, Searching Algorithms, Sorting Algorithms |
| EIE2051 | Sensors and Transducers Lab | Lab | 1 | Strain Gauge, LVDT, Thermistor, RTD, Photoelectric Sensors, Bridge Measurements |
| EIE2052 | Control Systems Lab | Lab | 1 | PID Controller, Lead-Lag Compensator, Root Locus, Bode Plot, System Stability |
| EIE2053 | Linear Integrated Circuits Lab | Lab | 1 | Op-Amp Amplifiers, Active Filters, Waveform Generators, PLL, Voltage Regulators |
| EIP2051 | Mini Project 1 | Project | 1 | Project Planning, Design Implementation, Testing and Debugging, Documentation, Teamwork |
Semester 5
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| EIC3001 | Microcontrollers and Embedded Systems | Core | 4 | 8051 Microcontroller, ARM Processors, Embedded System Design, Interfacing Techniques, RTOS Basics |
| EIC3002 | Industrial Instrumentation | Core | 4 | Pressure Measurement, Level Measurement, Flow Measurement, Temperature Measurement, Industrial Control Valves |
| EIC3003 | Digital Signal Processing | Core | 4 | Discrete-Time Signals, Z-Transform, DFT, FFT, Digital Filter Design, Multirate Signal Processing |
| EIE3001 | Microcontrollers and Embedded Systems Lab | Lab | 1 | Microcontroller Programming, Interfacing Sensors, Motor Control, LCD Display Interfacing |
| EIE3002 | Industrial Instrumentation Lab | Lab | 1 | Calibration of Instruments, Pressure Transmitters, Level Sensors, Flow Meters, Temperature Transmitters |
| EIE3003 | Digital Signal Processing Lab | Lab | 1 | Signal Generation, Filtering, DFT Computation, FIR/IIR Filter Design |
| EIP3001 | Major Project I | Project | 3 | Problem Definition, Literature Review, System Design, Prototype Development, Project Management |
| EIE3xxx | Elective 1 | Elective | 3 | Biomedical Instrumentation, Optoelectronics, VLSI Design Principles, Advanced Control Systems, Digital Image Processing |
| XXX3xxx | Open Elective 1 | Open Elective | 3 | Interdisciplinary Studies, Professional Skills, Business Management, Humanities, Social Sciences |
Semester 6
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| EIC3051 | Process Control | Core | 4 | Process Dynamics, PID Controllers, Tuning Methods, Control Loop Components, Advanced Control Strategies |
| EIC3052 | Analytical Instrumentation | Core | 4 | Spectroscopic Methods, Chromatographic Methods, pH Meters, Conductivity Meters, Gas Analyzers |
| EIC3053 | VLSI Design | Core | 4 | CMOS Logic, VLSI Fabrication, VHDL/Verilog, ASIC Design Flow, FPGA Architecture |
| EIE3051 | Process Control Lab | Lab | 1 | PID Controller Tuning, Cascade Control, Ratio Control, Feedforward Control, Process Simulation |
| EIE3052 | Analytical Instrumentation Lab | Lab | 1 | Spectrophotometer, Gas Chromatograph, pH Meter Operation, Conductometer, Turbidity Meter |
| EIE3053 | VLSI Design Lab | Lab | 1 | VHDL/Verilog Programming, Logic Synthesis, FPGA Implementation, Simulation and Verification |
| EIP3051 | Major Project II | Project | 3 | System Integration, Testing and Validation, Performance Evaluation, Technical Report Writing, Presentation Skills |
| EIE3xxx | Elective 2 | Elective | 3 | MEMS, Renewable Energy Systems, Robotics and Automation, Artificial Intelligence for IoT, Industrial Data Analytics |
| XXX3xxx | Open Elective 2 | Open Elective | 3 | Interdisciplinary Studies, Professional Skills, Business Management, Humanities, Social Sciences |
Semester 7
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| EIC4001 | Industrial Automation and Robotics | Core | 4 | PLC, SCADA, DCS, Industrial Robots, Robot Kinematics, Trajectory Planning |
| EIC4002 | Virtual Instrumentation | Core | 4 | LabVIEW Programming, Data Acquisition, Signal Processing, Instrument Control, Real-Time Systems |
| EIP4001 | Internship | Internship | 6 | Industry Exposure, Practical Skill Application, Project Work, Professional Networking, Corporate Culture |
| EIE4xxx | Elective 3 | Elective | 3 | Image Processing, Wireless Sensor Networks, Deep Learning for Instrumentation, Industrial Cyber Security, Embedded Linux |
| EIE4xxx | Elective 4 | Elective | 3 | Optical Instrumentation, Smart Materials, Automotive Electronics, Biometrics, Power Electronics |
| XXX4xxx | Open Elective 3 | Open Elective | 3 | Interdisciplinary Studies, Professional Skills, Business Management, Humanities, Social Sciences |
Semester 8
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| EIC4051 | Internet of Things for Instrumentation | Core | 4 | IoT Architecture, Sensors and Actuators, Communication Protocols, Cloud Platforms, IoT Security |
| EIP4051 | Major Project III | Project | 6 | Advanced System Design, Prototyping, Validation and Testing, Publication Opportunities, Final Presentation |
| EIE4xxx | Elective 5 | Elective | 3 | Advanced Digital Control, Power Plant Instrumentation, Quality Control, Fuzzy Logic and Neural Networks, Biomedical Signal Processing |
| XXX4xxx | Open Elective 4 | Open Elective | 3 | Interdisciplinary Studies, Professional Skills, Business Management, Humanities, Social Sciences |