.png&w=1920&q=75)
B-TECH in Electronics Instrumentation Engineering at Shanmugha Arts Science Technology & Research Academy (SASTRA)
Thanjavur, Tamil Nadu
.png&w=1920&q=75)
About the Specialization
What is Electronics & Instrumentation Engineering at Shanmugha Arts Science Technology & Research Academy (SASTRA) Thanjavur?
This Electronics & Instrumentation Engineering program at SASTRA Deemed University focuses on the integration of electronics, control systems, and measurement techniques crucial for modern industrial automation and smart systems. It emphasizes understanding and designing intelligent instruments and embedded systems, catering to the growing demand for automation experts in India''''s manufacturing, process, and technology sectors. The curriculum''''s blend of theoretical knowledge and practical application prepares students for complex real-world challenges in a rapidly evolving technological landscape.
Who Should Apply?
This program is ideal for fresh graduates with a strong foundation in science and mathematics, particularly those keen on engineering precise control systems, robotics, and industrial automation. It also serves working professionals in related fields looking to upskill in emerging areas like IoT, smart sensors, and embedded system design, and career changers transitioning into the high-demand instrumentation and automation industry. A strong analytical aptitude and interest in interdisciplinary problem-solving are key prerequisites.
Why Choose This Course?
Graduates of this program can expect diverse career paths in India as Instrumentation Engineers, Control Systems Engineers, Automation Specialists, Embedded Systems Developers, and R&D Engineers. Entry-level salaries typically range from INR 4-7 LPA, with experienced professionals earning upwards of INR 10-20 LPA in major Indian cities. Growth trajectories often lead to roles in project management, system integration, and advanced R&D, with opportunities for professional certifications in PLC, SCADA, and industrial IoT platforms.
Student Success Practices
Foundation Stage
Build Strong Mathematical and Programming Fundamentals- (Semester 1-2)
Dedicate time to thoroughly understand Calculus, Linear Algebra, and C Programming. These foundational subjects are crucial for advanced EIE concepts. Regularly solve problems from textbooks and online platforms to solidify understanding.
Tools & Resources
NPTEL courses on Calculus and Programming, HackerRank, CodeChef for C practice, Reference books like ''''Higher Engineering Mathematics'''' by B.S. Grewal
Career Connection
Strong fundamentals are essential for cracking technical interviews and building robust engineering solutions in later stages.
Develop Basic Circuit Simulation Skills- (Semester 1-2)
Start familiarizing yourself with basic circuit simulation software early on. Experiment with simple electrical and electronic circuits learned in courses like Basic Electrical and Electronics Engineering.
Tools & Resources
LTSpice, Tinkercad (for basic simulations), Multisim, College lab facilities
Career Connection
Proficiency in simulation tools is a vital skill for EIE engineers, used for design verification and troubleshooting in industrial roles.
Engage in Peer Learning and Study Groups- (Semester 1-2)
Form study groups with peers to discuss difficult concepts, solve problems together, and prepare for exams. Teaching and explaining concepts to others can significantly deepen your own understanding.
Tools & Resources
College library resources, Whiteboards, Online collaborative tools like Google Docs
Career Connection
Enhances communication and teamwork skills, which are highly valued in industrial settings and project environments.
Intermediate Stage
Pursue Mini-Projects and DIY Kits- (Semester 3-5)
Apply theoretical knowledge from Analog Electronics, Digital Logic, Microcontrollers, and Control Systems to build small-scale projects. Start with simple DIY kits involving Arduino/Raspberry Pi for sensor interfacing and automation.
Tools & Resources
Arduino/Raspberry Pi kits, Breadboards, Basic electronic components, Online tutorials (e.g., Instructables, YouTube channels), Department labs
Career Connection
Practical project experience demonstrates problem-solving abilities and hands-on skills to potential employers, especially for roles in embedded systems and industrial automation.
Seek Industry Exposure through Workshops and Internships- (Semester 4-5)
Actively participate in workshops on PLC, SCADA, industrial automation, IoT, or robotics. Look for short-term internships or industrial training programs during semester breaks to understand real-world applications.
Tools & Resources
College placement cell, Career fairs, Company websites, Industrial training institutes
Career Connection
Builds crucial industry contacts, provides insights into company culture, and enhances your resume with practical experience, significantly boosting placement chances.
Specialize in Key EIE Software Tools- (Semester 4-5)
Develop proficiency in industry-standard software tools relevant to EIE, such as MATLAB/Simulink for control system design, LabVIEW for virtual instrumentation, and EDA tools for circuit design.
Tools & Resources
University licensed software, Online courses (Coursera, Udemy) for MATLAB/LabVIEW, Official documentation, University labs
Career Connection
Mastery of these tools is often a prerequisite for specialized roles in R&D, design, and control engineering, making you highly employable.
Advanced Stage
Undertake a Substantial Capstone Project- (Semester 7-8)
Work on a challenging capstone project, ideally industry-sponsored or addressing a real-world problem. Focus on robust design, implementation, testing, and documentation, ensuring a complete and demonstrable solution.
Tools & Resources
Advanced lab equipment, Microcontrollers (ARM, ESP32), Sensor modules, Project guidance from faculty/industry mentors, Project management software
Career Connection
A strong final year project is a powerful portfolio item, showcasing expertise and problem-solving skills to recruiters, often leading to direct job offers.
Prepare Rigorously for Placements and Higher Studies- (Semester 6-8)
Begin intensive preparation for aptitude tests, technical interviews (focusing on EIE core subjects), and group discussions. Polish your resume, practice mock interviews, and attend career guidance sessions organized by the university. For higher studies, prepare for GATE/GRE/TOEFL.
Tools & Resources
SASTRA Placement Cell resources, Online aptitude platforms (e.g., IndiaBix), Technical interview guides, Previous year''''s question papers
Career Connection
Direct impact on securing desirable placements in core companies or admission to top universities for postgraduate studies.
Network with Industry Professionals and Alumni- (Semester 6-8)
Attend industry seminars, conferences, and technical symposiums. Leverage SASTRA''''s alumni network on platforms like LinkedIn to connect with professionals in your target industries. Seek advice and explore career opportunities.
Tools & Resources
LinkedIn, Professional body memberships (e.g., IEEE, IETE student chapters), University alumni events, Industry expos
Career Connection
Networking opens doors to hidden job markets, mentorship, and opportunities for referrals, critical for career advancement.
Program Structure and Curriculum
Eligibility:
- Passed 10+2 examination with Mathematics, Physics and Chemistry (or) 10+2 with Vocational Stream (Mathematics, Physics and Computer Science/Electronics/etc.) with a minimum aggregate of 60% in Mathematics, Physics and Chemistry/Vocational Subjects. Admission based on JEE Main scores and/or SASTRA''''s comprehensive evaluation process.
Duration: 8 semesters / 4 years
Credits: 158 Credits
Assessment: Internal: 40%, External: 60%
Semester-wise Curriculum Table
Semester 1
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| MAIR101 | Calculus and Linear Algebra | Core | 4 | Matrices, Eigenvalues and Eigenvectors, Calculus of Single Variable, Vector Calculus, Multiple Integrals |
| PHIR101 | Physics for Engineers | Core | 3 | Wave Optics, Laser Physics, Fiber Optics, Quantum Physics, Semiconductor Physics |
| CSIR101 | Programming in C | Core | 3 | C Fundamentals, Control Structures, Arrays and Strings, Functions and Pointers, Structures and Files |
| HSIR101 | English Language Skills | Core | 3 | Reading Comprehension, Writing Skills, Grammar and Vocabulary, Effective Communication, Presentation Techniques |
| MEIR101 | Engineering Graphics | Core | 2 | Orthographic Projections, Isometric Projections, Sectional Views, Development of Surfaces, Introduction to AutoCAD |
| PHIR102 | Physics Laboratory | Lab | 1 | Optics Experiments, Electricity and Magnetism, Semiconductor Device Characteristics, Measurement Techniques |
| CSIR102 | Programming in C Laboratory | Lab | 1 | Problem Solving using C, Conditional Statements and Loops, Array and String Operations, Function Implementation, File Handling |
| HSIR102 | Technical English Laboratory | Lab | 1 | Group Discussions, Presentation Skills, Public Speaking, Interview Preparation, Role Plays |
| IDIR101 | Environmental Science | Audit Course | 0 | Ecosystems and Biodiversity, Environmental Pollution, Natural Resources, Solid Waste Management, Renewable Energy Sources |
Semester 2
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| MAIR103 | Differential Equations and Laplace Transforms | Core | 4 | Ordinary Differential Equations, Partial Differential Equations, Laplace Transforms, Inverse Laplace Transforms, Fourier Series |
| CHIR101 | Engineering Chemistry | Core | 3 | Electrochemistry, Corrosion and its Control, Water Treatment, Polymer Chemistry, Nanomaterials and Applications |
| EEIR101 | Basic Electrical and Electronics Engineering | Core | 3 | DC and AC Circuits, Semiconductor Diodes, Bipolar Junction Transistors, Rectifiers and Filters, Basic Logic Gates |
| CSIR103 | Computational Statistics | Core | 3 | Probability Theory, Random Variables and Distributions, Hypothesis Testing, Regression Analysis, Statistical Software Applications |
| MEIR103 | Engineering Mechanics | Core | 3 | Statics of Particles and Rigid Bodies, Equilibrium, Dynamics of Particles, Kinematics of Rigid Bodies, Work, Energy, and Power |
| CHIR102 | Engineering Chemistry Laboratory | Lab | 1 | Volumetric Analysis, Water Hardness Determination, pH Metry and Conductometry, Spectrophotometric Analysis |
| EEIR102 | Basic Electrical and Electronics Engineering Laboratory | Lab | 1 | Verification of Circuit Laws, Diode and Transistor Characteristics, Rectifier Circuits, OP-Amp Applications |
| CSIR104 | Computational Statistics Laboratory | Lab | 1 | Data Visualization, Descriptive Statistics, Inferential Statistics, Regression and Correlation, Statistical Software Practice |
| IDIR102 | Professional Ethics and Human Values | Audit Course | 0 | Engineering Ethics, Moral Values, Professional Responsibilities, Ethical Dilemmas, Human Values in Society |
Semester 3
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| MAIR201 | Numerical Methods | Core | 4 | Solution of Algebraic Equations, Interpolation and Curve Fitting, Numerical Differentiation, Numerical Integration, Numerical Solution of ODEs |
| EIER201 | Analog Electronic Circuits | Core | 3 | BJT Biasing and Amplifiers, FET Characteristics and Amplifiers, Frequency Response of Amplifiers, Feedback Amplifiers and Oscillators, Operational Amplifiers |
| EIER202 | Digital Logic Design | Core | 3 | Boolean Algebra and Logic Gates, Combinational Logic Circuits, Sequential Logic Circuits, Registers and Counters, Memories and Programmable Logic Devices |
| EEIR201 | Network Analysis and Synthesis | Core | 3 | Circuit Laws and Network Theorems, AC Circuits and Resonance, Transient Analysis, Two-Port Networks, Network Synthesis Fundamentals |
| EIER203 | Signals and Systems | Core | 3 | Signal Classification, Linear Time-Invariant Systems, Fourier Series and Transforms, Laplace Transforms, Z-Transforms |
| EIER204 | Electronic Circuits Laboratory | Lab | 1 | BJT/FET Amplifier Design, Op-Amp Based Circuits, Oscillator Circuits, Rectifier and Filter Circuits |
| EIER205 | Digital Logic Design Laboratory | Lab | 1 | Logic Gates Implementation, Combinational Circuit Design, Sequential Circuit Design, HDL for Digital Circuits |
| EIER206 | Microprocessor and Microcontroller Fundamentals | Core | 3 | 8085/8086 Architecture, Instruction Set and Addressing Modes, Memory and I/O Interfacing, 8051 Microcontroller, Embedded C Programming |
| EIER207 | Microprocessor and Microcontroller Laboratory | Lab | 1 | Assembly Language Programming, I/O Device Interfacing, Timer and Interrupt Programming, Microcontroller Based Projects |
Semester 4
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| MAIR203 | Probability and Random Processes | Core | 4 | Probability Axioms, Random Variables and Functions, Probability Distributions, Stochastic Processes, Markov Chains |
| EIER208 | Linear Integrated Circuits | Core | 3 | Op-Amp Characteristics and Applications, Active Filters, Voltage Regulators, Phase Locked Loops (PLL), Data Converters (ADC/DAC) |
| EIER209 | Communication Systems | Core | 3 | Analog Modulation Techniques, Digital Modulation Techniques, Noise in Communication Systems, Radio Receivers and Transmitters, Multiplexing and Multiple Access |
| EEIR203 | Electrical Machines and Power Electronics | Core | 3 | Transformers, DC Machines, AC Machines, Thyristors and SCRs, DC-DC and DC-AC Converters |
| CSIR201 | Data Structures and Algorithms | Core | 3 | Arrays and Linked Lists, Stacks and Queues, Trees and Graphs, Sorting Algorithms, Searching Algorithms |
| EIER210 | Linear Integrated Circuits Laboratory | Lab | 1 | Op-Amp based Amplifier Design, Active Filter Implementation, Waveform Generators, PLL Applications |
| EIER211 | Communication Systems Laboratory | Lab | 1 | Amplitude Modulation/Demodulation, Frequency Modulation/Demodulation, Pulse Modulation Techniques, Digital Modulation Experiments |
| EEIR204 | Electrical Machines and Power Electronics Laboratory | Lab | 1 | Transformer Characteristics, DC Motor Control, AC Motor Control, Power Electronic Converter Testing |
| IDIR201 | Indian Constitution | Audit Course | 0 | Preamble and Fundamental Rights, Directive Principles of State Policy, Union and State Governments, Judiciary in India, Constitutional Amendments |
Semester 5
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| EIER301 | Control Systems | Core | 3 | Open and Closed Loop Systems, Transfer Functions and Block Diagrams, Stability Analysis (Routh-Hurwitz, Root Locus), Frequency Response Analysis (Bode, Nyquist), Compensator Design |
| EIER302 | Industrial Instrumentation | Core | 3 | Transducers and Sensors, Measurement of Temperature, Measurement of Pressure and Flow, Level and Displacement Measurement, Data Acquisition Systems |
| EIER303 | Digital Signal Processing | Core | 3 | Discrete-Time Signals and Systems, Z-Transform, Discrete Fourier Transform (DFT), Fast Fourier Transform (FFT), Digital Filter Design (FIR and IIR) |
| PEIR3XX | Program Elective I | Elective | 3 | Elective from a pool of specialized subjects in areas like VLSI, Advanced Control, Robotics, or Embedded Systems., Specific topics vary based on the elective chosen from the approved list., Examples include Virtual Instrumentation or Industrial Data Communication. |
| OEIR3XX | Open Elective I | Elective | 3 | Elective from inter-disciplinary subjects offered by other departments., Specific topics vary based on the elective chosen from the approved list., Examples include Fundamentals of Data Science or Principles of Management. |
| EIER304 | Control Systems Laboratory | Lab | 1 | System Modeling and Simulation, Controller Design using MATLAB/Simulink, PID Controller Tuning, Stability Analysis Experiments |
| EIER305 | Industrial Instrumentation Laboratory | Lab | 1 | Sensor Calibration and Characterization, Transducer Experiments (LVDT, RTD, Thermocouple), Flow and Pressure Measurement Systems, Introduction to PLC Programming |
| EIER306 | Digital Signal Processing Laboratory | Lab | 1 | Discrete-Time System Implementation, DFT and FFT Algorithms, FIR Filter Design, IIR Filter Design |
| EIER307 | Mini Project I | Project | 1 | Problem Identification, Literature Survey, System Design and Planning, Preliminary Implementation, Report Writing |
Semester 6
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| EIER308 | Process Control | Core | 3 | Process Dynamics, PID Controller Principles, Tuning Methods, Advanced Control Strategies, Introduction to PLC and DCS |
| EIER309 | Analytical Instrumentation | Core | 3 | Spectroscopic Methods (UV-Vis, IR), Chromatographic Techniques (GC, HPLC), pH and Conductivity Measurement, Gas Analyzers, Mass Spectrometry |
| EIER310 | Embedded Systems | Core | 3 | Microcontroller Architectures (ARM), Embedded C Programming, Real-Time Operating Systems (RTOS), Peripheral Interfacing (UART, SPI, I2C), IoT Applications |
| PEIR3XX | Program Elective II | Elective | 3 | Elective from a pool of specialized subjects in areas like VLSI, Advanced Control, Robotics, or Embedded Systems., Specific topics vary based on the elective chosen from the approved list., Examples include Power Plant Instrumentation or Computer Control of Processes. |
| OEIR3XX | Open Elective II | Elective | 3 | Elective from inter-disciplinary subjects offered by other departments., Specific topics vary based on the elective chosen from the approved list., Examples include Total Quality Management or Entrepreneurship Development. |
| EIER311 | Process Control Laboratory | Lab | 1 | PID Controller Implementation, Process Simulation, PLC/DCS Configuration, Control Valve Characteristics |
| EIER312 | Analytical Instrumentation Laboratory | Lab | 1 | Spectrophotometer Usage, pH and Conductivity Meters, Chromatography Experiments, Gas Analyzer Principles |
| EIER313 | Embedded Systems Laboratory | Lab | 1 | Microcontroller Programming, Sensor and Actuator Interfacing, RTOS Concepts, Embedded System Project Development |
| EIER314 | Mini Project II | Project | 1 | System Prototyping, Hardware-Software Integration, Testing and Debugging, Project Documentation |
| IDIR301 | Aptitude and Soft Skills | Audit Course | 0 | Quantitative Aptitude, Logical Reasoning, Verbal Ability, Group Discussion Skills, Interview Preparation |
Semester 7
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| EIER401 | Biomedical Instrumentation | Core | 3 | Bio-potential Electrodes, ECG, EEG, EMG Measurement, Blood Pressure and Respiration Monitors, Medical Imaging Systems, Therapeutic Equipment |
| EIER402 | Industrial Automation and Robotics | Core | 3 | PLC and SCADA Systems, Distributed Control Systems (DCS), Industrial IoT, Robotics Kinematics, Robot Control and Programming |
| PEIR4XX | Program Elective III | Elective | 3 | Elective from advanced EIE topics like Smart Sensors, IoT in Industry, or Advanced Digital Signal Processing., Specific topics vary based on the elective chosen from the approved list., Examples include Fiber Optic Instrumentation or Telemetry and Telecontrol. |
| PEIR4XX | Program Elective IV | Elective | 3 | Elective from advanced EIE topics like Smart Sensors, IoT in Industry, or Advanced Digital Signal Processing., Specific topics vary based on the elective chosen from the approved list., Examples include Mechatronics or Digital Image Processing. |
| OEIR4XX | Open Elective III | Elective | 3 | Elective from inter-disciplinary subjects offered by other departments., Specific topics vary based on the elective chosen from the approved list., Examples include Artificial Intelligence or Data Analytics. |
| EIER403 | Industrial Automation and Robotics Laboratory | Lab | 1 | PLC Programming with Ladder Logic, SCADA System Development, Robot Programming and Control, Industrial Communication Protocols |
| EIER404 | Project Work - Phase I | Project | 4 | Detailed Literature Review, Problem Definition and Scope, Methodology and Design Specification, Preliminary Results and Analysis |
| EIER405 | Comprehensive Viva Voce | Core | 1 | Assessment of overall subject knowledge, Understanding of core EIE concepts, Ability to articulate technical topics |
Semester 8
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| PEIR4XX | Program Elective V | Elective | 3 | Elective from highly specialized EIE domains like MEMS, Smart Manufacturing, or Machine Learning for Control., Specific topics vary based on the elective chosen from the approved list., Examples include Automotive Embedded Systems or Renewable Energy Systems. |
| PEIR4XX | Program Elective VI | Elective | 3 | Elective from highly specialized EIE domains like MEMS, Smart Manufacturing, or Machine Learning for Control., Specific topics vary based on the elective chosen from the approved list., Examples include Fuzzy Logic and Neural Networks or Virtual and Augmented Reality for Industrial Applications. |
| OEIR4XX | Open Elective IV | Elective | 3 | Elective from inter-disciplinary subjects offered by other departments., Specific topics vary based on the elective chosen from the approved list., Examples include Cyber Physical Systems or Supply Chain Management. |
| EIER406 | Project Work - Phase II | Project | 6 | Detailed Implementation and Fabrication, Testing, Validation and Performance Analysis, Results Interpretation, Technical Report Writing and Presentation |
| EIER407 | Industrial Internship | Core | 6 | Practical Application of Engineering Principles, Industry Specific Tools and Technologies, Problem Solving in Real-world Scenarios, Professional Work Ethics and Teamwork |
