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BSC in Electronics at Acharya Jagadish Chandra Bose College
Kolkata, West Bengal
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About the Specialization
What is Electronics at Acharya Jagadish Chandra Bose College Kolkata?
This Electronics Honours program at Acharya Jagadish Chandra Bose College focuses on foundational and advanced concepts in electronics, preparing students for the rapidly evolving Indian tech landscape. It delves into analog and digital electronics, communication systems, microprocessors, and VLSI design. The curriculum is designed to meet the growing industry demand for skilled professionals in areas like consumer electronics, telecommunications, and embedded systems in India.
Who Should Apply?
This program is ideal for high school graduates with a strong aptitude for physics and mathematics, seeking entry into the core electronics industry. it also caters to individuals passionate about understanding how electronic devices work and aspiring to build innovative solutions. Students looking for a robust theoretical foundation combined with practical skills to excel in the electronics sector will find this program highly beneficial.
Why Choose This Course?
Graduates of this program can expect diverse career paths in India, including roles as design engineers, test engineers, R&D associates, and technical support specialists in companies like TCS, Wipro, and various startups. Entry-level salaries typically range from INR 3-5 lakhs per annum, with significant growth potential. The program also serves as a strong foundation for pursuing higher studies like M.Sc. or M.Tech in specialized electronics fields.
Student Success Practices
Foundation Stage
Build Strong Mathematical & Physics Foundations- (Semester 1-2)
Dedicate extra time to understanding core concepts in calculus, differential equations, circuit theory, and electromagnetism. These form the bedrock of advanced electronics. Utilize online resources like Khan Academy, NPTEL, and textbooks beyond the curriculum.
Tools & Resources
NPTEL courses on Basic Electronics, Physics text-books (e.g., H.C. Verma, Resnick-Halliday), Online calculus tutorials
Career Connection
A solid foundation ensures understanding complex circuits and systems, crucial for R&D and design roles.
Master Basic Circuit Simulation & Prototyping- (Semester 1-2)
Actively engage in lab sessions, learning to use breadboards, multimeters, oscilloscopes, and signal generators. Supplement with virtual lab simulations (e.g., Proteus, Tinkercad, LTSpice) to experiment with circuits beyond classroom hours.
Tools & Resources
LTSpice, Proteus, Tinkercad, Breadboards, basic electronic components
Career Connection
Hands-on skills are essential for entry-level hardware design, testing, and troubleshooting roles in India''''s electronics manufacturing sector.
Develop Problem-Solving & Logical Thinking- (Semester 1-2)
Form study groups with peers to discuss complex problems and work through challenging assignments. Participate in college-level hackathons or mini-project competitions that involve basic electronic solutions.
Tools & Resources
Peer study groups, College technical clubs, Online problem-solving platforms
Career Connection
Enhances analytical skills, critical for debugging, circuit optimization, and innovative product development in any engineering role.
Intermediate Stage
Gain Proficiency in Microcontroller & Programming- (Semester 3-5)
Beyond syllabus, explore various microcontrollers (e.g., Arduino, Raspberry Pi) and embedded C programming. Undertake personal projects involving sensor interfacing, automation, or IoT devices to deepen understanding.
Tools & Resources
Arduino IDE, Raspberry Pi, Microcontroller development kits, Online tutorials (e.g., Circuit Digest, Electronics For You)
Career Connection
Highly sought-after skill in India''''s embedded systems, IoT, and automotive electronics industries, opening doors to design and development roles.
Undertake Skill-Specific Certifications & Workshops- (Semester 3-5)
Participate in workshops or pursue certifications in areas like Digital Signal Processing (DSP), PCB design, or specific EDA tools (e.g., MATLAB, Verilog/VHDL). This specialized knowledge complements the core curriculum.
Tools & Resources
NPTEL certifications, Coursera/edX courses, Local electronics training centers, College-organized workshops
Career Connection
Provides a competitive edge for internships and jobs, demonstrating expertise in niche areas relevant to companies like Synopsis, Cadence, or Tata Elxsi.
Seek Industry Internships & Projects- (Semester 3-5)
Actively search for summer internships in electronics manufacturing, telecommunication companies, or R&D firms. Engage in department projects that simulate real-world industry challenges under faculty guidance.
Tools & Resources
College placement cell, LinkedIn, Internshala, Industry contacts, faculty research labs
Career Connection
Practical industry exposure is invaluable for understanding work environments, building professional networks, and securing pre-placement offers in Indian companies.
Advanced Stage
Specialization & Capstone Project Excellence- (Semester 5-6)
Focus on a chosen specialization (e.g., VLSI, Digital Communication, Embedded Systems) through DSEs. Dedicate significant effort to the final year capstone project, ensuring it addresses a relevant problem, demonstrates innovative solutions, and utilizes advanced tools.
Tools & Resources
Advanced EDA software (e.g., Tanner EDA for VLSI, MATLAB for DSP), Research papers, Project guides
Career Connection
A strong project acts as a portfolio piece, showcasing expertise and problem-solving abilities to recruiters from core electronics companies and startups.
Intensive Placement & Interview Preparation- (Semester 6)
Begin rigorous preparation for placement drives by practicing aptitude tests, technical interviews (focusing on core electronics concepts), and soft skills. Attend mock interviews and career counseling sessions offered by the college.
Tools & Resources
Online aptitude platforms (e.g., IndiaBix, GeeksforGeeks), Interview preparation books, College career services, Alumni network
Career Connection
Essential for converting opportunities into successful placements with leading Indian and multinational companies recruiting from campuses.
Professional Networking & Higher Education Planning- (Semester 5-6)
Attend industry seminars, conferences, and networking events to connect with professionals and stay updated on industry trends. For those considering higher studies, research M.Tech/M.Sc. programs, GATE exam preparation, or international study options.
Tools & Resources
LinkedIn, Industry events (e.g., Electronica India), Educational fairs, GRE/GATE coaching centers
Career Connection
Opens doors to advanced career opportunities, specialized research roles, and academic pursuits both within India and abroad, fostering long-term professional growth.
Program Structure and Curriculum
Eligibility:
- Passed Higher Secondary (10+2) or equivalent with Physics, Chemistry, and Mathematics (or Computer Science/Electronics) as subjects. Minimum 45% marks in aggregate and 50% in the subject/related subject OR 50% in aggregate and 45% in the subject/related subject in the previous qualifying examination.
Duration: 3 years (6 semesters)
Credits: 144 Credits
Assessment: Internal: 20% (for theoretical components), External: 80% (for theoretical components, plus 100% for practical components)
Semester-wise Curriculum Table
Semester 1
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| AECC1 | Environmental Studies | Ability Enhancement Compulsory Course | 2 | Multidisciplinary nature of environmental studies, Natural resources and associated problems, Ecosystems, Biodiversity and its conservation, Environmental pollution, Social issues and the environment |
| GE1 | Generic Elective - 1 | Generic Elective | 6 | Subject will be chosen from a list of generic electives (e.g., Physics, Chemistry, Mathematics, Computer Science, Statistics), Core concepts of the chosen discipline, Fundamental theories and principles, Problem-solving approaches, Basic applications |
| ELT-A-CC-1-1-TH | Basic Electronic Circuits | Core | 4 | Circuit Analysis Techniques (KCL, KVL), Network Theorems (Thevenin, Norton), P-N Junction Diode & Zener Diode, Rectifier Circuits & Filters, Bipolar Junction Transistor (BJT) Characteristics |
| ELT-A-CC-1-1-P | Basic Electronic Circuits Lab | Core Lab | 2 | Ohm''''s Law, KVL, KCL verification, Diode & Zener Diode characteristics, Half-wave & Full-wave Rectifiers, BJT input & output characteristics, Voltage Divider Biasing |
| ELT-A-CC-1-2-TH | Applied Physics | Core | 4 | Vector Calculus & Electrostatics, Magnetostatics & Electromagnetic Induction, AC Circuits & Resonance, Geometrical & Physical Optics, Quantum Mechanics & Atomic Structure |
| ELT-A-CC-1-2-P | Applied Physics Lab | Core Lab | 2 | Electrical Measurements (Multimeter, Galvanometer), Capacitor charging & discharging, Series & Parallel Resonance, Refractive Index of liquids, Spectrometer experiments |
Semester 2
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| AECC2 | Communication Skills / Bengali / Hindi / Urdu / Santali | Ability Enhancement Compulsory Course | 2 | Reading comprehension, Writing skills, Grammar and vocabulary, Effective communication strategies, Official Language studies (Bengali/Hindi/Urdu/Santali) |
| GE2 | Generic Elective - 2 | Generic Elective | 6 | Subject will be chosen from a list of generic electives (different from GE1), Fundamental concepts and theories, Analytical techniques, Applications and problem-solving, Basic experimental methods |
| ELT-A-CC-2-3-TH | Digital Electronics | Core | 4 | Number Systems & Binary Codes, Boolean Algebra & Logic Gates, Combinational Circuits (Adders, Decoders), Sequential Circuits (Flip-Flops, Registers), Counters & Memory Devices |
| ELT-A-CC-2-3-P | Digital Electronics Lab | Core Lab | 2 | Verification of Logic Gates, Universal Gates (NAND, NOR), Half & Full Adders/Subtractors, Multiplexers & Demultiplexers, Flip-Flop operation (SR, JK, D, T) |
| ELT-A-CC-2-4-TH | Electronic Devices | Core | 4 | Semiconductor Physics, Special Purpose Diodes (LED, Photodiode), Field Effect Transistors (JFET, MOSFET), Biasing of Transistors, Operational Amplifier Basics |
| ELT-A-CC-2-4-P | Electronic Devices Lab | Core Lab | 2 | Characteristics of JFET & MOSFET, Common Emitter Amplifier, Common Source Amplifier, Clipping & Clamping Circuits, Op-Amp as Inverting/Non-Inverting Amplifier |
Semester 3
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| SEC1 | Basic Instrumentation | Skill Enhancement Course | 2 | Introduction to Measurement Systems, Analog & Digital Multimeters, Cathode Ray Oscilloscope (CRO), Signal Generators & Power Supplies, Basic Sensors & Transducers |
| GE3 | Generic Elective - 3 | Generic Elective | 6 | Subject will be chosen from a list of generic electives (different from GE1, GE2), Advanced topics in the chosen discipline, Methodologies and techniques, Application-oriented studies, Data analysis and interpretation |
| ELT-A-CC-3-5-TH | Operational Amplifiers and Analog Communication | Core | 4 | Op-Amp Applications (Adder, Integrator, Differentiator), Active Filters (Low Pass, High Pass), Comparators & Oscillators (Wien Bridge, Phase Shift), Amplitude Modulation (AM), Frequency Modulation (FM) |
| ELT-A-CC-3-5-P | Operational Amplifiers and Analog Communication Lab | Core Lab | 2 | Op-Amp as Summing Amplifier & Subtractor, Active Low Pass & High Pass Filters, Wien Bridge Oscillator, AM Modulator & Demodulator, FM Modulator & Demodulator |
| ELT-A-CC-3-6-TH | Microprocessors and Microcontrollers | Core | 4 | 8085 Microprocessor Architecture, 8085 Instruction Set & Addressing Modes, Assembly Language Programming, Memory & I/O Interfacing, 8051 Microcontroller Architecture & Basics |
| ELT-A-CC-3-6-P | Microprocessors and Microcontrollers Lab | Core Lab | 2 | 8085 Assembly Language Programs, Data Transfer Operations, Arithmetic & Logical Operations, Interfacing with LEDs & Switches, Memory & I/O Address Decoding |
| ELT-A-CC-3-7-TH | Electromagnetic Theory and Wave Propagation | Core | 4 | Vector Calculus & Coordinate Systems, Electrostatic Fields (Coulomb''''s Law, Gauss''''s Law), Magnetostatic Fields (Ampere''''s Law, Biot-Savart Law), Maxwell''''s Equations, Electromagnetic Wave Propagation (Plane Waves) |
| ELT-A-CC-3-7-P | Electromagnetic Theory and Wave Propagation Lab | Core Lab | 2 | Magnetic Field measurement, Faraday''''s Law verification, Study of EM spectrum, Antenna Radiation Patterns, Transmission Line characteristics |
Semester 4
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| SEC2 | Python Programming | Skill Enhancement Course | 2 | Python Basics & Data Types, Control Flow Statements, Functions & Modules, File Handling, Object-Oriented Programming Concepts |
| GE4 | Generic Elective - 4 | Generic Elective | 6 | Subject will be chosen from a list of generic electives (different from GE1, GE2, GE3), Advanced concepts and applications, Research methodologies, Problem-solving in specialized domains, Interdisciplinary connections |
| ELT-A-CC-4-8-TH | Communication Electronics | Core | 4 | Communication Systems Block Diagram, Noise in Communication Systems, Pulse Modulation Techniques (PAM, PWM, PPM), Digital Modulation Techniques (ASK, FSK, PSK), Radio Transmitters & Receivers |
| ELT-A-CC-4-8-P | Communication Electronics Lab | Core Lab | 2 | PAM & PWM generation/detection, ASK & FSK modulation/demodulation, PLL (Phase Locked Loop) characteristics, Mixer Circuits, AM/FM Transceiver study |
| ELT-A-CC-4-9-TH | Signals and Systems | Core | 4 | Classification of Signals & Systems, Linear Time Invariant (LTI) Systems, Convolution & Correlation, Fourier Series & Fourier Transform, Laplace Transform & Z-transform |
| ELT-A-CC-4-9-P | Signals and Systems Lab | Core Lab | 2 | Generation of elementary signals, System response to various inputs, Convolution using software (MATLAB/Scilab), Fourier Series analysis, Z-transform computations |
| ELT-A-CC-4-10-TH | Analog Circuit Design | Core | 4 | Feedback Amplifiers, Sinusoidal Oscillators (RC, LC, Crystal), Power Amplifiers (Class A, B, AB, C), Voltage Regulators (Series, Shunt), Filters (Butterworth, Chebyshev) |
| ELT-A-CC-4-10-P | Analog Circuit Design Lab | Core Lab | 2 | Negative Feedback Amplifier design, Wien Bridge Oscillator design, Class A & Class B Power Amplifiers, Zener Diode based Voltage Regulator, Active Filter characteristics |
Semester 5
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| SEC3 | PCB Design | Skill Enhancement Course | 2 | Introduction to PCB Technology, Schematic Capture using EDA Tools, Component Placement & Routing, Design Rules Checking (DRC), PCB Fabrication Process |
| DSE1 | Digital Communication | Discipline Specific Elective | 6 | Sampling Theorem & Quantization, Pulse Code Modulation (PCM) & Delta Modulation (DM), Line Coding Techniques, Digital Modulation Schemes (ASK, FSK, PSK, QAM), Error Control Coding (Block Codes, Convolution Codes) |
| ELT-A-CC-5-11-TH | Digital Signal Processing | Core | 4 | Discrete-Time Signals & Systems, Z-Transform & its properties, Discrete Fourier Transform (DFT) & FFT Algorithms, Digital Filter Design (FIR & IIR), Multirate Digital Signal Processing |
| ELT-A-CC-5-11-P | Digital Signal Processing Lab | Core Lab | 2 | DFT & FFT computation using software (MATLAB/Scilab), FIR Filter Design (Window Method), IIR Filter Design (Bilinear Transformation), Sampling Rate Conversion, Applications of DSP |
| ELT-A-CC-5-12-TH | Computer Networks | Core | 4 | Network Models (OSI, TCP/IP), Physical Layer & Data Link Layer, Network Layer (IP Addressing, Routing), Transport Layer (TCP, UDP), Application Layer Protocols (HTTP, FTP, DNS) |
| ELT-A-CC-5-12-P | Computer Networks Lab | Core Lab | 2 | Network Configuration & IP Addressing, Packet Analysis using Wireshark, Socket Programming, Client-Server Communication, Network Troubleshooting Commands |
Semester 6
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| SEC4 | Project Work | Skill Enhancement Course | 2 | Project Idea Generation & Feasibility Study, System Design & Component Selection, Hardware/Software Implementation, Testing & Debugging, Report Writing & Presentation |
| DSE2 | Embedded Systems | Discipline Specific Elective | 6 | Introduction to Embedded Systems, Microcontroller Architectures (PIC, ARM), Interfacing with Peripherals (ADC, DAC, Sensors), Real-Time Operating Systems (RTOS) Concepts, Embedded C Programming |
| ELT-A-CC-6-13-TH | Control Systems | Core | 4 | Open-loop & Closed-loop Control Systems, Transfer Function & Block Diagram Reduction, Time Domain Analysis (Transient & Steady State), Stability Analysis (Routh-Hurwitz, Bode Plots), PID Controllers & Compensation Techniques |
| ELT-A-CC-6-13-P | Control Systems Lab | Core Lab | 2 | Step Response of First & Second Order Systems, Frequency Response Analysis, PID Controller implementation, Root Locus Plotting, System Simulation using software (MATLAB/Scilab) |
| ELT-A-CC-6-14-TH | VLSI Design | Core | 4 | CMOS Technology & Fabrication Process, MOS Transistor Theory & Characteristics, CMOS Inverter & Logic Gates, Sequential Circuit Design, ASIC Design Flow & HDL (Verilog/VHDL) Basics |
| ELT-A-CC-6-14-P | VLSI Design Lab | Core Lab | 2 | CMOS Inverter Characteristics using SPICE, Design of basic logic gates in CMOS, Layout Design of simple gates, Simulation of Sequential Circuits, Introduction to FPGA/CPLD programming |
