B.Tech in Telecommunication Engineering
Semester-wise syllabus for B.Tech in Telecommunication Engineering
Year 1: Foundation in Basic Sciences & Engineering
Semester 1
1. Mathematics-I
- Calculus, matrices, differential equations.
2. Physics-I
- Mechanics, optics, thermodynamics.
3. Chemistry/Environmental Science
- Basics of chemistry or sustainability principles.
4. Basics of Electronics
- Semiconductor devices, diodes, transistors.
5. Programming in C
- Algorithms, data structures, problem-solving.
6. Workshop Practice
- Soldering, PCB design, basic circuits.
Semester 2
1. Mathematics-II
- Probability, statistics, Fourier series.
2. Physics-II
- Electromagnetism, quantum mechanics basics.
3. Digital Electronics
- Logic gates, combinational/sequential circuits.
4. Engineering Mechanics
- Statics, dynamics, and material properties.
5. Data Structures & Algorithms
- Linked lists, trees, sorting algorithms.
6. Lab-I
- Circuit simulations (Multisim), C programming.
Year 2: Core Electronics & Communication Principles
Semester 3
1. Mathematics-III
- Numerical methods, complex analysis.
2. Analog Communication Systems
- AM, FM, PM, modulation/demodulation techniques.
3. Network Analysis & Synthesis
- Thevenin/Norton theorems, filters, two-port networks.
4. Signals & Systems
- Time/frequency domain analysis, Laplace/Z-transforms.
5. Lab-II
- Analog communication circuits, signal processing (MATLAB).
Semester 4
1. Electromagnetic Theory
- Maxwell’s equations, wave propagation, antennas.
2. Digital Communication
- PCM, ASK, FSK, PSK, error detection/correction.
3. Microprocessors & Microcontrollers
- 8085/8086, ARM architecture, embedded systems.
4. Control Systems
- Feedback systems, stability analysis.
5. Lab-III
- Microcontroller programming (Arduino/8051), digital modulation.
Year 3: Advanced Communication & Networking
Semester 5
1. Optical Communication
- Fiber optics, WDM, OTDR, optical amplifiers.
2. Wireless Communication
- Cellular networks (2G to 5G), MIMO, OFDM.
3. Microwave Engineering
- Waveguides, RF components, microwave devices.
4. Elective-I
- IoT Fundamentals or Satellite Communication.
5. Lab-IV
- Antenna design (HFSS), optical fiber experiments.
Semester 6
1. Telecom Networks
- TCP/IP, OSI model, VoIP, SDN, VPN.
2. Mobile Communication
- GSM, CDMA, LTE, 5G architecture.
3. Telecom Software & Tools
- NS-3, Wireshark, MATLAB/Simulink.
4. Elective-II
- Network Security or Cloud Computing.
5. Lab-V
- Network simulation (Cisco Packet Tracer), 4G/5G testing.
6. Mini-Project
- Example: Designing a small-scale IoT-based communication system.
Year 4: Specializations & Industry Integration
Semester 7
1. Internet of Things (IoT)
- Sensor networks, protocols (MQTT, CoAP), edge computing.
2. Satellite Communication
- Orbits, link budget, VSAT, GPS systems.
3. Elective-III
- AI/ML for Telecom or 5G/6G Technologies.
4. Project Management
- Agile, SDLC, cost estimation.
5. Lab-VI
- IoT device integration, satellite signal analysis.
6. Internship/Industrial Training
- Industry exposure (e.g., telecom operators, hardware firms).
Semester 8
1. Telecom Policy & Regulations
- Spectrum allocation, TRAI guidelines, global standards.
2. Emerging Trends
- 6G, quantum communication, network virtualization.
3. Capstone Project
- Example projects:
- Designing a 5G network slice for smart cities.
- Building a secure VoIP system with encryption.
4. Viva/Comprehensive Exam
- Assessment of core telecom concepts.
Elective Options
- Network Security: Cryptography, firewalls, intrusion detection.
- Cloud & Edge Computing: AWS, Azure, fog computing.
- Radar Systems: Signal processing, target tracking.
- Wireless Sensor Networks: Zigbee, LoRaWAN.
- Embedded Systems: RTOS, IoT device programming.
Key Labs & Tools
- Simulation Tools: MATLAB, NS-3, Cisco Packet Tracer.
- Hardware: Spectrum analyzers, oscilloscopes, SDR (Software-Defined Radio).
- Programming: Python, C/C++, embedded systems (Arduino, Raspberry Pi).
- Networking: Configuring routers/switches, Wireshark for packet analysis.
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