Syllabus

UGC NET Electronic Science Syllabus 2026: Official Exam Pattern & PDF

R
Virat
Updated: Jun 22, 2026
5 MIN READ
Get the latest UGC NET Electronic Science Syllabus 2026 and official exam pattern. Access the detailed curriculum and download the official PDF guide to streamline your exam preparation.

UGC NET Electronic Science Syllabus 2026

The UGC NET Electronic Science exam is divided into two distinct sections. Paper 1 evaluates core teaching and research aptitude, logical reasoning, and communication skills. Paper 2 is subject-specific, covering essential topics such as semiconductor physics, IC fabrication, network theory, digital electronics, microprocessor architecture, control systems, and transducer technology. This syllabus is meticulously designed to assess both conceptual knowledge and academic proficiency, preparing candidates for successful careers in research and higher education.

Download the UGC NET Electronic Science Syllabus PDF Here

For students aiming for a top rank in the UGC NET Electronic Science exam, leveraging the official syllabus PDF is essential. This document acts as your roadmap, outlining the critical sub-topics required for both Paper 1 and Paper 2. Click the link below to access and download your copy of the syllabus.

Download Official UGC NET Electronic Science Syllabus PDF

UGC NET Electronic Science Syllabus in Detail

The comprehensive unit-wise breakdown for the UGC NET Electronic Science Paper 2 syllabus is provided below:

Unit 1: Semiconductor Physics and Materials

  • Introduction to Semiconductors: This unit covers the fundamental concepts of semiconductors, including energy bands in solids, effective mass, density of states, and Fermi levels.
  • Semiconductor Devices: This section delves into various semiconductor devices like diodes, bipolar junction transistors (BJTs), and field-effect transistors (FETs), exploring their characteristics, operation principles, and biasing techniques.

Unit 2: Integrated Circuits (ICs) Fabrication

  • IC Fabrication Processes: This unit explores the different processes involved in IC fabrication, such as crystal growth, epitaxy, oxidation, lithography, doping, etching, isolation methods, metallization, and bonding.
  • Thin-Film Technology: This section covers thin-film deposition techniques like sputtering, evaporation, and chemical vapour deposition (CVD), along with characterization techniques like X-ray diffraction (XRD), transmission electron microscopy (TEM), scanning electron microscopy (SEM), and energy-dispersive X-ray spectroscopy (EDX).

Unit 3: Network Theory

  • Network Analysis Techniques: This unit focuses on methods for analyzing electrical circuits, including Kirchhoff’s current and voltage laws, nodal analysis, mesh analysis, superposition theorem, Thevenin’s theorem, Norton’s theorem, and maximum power transfer theorem.
  • Network Synthesis: This section explores techniques for designing electrical circuits with desired characteristics, including passive filter design and two-port network parameters.

Unit 4: Analog Electronics

  • Rectifiers and Power Supplies: This unit covers various rectifier circuits (half-wave, full-wave, bridge), along with power supply design principles, including voltage regulation and filtering techniques.
  • Linear Integrated Circuits (ICs): This section explores operational amplifiers (op-amps), their characteristics, and applications as inverting and non-inverting amplifiers, comparators, integrators, and differentiators.

Unit 5: Digital Electronics

  • Logic Families: This unit covers different digital logic families like TTL, CMOS, and ECL, exploring their characteristics, noise immunity, and power consumption.
  • Combinational and Sequential Circuits: This section dives into designing digital circuits using logic gates, including adders, subtractors, multiplexers, decoders, flip-flops, and counters.

Unit 6: Microprocessors and Microcontrollers

  • Microprocessor Fundamentals: This unit introduces the architecture of microprocessors, including the central processing unit (CPU), memory organization, instruction set, and addressing modes.
  • Microcontroller Programming: This section focuses on a specific microcontroller (e.g., 8051), exploring its architecture, instruction set, addressing modes, and interfacing techniques with external devices.

Unit 7: Communication Systems

  • Analog Communication Systems: This unit covers amplitude modulation (AM), frequency modulation (FM), and pulse modulation techniques, along with demodulation techniques.
  • Digital Communication Systems: This section explores digital modulation techniques like binary phase shift keying (BPSK), quadrature phase shift keying (QPSK), and Manchester encoding, along with digital transmission channels and error detection/correction techniques.

Unit 8: Control Systems

  • Control System Fundamentals: This unit introduces the basic concepts of control systems, including block diagrams, transfer functions, signal flow graphs, time-domain analysis, and frequency-domain analysis using Bode plots and root locus.
  • Applications of Control Systems: This section explores various applications of control systems in feedback control loops, industrial process control, and electromechanical systems.

Unit 9: Microwave Engineering

  • Microwave Theory: This unit covers the fundamentals of electromagnetic waves at microwave frequencies, including wave propagation in waveguides, cavity resonators, and transmission lines.
  • Microwave Devices and Circuits: This section explores various microwave devices like klystrons, magnetrons, travelling-wave tubes (TWTs), and microwave transistors, along with their applications in radar and communication systems.

Unit 10: Electronic Measurements and Instrumentation

  • Electronic Measuring Instruments: This unit covers various electronic instruments used for measuring voltage, current, resistance, power, frequency, and other electrical parameters.
  • Digital Instrumentation: This section explores the use of digital instruments like digital multimeters (DMMs) and oscilloscopes, along with data acquisition systems and computer-aided instrumentation.

Important Topics in UGC NET Electronic Science Syllabus

Below is an overview of the key topics and exam structure for the UGC NET Electronic Science paper.

  1. Electromagnetic Theory
  2. Quantum Mechanics
  3. Solid-State Electronics
  4. Digital Electronics
  5. Analog Electronics
  6. Microprocessors and Microcontrollers
  7. Communication Systems
  8. Electromagnetic Waves and Antennas
  9. Network Theory
  10. Control Systems
  11. Electronic Materials and Devices
  12. Signal Processing

UGC NET Electronic Science Exam Pattern

The UGC NET exam format is designed to test both general awareness and deep technical subject knowledge. The online examination lasts 3 hours, with no negative marking. Paper 1 consists of 50 compulsory multiple-choice questions (100 marks), while Paper 2 includes 100 questions (200 marks). Mastering this structure is vital for creating an effective study plan and achieving a qualifying score.

Paper Duration Total Questions Total Marks Question Type Sections Marking Scheme
Paper 1 1 hour 50 100 MCQs Teaching Aptitude, Research Aptitude, Reasoning, etc. +2 for Correct, No Negative Marking
Paper 2 2 hours 100 200 MCQs Electromagnetic Theory, Quantum Mechanics, etc. +2 for Correct, No Negative Marking

 

UGC NET Electronic Science Syllabus

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