UGC NET Electronic Science Syllabus 2024 & Exam Pattern PDF Download

NTA has announced the exam date for UGC NET 2024 from 1st January 2025 to 19th January 2025. Application link is live now, apply before 10th December 2024. The syllabus can be checked from the official notification. Candidates choosing Electronic Science can also find their syllabus. UGC will conduct two papers on Electronic Science subjects. Candidates should check the detailed Electronic Science syllabus before starting their exam preparation. Here we are providing UGC NET Electronic Science Syllabus 2024 and Exam Pattern PDF with details in the article below.

UGC NET Electronic Science Syllabus 2024

UGC NET Electronic Science exam consists of two papers. Paper 1 assesses communication and reasoning skills as well as general research and teaching aptitude. Paper 2 throws in-depth light on core electronics topics such as semiconductors, integrated circuit manufacturing, network theory, digital circuits, microprocessors, control systems and transducers. This course is designed to assess the proficiency of candidates in both basic and specialized knowledge areas, ensuring that they are well equipped to excel in the field of electronic science.

Download UGC NET Electronic Science Syllabus PDF Here

For candidates looking to excel in the UGC NET syllabus for the Electronic Science exam, access to the Electronic Science syllabus PDF is of paramount importance. This document serves as a comprehensive guide, detailing the topics covered in both Paper 1 and Paper 2 of the exam. Click on the link given below to download UGC NET Electronic Science Syllabus PDF here.

Download UGC NET Electronic Science Syllabus PDF Here

UGC NET Electronic Science Syllabus in detail

The detailed unit-wise UGC NET Electronics Science syllabus for Paper 2 is explained below.

Unit 1: Semiconductor Physics and Materials

• Introduction to Semiconductors: This unit covers the fundamental concepts of semiconductors, including energy bands, effective mass, density of states and the Fermi level in solids.
• Semiconductor Devices: This section explains in detail various semiconductor devices such as diode, bipolar junction transistor (BJT), and field-effect transistor (FET), exploring their characteristics, operating principles, and biasing techniques.

Unit 2: Integrated Circuit (IC) Manufacturing

• IC Fabrication Processes: This unit explores the various processes involved in IC manufacturing, such as crystal growth, epitaxy, oxidation, lithography, doping, etching, isolation methods, metallization and bonding.
• Thin-film technology: This section covers thin-film deposition techniques such as sputtering, evaporation, and chemical vapor deposition (CVD). characterization techniques such as 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 of analysis of 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 power supply design principles, as well as various rectifier circuits (half-wave, full-wave, bridge), including voltage regulation and filtering techniques.
• Linear Integrated Circuits (IC): 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 various digital logic families such as 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: Microprocessor and Microcontroller

• 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 (for example, 8051), exploring its architecture, instruction set, addressing modes, and interfacing techniques with external devices.

Unit 7: Communication Systems

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

Unit 8: Control Systems

• Fundamentals of Control Systems: 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 such as the klystron, magnetron, traveling-wave tube (TWT), and microwave transistor, along with their applications in radar and communications systems.

Unit 10: Electronic Measurements and Instrumentation

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

Important topics in UGC NET Electronic Science Syllabus

Important topics in UGC NET Electronic Syllabus are explained below.

1. electromagnetic theory
2. quantum mechanics
3. Solid-State Electronics
4. digital electronics
5. analog electronics
6. microprocessor and microcontroller
7. communication system
8. Electromagnetic Waves and Antennas
9. network theory
10. control system
11. Electronic Materials and Equipment
12. signal processing

ugc net electronic science exam pattern

Paper 1 evaluates the general aptitude and reasoning abilities of the candidate, while Paper 2 assesses his understanding of electronic science concepts and principles. To qualify the UGC NET exam, candidates have to perform well in both the papers. The table below provides a clear and concise overview of the exam pattern for both Paper 1 and Paper 2 of the UGC NET Electronic Science exam, including details of mode, duration, total questions, total marks, question types, sections and marking scheme. Is.

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