Important Topics in GATE 2026 Electrical Engineering
Since the syllabus for GATE Electrical Engineering is so vast, the number of important topics for this subject is also substantial. Some of the most important topics include Feedback control, Network topology, Power generation concepts, etc.
Important Topics in GATE 2026 Electrical Engineering are essential for a great score in the exam, as these topics are the most frequently asked in the exam. Although you are expected to cover the entire GATE 2026 syllabus for Electrical Engineering, important topics should receive priority during GATE preparation. Understanding which topics to prioritise can help you plan your preparation and exam strategy forGATE 2026!
Also Read:Will GATE 2026 be Tougher Than Last Year?
List of GATE 2026 Electrical Engineering Important Topics
If you wish to know all the important topics from GATE 2026 Electrical Engineering, check the table below:
Important Topics | Key Subtopics | Typical Weightage | Quick Study Tips |
Engineering Mathematics | Linear algebra (matrices, eigenvalues/vectors), Calculus (multivariable, maxima/minima, integrals), Differential equations, Laplace/Fourier series basics, Probability & statistics. | ~10–13% — high scoring if neat. | Master basic proofs, solve previous-year problems, memorize standard transforms. |
Electric Circuits & Networks | Nodal/mesh analysis, Thevenin/Norton, transient RLC, phasors, steady-state AC, network theorems, two-port parameters, resonance. | ~7–10% | Practice circuit reduction, transient ODEs, and phasor problems; use systematic KCL/KVL steps. |
Electromagnetic Fields | Electrostatics, magnetostatics, Maxwell’s equations (quasi-static), boundary conditions, transmission lines (TL) basics, wave equations. | ~2–4% | Focus on conceptual Maxwell’s relations and TL characteristic impedance / reflection coefficient formulas. |
Signals & Systems | LTI systems, convolution, Fourier/Laplace transforms, sampling theorem, stability, ROC, frequency response. | ~8–10% | Derive convolution and transform pairs; practice time/frequency domain conversions and sampling problems. |
Electrical Machines | Transformers (equivalent circuit, phasors), DC machines (torque, speed control), induction machines (equivalent circuit, slip), synchronous machines (sync reactance, V–I, phasor diagrams). | ~10–14% — consistently high. | Emphasize phasor diagrams, equivalent circuit derivations, and numerical machine tests. |
Power Systems | Power flow basics, per-unit system, fault analysis (symmetrical/unsymmetrical), transmission line models, stability (swing equation basics), protection fundamentals. | ~8–12% | Be fluent with single-line diagrams, per-unit conversion, and one-line fault calculations; practice short numerical problems. |
Control Systems | System modeling, block diagrams, time/frequency response, Routh/Hurwitz, root locus, Bode/Nyquist plots, state-space basics. | ~6–9% | Sketch root locus/Bode quickly; link time-domain specs (Ts, OS, ζ) to frequency domain margins. |
Analog Circuits & Electronics | Diode & transistor basics, biasing, small-signal models, OP-AMP circuits, amplifiers, feedback, frequency response. | ~6–8% | Small-signal analysis and op-amp ideal properties are high-yield — solve circuit-by-circuit. |
Digital Logic & Microelectronics | Combinational/sequential circuits, Boolean algebra, timing, ADC/DAC essentials, logic families. | ~2–4% | Practice timing diagrams and minimization (K-maps); know ADC/DAC types and resolutions. |
Power Electronics | Converters (AC–DC, DC–DC), thyristor/IGBT operation, PWM, control of converters, harmonic & filtering basics. | ~8–11% | Understand switching waveforms, average-value models, and basic converter design equations. |
Measurements & Instrumentation | Measurement errors, transducers, bridges, CRO basics, digital meters, signal conditioning. | ~1–3% | Memorize measurement formulae and typical instrument characteristics; practice error estimation. |
Revision & Aptitude | General Aptitude (verbal + numerical) and previous-year analysis; question patterns. | ~10–15% (GA + overall test strategy) | Do timed mocks, analyze mistakes, and maintain accuracy under time pressure. |
GATE 2026 Electrical Engineering Preparation Plan
In addition to knowing all the important topics in GATE 2026 Electrical Engineering, you must have a well devised preparation plan for the subject, similar to the one below:
Phase | Duration | Subjects to Cover | Key Activities | Expected Outcome |
Phase 1: Foundation Building | Months 1–3 | Engineering Mathematics, Network Theory, Signals & Systems | Study concepts from standard textbooks, derive formulas, solve basic numericals, make short notes | Strong conceptual base; comfort with core mathematics and analytical tools |
Mathematics Focus | Parallel (Daily) | Linear Algebra, Calculus, Probability | Daily practice of numericals, formula revision, PYQs topic-wise | High accuracy in scoring subject (~12–13 marks) |
Phase 2: Core Electrical Subjects – I | Months 4–5 | Electrical Machines, Analog Electronics | Detailed theory, phasor diagrams, circuit analysis, numericals from previous years | Mastery of high-weight subjects with repeatable questions |
Machines Emphasis | Extra 1–2 weeks | DC, Induction, Synchronous Machines, Transformers | Solve PYQs (last 30 years), focus on equivalent circuits and performance | Ability to solve 80–90% machine-related questions |
Phase 3: Core Electrical Subjects – II | Months 6–7 | Power Systems, Control Systems | Per-unit system, faults, stability, block diagrams, Routh, root locus | Conceptual clarity and speed in analytical problems |
Power Systems Practice | Parallel | Load flow, faults, transmission lines | Numerical practice, formula application, conceptual MCQs | Improved confidence in numerical-heavy questions |
Phase 4: Electronics & Applications | Month 8 | Power Electronics, Digital Logic, Measurements | Converter analysis, waveforms, logic circuits, instruments | Completion of full syllabus |
Power Electronics Priority | Extra focus | Rectifiers, choppers, inverters, PWM | Solve numerical and conceptual PYQs | Strong grip on one of the most scoring areas |
Phase 5: First Revision Cycle | Month 9 | All Subjects | Revise notes, formulas, error log, re-solve PYQs | Retention improvement and gap identification |
General Aptitude (GA) | Continuous | Verbal & Numerical Ability | Weekly GA practice sets, vocabulary, arithmetic | Secure easy 10–12 marks |
Phase 6: Test Series & Analysis | Months 10–11 | Full-length syllabus | Attempt 1–2 mock tests/week, deep analysis, revise weak areas | Improved speed, accuracy, and exam temperament |
Mock Test Strategy | Weekly | Subject + Full mocks | Analyze mistakes, update short notes | Rank stabilization |
Phase 7: Final Revision & Polishing | Last 4–6 weeks | High-weight topics only | Formula revision, short notes, selective PYQs | Peak performance readiness |
Last 15 Days | Final stretch | Machines, Power Systems, Math, Power Electronics | Light revision, no new topics, mental conditioning | Calm, confident exam mindset |
We hope we were able to inform you on the Important Topics in GATE 2026 Electrical Engineering. Check the links below to learn more!
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