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Updated 2026-05-30 · 2026 Edition

AP EAPCET 2-Year Plan

A complete 730-day plan covering 45 highest-weightage topics — prioritised by subject weight, not alphabet. No signup, no fees.

Days
730
Topics
45
Subjects
3
Phases
4
Generate My Personalised Plan ← AP EAPCET Overview
Two-year deep build a foundations year, a mastery-and-depth year, and a sustained mock campaign across both

How to actually use your 730 days

The long game: build from zero across two cycles, with depth and a sustained mock habit most candidates never reach.

Daily study
1.5–2.5 hours
New topics / day
≈ 0.06
Approach
a foundations year, a mastery-and-depth year, and a sustained mock campaign across both

This 2-year plan gives you 730 days to work through 45 weighted AP EAPCET topics across 3 subjects — roughly 0.06 new topics a day at 1.5–2.5 hours of focused study. That gentle daily load is the whole advantage of a two-year run — you build mastery slowly enough that it actually sticks.

AP EAPCET marks are not spread evenly across subjects. Mathematics, Physics, and Chemistry carry the heaviest weightage in recent papers, so this plan front-loads them — so the first year builds genuine mastery of them, not just familiarity. Nothing is cut and nothing is rushed. At this length the differentiator is depth on the hardest, lowest-frequency topics and relentless revision — the work most candidates skip.

Two years is a genuine head start. You can build AP EAPCET from zero in year one and convert understanding into rank-grade speed and accuracy in year two — every one of the 45 topics, twice over, with room for the hardest material. The two-year risk is losing momentum in the long flat middle. Set quarterly milestones and treat year-one mocks as checkpoints, or the early lead quietly evaporates.

What to prioritise & cut

Nothing is cut and nothing is rushed. At this length the differentiator is depth on the hardest, lowest-frequency topics and relentless revision — the work most candidates skip.

Mock tests & revision

Year one: topic and sectional tests only, building accuracy. Year two: monthly then fortnightly then weekly full-length mocks, with a disciplined error log you actually revisit.

Weekly rhythm

Think in semesters, not weeks: build, deepen, revise, simulate — repeated across two cycles so every subject is seen many times on a spaced schedule.

Phase-by-phase plan

104 weeks total

A 730-day plan only works when you sequence it. Here is how the 2-Year Plan breaks down — foundation, depth, then mocks.

  1. 1

    Y1 Foundation

    24 weeks

    Concept depth + NCERT-level coverage

    Subject-wise mastery
    Topic notes
    Monthly tests
  2. 2

    Y1 Advanced

    28 weeks

    Reference-book level problems + first PYQ pass

    Topic-wise problem mastery
    PYQ pass 1
    Weak-area journal
  3. 3

    Y2 Practice

    26 weeks

    PYQ deep-dive + topic-wise mocks

    PYQ pass 2
    Topic-mock cycles
    Concept-gap closure
  4. 4

    Y2 Mocks + final

    26 weeks

    Weekly full-length mocks + final revision

    20+ mocks
    Last-mile cheatsheets
    Exam-mode drills

Week-by-week schedule

Week Days Topics covered
1 1–7 Mathematics: Complex Numbers and Quadratic Equations (w3)
2 8–14 Physics: Physics and Measurement (w3)
3 15–21 Chemistry: Atomic Structure (w3)
4 22–28 Mathematics: Matrices and Determinants (w3)
5 29–35 Physics: Kinematics (w3)
6 36–42 Chemistry: Chemical Bonding and Molecular Structure (w3)
7 43–49 Mathematics: Permutations and Combinations (w3)
8 50–56 Physics: Laws of Motion (w3)
9 57–63 Chemistry: Classification of Elements and Periodicity (w3)
10 64–70 Mathematics: Sequence and Series (w3)
11 71–77 Physics: Work, Energy and Power (w3)
12 78–84 Chemistry: States of Matter (w3)
13 85–91 Mathematics: Binomial Theorem (w3)
14 92–98 Physics: Rotational Motion (w3)
15 99–105 Chemistry: Thermodynamics (w3)
16 106–112 Mathematics: Trigonometric Functions and Identities (w3)
17 113–119 Physics: Gravitation (w3)
18 120–126 Chemistry: Chemical Equilibrium (w3)
19 127–133 Mathematics: Straight Lines and Pair of Linear Equations (w3)
20 134–140 Physics: Properties of Bulk Matter (w3)
21 141–147 Chemistry: Chemical Kinetics (w3)
22 148–154 Mathematics: Conic Sections (w3)
23 155–161 Physics: Thermodynamics (w3)
24 162–168 Chemistry: Redox Reactions and Electrochemistry (w3)
25 169–175 Mathematics: Three-Dimensional Geometry (w3)
26 176–182 Physics: Kinetic Theory of Gases (w3)
27 183–189 Chemistry: Surface Chemistry (w3)
28 190–196 Mathematics: Vector Algebra (w3)
29 197–203 Physics: Oscillations and Waves (w3)
30 204–210 Chemistry: s-Block and Hydrogen (w3)
31 211–217 Mathematics: Differential Calculus (w3)
32 218–224 Physics: Electrostatics (w3)
33 225–231 Chemistry: p-Block Elements (w3)
34 232–238 Mathematics: Applications of Derivatives (w3)
35 239–245 Physics: Current Electricity (w3)
36 246–252 Chemistry: d and f-Block Elements (w3)
37 253–259 Mathematics: Integral Calculus (w3)
38 260–266 Physics: Magnetic Effects (w3)
39 267–273 Chemistry: Organic Chemistry — Basic Principles (w3)
40 274–280 Mathematics: Differential Equations (w3)
41 281–287 Physics: Electromagnetic Induction and AC (w3)
42 288–294 Chemistry: Hydrocarbons and Haloalkanes (w3)
43 295–301 Mathematics: Probability and Statistics (w3)
44 302–308 Physics: Optics and Modern Physics (w3)
45 309–315 Chemistry: Alcohols, Phenols, Ethers, Carbonyls and Biomolecules (w3)

Subject-wise topic split

Each topic shows its weightage (1–5 dots) and the concepts you'll cover. Higher-weight topics appear first.

Mathematics

15 topics
  • Complex Numbers and Quadratic Equations ●●●○○

    Complex numbers as a+ib, algebra of complex numbers, modulus and argument, De Moivre's theorem, cube roots of unity, quadratic equations with real and complex roots, discriminant, and nature of roots.

  • Matrices and Determinants ●●●○○

    Types of matrices, matrix operations (addition, multiplication, transpose), adjoint and inverse of matrices, determinant evaluation (up to 3×3), properties of determinants, and solving linear equations using matrices.

  • Permutations and Combinations ●●●○○

    Fundamental principle of counting, permutation (linear and circular), combination, Pascal's triangle, binomial theorem (general and middle term), binomial expansion for positive integer indices, and arrangement problems.

  • Sequence and Series ●●●○○

    Arithmetic progression (AP), geometric progression (GP), arithmetic-geometric progression (AGP), harmonic progression (HP), sum of n terms, infinite series convergence, and AM-GM inequality applications.

  • Binomial Theorem ●●●○○

    Positive integral index binomial expansion, general and middle terms, Pascal's triangle, binomial coefficient properties, and applications in finding coefficients and approximations.

  • Trigonometric Functions and Identities ●●●○○

    Trigonometric ratios, identities (basic and conditional), signs in quadrants, allied angles, sum-to-product and product-to-sum formulas, multiple and submultiple angles, and solving trigonometric equations.

  • Straight Lines and Pair of Linear Equations ●●●○○

    Cartesian coordinate system, distance formula, section formula, area of triangle, slope-intercept form, general equation of line, angle between lines, perpendicular and parallel conditions, and solving linear equations graphically.

  • Conic Sections ●●●○○

    Circle (equation, tangents, normals), parabola (standard forms, focal properties), ellipse (eccentricity, latus rectum), hyperbola (asymptotes, rectangular hyperbola), and standard equations with transformations.

  • + 7 more topics on the full roadmap →

Physics

15 topics
  • Physics and Measurement ●●●○○

    Units and dimensions, SI base units, errors in measurement, significant figures, vernier calipers, screw gauge, and dimensional analysis — foundational concepts for all physics problem-solving.

  • Kinematics ●●●○○

    Motion in one and two dimensions — displacement, velocity, acceleration, equations of motion, projectile motion, relative velocity, and circular motion with numerical applications.

  • Laws of Motion ●●●○○

    Newton's three laws, friction (static and kinetic), circular motion dynamics, tension, spring force, and momentum conservation — core mechanics for engineering entrance exams.

  • Work, Energy and Power ●●●○○

    Work done by constant and variable forces, kinetic and potential energy, work-energy theorem, conservation of mechanical energy, power, and collisions (elastic and inelastic).

  • Rotational Motion ●●●○○

    Torque, moment of inertia, angular momentum, radius of gyration, theorems of moment of inertia, rotational kinematics, and conservation of angular momentum.

  • Gravitation ●●●○○

    Newton's law of gravitation, acceleration due to gravity, variation of g with altitude and depth, Kepler's laws, orbital velocity, escape velocity, and gravitational potential energy.

  • Properties of Bulk Matter ●●●○○

    Elasticity (stress-strain, Hooke's law, Young's modulus), fluid mechanics (Pascal's law, Bernoulli's principle, viscosity, surface tension, capillarity), and Archimedes' principle.

  • Thermodynamics ●●●○○

    Heat, temperature, calorimetry, heat transfer (conduction, convection, radiation), first and second law of thermodynamics, specific heat capacity, and thermodynamic processes.

  • + 7 more topics on the full roadmap →

Chemistry

15 topics
  • Atomic Structure ●●●○○

    Dual nature of matter, de Broglie relation, Heisenberg uncertainty principle, quantum numbers, orbital shapes (s, p, d, f), Aufbau principle, Hund's rule, Pauli's exclusion principle, and electronic configurations.

  • Chemical Bonding and Molecular Structure ●●●○○

    Ionic and covalent bonding, VSEPR theory, hybridization (sp, sp², sp³, sp³d, sp³d²), valence bond theory, MOT (bond order, HOMO-LUMO), dipole moment, and resonance structures.

  • Classification of Elements and Periodicity ●●●○○

    Modern periodic table, periodic trends — atomic radius, ionization enthalpy, electron gain enthalpy, electronegativity, valence electrons, metallic/non-metallic character across periods and groups.

  • States of Matter ●●●○○

    Gas laws (Boyle's, Charles's, Avogadro's), ideal gas equation, kinetic theory of gases, van der Waals equation, liquefaction of gases, critical temperature, and solid-state (lattice, crystal systems, Bragg's law).

  • Thermodynamics ●●●○○

    System and surroundings, first law of thermodynamics (internal energy, work, heat), enthalpy, Hess's law, spontaneity, Gibbs free energy, second law of thermodynamics, and entropy change calculations.

  • Chemical Equilibrium ●●●○○

    Reversible reactions, equilibrium constant (Kp, Kc), Le Chatelier's principle, factors affecting equilibrium, relationship between Kp and Kc, ionic equilibrium in solutions, pH, buffers, and solubility product.

  • Chemical Kinetics ●●●○○

    Rate of reaction, rate law and order, molecularity, zero, first, and second-order reactions, Arrhenius equation, activation energy, catalyst role, and half-life calculations.

  • Redox Reactions and Electrochemistry ●●●○○

    Oxidation-reduction concepts, balancing redox equations, electrochemical cells (galvanic, electrolytic), Nernst equation, standard electrode potentials, Faraday's laws of electrolysis, and corrosion prevention.

  • + 7 more topics on the full roadmap →

Why a 730-day plan beats a 1,200-page prep book

DimensionTypical AP EAPCET bookThis 2-Year Plan
Time to startHours of reading before any study startsSeconds — plan is already here
PersonalisationOne-size-fits-allFits exactly your 730 days
FreshnessPrinted months agoUpdated for the 2026 cycle · verified 2026-05-30
Weightage signalAuthor guessDerived from last 5 years' papers
Cost₹500–2,500₹0
Sign-up requiredOften (with a trial trap)None

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AP EAPCET 2-Year Plan — common questions

Is 730 days enough to prepare for AP EAPCET? +

Two years is a genuine head start. You can build AP EAPCET from zero in year one and convert understanding into rank-grade speed and accuracy in year two — every one of the 45 topics, twice over, with room for the hardest material. The honest answer depends on your starting point, but this 2-year plan is built to get the most from the time you have: the long game: build from zero across two cycles, with depth and a sustained mock habit most candidates never reach.

How many hours a day does this AP EAPCET 2-year plan need? +

Plan for 1.5–2.5 hours of focused study, covering about 0.06 new topics a day. Think in semesters, not weeks: build, deepen, revise, simulate — repeated across two cycles so every subject is seen many times on a spaced schedule.

What should I skip if I am short on time? +

Nothing is cut and nothing is rushed. At this length the differentiator is depth on the hardest, lowest-frequency topics and relentless revision — the work most candidates skip.

When should I start mock tests on this plan? +

Year one: topic and sectional tests only, building accuracy. Year two: monthly then fortnightly then weekly full-length mocks, with a disciplined error log you actually revisit.

Already know the pattern? Generate a topic-by-topic plan.

The full personalised roadmap covers weak topics first, tracks completion, and adapts as you mark topics done.

Generate Personalised Plan →