Real Numbers (R)<\/strong><\/td>All rational and irrational numbers together. They represent every possible number on the number line.<\/td> All numbers on the number line<\/td><\/tr><\/tbody><\/table><\/figure>\n\n\n\nHow number system is useful for competitive examination:<\/strong><\/p>\n\n\n\n\nMost exam questions in arithmetic, algebra, data interpretation, and simplification are built on number system concepts. Without this base, solving advanced problems becomes difficult.<\/li>\n\n\n\n Competitive exams are time-bound. Knowing properties of numbers, divisibility rules, and shortcuts in fractions or decimals reduces calculation time.<\/li>\n\n\n\n Questions related to LCM, HCF, percentages, ratios, probability, and equations use number system principles. Mastering this section makes other areas easier.<\/li>\n\n\n\n Many exams include direct number system questions such as identifying even\/odd numbers, prime numbers, or remainder-based problems. These can be quick marks if concepts are clear.<\/li>\n\n\n\n A strong number system helps avoid common mistakes in decimals, fractions, and negative values, which improves overall accuracy in competitive tests.<\/li>\n<\/ul>\n\n\n\n2. Divisibility Rules for Competitive Exams<\/h3>\n\n\n\n Divisibility rules provide shortcuts to identify whether a number can be divided by another without performing actual division. In competitive exams, these rules are applied in problems involving missing digits, remainders, and simplification. Mastering divisibility improves both speed and accuracy in quantitative aptitude sections. Since these rules form the base for many arithmetic problems, understanding them thoroughly is essential. Let us now go through the key rules of divisibility in detail.<\/p>\n\n\n\nNumber<\/strong><\/td>Divisibility Rules<\/strong><\/td>Examples<\/strong><\/td><\/tr>2<\/strong><\/td>A number is divisible if its last digit is even (0, 2, 4, 6, 8).<\/td> 746 \u2192 last digit 6 \u2192 divisible by 2<\/td><\/tr> 3<\/strong><\/td>A number is divisible if the sum of its digits is divisible by 3.<\/td> 345 \u2192 3+4+5=12 \u2192 divisible by 3<\/td><\/tr> 4<\/strong><\/td>A number is divisible if the last two digits form a number divisible by 4.<\/td> 3216 \u2192 last two digits 16 \u2192 divisible by 4<\/td><\/tr> 5<\/strong><\/td>A number is divisible if its last digit is 0 or 5.<\/td> 8905 \u2192 last digit 5 \u2192 divisible by 5<\/td><\/tr> 6<\/strong><\/td>A number is divisible if it is divisible by both 2 and 3.<\/td> 354 \u2192 even number and 3+5+4=12 divisible by 3<\/td><\/tr> 9<\/strong><\/td>A number is divisible if the sum of its digits is divisible by 9.<\/td> 837 \u2192 8+3+7=18 \u2192 divisible by 9<\/td><\/tr> 11<\/strong><\/td>A number is divisible if the difference of the sum of digits at odd and even places is divisible by 11.<\/td> 2728 \u2192 (2+2) \u2013 (7+8) = -11 \u2192 divisible by 11<\/td><\/tr><\/tbody><\/table><\/figure>\n\n\n\n3. HCF and LCM <\/h2>\n\n\n\n Highest Common Factor (HCF) and Lowest Common Multiple (LCM) are widely used in questions related to ratios, remainders, and problem-solving involving cycles and repetitions. Competitive exams often include real-life applications such as arranging events, dividing items, or synchronisation problems.<\/p>\n\n\n\nConcept of HCF and LCM<\/strong><\/td>Explanation<\/strong><\/td>Examples<\/strong><\/td><\/tr>HCF (Highest Common Factor)<\/strong><\/td>The greatest number that divides two or more numbers exactly. Also called Greatest Common Divisor (GCD).<\/td> HCF of 12 and 18 = 6<\/td><\/tr> LCM (Least Common Multiple)<\/strong><\/td>The smallest number that is a multiple of two or more given numbers.<\/td> LCM of 12 and 18 = 36<\/td><\/tr> Important Formula<\/strong><\/td>For two numbers:HCF \u00d7 LCM = Product of the numbers<\/td> For 12 and 18:6 \u00d7 36 = 216 = 12 \u00d7 18<\/td><\/tr><\/tbody><\/table><\/figure>\n\n\n\n4. Algebra<\/h3>\n\n\n\n Algebra is one of the most scoring topics in competitive mathematics. It covers expressions, equations, factorisation, and identities. Questions may range from simple substitutions to advanced simplifications and logical applications. A strong grasp of algebraic manipulation is crucial for exams like SSC CGL, RRB, CAT, and GRE. Algebra becomes easier to master when the basic identities are well understood. The following are the fundamental algebraic identities along with their expansions and examples.<\/p>\n\n\n\nBasic Algebraic Identities<\/strong><\/td>Expansion<\/strong><\/td>Examples<\/strong><\/td><\/tr>(a + b)\u00b2<\/strong><\/td>a\u00b2 + 2ab + b\u00b2<\/td> (x + 5)\u00b2 = x\u00b2 + 10x + 25<\/td><\/tr> (a \u2013 b)\u00b2<\/strong><\/td>a\u00b2 \u2013 2ab + b\u00b2<\/td> (2y \u2013 3)\u00b2 = 4y\u00b2 \u2013 12y + 9<\/td><\/tr> a\u00b2 \u2013 b\u00b2<\/strong><\/td>(a + b)(a \u2013 b)<\/td> 49 \u2013 16 = (7 + 4)(7 \u2013 4) = 33<\/td><\/tr> (a + b)\u00b3<\/strong><\/td>a\u00b3 + b\u00b3 + 3ab(a + b)<\/td> (x + 2)\u00b3 = x\u00b3 + 6x\u00b2 + 12x + 8<\/td><\/tr> (a \u2013 b)\u00b3<\/strong><\/td>a\u00b3 \u2013 b\u00b3 \u2013 3ab(a \u2013 b)<\/td> (p \u2013 4)\u00b3 = p\u00b3 \u2013 12p\u00b2 + 48p \u2013 64<\/td><\/tr> a\u00b3 + b\u00b3<\/strong><\/td>(a + b)(a\u00b2 \u2013 ab + b\u00b2)<\/td> x\u00b3 + 8 = (x + 2)(x\u00b2 \u2013 2x + 4)<\/td><\/tr> a\u00b3 \u2013 b\u00b3<\/strong><\/td>(a \u2013 b)(a\u00b2 + ab + b\u00b2)<\/td> 27 \u2013 y\u00b3 = (3 \u2013 y)(9 + 3y + y\u00b2)<\/td><\/tr><\/tbody><\/table><\/figure>\n\n\n\n5. Quadratic Equations<\/h3>\n\n\n\n Quadratic equations test both conceptual clarity and problem-solving ability. Questions may ask about the nature of roots, relationships between roots, or applications in word problems. In exams, quadratic equations are often framed to test both algebraic and logical thinking.<\/p>\n\n\n\nConcept of Quadratic Equations<\/strong><\/td>List of Formulas <\/strong><\/td>Questions<\/strong><\/td>Solutions<\/strong><\/td><\/tr>Standard Form<\/strong><\/td>ax\u00b2 + bx + c = 0<\/td> 2x\u00b2 + 5x \u2013 3 = 0<\/td> Already in standard form<\/td><\/tr> Roots (solutions)<\/strong><\/td>x = [\u2212b \u00b1 \u221a(b\u00b2 \u2013 4ac)] \/ 2a<\/td> Solve x\u00b2 \u2013 5x + 6 = 0<\/td> a = 1, b = \u20135, c = 6; Sum of roots<\/strong><\/td>\u2013b \/ a<\/td> x\u00b2 \u2013 5x + 6 = 0<\/td> Sum = \u2013(\u20135)\/1 = 5<\/td><\/tr> Product of roots<\/strong><\/td>c \/ a<\/td> x\u00b2 \u2013 5x + 6 = 0<\/td> Product = 6 \/ 1 = 6<\/td><\/tr> Discriminant (D)<\/strong><\/td>D = b\u00b2 \u2013 4ac<\/td> x\u00b2 \u2013 5x + 6 = 0<\/td> D = (\u20135)\u00b2 \u2013 4(1)(6) Nature of Roots<\/strong><\/td>D > 0 \u2192 Real & distinctD = 0 \u2192 Real & equalD < 0 \u2192 Imaginary<\/td> x\u00b2 \u2013 4x + 4 = 0<\/td> D = 16 \u2013 16 = 0 6. Average <\/h3>\n\n\n\n The concept of average (arithmetic mean) is commonly tested in competitive exams through questions on results, weights, and salaries. Many problems involve using averages to find missing values or to compare data sets. Candidates must learn shortcuts and properties to solve these efficiently.<\/p>\n\n\n\n
1. Simple Average<\/strong><\/p>\n\n\n\nAverage is a commonly tested concept in competitive exams. It helps simplify a set of numbers to a single representative value. Questions on average appear in exams like SSC, Banking, Railways, and other aptitude sections.<\/p>\n\n\n\n
Formula:<\/strong> Average = (Sum of Observations) \u00f7 (Number of Observations)<\/p>\n\n\n\nExample:<\/strong> Find the average of 10, 20, 30, 40.<\/p>\n\n\n\nSum = 10 + 20 + 30 + 40 = 100, n = 4<\/p>\n\n\n\n
Average = 100 \u00f7 4 = 25<\/p>\n\n\n\n
Importance for Exams:<\/strong><\/p>\n\n\n\n\nDirectly tested in quantitative aptitude sections.<\/li>\n\n\n\n Used in problems on speed, work, profit, and data interpretation.<\/li>\n\n\n\n Quick calculation techniques save time in time-bound exams.<\/li>\n<\/ul>\n\n\n\n2. Weighted Average<\/strong><\/p>\n\n\n\nWeighted average is used when observations have unequal importance. It is frequently tested in competitive exams in topics like marks distribution, mixtures, and population problems.<\/p>\n\n\n\n
Formula:<\/strong> Weighted Average = (w\u2081x\u2081 + w\u2082x\u2082 + \u2026 + w\u2099x\u2099) \u00f7 (w\u2081 + w\u2082 + \u2026 + w\u2099)<\/p>\n\n\n\nExample: <\/strong>A student scores 80 in Maths (weight 3) and 70 in English (weight 2). Find the weighted average.<\/p>\n\n\n\nWeighted Average = (80\u00d73 + 70\u00d72) \u00f7 (3+2)<\/p>\n\n\n\n
= (240 + 140) \u00f7 5<\/p>\n\n\n\n
= 380 \u00f7 5 = 76<\/p>\n\n\n\n
Importance for Exams:<\/strong><\/p>\n\n\n\n\nDirectly applied in marks, population, and mixture-based questions.<\/li>\n\n\n\n Helps solve real-life quantitative problems quickly.<\/li>\n\n\n\n Saves time by avoiding repeated manual calculations of averages.<\/li>\n<\/ul>\n\n\n\n3. New Average (When a Number is Added or Removed)<\/strong><\/p>\n\n\n\nNew average is calculated when a number is added to or removed from a set of observations. This concept is frequently tested in competitive exams in questions related to marks, scores, or data adjustment.<\/p>\n\n\n\n
Formulas:<\/strong><\/p>\n\n\n\n\nIf the average of n numbers is A, and a new number x is added:<\/strong><\/li>\n<\/ul>\n\n\n\nNew Average = A + (x \u2013 A) \u00f7 (n + 1)<\/p>\n\n\n\n
\nIf the average of n numbers is A, and a number x is removed:<\/strong><\/li>\n<\/ul>\n\n\n\n New Average = A \u2013 (x \u2013 A) \u00f7 (n \u2013 1)<\/p>\n\n\n\n
Example: <\/strong>The average of 5 numbers is 20. A new number 30 is added. Find the new average.<\/p>\n\n\n\nNew Average = 20 + (30 \u2013 20) \u00f7 6<\/p>\n\n\n\n
= 20 + 10 \u00f7 6<\/p>\n\n\n\n
= 21.67<\/p>\n\n\n\n
7. Percentage<\/h3>\n\n\n\n In competitive exams, questions on percentages test the ability to calculate proportions and changes quickly. These are widely asked in exams like SSC, Banking, Railway, CAT, and State PSC.<\/p>\n\n\n\nConcept of Percentage<\/strong><\/td>List of Formulas<\/strong><\/td>Questions<\/strong><\/td>Solution<\/strong><\/td><\/tr>Basic Percentage<\/strong><\/td>Percentage = (Value \/ Total) \u00d7 100<\/td> A student scored 45 out of 60 marks.<\/td> (45 \/ 60) \u00d7 100 Percentage Change<\/strong><\/td>Percentage Change = (New Value \u2013 Old Value) \/ Old Value \u00d7 100<\/td> Price of a book increased from \u20b9200 to \u20b9250.<\/td> (250 \u2013 200) \/ 200 \u00d7 100 = 25%<\/td><\/tr> Successive Percentage Change<\/strong><\/td>Effective Change % = a + b + (a \u00d7 b) \/ 100<\/td> Price increased by 10% in January and 20% in February.<\/td> 10 + 20 + (10 \u00d7 20)\/100 = 32%<\/td><\/tr> Equal Increase & Decrease<\/strong><\/td>Net Effect % = x\u00b2 \/ 100<\/td> Price increased by 10% and then decreased by 10%.<\/td> (10\u00b2)\/100 8. Profit, Loss, and Discount <\/h3>\n\n\n\n Profit, Loss and Discount topic has direct applications in commercial mathematics. Competitive exams test questions on cost price, selling price, discounts, successive profits, and marked price adjustments. Questions often combine percentage concepts, requiring quick calculations for accurate results.<\/p>\n\n\n\nConcept of Profit, Loss and Discount <\/strong><\/td>List of Formulas<\/strong><\/td>Questions<\/strong><\/td>Solutions<\/strong><\/td><\/tr>Profit (%)<\/strong><\/td>Profit (%) = [(S.P. – C.P.) \/ C.P.] \u00d7 100<\/td> C.P. = \u20b9500, S.P. = \u20b9600<\/td> [(600 \u2013 500) \/ 500] \u00d7 100 = 20%<\/td><\/tr> Loss (%)<\/strong><\/td>Loss (%) = [(C.P. – S.P.) \/ C.P.] \u00d7 100<\/td> C.P. = \u20b9800, S.P. = \u20b9700<\/td> [(800 \u2013 700) \/ 800] \u00d7 100 = 12.5%<\/td><\/tr> Selling Price from Profit\/Loss<\/strong><\/td>S.P. = C.P. \u00d7 (100 \u00b1 Profit%\/Loss%) \/ 100<\/td> C.P. = \u20b9400, Profit = 25%<\/td> S.P. = 400 \u00d7 (100 + 25)\/100 Discount<\/strong><\/td>Discount = M.P. \u2013 S.P.<\/td> M.P. = \u20b91200, S.P. = \u20b91000<\/td> Discount = 1200 \u2013 1000 = \u20b9200<\/td><\/tr> Discount %<\/strong><\/td>Discount % = (Discount \/ M.P.) \u00d7 100<\/td> Discount = \u20b9200, M.P. = \u20b91200<\/td> (200 \/ 1200) \u00d7 100 = 16.67%<\/td><\/tr> S.P. after Discount<\/strong><\/td>S.P. = M.P. \u00d7 (100 \u2013 Discount%) \/ 100<\/td> M.P. = \u20b91500, Discount = 20%<\/td> S.P. = 1500 \u00d7 (100 \u2013 20)\/100 9. Ratio, Proportion, and Variation<\/h3>\n\n\n\n Ratio and proportion are the backbone of many aptitude problems. Applications include mixtures, partnerships, direct and inverse variations, and real-life problem solving. Exams frequently include questions that integrate ratios with speed, time, and work problems, making it an essential topic for practice.<\/p>\n\n\n\n