The World of Numbers (RBSE Class 9 · Mathematics)
Long before cities or laws, humans scratched tally marks on bone to count. India then gave the world its most powerful idea — śhūnya (zero) — and the place-value system we still use. This chapter walks that journey and then builds the full real number system.
RBSE note (2026-27). Class 9 uses the new NCF (Ganita Prakash 9) Mathematics textbook. The World of Numbers is the new book's number-system chapter (it opens with the history of counting and zero). BSER (Ajmer) sets the exam.
1. The story so far — types of numbers
| Set | Symbol | Members |
|---|---|---|
| Natural numbers | ℕ | 1, 2, 3, … |
| Whole numbers | W | 0, 1, 2, 3, … |
| Integers | ℤ | …, −2, −1, 0, 1, 2, … |
| Rational numbers | ℚ | p/q, where p, q are integers and q ≠ 0 |
| Irrational numbers | — | cannot be written as p/q (e.g. √2, π) |
| Real numbers | ℝ | all rational + all irrational numbers |
The Indian invention of śhūnya (zero) and Brahmagupta's rules for operating with it made our place-value arithmetic possible.
2. Rational numbers
A rational number can be written as p/q with integers p, q and q ≠ 0. Key facts:
- Between any two rational numbers there are infinitely many rationals (e.g. the average lies between them).
- The decimal form of a rational number is either terminating (0.75) or non-terminating but recurring (0.333… = ⅓).
3. Irrational numbers
An irrational number cannot be expressed as p/q. Its decimal expansion is non-terminating and non-recurring. Examples: √2, √3, π, and 0.101001000100001…
√2 is irrational — a famous proof by contradiction shows no fraction squares to exactly 2.
Together, the rationals and irrationals fill the entire number line — they are the real numbers, and every point on the number line is exactly one real number.
4. Representing numbers on the number line
- Any rational number can be marked by successive division of unit segments.
- Irrationals like √2 are located using the Pythagoras construction: a right triangle with legs 1 and 1 has hypotenuse √2; sweep that length onto the line with a compass. Repeating gives the square-root spiral.
5. Operations and laws of exponents for real numbers
For real numbers and rational exponents (a, b > 0):
Surds (roots of non-perfect numbers) follow: √a · √b = √(ab) and √a / √b = √(a/b).
6. Rationalising the denominator
To remove a surd from a denominator, multiply by a clever form of 1:
For a denominator like (√a + √b), multiply by its conjugate (√a − √b):
7. Worked example
Simplify by rationalising the denominator.
Multiply numerator and denominator by the conjugate (√3 + √2):
8. Quick recap
- ℕ ⊂ W ⊂ ℤ ⊂ ℚ ⊂ ℝ; irrationals + rationals = real numbers (fill the number line).
- Rational = p/q (q ≠ 0); decimals terminate or recur. Irrational = non-terminating, non-recurring.
- Locate irrationals on the line by the Pythagoras/√-spiral construction.
- Use the laws of exponents and surd rules to simplify.
- Rationalise denominators using the conjugate; (√a)² − (√b)² = a − b.
