In this section, we will establish a few useful formulas related to the sum of natural numbers. These formulas are often used in various competitive exams.
Table of Contents
Sum of first n natural numbers:
Question: What is the sum of first n natural numbers?
Answer: The formula of the sum of first n natural numbers is n(n+1)/2.
The sum of consecutive natural numbers is given by the following formula:
| Prove that: $1+2+3+\cdots+n$ $=\dfrac{n(n+1)}{2}$ |
Proof: Note that $1, 2, 3, …, n$ form an arithmetic progression (AP) with the first term $a=1$ and with the common difference $d=1.$
By the sum formula of an AP, we have
$1+2+3+…+n$ $=\dfrac{n}{2}[2a+(n-1)d]$
$=\dfrac{n}{2}[2.1+(n-1).1]$
$=\dfrac{n}{2}[2+n-1]$
$=\dfrac{n(n+1)}{2}$
SOLVED PROBLEMS
Problem 1: Find the sum of first 10 natural numbers.
Solution: The desired sum = 1+2+…+10
$=\dfrac{10(10+1)}{2}$ by the above formula.
= 5×11
=55
So the sum of first 10 natural numbers is 55.
Problem 2: Find the sum of the first 100 natural numbers.
Solution: We have to find the sum 1+2+…+100
In the above formula of the sum of first n natural numbers, we put n=100
$\therefore$ the sum $=\dfrac{100(100+1)}{2}$
= 50 × 101
=5050
Thus, the sum of first 100 natural numbers is 5050.
Problem 3: Find the sum of the first 50 natural numbers.
Solution: We have to find the sum 1+2+…+50
In the formula $1+2+3+\cdots+n$ $=\dfrac{n(n+1)}{2},$ we put n=50
$\therefore$ the sum $=\dfrac{50(50+1)}{2}$
= 25 × 51
= 1275
So the sum of first 50 natural numbers is 1275.
Problem 4: In a similar way, the sum of the first 20 natural numbers is
$1+2+3+\cdots +20$
$=\dfrac{20(20+1)}{2}$
= 10 × 21 = 210.
So the sum of first 20 natural numbers is 210.
Sum of first n even natural numbers:
| Prove that: $2+4+6+\cdots+2n$ $=n(n+1)$ |
Proof: Note that $2+4+6+…+2n$ $=2(1+2+3+…+n)$
$=2 \times \dfrac{n(n+1)}{2}$
$=n(n+1)$
SOLVED PROBLEMS
Problem I: Find the sum of the first 100 even natural numbers.
Solution: We have to find the sum 2+4+…+98+100
In the above formula of the sum of consecutive even natural numbers, we put 2n=100. So n=50.
$\therefore$ the sum $=50(50+1)$
$=50 \times 51$
$=2550$
Sum of first n odd natural numbers:
| Prove that: $1+3+5+\cdots+(2n+1)$ $=n^2$ |
Proof: Note that $1, 3, 5, \cdots,$$(2n-1)$ forms an AP with $n$ terms. The first term is $a=1$ and the common difference is $d=2.$
$\therefore$ the sum $=1+3+5+$ $\cdots+(2n-1)$ $=\dfrac{n}{2}[2a+(n-1)d]$
$=\dfrac{n}{2}[2.1+(n-1).2]$
$=\dfrac{n}{2} \times 2n$
$=n^2$
SOLVED PROBLEMS
Problem A: Find the sum of the first 100 odd natural numbers.
Solution: We have to find the sum 1+3+…+97+99
In the above formula of the sum of consecutive odd natural numbers, we put 2n-1=99. So 2n=100, that is, n=50.
$\therefore$ the sum of the first 100 odd natural numbers is $50^2$ $=2500.$
FAQs on Sum of Natural Numbers Formula
Answer: The formula for the sum of the first n natural numbers is n(n+1)/2.
Answer: The sum of the first n even numbers is n(n+1).
Answer: The sum of the first n odd numbers is $n^2.$
