Sum of Infinite Series Formula

How to Find Sum of Alternating Series?

The infinite series formula is used to find the sum of an infinite number of terms, given that the terms are in infinite geometric progression with the absolute value of the common ratio less than 1. This is because, only if the common ratio is less than 1, the sum will converge to a definite value, else the absolute value of the sum will tend to infinity. Let’s know more about Sum of Infinite Series Formula in detail below.

Sum of Infinite Series Formula

Below is the formula for sum of Infinite Series.

For a geometric series, we can express the sum as,

a + ar + ar² + ar³ + … + (infinite terms) = a/(1 – r)

where,

a = first term of the geometric series

r = common ratio, where -1 < r < 1

Condition

The series should be in geometric progression.
The absolute value of the common ratio should be less than 1.

Derivation of the Formula

Let’s consider,

a = first term of the geometric series

r = common ratio, where -1 < r < 1

Let us consider the sum of the geometric progression be S.

Then we can write,

S = a + ar + ar²+ ar³ + … —– (i)

Multiplying both sides of the equation by r, we get,

Sr = ar + ar² + ar³ + ar⁴ + … —– (ii)

Subtracting Eq. (ii) from Eq. (i), we get

S – Sr = (a + ar + ar²+ ar³) + … – (ar + ar² + ar³ + ar⁴ + …)

S(1 – r) = a

S = a/(1 – r)

Hence, the sum of infinite series of a geometric progression is a/(1 – r)

Note:

If the absolute value of the common ratio ‘r’ is greater than 1, then the sum will not converge.

Thus, the absolute value of the sum will tend to infinity. Thus, if r > 1,

| S | = | a + ar + ar² + ar³ + … | = ∞

Sample Problems on Sum of Infinite Series

Question 1. Find the sum of the infinite series with first term 4 and common ratio 1/2.

Solution:

Given, the first term a = 4

The common ratio r = 1/2

Thus, we can write the series as,

S = 4 + 4 × (1/2) + 4 × (1/2)² + …

So, the sum will stand as

S = 4/(1 – (1 / 2)) = 4/(1/2) = 4 × 2 = 8

S = 8

So, the sum of the series is equal to 8.

Question 2. Find the sum of the infinite series 1 + (1/2) + (1/2)² + (1/2)³ + … .

Solution:

Given, the first term of the series a = 1.

The common ratio is r = 1/2.

Since the absolute value of the common ratio is less than 1, we can apply the general formula.

So, the sum is,

S = 1/(1 – (1/2)) = 2

So, the sum of the given infinite series is 2.

Question 3. Evaluate the sum 2 + 4 + 8 + 16 + … .

Solution:

We can write the sum of the given series as,

S = 2 + 2²+ 2³ + 2⁴ + …

We can observe that it is a geometric progression with infinite terms and first term equal to 2 and common ratio equals 2.

Thus, r = 2.

Since, the value of r > 1, the sum will not converge and tend to infinity. Thus,

S = + ∞

Question 4. Find the sum of the series 2 – 1/5 + 1 – 1/25 + 1/2 – 1/125 + … .

Solution:

We can write the sum of the series as the difference of two infinite series as:

S = (2 + 1 + 1/2 + 1/2² + …) – (1/5 + 1/25 + 1/125 + … )

S = (2 + 1 + 1/2 + 1/2² + …) – (1/5 + 1/5² + 1/5³ + …)

S = S1 – S2

where,

S1 = 2 + 1 + 1/2 + 1/2² + …

S2 = 1/5 + 1/5² + 1/5³ + …

Here, we can see both S1 and S2 are infinite summation of geometric series, where,

a1 = 2, r1 = 1/2

a2 = 1/5, r2 = 1/5

Thus, we can write,

S1 = 2/(1 – (1/2)) = 2/(1/2) = 4

S2 = (1/5)/(1 – (1/5)) = (1/5) / (4/5) = 1/4

So, the summation S stands as,

S = S1 – S2 = 4 – 1/4 = (16 – 1)/4 = 15/4 = 3.75

S = 3.75

Thus, the sum of the given series is 3.75 .