A geometric series has first term 5 and common ratio \( \frac{4}{5} \) - Edexcel - A-Level Maths Pure - Question 7 - 2008 - Paper 2

The sum to infinity for a geometric series is calculated using:

[ S_{\infty} = \frac{a}{1 - r} ]

The condition for this formula to be valid is that ( |r| < 1 ). Since ( r = \frac{4}{5} ), this condition is satisfied.

Substituting the values:

[ S_{\infty} = \frac{5}{1 - \frac{4}{5}} = \frac{5}{\frac{1}{5}} = 25 ]

Therefore, the sum to infinity of the series is ( 25 ).

Given the sum to ( k ) terms is greater than 24.95, we use the formula for the sum of the first ( k ) terms:

[ S_k = \frac{a(1 - r^k)}{1 - r} ]

Setting this greater than 24.95:

[ \frac{5(1 - r^k)}{1 - \frac{4}{5}} > 24.95 ]

This simplifies to:

[ 5(1 - r^k) > 24.95 ] [ 1 - r^k > 4.99 ] [ -r^k > 3.99 ] [ r^k < -3.99 ] (not valid as ( r^k ) cannot be negative)

Instead, rearranging gives:

[ r^k < 1 - \frac{24.95(1 - \frac{4}{5})}{5} ] [ r^k < 0.8 ]

Taking logs, we observe:

[ k \log r < \log 0.8 \quad \text{(if } r < 1\text{)} ] [ k > \frac{\log 0.002}{\log 0.8} ]

Thus, this shows that ( k > \frac{\log 0.002}{\log 0.8} ).

From part (c), we derived:

[ k > \frac{\log 0.002}{\log 0.8} ]

Calculating this value:

• ( \log 0.002 \approx -2.6990 )
• ( \log 0.8 \approx -0.09691 )

Thus:

[ k > \frac{-2.6990}{-0.09691} \approx 27.8 ]

The smallest integer value of ( k ) that satisfies this condition is ( k = 28 ).