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Algebra

Bouncing Ball Geometric Series

A ball drops from 16 feet and bounces to 3/4 of its previous height each time. Learn how to use geometric sequences to find any bounce height and apply infinite series to calculate the total distance traveled.

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Problem

A ball is dropped from 1616 feet and each bounce reaches 34\dfrac{3}{4} of the previous height; find the height after the fifth bounce and the total vertical distance traveled before the ball comes to rest.

Step 1: Write the bounce heights as a geometric sequence

The rebound heights form a geometric sequence with starting value a0=16a_0 = 16 and ratio r=34r = \dfrac{3}{4}. For the fifth bounce,

a5=16(34)5.a_5 = 16\left(\dfrac{3}{4}\right)^5.

Evaluating gives

(34)5=2431024,162431024=243643.80.\left(\dfrac{3}{4}\right)^5 = \dfrac{243}{1024}, \qquad 16 \cdot \dfrac{243}{1024} = \dfrac{243}{64} \approx 3.80.

So after the fifth bounce, the ball rises to about 3.803.80 feet.

Step 2: Sum the repeated bounce distances

The ball first falls 1616 feet. After that, each bounce contributes an up-and-down distance, so the rebound heights are doubled. The bounce heights are

12, 9, 6.75, 12,\ 9,\ 6.75,\ \dots

This is an infinite geometric series with first term a=12a = 12 and ratio r=34r = \dfrac{3}{4}. Its sum is

S=12134=1214=48.S = \dfrac{12}{1 - \dfrac{3}{4}} = \dfrac{12}{\dfrac{1}{4}} = 48.

So the total distance is

16+2(48)=112.16 + 2(48) = 112.

Answer

The fifth-bounce height is 243643.80\dfrac{243}{64} \approx 3.80 feet, and the total distance traveled is 112112 feet.

Concepts

Geometric Sequences and Common Ratios

A sequence where each term is found by multiplying the previous term by the same fixed number (the common ratio, rr). Unlike arithmetic sequences, which grow by adding, geometric sequences grow by multiplying. You can find any term using an=a1rn1a_n = a_1 \cdot r^{n-1}.

Geometric Series

The sum of the terms of a geometric sequence. For a finite series, use the formula with the common ratio. An infinite geometric series converges (has a finite sum) only when r<1|r| < 1.

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