Write the recurring decimal as a fraction. The ratio is since is divided by 10 to make and so on. The recurring decimal can be written as a series of fractions out of 10, 100, 1000 and so on. Written in this way, the recurring decimal can be written as a geometric series in which the first term and ratio can be found. A decimal can be written as fractions out of 10, 100, 1000 and so on. Recurring decimals can be written as a fraction using the geometric infinite series formula S â=a/. How to Write a Recurring Decimal as a Fraction with an Infinite Series In each case, the sum to infinity formula will be used, where a 1 is the first term and r is the ratio. Here are sum examples of calculating the sum to infinity for geometric series. Examples of Calculating the Sum to Infinity The denominator simplifies to and this can be evaluated so that. Sum to Infinity of an Alternating SeriesĪ geometric series will alternate between positive and negative terms if the ratio is negative.įor example, in the series the terms alternate from negative to positive. Therefore the sum to infinity becomes which equates to. Hence, if the first term is negative, the sum to infinity will also be negative. The only way to obtain a negative sum to infinity is for the numerator, a 1, to be negative.Ī 1 is the first term of the series. ![]() This means that the denominator of the sum to infinity equation can never be negative. This is because the sum to infinity is given by. The sum to infinity of a geometric series will be negative if the first term of the series is negative. ![]() Sum to Infinity CalculatorÄ®nter the first two terms of a geometric sequence into the calculator below to calculate its sum to infinity. If the common difference is negative, the sum to infinity is -â. If the common difference is positive, then the sum to infinity of an arithmetic series is +â. The common ratio is 2 and a geometric series will diverge if |r|â¥1.įor a series to converge, the terms must get smaller and smaller in magnitude as the series progresses.įor a geometric series, the series converges if |r|<1.Īrithmetic series do not converge and so they do not have a defined sum to infinity. The sum to infinity does not exist if |r|â¥1.įor example, the series is a divergent series because the terms get larger. If the terms get larger as the series progresses, the series diverges. The common ratio must be between -1 and 1.Ī geometric series diverges and does not have a sum to infinity if |r|â¥1. Geometric series converge and have a sum to infinity if |r|<1. The series converges because the terms are getting smaller in magnitude. Therefore the fractions will fill an area of. The series converges to a final value.įor example, in the series, the fractions can be seen to fit inside the area of a 1 by 1 square. This means that the terms being added to the total sum get increasingly small. If |r|<1, the sequence will converge to the sum to infinity given by S â=a/(1-r).Ī convergent geometric series is one in which the terms get smaller and smaller. If the common ratio is outside of this range, then the series will diverge and the sum to infinity will not exist. The sum to infinity only exists if -1 ![]() The first term is simply the first number in the series, which is 1. It does not matter which term you choose, simply divide any term by the term before it to find the value of r.įor example, the same result is obtained by considering the last two terms instead. We can divide the term by the term before it, which is 1. Calculate r by dividing any term by the previous term
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