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Chapter 13: Problem 97

Suppose that, throughout the U.S. economy, individuals spend \(90 \%\) of every additional dollar that they earn. Economists would say that an individual's marginal propensity to consume is \(0.90 .\) For example, if Jane earns an additional dollar, she will spend \(0.9(1)=\$ 0.90\) of it. The individual who earns \(\$ 0.90\) (from Jane) will spend \(90 \%\) of it, or \(\$ 0.81 .\) This process of spending continues and results in an infinite geometric series as follows: $$1,0.90,0.90^{2}, 0.90^{3}, 0.90^{4}, \ldots$$ The sum of this infinite geometric series is called the multiplier. What is the multiplier if individuals spend \(90 \%\) of every additional dollar that they earn?

Short Answer

Expert verified
The multiplier is 10.

Step by step solution

01

Identify the First Term and Common Ratio

The first term of the geometric series is 1 (since the initial dollar earned is taken as the first term). The common ratio is given as 0.90 because each subsequent term is 90% of the previous term.
02

Use the Sum Formula for an Infinite Geometric Series

The formula for the sum of an infinite geometric series is \[ S = \frac{a}{1 - r} \] where \( a \) is the first term and \( r \) is the common ratio.
03

Substitute the Values

For this series, \( a = 1 \) and \( r = 0.90 \). Substituting these values into the formula gives: \[ S = \frac{1}{1-0.90} \]
04

Calculate the Multiplier

Perform the calculation: \[ S = \frac{1}{0.10} = 10 \]

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Key Concepts

These are the key concepts you need to understand to accurately answer the question.

Infinite Geometric Series
An infinite geometric series is a sequence of numbers where each term after the first is found by multiplying the previous term by a constant called the common ratio. This series goes on indefinitely without ending. For example, if you start with 1 (the first term) and keep multiplying by 0.90 (the common ratio), you get 1, 0.90, 0.90^2, 0.90^3, and so on.
The remarkable thing about infinite geometric series is that even though they have infinitely many terms, their sum can be finite! This property makes them very useful in economics and finance, among other fields.
Marginal Propensity to Consume
The marginal propensity to consume (MPC) is a measure used in economics to quantify the change in personal consumer spending (consumption) due to a change in disposable income. Essentially, it represents the portion of additional income that an individual is likely to spend rather than save. In this example, the MPC is 0.90, which means individuals spend 90% of every additional dollar they earn.
Let's break it down:
  • If Jane earns an extra \(1, she spends \)0.90 (or 90%) of it.
  • The person who receives Jane's \(0.90 will spend 90% of this amount, which is \)0.81.
  • This spending cycle continues, following the pattern of the geometric series.
Sum Formula for Infinite Geometric Series
To find the sum of an infinite geometric series, you use the following formula: where \(S = \frac{a}{1 - r}\), where \(a\) is the first term and \(r\) is the common ratio.
In the given exercise, the first term \(a\) is 1, and the common ratio \(r\) is 0.90. By substituting these values into the formula, we get: \( S = \frac{1}{1 - 0.90} = \frac{1}{0.10} = 10 \)
This means the multiplier is 10, indicating the overall impact of the initial dollar spent reverberates through the economy, leading to a total spending of ten dollars throughout the process.
Common Ratio
The common ratio in a geometric series is the factor by which each term is multiplied to obtain the subsequent term. In mathematical notation, if you have a geometric series with first term \(a\) and common ratio \(r\), the series is: \(a, ar, ar^2, ar^3, ...\)
For the given problem, the common ratio is 0.90. This ratio indicates that each term is 90% of the previous term. Understanding the common ratio is crucial as it helps us determine the behavior of the series. In this exercise, the common ratio being less than 1 (0.90 in this case) ensures that the terms get smaller and smaller, allowing the sum of the infinite series to converge to a specific value. This convergence is why we can find a finite sum even for an infinite series!

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Most popular questions from this chapter

Determine whether the given sequence is arithmetic, geometric, or neither. If the sequence is arithmetic, find the common difference; if it is geometric, find the common ratio. If the sequence is arithmetic or geometric, find the sum of the first 50 terms. $$ \left\\{3-\frac{2}{3} n\right\\} $$

Suppose \(x, y, z\) are consecutive terms in a geometric sequence. If \(x+y+z=103\) and \(x^{2}+y^{2}+z^{2}=6901,\) find the value of \(y\)

Bode's Law In \(1772,\) Johann Bode published the following formula for predicting the mean distances, in astronomical units (AU), of the planets from the sun: $$ a_{1}=0.4 \quad a_{n}=0.4+0.3 \cdot 2^{n-2} $$ where \(n \geq 2\) is the number of the planet from the sun. (a) Determine the first eight terms of the sequence. (b) At the time of Bode's publication, the known planets were Mercury \((0.39 \mathrm{AU}),\) Venus \((0.72 \mathrm{AU}),\) Earth \((1 \mathrm{AU})\) Mars \((1.52 \mathrm{AU}),\) Jupiter \((5.20 \mathrm{AU}),\) and Saturn \((9.54 \mathrm{AU})\) How do the actual distances compare to the terms of the sequence? (c) The planet Uranus was discovered in \(1781,\) and the asteroid Ceres was discovered in \(1801 .\) The mean orbital distances from the sun to Uranus and Ceres " are \(19.2 \mathrm{AU}\) and \(2.77 \mathrm{AU},\) respectively. How well do these values fit within the sequence? (d) Determine the ninth and tenth terms of Bode's sequence. (e) The planets Neptune and Pluto" were discovered in 1846 and \(1930,\) respectively. Their mean orbital distances from the sun are \(30.07 \mathrm{AU}\) and \(39.44 \mathrm{AU},\) respectively. How do these actual distances compare to the terms of the sequence? (f) On July \(29,2005,\) NASA announced the discovery of a dwarf planet \((n=11),\) which has been named Eris. Use Bode's Law to predict the mean orbital distance of Eris from the sun. Its actual mean distance is not yet known, but Eris is currently about 97 astronomical units from the sun.

You have just signed a 7-year professional football league contract with a beginning salary of \(\$ 2,000,000\) per year. Management gives you the following options with regard to your salary over the 7 years. 1\. A bonus of \(\$ 100,000\) each year 2\. An annual increase of \(4.5 \%\) per year beginning after 1 year 3\. An annual increase of \(\$ 95,000\) per year beginning after 1 year Which option provides the most money over the 7-year period? Which the least? Which would you choose? Why?

A special section in the end zone of a football stadium has 2 seats in the first row and 14 rows total. Each successive row has 2 seats more than the row before. In this particular section, the first seat is sold for 1 cent, and each following seat sells for \(5 \%\) more than the previous seat. Find the total revenue generated if every seat in the section is sold. Round only the final answer, and state the final answer in dollars rounded to two decimal places. (JJC) \(^{\dagger}\)
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