/*! This file is auto-generated */ .wp-block-button__link{color:#fff;background-color:#32373c;border-radius:9999px;box-shadow:none;text-decoration:none;padding:calc(.667em + 2px) calc(1.333em + 2px);font-size:1.125em}.wp-block-file__button{background:#32373c;color:#fff;text-decoration:none} Problem 2 Each of the following functions ... [FREE SOLUTION] | 91Ó°ÊÓ

91Ó°ÊÓ

Log out

Learning Materials

Features

Discover

Chapter 1: Problem 2

Each of the following functions gives the amount of a substance present at time \(t .\) In each case, give the amount present initially (at \(t=0\) ), state whether the function represents exponential growth or decay, and give the percent growth or decay rate. (a) \(\quad A=100(1.07)^{t}\) (b) \(\quad A=5.3(1.054)^{t}\) (c) \(\quad A=3500(0.93)^{t}\) (d) \(\quad A=12(0.88)^{t}\)

Short Answer

Expert verified
(a) Initial: 100, Growth: 7%; (b) Initial: 5.3, Growth: 5.4%; (c) Initial: 3500, Decay: 7%; (d) Initial: 12, Decay: 12%.

Step by step solution

01

Find Initial Amount for (a)

For function \( A = 100(1.07)^t \), the initial amount is the value of \( A \) when \( t = 0 \). Substituting \( t = 0 \), we get:\[A = 100(1.07)^0 = 100 \]Thus, the initial amount is 100.
02

Determine Growth or Decay for (a)

The expression inside the parentheses for this function is \(1.07\), which is greater than 1. This represents exponential growth.
03

Calculate Percent Growth for (a)

The growth factor is \(1.07\). To find the percent growth rate, subtract 1 and multiply by 100:\[(1.07 - 1) \times 100 = 7\%\]So, the percent growth rate is 7%.
04

Find Initial Amount for (b)

For function \( A = 5.3(1.054)^t \), the initial amount at \( t = 0 \) is calculated as:\[A = 5.3(1.054)^0 = 5.3\]Thus, the initial amount is 5.3.
05

Determine Growth or Decay for (b)

The base \(1.054\) is greater than 1, indicating exponential growth.
06

Calculate Percent Growth for (b)

The growth factor is \(1.054\). To find the percent growth rate:\[(1.054 - 1) \times 100 = 5.4\%\]So, the percent growth rate is 5.4%.
07

Find Initial Amount for (c)

For function \( A = 3500(0.93)^t \), calculate the initial amount at \( t = 0 \):\[A = 3500(0.93)^0 = 3500\]Thus, the initial amount is 3500.
08

Determine Growth or Decay for (c)

The base \(0.93\) is less than 1, indicating exponential decay.
09

Calculate Percent Decay for (c)

The decay factor is \(0.93\). To find the percent decay rate:\[(1 - 0.93) \times 100 = 7\%\]So, the percent decay rate is 7%.
10

Find Initial Amount for (d)

For function \( A = 12(0.88)^t \), the initial amount at \( t = 0 \) is:\[A = 12(0.88)^0 = 12\]Thus, the initial amount is 12.
11

Determine Growth or Decay for (d)

The base \(0.88\) is less than 1, indicating exponential decay.
12

Calculate Percent Decay for (d)

The decay factor is \(0.88\). To find the percent decay rate:\[(1 - 0.88) \times 100 = 12\%\]So, the percent decay rate is 12%.

Unlock Step-by-Step Solutions & Ace Your Exams!

  • Full Textbook Solutions

    Get detailed explanations and key concepts

  • Unlimited Al creation

    Al flashcards, explanations, exams and more...

  • Ads-free access

    To over 500 millions flashcards

  • Money-back guarantee

    We refund you if you fail your exam.

Over 30 million students worldwide already upgrade their learning with 91Ó°ÊÓ!

Key Concepts

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

Exponential Growth
Exponential growth occurs when the amount of a substance increases over time. This pattern can be seen in natural phenomena such as populations or investments.

When you encounter an exponential function like \(A = 100(1.07)^t\), the number 1.07 within the parentheses is crucial. If this number, also known as the growth factor, is greater than 1, it indicates exponential growth.
  • Easy to spot: If the growth factor is more than 1.
  • The effect: The quantity gets larger as time progresses.
  • Example: A growing population or increasing interest on savings.
In our example for functions \(A = 100(1.07)^t\) and \(A = 5.3(1.054)^t\), the substances are experiencing exponential growth because 1.07 and 1.054 are greater than 1. This tells us that at each time period \(t\), the amount increases based on that growth factor.
Exponential Decay
Exponential decay is the process by which a quantity steadily decreases over time. This concept is often applied to things like radioactive decay or depreciation of assets.

In an exponential function, such as \(A = 3500(0.93)^t\) or \(A = 12(0.88)^t\), if the number inside the parentheses is less than 1, it signals decay.
  • Easy to identify: If the decay factor is less than 1.
  • The impact: The amount of substance declines as time moves on.
  • Example: A melting ice cube or a deflating balloon.
For these functions, with the decay factors of 0.93 and 0.88 respectively, we see that they represent exponential decay. Each time period brings a further reduction in the quantity by a consistent factor.
Percent Growth Rate
The percent growth rate shows how much a quantity grows per time period in percentage terms. This number gives a clearer picture than the growth factor alone.

To calculate the percent growth rate from a growth factor, subtract 1 from the growth factor and then multiply by 100:
  • First step: Subtract 1 from the growth factor.
  • Second step: Multiply the result by 100 to convert it to a percentage.
For example, if we have a growth factor of 1.07, the percent growth rate is \[(1.07 - 1) \times 100 = 7\%\].This means every period, the amount grows by 7%.

In our examples, the functions \(A = 100(1.07)^t\) and \(A = 5.3(1.054)^t\) have percent growth rates of 7% and 5.4% respectively. This percentage reflects how much the quantity increases every time unit.
Percent Decay Rate
The percent decay rate is useful for understanding how much a quantity decreases in percentage terms over each time period.

Here's how to find the percent decay rate from a decay factor:
  • First step: Subtract the decay factor from 1.
  • Second step: Multiply by 100 to express it as a percentage.
For instance, with a decay factor of 0.93, the percent decay rate is \[(1 - 0.93) \times 100 = 7\%\].This value tells us the amount decreases by 7% each period.

The functions \(A = 3500(0.93)^t\) and \(A = 12(0.88)^t\) illustrate exponential decay with percent decay rates of 7% and 12%, respectively. These rates signify the percentage of the original quantity that diminishes in every time increment.

One App. One Place for Learning.

All the tools & learning materials you need for study success - in one app.

Get started for free

Most popular questions from this chapter

In Problems \(29-30,\) a quantity \(P\) is an exponential function of time \(t .\) Use the given information about the function \(P=P_{0} e^{k t}\) to: (a) Find values for the parameters \(k\) and \(P_{0}\). (b) State the initial quantity and the continuous percent rate of growth or decay. \(P=40\) when \(t=4\) and \(P=50\) when \(t=3\)

The blood mass of a mammal is proportional to its body mass. A rhinoceros with body mass 3000 kilograms has blood mass of 150 kilograms. Find a formula for the blood mass of a mammal as a function of the body mass and estimate the blood mass of a human with body mass 70 kilograms.

For Problems \(1-16,\) solve for \(t\) using natural logarithms. $$a=b^{t}$$

Hydroelectric power is electric power generated by the force of moving water. The table shows the annual percent change in hydroelectric power consumption by the US industrial sector. $$\begin{array}{c|c|c|c|c|c} \hline \text { Year } & 2005 & 2006 & 2007 & 2008 & 2009 \\ \hline \text { \% growth over previous yr } & -1.9 & -10 & -45.4 & 5.1 & 11 \\ \hline \end{array}$$ (a) According to the US Department of Energy, the US industrial sector consumed about 29 trillion BTUs of hydroelectric power in \(2006 .\) Approximately how much hydroelectric power (in trillion BTUs) did the US consume in \(2007 ?\) In \(2005 ?\) (b) Graph the points showing the annual US consumption of hydroelectric power, in trillion BTUs, for the years 2004 to \(2009 .\) Label the scales on the horizontal and vertical axes. (c) According to this data, when did the largest yearly decrease, in trillion BTUs, in the US consumption of hydroelectric power occur? What was this decrease?

A person is to be paid 2000 for work done over a year. Three payment options are being considered. Option 1 is to pay the 2000 in full now. Option 2 is to pay \(\$ 1000\) now and \(\$ 1000\) in a year. Option 3 is to pay the full 2000 in a year. Assume an annual interest rate of \(5 \%\) a year, compounded continuously. (a) Without doing any calculations, which option is the best option financially for the worker? Explain. (b) Find the future value, in one year's time, of all three options. (c) Find the present value of all three options.
See all solutions

Recommended explanations on Math Textbooks

Logic and Functions

Read Explanation

Calculus

Read Explanation

Applied Mathematics

Read Explanation

Mechanics Maths

Read Explanation

Statistics

Read Explanation

Probability and Statistics

Read Explanation
View all explanations

What do you think about this solution?

We value your feedback to improve our textbook solutions.

Study anywhere. Anytime. Across all devices.