1.7 exponential growth and decay math 150 spring 2005
TRANSCRIPT
Lab: Exponential Growth and Decay (2)
This lab is a guided exercise. It consists of an exercise in Vista titled as above
with the notes contained in this presentation. You should read these notes and work the exercises
when told to do so. You may use a graphing calculator, your text and
your notes as needed. You must work this lab individually but you may ask
the mentors or your instructor for help.
Growth and Decay (Decrease) A quantity that changes over time may either increase or
decrease. A quantity Q that increases by a fixed percent every year is said
to have “exponential growth” A quantity Q that decreases by a fixed percent every year is said
to have “exponential decay” In general, we say that a function Q(t) is exponential if it has a relative (percent) rate of change that is constant.
Another way of saying this is that the amount by which the function Q(t) changes at time t depends on the actual value of the function at time t
You should work exercises 1 and 2 from the lab now.
A Familiar Example In the example to the right,
the population is increasing at a constant rate of .042 (i.e. 0.042P(t) people are being added at time t)
You need to know what the population is at a given time in order to determine how many people are being added, but it will always be 4.2% of the population at that time.
You should work exercise 3 from the lab now.
Doubling and Halving
Quantities that get smaller over time will at some point be half of where they started
Quantities that get larger will at some point be twice their original size
Financial Applications
Compound Interest Exponential growth Investment value goes up (hopefully) Property value Equipment and facilities depreciation (value goes
down a fixed percent every year) Future and Present Value
Two Kinds of Compounding
Compounding can occur a fixed number of times per year We will focus on compounding once per year
Compounding can occur continuously In this case, use e
Present and Future Value The value of money now will differ from the value years from now (due to
inflation, investment growth, etc.) To find the value B of a sum P in some number of years, we will only consider
interest accumulations For example, $100 deposited in an account paying 7% interest compounded
annually will be worth $107 in 1 year. $100 is the present value and $107 is the future value.
Computations
In order to apply these ideas, we need some formulas.
Future and Present values depend on the type of interest that is accumulating