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Exponential and Log Functions: Properties and Graphs, Lecture notes of Elementary Mathematics

Wingate UniversityElementary Mathematics

An overview of exponential functions, their graphs, and the relationship between exponential functions and logarithmic functions. Topics covered include the definition of exponential functions, the features of their graphs, and the properties of logarithmic functions as the inverse of exponential functions.

What you will learn

  • What are the features of the graph of an exponential function?
  • What is an exponential function?
  • What is the relationship between exponential and logarithmic functions?

Typology: Lecture notes

2021/2022

Uploaded on 09/12/2022

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C3 Exponential and Log Functions
Mrs S Richards Hawthorn High
EXPONENTIAL FUNCTIONS and GRAPHS
An exponential function is one of the form
x
yk
where k is a constant
(which is not equal to 1), and x is the variable.
In other words an exponential function is a power function.
ALL exponential functions display similar features but we will look specifically at THE
EXPONENTIAL FUNCTION
() x
f x e
Once you know the shape of an exponential graph, you can shift it vertically or
horizontally, stretch it, shrink it, reflect it, check answers with it, and most important
interpret the graph.
The function
() x
f x e
is always positive.
There is simply no value of x that will cause the value of to be negative.
What does this mean in terms of a graph? It means that the entire graph of the function
() x
f x e
is located in quadrants I and II.
Notice that the graph never crosses the x-axis. WHY?
It is because there is no value of x that will cause the value of f(x) in the formula to equal 0.
Notice that the graph crosses the y-axis at 1. WHY?
The value of x is always zero on the y-axis. Substitute 0 for x in the equation
: .
pf3

Partial preview of the text

Download Exponential and Log Functions: Properties and Graphs and more Lecture notes Elementary Mathematics in PDF only on Docsity!

EXPONENTIAL FUNCTIONS and GRAPHS

An exponential function is one of the form

x ^ y^  k where k is a constant

(which is not equal to 1), and x is the variable.

In other words an exponential function is a power function.

ALL exponential functions display similar features but we will look specifically at THE EXPONENTIAL FUNCTION

x

f x  e

Once you know the shape of an exponential graph, you can shift it vertically or horizontally, stretch it, shrink it, reflect it, check answers with it, and most important interpret the graph.

 The function ( )^

x

^ f^ x^  e is always positive.

There is simply no value of x that will cause the value of to be negative.

What does this mean in terms of a graph? It means that the entire graph of the function

x

f x  e is located in quadrants I and II.

 Notice that the graph never crosses the x-axis. WHY?

It is because there is no value of x that will cause the value of f(x) in the formula to equal 0.

 Notice that the graph crosses the y-axis at 1. WHY?

The value of x is always zero on the y-axis. Substitute 0 for x in the equation

:.

So the graph will always pass through the point (0,1)

 WHAT IS THIS NUMBER CALLED e? What makes it special?

We have already seen in out work on differentiation that ^ 

d (^) x x e e dx

THIS IS WHAT MAKES THE FUNCTION

x

^ e SO SPECIAL!!!!

The Number e is an irrational number which is approx 2.718281828……. and ex is the ONLY function that has a gradient function equal to the function itself.

We see from the graph of

x

^ y^  e that it is a ONE TO ONE INCREASING FUNCTION

And as we know all one to one functions have an INVERSE FUNCTION.

The INVERSE FUNCTION of ( )^

x

^ f^ x^  e is

1

f ( ) x ln x

This is the NATURAL LOGARITHM OF x TO THE BASE e

We must remember the general properties of logarithms and apply them to the base e.

If 102  100 thenlog 10 100  2

would be an appropriate statement when working to the base of 10

To the base e, we could say:

number x

e  then ln e number^  x

but when we work with natural logarithms to the base e we do not bother to write the base e

we simply call this special function ln^ x

Since they are inverse functions we can quote the important results that:

ln( )

x

e  x

and

ln x

e  x