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Chapter 1: Introduction to Functions and Graphs

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Title: Chapter 1: Introduction to Functions and Graphs

1
Chapter 1 Introduction to Functions and Graphs

2
Several Common Types of Functions

While the definition of a function in mathematics
is very general, there are several more specific
types of functions which are very useful in
modeling applications.
The three basic types of functions we will study
in this section are constant, linear, and
nonlinear functions.
Constant FunctionA function f represented by
,where b is a fixed real number, is
a constant function.
Example 1 Let . Then f is a
constant function.
Notice that the graph of a constant (continuous)
function is a perfectly horizontal line.
Linear FunctionA function f represented by
, where a and b are fixed real
numbers (constants), is a linear function.

3
Several Common Types of Functions (contd)

4
Several Common Types of Functions (contd)

Note that we can also determine whether a
function is constant, linear, or nonlinear
without having to see its graph. We can look
simply at a functions symbolic representation.
Determining Constant, Linear, Nonlinear Functions
A function for which the independent variable
takes on only a power (exponent) of 0
(zero)typically, not written explicitlyis a
constant function.
A function for which the independent variable
takes on only a power of 1 (one) is a linear
function.
A function whose independent variable takes on
any other power than zero or one is a nonlinear
function. (For our current purposes, we shall
take this to be the definition of a nonlinear
function).
Example 3 Let
. Then f is a constant function (x is
raised to the zero power), g is a linear function
(x is raised to the 1st power), and h is a
nonlinear function (x is raised to a power other
than zero or onespecifically, power 2). Note
that since f is a constant function, it is also
a linear function.

5
Function Characteristics Rates of Change

Having these important types of functions, we
proceed to study important characteristics
concerning our functions. One of the most
important things we often need to know is how
much a functions output value (y-value) changes
as we move from a particular x-value to another
particular x-value. (This notion of a functions
rate of change is, in fact, the conceptual
foundation for the differential calculus). We
proceed to define the average rate of change of a
function from points x1 to x2 in the domain of
that function.
Average Rate of Change
Let be distinct points on
the graph of a function f.The average rate of
change of f from x1 to x2 is

6
Function Characteristics Rates of Change (contd)

Example 4 Let . What is the
average rate of change of f on the interval
2,5? (That is, from x2 to x5).
Solution We let x1 2, x2 5. We have y1
f(x1) f(2) 2(4) 8, and y2 f(x2) f(5)
2(25) 50. Thus, the average rate of change of f
on the interval 2,5 is given by (50-8)/(5-2)
(42)/(3) 14.
Problem What is the average rate of change of
the function on the interval
x1,x2?

7
Function Characteristics Slope

Notice that for the given f below, it doesnt
matter which values we assign to x1 and x2 the
average rate of change of f remains the same no
matter which interval of its domain we consider.
That is, this particular function exhibits a
constant rate of change. This is because f is a
linear function.
The average rate of change of a linear function
is called the slope of that linear function
(i.e., the slope of the line represented by that
function) and is conventionally denoted by the
letter m.
Problem Let . Then f is a
linear function. Find the slope of the line
represented by f.
Since any two points determine a unique line in
the cartesian plane, we can find the slope of the
line passing through any two points (x1,y1) and
(x2,y2).
Problem Find the slope of the line passing
through the points (4,6) and (2,5).
Note that it doesnt matter which point we choose
as our first, and which as our second.

8
A Few Comments About Slope

Notice that the slope of any constant function
(i.e., horizontal line) is equal to zero. (Why?)
The slope of a line can be thought of in the
following manner if a line f has slope m, then
for every one unit we move right on the x-axis,
we must move m units up or down (depending on
whether m is positive or negative) to find
another point on the line. (Example?)
Suppose that a line f has slope m. If mgt0, then
the graph of f rises as we move from left to
right on the x-axis. This line is said to have
positive slope. If mlt0, then the graph of f
falls as we move from left to right on the
x-axis. This line is said to have negative slope.
(Examples?) If the line f has slope m0, then
of course f is a constant function and so the
line is horizontal.
A perfectly vertical line is said to have
undefined slope (or, sometimes, infinite slope).
(Why is this slope undefined?) Note that, in
any case, undefined slope is not a problem since
slope is defined for functions. A vertical line
is not a function. (Why?)
Finally, note that for a nonlinear function, the
average rate of change of that function on an
interval a,b is really only the slope of the
line passing through the points (a, f(a)) and (b,
f(b)).
Homework for this section