Functions and Variations - Pre Calculus PDF

Summary

These are notes on functions and variations, focusing on precalculus concepts. They cover topics ranging from relations and functions to function notation, rectangular coordinate systems, graphs of functions, and shifts in graphs.

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Functions and Variations
-Pre Calculus-

Raye Rhouieze B. Miranda
Functions
 Relations
A relation is a set of ordered pairs. The relation may be specified by an
equation, a rule, or a table. The set of the first components of the ordered pairs
is called the domain of the relation. The set of the second components is called
the range of the relation. In this chapter, we shall consider only relations that
have sets of real numbers for their domain and range.
 Functions
A function is a relation such that each element in the domain is paired with
exactly one element in the range.
 Functions
Often functions and relations are stated as equations. When the domain is not
stated, we determine the largest subset of the real numbers for which the
equation is defined, and that is the domain.
Once the domain has been determined, we determine the range by finding the
value of the equation for each value of the domain. The variable associated with
the domain is called an independent variable and the variable associated with
the range is called the dependent variable.
In equations with the variables x and y, we generally assume that x is the
independent variable and that y is the dependent variable.
Functions
Functions
 Function Notation
The notation y = f (x), read "y equals f of x," is used to designate that y is a
function of x. With this notation f(a) represents the value of; the dependent
variable y when x = a (provided that there is a value).

Thus y = x² − 5x + 2 may be written f (x) = x² − 5x + 2. Then f (2), i.e., the value
of f(x) or y when x = 2, is f (2) = 2² − 5(2) + 2 = −4.
Similarly, f (−1) = (−1)² − 5(−1) + 2 = 8.

Any letter may be used in the function notation; thus g(x), h(x), F(x), etc., may
represent functions of x.
 Rectangular Coordinate System
A rectangular coordinate system is used to give a picture of the relationship
between two variables.
Consider two mutually perpendicular lines X′X and Y′Y intersecting in the point
O, as shown
 Rectangular Coordinate System
Given a point P in this xy plane, drop perpendiculars from P to the x and y axes.
The values of x and y at the points where these perpendiculars meet the x and y
axes determine respectively the x coordinate (or abscissa) of the point and the
y coordinate (or ordinate) of the point P. These coordinates are indicated by the
symbol (x, y).

Conversely, given the coordinates of a point, we may locate or plot the point in
the xy plane.

For example, the point P in the figure has coordinates (3, 2); the point having
coordinates (−2, −3) is Q. The graph of a function y = f (x) is the set of all points
(x, y) satisfied by the equation y = f (x).
 Function of Two Variables
The variable z is said to be a function of the variables x and y if there exists a
relation such that to each pair of values of x and y there corresponds one or
more values of z. Here x and y are independent variables and z is the dependent
variable.

The function notation used in this case is z = f (x, y): read "z equals f of x and y."
Then f (a, b) denotes the value of z when x = a and y = b, provided the function
is defined for these values.

Thus if f (x, y) = x³ + xy² − 2x, then f (2, 3) = (2³) + (2 · 3²) − (2 · 3) = 20.

In like manner we may define functions of more than two independent
variables.
 Graphs of Functions
In each case, for any value of x, there is only one value for y. Contrast this with
the graphs
 Graphs of NOT Functions
In each of the relations, a single value of x is associated with two or more values
of y. These relations are not functions.
 Symmetry
When the left half of a graph is a mirror image of the right half, we say the
graph is symmetric with respect to the y axis. This symmetry occurs because
for any x value, both x and −x result in the same y value, that is f (x) = f (−x). The
equation may or may not be a function for y in terms of x.
 Symmetry
Some graphs have a bottom half that is the mirror image of the top half, and we
say these graphs are symmetric with respect to the x axis. Symmetry with
respect to the x axis results when for each y, both y and −y result in the same x
value. In these cases, you do not have a function for y in terms of x.
 Shifts
The graph of y = f (x) is shifted upward by adding a positive constant to each y-
value in the graph. It is shifted downward by adding a negative constant to each
y-value in the graph of y = f (x). Thus, the graph of y = f (x) + b differs from the
graph of y = f (x) by a vertical shift of |b| units. The shift is up if b > 0 and the
shift is down if b < 0.
Shifts
 Shifts
How do the graphs of y = (x + 1)² and y = (x − 2)² differ from the graph of y
= x²?

The graph of y = x² is shifted 1 unit to the left to yield the graph of y = (x + 1)²
since x + 1 = x − (−1)

The graph of y = x² is shifted 2 units to the right to yield the graph of
y = (x − 2)²
Shifts
Seatwork #2
1. Given y = 2x − 1, obtain the values of y corresponding to x = −3, −2, −1, 0, 1,
2, 3 and plot the points (x, y) thus obtained.
2. Obtain the graph of the function defined by y = x2 − 2x − 8 or f (x) = x2 − 2x
− 8.
3. Graph the function defined by y = 3 − 2x − x2.
4. In which of these equations is y a function of x?
a. y = 3x³
b. y² = x
c. xy = 1
d. y = 2x + 5
e. y=√4x
f. y² = 8x
-The End-