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Trigonometry |
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Graphs of
Trigonometric Functions |
The Graph of the
Sine Function f
(x) = sin
x |
Properties of the sine
function |
Domain and range |
Zeros of the function |
Extremes, maximum and
minimum of the sine function |
Parity and periodicity
of the sine function |
Behavior of the sine function |
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Graphs of
trigonometric functions |
Visual presentation of changes and behavior of each trigonometric function shows us its graph in the coordinate plane
xOy.
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A graph of a function is formed by points
P (x, f (x)), where the abscissas
x
belong to the domain and the calculated values of the function f
(x)
as the ordinates, which are the corresponding values from the range.
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The graph of the
sine function f
(x) = sin
x |
The unit circle is divided to arbitrary number of equal parts, for example
12
as on the below figure, which then measure
2p/12
= p/6
each.
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On the same way starting from the origin divided is its circumference
2p
to the same number of equal parts on the
x-axis.
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That way, an arc
x
becomes the abscissa of a point in a coordinate system. By associating the ordinates of the ending points of
the arcs x of the unit circle to the corresponding abscissas
x obtained are the points
P (x,
sin x) of the curve named sine curve or
sinusoid.
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Properties of the sine
function |
- Domain and range |
From the graph in the down figure we see that the sine function is defined for all real numbers
x
that is, the domain
of the function
Df = R.
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The graph of the sine function is bounded between lines
y = -1 and
y = 1. Therefore, the function takes all
values from the closed interval
[-1,
1], written range
( f )
or f (D) =
[-1,
1].
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- Zeros of the function |
The points of intersection of a function with the
x-axis we obtain by solving equation
f (x) = 0, |
sin
x = 0, where x =
kp,
k Î
Z |
that is,
the x-intercepts are,
x = 0, ± p, ±
2p, ±
3p,
¼
as shows the above diagram.
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- Extremes, maximum and
minimum of the sine function |
The sine function reaches its maximum value
1
at the points whose abscissas are the solutions of the
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equation, |
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and its minimal value
-1 at the points whose abscissas satisfy the equation
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- Parity and periodicity
of the sine function |
Parity - A function that change sign but not absolute value when the sign of the independent variable is changed is
odd function, that is if
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f
(-x)
= -
f (x). |
Such a function is symmetrical about the origin, as
shows the figure above. |
Let examine parity of the sine function
f (x)
=
sin x, |
f
(-x)
=
sin (-x)
= -
sin x
= -
f (x) therefore,
the sine is odd function.
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The
sine function is periodic |
A function
f (x)
that repeats its value for all integral multiples of a constant number
p
added to the independent variable, is called
periodic function with period p. That is, if |
f
(x)
= f (x + n · p),
n
= 1, 2, 3, . . . |
For the sine function holds the identity |
sin (x + k · 2p)
= sin x, k
Î
Z |
that
means that all positive and negative multiples of 2p
are periods of the sine function but the least (principal) period
P = 2p. |
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Behavior of the sine function |
We analyze behavior of a function by moving from left to right, i.e., in the direction of the positive
x-axis
examining the following
characteristics, |
- intervals where the function is increasing or decreasing, |
- maximums and minimums, and |
- roots or zero function values. |
Since trigonometric functions are periodic, it is enough to examine its behavior inside of one period. |
Therefore, for the sine function we examine the interval
0 < x
< 2p. |
The
graph of the sine function shows, |
- when the arc x
increases from 0
to p/2
the function
sin x increases from 0
to 1, |
- when the arc x increases from
p/2
to p the function
sin x decreases from 1
to 0, |
- when the arc x increases from
p
to 3p/2 the function
sin x decreases from 0 to
-1, |
- when the arc x increases from
3p/2
to 2p
the function
sin x increases from -1
to 0. |
Behavior of a function can also be shown in the tabular form, |
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Functions
contents D |
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