9 trigonometric functions via the unit circle nat

Radian Measurements
The unit circle is the circle
centered at (0, 0) with radius 1.

Radian Measurements
r = 1
(1, 0)

Radian Measurements
It's the graph of the equation
x2 + y2 = 1.
r = 1
(1, 0)

The radian measurement of an
angle is the length of the arc
that the angle cuts out on the
unit circle.
Radian Measurements
x2 + y2 = 1.
r = 1
(1, 0)

unit circle.
Arc length as angle
measurement for 
Radian Measurements

r = 1
x2 + y2 = 1.
(1, 0)

unit circle.
Arc length as angle
measurement for 
Radian Measurements

Hence 2π rad, the circumference of the unit circle,
is the radian measurement for the 360o angle.
r = 1
x2 + y2 = 1.
(1, 0)

unit circle.
Arc length as angle
measurement for 
Radian Measurements

Hence 2π rad, the circumference of the unit circle,
is the radian measurement for the 360o angle.
r = 1
Important Conversions between Degree and Radian
π
180 π
180o
x2 + y2 = 1.
1o =  0.0175 rad 1 rad =  57o
180o = π rad 90o = radπ
2 60o = radπ
3 45o = radπ
4
(1, 0)

Let’s extend the measurements
of angles to all real numbers.
Trigonometric Functions via the Unit Circle

of angles to all real numbers. We
say an angle  is in the standard
position if it’s formed by spinning
a dial against the positive x–axis.

The direction of the spin sets the
sign of ,  is set to positive if it’s
formed counter-clockwise,
 is +

formed counter-clockwise, and
negative if it’s formed clockwise.
 is +
 is –

(1,0)

 is +
 is –
(x , y)
Given  in the standard position,
let the coordinate of the tip of the
dial on the unit circle be (x, y),

(1,0)

 is +
 is –
y=sin()
(x , y)
we define:
sin() = y,

(1,0)

x=cos()
 is +
 is –
y=sin()
(x , y)
we define:
sin() = y, cos() = x,

(1,0)

x=cos()
 is +
 is –
y=sin()
(x , y)
tan()
we define:
sin() = y, cos() = x, tan() = y
x
(1, tan())

negative if it’s formed clockwise.(1, tan())
we define:
sin() = y, cos() = x, tan() =

x=cos()
 is +
 is –
y=sin()
(x , y)
y
x
tan()
Note: The slope of the dial is tan().
(1,0)

Important Trigonometric Values
From here on, all angles measurements will be in
radian, unless stated otherwise.

Angles with measurements of nπ rad,
where n = 0,1,2,3.. .is an integer,
correspond to the x–axial angles.
0, ±2π, ±4π..±π, ±3π..

0, ±2π, ±4π..±π, ±3π..
Angles with measurements of
rad correspond
to the y–axial angles.
.. –3π/2, π/2, 5π/2..
..–5π/2, –π/2, 3π/2 , 7π/2..
kπ
2

0, ±2π, ±4π..±π, ±3π..
rad correspond
.. –3π/2, π/2, 5π/2..
..–5π/2, –π/2, 3π/2 , 7π/2..
rad are diagonals.
π/4, –7π/4..3π/4, –5π/4..
5π/4, –3π/4.. 7π/4, –π/4..
kπ
2
4
kπ

0, ±2π, ±4π..±π, ±3π..
rad correspond
.. –3π/2, π/2, 5π/2..
..–5π/2, –π/2, 3π/2 , 7π/2..
rad are diagonals.
π/4, –7π/4..3π/4, –5π/4..
5π/4, –3π/4.. 7π/4, –π/4..
(reduced) or rad. π/6, –11π/6..
π/3, –5π/3..2π/3,..
5π/6,..
7π/6,..
4π/3,.. 5π/3,..
11π/6,..
kπ
2
4
6 3
kπ
kπ k π
These are the clock hourly positions.

The trig–values of an angle  depend on the position
of the dial at the angle .

of the dial at the angle . For an integer n, the angle
2nπ corresponds to spinning n complete cycles,

so the dial spin to the same position for  and  + 2nπ
and  and  + 2nπ have the same trig-outputs.

Two Important Right Triangles
Recall the following two triangles which are useful for
extracting the trigonometric values of angles related
to π/4, π/6 and π/3.

to π/4, π/6 and π/3. From these “templates” we can
determine the trig-values of the following angles.

I. (nπ/4) : The angles at the
diagonal positions (n is odd.)

I. (nπ/4) : The angles at the
diagonal positions (n is odd.)
II. (nπ/6) : The angles at the
clock hourly positions.

Example A. Draw the angle, label the coordinates of
the corresponding position on the unit circle and list
the sine, cosine, and tangent trig–values.
a.  = –3π

a.  = –3π
–3π
(–1, 0)

a.  = –3π
–3π
(–1, 0)
sin(–3π) = 0
cos(–3π) = –1
tan(–3π) = 0

a.  = –3π
–3π
(–1, 0)
b.  = 5π/4
sin(–3π) = 0
cos(–3π) = –1
tan(–3π) = 0

a.  = –3π
–3π
(–1, 0)
b.  = 5π/4
sin(–3π) = 0
cos(–3π) = –1
tan(–3π) = 0
5π/4

a.  = –3π
–3π
(–1, 0)
b.  = 5π/4
sin(–3π) = 0
cos(–3π) = –1
tan(–3π) = 0
Place the π/4–rt–triangle as shown,
5π/4

a.  = –3π
–3π
(–1, 0)
b.  = 5π/4
sin(–3π) = 0
cos(–3π) = –1
tan(–3π) = 0
1
5π/4

a.  = –3π
5π/4
(–2/2, –2/2)
–3π
(–1, 0)
b.  = 5π/4
sin(–3π) = 0
cos(–3π) = –1
tan(–3π) = 0
we get the coordinate = (–2/2, –2/2).
1

a.  = –3π
(–2/2, –2/2)
–3π
(–1, 0)
b.  = 5π/4
sin(–3π) = 0
cos(–3π) = –1
tan(–3π) = 0
sin(5π/4) = –2/2
tan(5π/4) = 1
cos(5π/4) = –2/2
we get the coordinate = (–2/2, –2/2).
1
5π/4

c.  = –11π/6

c.  = –11π/6
–11π/6
1

c.  = –11π/6
–11π/6
(3/2, ½)
we get the coordinate = (3/2, 1/2). 1

c.  = –11π/6
–11π/6
(3/2, ½)
we get the coordinate = (3/2, 1/2).
sin(–11π/6) = 1/2
cos(–11π/6) = 3/2
tan(–11π/6) = 1/3 =3/3
1

c.  = –11π/6
–11π/6
(3/2, ½)
sin(–11π/6) = 1/2
cos(–11π/6) = 3/2
tan(–11π/6) = 1/3 =3/3
1
Conversely, in general, there are two locations on the
unit circle having a specified trig-value.

c.  = –11π/6
–11π/6
(3/2, ½)
sin(–11π/6) = 1/2
cos(–11π/6) = 3/2
tan(–11π/6) = 1/3 =3/3
1
Example B. a. Find the two locations on
the unit circle where tan() = 3/4. Draw.

c.  = –11π/6
–11π/6
(3/2, ½)
sin(–11π/6) = 1/2
cos(–11π/6) = 3/2
tan(–11π/6) = 1/3 =3/3
1
We want the points (x, y) on the circle
where tan() = y/x = ¾.
(x, y)

c.  = –11π/6
–11π/6
(3/2, ½)
sin(–11π/6) = 1/2
cos(–11π/6) = 3/2
tan(–11π/6) = 1/3 =3/3
1
We want the points (x, y) on the circle
where tan() = y/x = ¾.
Here are two ways to obtain the answers.
(x, y)

I. (Numerical Computation) We’ve y/x = ¾ or y = ¾ x,

so by the Pythagorean Theorem, x2 + (¾ x)2 = 1.

Solving for x, we get x2 = 16/25 or x = ±4/5,

so (x, y) = (4/5, 3/5) or (–4/5, –3/5).

so (x, y) = (4/5, 3/5) or (–4/5, –3/5).
(4, 3)
(x, y) = (4/5, 3/5)
(–4/5, –3/5)

Il. (Using proportional triangles)
so (x, y) = (4/5, 3/5) or (–4/5, –3/5).
Given that
(4, 3)
y
=x 4
3 we have that (4, 3) is a point
on the radial line through (x, y).
(x, y) = (4/5, 3/5)
(–4/5, –3/5)

so (x, y) = (4/5, 3/5) or (–4/5, –3/5).
Given that
(4, 3)
y
=x 4
The point (4, 3) is 5 units away
from the origin (why?).
(x, y) = (4/5, 3/5)
(–4/5, –3/5)

so (x, y) = (4/5, 3/5) or (–4/5, –3/5).
Given that
(4, 3)
y
=x 4
By dividing the coordinates by 5,
so (x, y) = (4/5, 3/5) and the
other point is (–4/5, –3/5).
(x, y) = (4/5, 3/5)
(–4/5, –3/5)

so (x, y) = (4/5, 3/5) or (–4/5, –3/5).
Given that
(4, 3)
y
=x 4
By dividing the coordinates by 5,
so (x, y) = (4/5, 3/5) and the
other point is (–4/5, –3/5).
(x, y) = (4/5, 3/5)
(–4/5, –3/5)
Buy providing more information
we may narrow the answer to one location.

Example B. b. Find cos()
if tan() = ¾ and that sin() is negative.

The two points where tan() = ¾
are (4/5, 3/5) or (–4/5, –3/5).

are (4/5, 3/5) or (–4/5, –3/5). (–4/5, –3/5)

are (4/5, 3/5) or (–4/5, –3/5).
The one with negative sin() or y
must is (–4/5, –3/5), hence cos() = –4/5.
(–4/5, –3/5)

are (4/5, 3/5) or (–4/5, –3/5).
must is (–4/5, –3/5), hence cos() = –4/5.
(–4/5, –3/5)
Example C. a. Draw and find the locations on
the unit circle where sin() = 1/3.

are (4/5, 3/5) or (–4/5, –3/5).
must is (–4/5, –3/5), hence cos() = –4/5.
(–4/5, –3/5)
1/3

are (4/5, 3/5) or (–4/5, –3/5).
must is (–4/5, –3/5), hence cos() = –4/5.
(–4/5, –3/5)
Sin() = 1/3 = y, so x2 + (1/3)2 = 1
1/3

are (4/5, 3/5) or (–4/5, –3/5).
must is (–4/5, –3/5), hence cos() = –4/5.
(–4/5, –3/5)
Sin() = 1/3 = y, so x2 + (1/3)2 = 1
and that x = ±√8/9 = ±(2√2)/3. 1/3

are (4/5, 3/5) or (–4/5, –3/5).
must is (–4/5, –3/5), hence cos() = –4/5.
(–4/5, –3/5)
Sin() = 1/3 = y, so x2 + (1/3)2 = 1
and that x = ±√8/9 = ±(2√2)/3.
Both points are at the top-half of
the circle as shown.
(–(2√2)/3, 1/3) ((2√2)/3, 1/3)
1/3

are (4/5, 3/5) or (–4/5, –3/5).
must is (–4/5, –3/5), hence cos() = –4/5.
(–4/5, –3/5)
Sin() = 1/3 = y, so x2 + (1/3)2 = 1
and that x = ±√8/9 = ±(2√2)/3.
b. What is cos() if tan() is negative?
1/3
(–(2√2)/3, 1/3) ((2√2)/3, 1/3)

are (4/5, 3/5) or (–4/5, –3/5).
must is (–4/5, –3/5), hence cos() = –4/5.
(–4/5, –3/5)
Sin() = 1/3 = y, so x2 + (1/3)2 = 1
and that x = ±√8/9 = ±(2√2)/3.
b. What is cos() if tan() is negative?
If tan() is negative, we have cos() = –(2√2)/3.
1/3
(–(2√2)/3, 1/3) ((2√2)/3, 1/3)

Here are some basic facts of sine, cosine and tangent
as the consequences of the unit–circle definition.

For all angles A:
* –1 ≤ sin(A) ≤ 1
or l sin(A) l ≤ 1
(1,0)
A
sin(A)
(x , y)

For all angles A:
* –1 ≤ sin(A) ≤ 1
or l sin(A) l ≤ 1
* sin(–A) = –sin(A)
(1,0)
A
sin(A)
(x , y)
–A
sin(–A)
(x , –y)

For all angles A:
* –1 ≤ sin(A) ≤ 1
or l sin(A) l ≤ 1
(1,0)
A
sin(A)
(x , y)
–A
sin(–A)
(1,0)
A
cos(A)
(x , y)
(x , –y)
* –1 ≤ cos(A) ≤ 1
or l cos(A) l ≤ 1

For all angles A:
* –1 ≤ sin(A) ≤ 1
or l sin(A) l ≤ 1
(1,0)
A
sin(A)
(x , y)
–A
sin(–A)
(1,0)
A
cos(A) = cos(–A)
(x , y)
–A
(x , –y) (x , –y)
* –1 ≤ cos(A) ≤ 1
or l cos(A) l ≤ 1
* cos(–A) = cos(A)

Rotational Identities

Given an angle A and let (x, y) be the point on the
unit circle corresponding to A,
A
(x , y)
(1,0)

unit circle corresponding to A, since the angles
(A + π) and (A – π) point in the opposite direction of A
A
(x , y)
(1,0)
A – π
A + π

so (–x, –y) corresponds to (A + π) and (A – π).
A
(x , y)
(–x , –y)
(1,0)
A – π
A + π

A
(x , y)
(–x , –y)
sin(A ± π) = –sin(A)
cos(A ± π) = –cos(A)
180o rotational identities:
(1,0)
A – π
A + π

(1,0)A
(x , y)
A – π
(–x , –y)
sin(A ± π) = –sin(A)
cos(A ± π) = –cos(A)
(A + π/2 ) and (A – π/2) are 90o
counterclockwise and clockwise
rotations of A and the points
(–y, x) and (y, –x) correspond to
A + π/2 and A – π/2 respectively.
(–y, x)
(y, –x)
A + π

(1,0)
A
(x, y)
A + π/2(–y, x)

(1,0)
A
(x, y)
A + π/2(–y, x)
sin(A + π/2) = cos(A)

(1,0)
A
(x, y)
A + π/2(–y, x)
cos(A + π/2) = –sin(A)

(1,0)
A
(x, y)
A + π/2
A – π/2
(–y, x)
(y, –x)
sin(A – π/2) = –cos(A)
cos(A – π/2) = sin(A)

(1,0)
A
(x, y)
A + π/2
A – π/2
(–y, x)
(y, –x)
(1,0)
A x
y
(x, y)
Given the angle A, tan(A) =
y
x

(1,0)
A
(x, y)
A + π/2
A – π/2
(–y, x)
(y, –x)
(1,0)
A x
y
(x, y)
tan(A)
=Given the angle A, tan(A) =
which is the slope of the dial.
y
x
y
x
(1, tan())

(1,0)
A
(x, y)
A + π/2
A – π/2
(–y, x)
(y, –x)
(1,0)
A x
y
(x, y)
tan(A)
Tangent is UDF for π/2 ± nπ
where n is an integer.
y
x
y
x
(1, tan())

(1,0)
A
(x, y)
A + π/2
A – π/2
(–y, x)
(y, –x)
(1,0)
A x
y
(x, y)
tan(A)
Tangent is UDF for π/2 ± nπ
where n is an integer. In particular
y
x
y
x
–∞ < tan(A) < ∞
tan(A ± π) = tan(A) tan(A ± π/2) = –1/tan(A)
(1, tan())

Given an angle A, its horizontal reflection is (π – A).
From that we have:
sin(A) = sin(π – A)
(1,0)
A
(x , y)
π – A
(–x , y)
cos(A) = –cos(π – A)
tan(A) = –tan(π – A)

The reciprocals of sine, cosine, and tangent
appear frequently amongst their algebraic relations.
Hence we define secant, cosecant, and cotangent
as their reciprocals respectively.

cos(A)
1
sec(A) =

cos(A)
1
sec(A) =
Secant is UDF for
{π/2 + nπ} with integer n.

cos(A)
1
sec(A) =
Secant is UDF for
Since l cos(A) l ≤ 1
we’ve I sec(A) l ≥ 1.

cos(A)
1
sec(A) =
Secant is UDF for
Specifically,
sec(A) ≥ 1 for 0 ≤ A < π/2,
sec(A) ≤ –1 for π/2 < A ≤ π.

cos(A)
1
sec(A) =
Secant is UDF for
Specifically,
sec(A) ≥ 1 for 0 ≤ A < π/2,
sec(A) ≤ –1 for π/2 < A ≤ π.
sin(A)
1
csc(A) =

cos(A)
1
sec(A) =
Secant is UDF for
Specifically,
sec(A) ≥ 1 for 0 ≤ A < π/2,
sec(A) ≤ –1 for π/2 < A ≤ π.
sin(A)
1
csc(A) =
Cosecant is UDF for
{nπ} with integer n.

cos(A)
1
sec(A) =
Secant is UDF for
Specifically,
sec(A) ≥ 1 for 0 ≤ A < π/2,
sec(A) ≤ –1 for π/2 < A ≤ π.
sin(A)
1
csc(A) =
Cosecant is UDF for
{nπ} with integer n.
Since l sin(A) l ≤ 1 we
have I csc(A) l ≥ 1.
Specifically,
csc(A) ≥ 1 for 0 < A ≤ π/2,
csc(A) ≤ –1 for –π/2 <A ≤ 0.

tan(A)
1
cot(A) =

Cot(A) is UDF for
{π/2 + nπ}.
tan(A)
1
cot(A) =

Cot(A) is UDF for
{π/2 + nπ}.
Since –∞ < tan(A) < ∞
we have –∞ < cot(A) < ∞.
tan(A)
1
cot(A) =

Cot(A) is UDF for
{π/2 + nπ}.
tan(A)
1
cot(A) =
Given the angle A and let (x , y) be the corresponding
position on the unit circle,
(1,0)
(x , y)
A
1

Cot(A) is UDF for
{π/2 + nπ}.
tan(A)
1
cot(A) =
(1,0)
(x , y)
position on the unit circle, then the tangent and the
cotangent are lengths shown in the figure.
We leave the justification as homework.
A
1

Cot(A) is UDF for
{π/2 + nπ}.
tan(A)
1
cot(A) =
(1,0)
(x , y)
tan(A)
(1,tan(A))
A
1

Cot(A) is UDF for
{π/2 + nπ}.
tan(A)
1
cot(A) =
(1,0)
A
(x , y)
tan(A)
cot(A)
1
(1,tan(A))
(cot(A),1)

With the unit–circle definition, except at isolated
inputs, the trig-functions are defined for all angles,
thus removing the restriction of the SOCAHTOA
definition based on right triangles.

With the unit–circle definition, except at isolated
inputs, the trig-functions are defined for all angles,
thus removing the restriction of the SOCAHTOA
definition based on right triangles.
Since trig–functions produce the same output for
every 2nπ increment, i.e. for any trig–function f,
f(x) = f(x + 2nπ), where n is an integer,
trig–functions are useful to describe cyclical data.
Circadian Rhythms
Circadian rhythms are the bio–rhythms of a person
or of any living beings, that fluctuate through out
some fixed period of time: hourly, daily, etc..
For people, the measurements could be the blood
pressures, or the heart rates, etc..

The temperature of a person drops when sleeping
and rises during the day due to activities.
A way to summarize the collected temperature data
is to use a trig–function to model the data.
For example, using the sine formula,
the temperature T might be given as
T(t) = 37.2 – 0.5*sin(πt/12)
where t is the number of hours passed 11 pm
when the person falls asleep.
So at 11 pm, t = 0 the temperature is 37.2o,
at 5 am, t = 6, the temperature drops to 36.7o,
at 11 am, t = 12, the temperature rises back to 37.2o,
and at 5 pm, t = l8, the temperature peaks at 37.7o.
This gives a convenient estimation of the temperature.

https://en.wikipedia.org/
wiki/Trigonometric_funct
ions#sec
We utilize the following angles and coordinates on
the unit circle for examples and homework.
One should memorize them.

1. Fill in the angles and the coordinates of
points on the unit circle
a. in the four diagonal directions and
b. in the twelve hourly directions.
(See the last slide.)
2.
Convert the angles into degree and
find their values. If it’s undefined, state So. (No calculator.)
sin(4π)cos(2π), tan(3π),sec(–2π), cot(–3π),csc(–π),
3. cos(2π), tan(π),sec(–3π), cot(–5π),csc(–2π), sin (–3π)
4. cos(π /2), tan(3π/2),sec(–π/2), cot(–3π /2),
cot(–5π/2),csc(–π/2),sin(–π/2),5. sec(–π/2),
7. cos(–11π/4),
tan(7π/4),
sec(–7π/4),cot(5π/4),
cot(5π/4),
csc(π/4),
sin(–π/4),6. sec(–3π/4),

9. cos(–2π/3),
tan(7π/3),
sec(–7π/3),cot(5π/3),
cot(5π/3),
csc(4π/3),
sin(–π/3),8. sec(–2π/3),
11. cos(–23π/6),
tan(7π/6),
sec(–17π/6),cot(25π/6),
cot(5π/6),
csc(–5π/6),
sin(–π/6),10. sec(–5π/6),
12. a. Draw and find the locations on the unit circle where
cos() = 1/3. b. If tan() is positive, find tan().
tan() = 1/3. b. If sec() is positive, find sin().
14. a. Draw the and find locations on the unit circle where
csc() = –4. b. If cot() is positive, find cos().
cot() = –4/3. b. If sin() is positive, find sec().
sec() = –3/2. b. If tan() is positive, find sin().

17. a. Draw the locations on the unit circle where cos() = a.
b. If tan() is positive, find tan() in terms of a.
18. a. Draw the locations on the unit circle where tan() = 2b.
b. If sec() is positive, find sin() in terms of b.
19. a. Draw the locations on the unit circle where cot() = 3a.
b. If sin() is positive, find sec() in terms of a.
20. a. Draw the locations on the unit circle where sec() = 1/b.
b. If tan() is positive, find sin() in terms of b.
21. Justify the tangent and
the cotangent are the
distances shown.

Answers
For problem 1. See Side 106
For problems 2–11, verify your answers with a calculator.
b. sec() = –5/4.b. sin() = 1/√10
13.
(3/√10 , 1/√10)
(–3/√10 , –1/√10)
15. (–4/5, 3/5)
(4/5, –3/5)
b. Sec() = 1 + 9𝑎2 / 3a
19.
(−3a/ 1 + 9𝑎2 , –1/ 1 + 9𝑎2)
for a > 0
(3a/ 1 + 9𝑎2 , 1/ 1 + 9𝑎2)
b. Tan() = 1 − 𝑎2 / a
17.
for a > 0
(a , 1 − 𝑎2)
(−a ,− 1 − 𝑎2)

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