Difference between revisions of "Angles and their measure"

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<math>\frac{1}{9} \pi\ radian \left(s \right ) = \frac {\frac{1}{9} \pi \times 180}{\pi } = 20^\circ </math>
 
<math>\frac{1}{9} \pi\ radian \left(s \right ) = \frac {\frac{1}{9} \pi \times 180}{\pi } = 20^\circ </math>
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===Arc Length===
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In most cases it is very difficult to measure the length of an arc with a ruler. Therefore we need to use a formula in order to determine the length of the arc. The formula that we use is:
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<math>Arc\ Length = ( \theta\ in\ radians)(radius)\,</math> in symbols this is <math>s= \theta r\,</math>. Note: θ need to be in radians
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Here is an example, determine the length of the arc created by a sector with a 6&nbsp;cm radius and an angle of <math>53^\circ</math>.
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The first thing we need to do is convert θ from degrees to radians.
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<math>53^\circ = \frac {53 \pi}{180}rad</math>
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Now we can calcuate the length of the arc.
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<math>s = \frac {53 \pi}{180} \times 6 \approx 5.55cm</math>
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===Area of a Sector===
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The area of a sector can be found using this formula:
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<math>Area = \frac{1}{2}r^2 \theta</math>Note: θ need to be in radians.
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Calculate the area of a sector with a 3&nbsp;cm radius and an angle of 2π.
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<math>Area = \frac{1}{2}3^2 \times 2 \pi \approx 28.3cm^2</math>
  
 
==The unit circle==
 
==The unit circle==
 
[[File:Unit Circle Definitions of Six Trigonometric Functions.png|thumb|264x264px|The center of the unit circle is the origin <math>O</math>, point <math>A=(x_A,y_A)</math>. Creating line segments starting from point <math>A</math> to <math>x</math> on the <math>x</math>-axis will create two line segments. From this, we learn that, in terms of <math>\theta</math>, point <math>A=(\cos\theta,\sin\theta)</math>and other properties.]]
 
[[File:Unit Circle Definitions of Six Trigonometric Functions.png|thumb|264x264px|The center of the unit circle is the origin <math>O</math>, point <math>A=(x_A,y_A)</math>. Creating line segments starting from point <math>A</math> to <math>x</math> on the <math>x</math>-axis will create two line segments. From this, we learn that, in terms of <math>\theta</math>, point <math>A=(\cos\theta,\sin\theta)</math>and other properties.]]
A circle with the equation <math>x^2+y^2=1</math> is called a ''unit circle''. Imagine a circle with center at the origin of a [[wikipedia:Cartesian_coordinate_system|Cartesian coordinate system]].
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A circle with the equation <math>x^2+y^2=1</math> is called a ''unit circle''. Imagine a circle with center at the origin of a Cartesian coordinate system.
  
Rotating a ray from the direction of the positive half of the ''x''-axis by an angle <math>\theta</math> (counterclockwise for <math>\theta > 0,</math> and clockwise for <math>\theta < 0</math>) yields intersection points of this ray with the unit {{nowrap|circle: <math>\mathrm{A} = (x_\mathrm{A},y_\mathrm{A})</math>,}} and, by extending the ray to a line if necessary, with the {{nowrap|line <math> \text{“}x=1\text{”}:\;\mathrm{B} = (x_\mathrm{B},y_\mathrm{B}),</math>}} and with the {{nowrap|line <math> \text{“}y=1\text{”}:\;\mathrm{C} = (x_\mathrm{C},y_\mathrm{C}).</math>}} The tangent line to the unit circle in point {{math|A}}, which is orthogonal to this ray, intersects the ''y''- and ''x''-axis at points <math>\mathrm{D} = (0,y_\mathrm{D})</math> and <math>\mathrm{E} = (x_\mathrm{E},0)</math>. The coordinate values of these points give all the existing values of the trigonometric functions for arbitrary real values of <math>\theta</math> in the following manner:
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Rotating a ray from the direction of the positive half of the ''x''-axis by an angle <math>\theta</math> (counterclockwise for <math>\theta > 0,</math> and clockwise for <math>\theta < 0</math>) yields intersection points of this ray with the unit circle: <math>\mathrm{A} = (x_\mathrm{A},y_\mathrm{A})</math>, and, by extending the ray to a line if necessary, with the <math> \text{“}x=1\text{”}:\;\mathrm{B} = (x_\mathrm{B},y_\mathrm{B}),</math> and with the <math> \text{“}y=1\text{”}:\;\mathrm{C} = (x_\mathrm{C},y_\mathrm{C}).</math> The tangent line to the unit circle in point {{math|A}}, which is orthogonal to this ray, intersects the ''y''- and ''x''-axis at points <math>\mathrm{D} = (0,y_\mathrm{D})</math> and <math>\mathrm{E} = (x_\mathrm{E},0)</math>. The coordinate values of these points give all the existing values of the trigonometric functions for arbitrary real values of <math>\theta</math> in the following manner:
 
<center>
 
<center>
 
{| class="wikitable"
 
{| class="wikitable"
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* [https://en.wikibooks.org/w/index.php?title=Calculus/Trigonometry&action=edit&section=5 Trigonometry], Wikibooks: Calculus
 
* [https://en.wikibooks.org/w/index.php?title=Calculus/Trigonometry&action=edit&section=5 Trigonometry], Wikibooks: Calculus
 
* [https://en.wikibooks.org/wiki/Geometry/Angles Angles], Wikibooks: Geometry
 
* [https://en.wikibooks.org/wiki/Geometry/Angles Angles], Wikibooks: Geometry
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* [https://en.wikibooks.org/wiki/A-level_Mathematics/OCR/C2/Circles_and_Angles Circles and Angles], Wikibooks: A-Level Mathematics
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==Licensing==
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Content obtained and/or adapted from:
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* [https://en.wikibooks.org/w/index.php?title=Calculus/Trigonometry&action=edit&section=5 Trigonometry, Wikibooks: Calculus] under a CC BY-SA license
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* [https://en.wikibooks.org/wiki/Geometry/Angles Angles, Wikibooks: Geometry] under a CC BY-SA license
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* [https://en.wikibooks.org/wiki/A-level_Mathematics/OCR/C2/Circles_and_Angles Circles and Angles, Wikibooks: A-Level Mathematics] under a CC BY-SA license

Latest revision as of 12:51, 25 October 2021

Angular Measurement and Circular Sectors

A section of a circle is known as a sector. One side of the sector is the radius. The portion of the cirumference that is included in the sector is known as an arc.

SectorArc.png

Angular Degree

A circle has 360 degrees. Each degree can have 60 minutes (designated as ' ) and each minute can have 60 seconds (designated as " ). Since we can not convert minutes or seconds into radians directly we need to convert the minutes and seconds into a decimal number. Here is the formula:

Convert Y' Z" into degrees. For a practical example, convert 18' 38" into degrees.

Classification of Angles by Degree Measure

Acute Angle

  • an angle is said to be acute if it measures between 0 and 90 degrees, exclusive.

Acute Angle

Right Angle

  • an angle is said to be right if it measures 90 degrees.
  • notice the small box placed in the corner of a right angle, unless the box is present it is not assumed the angle is 90 degrees.
  • all right angles are congruent

Right angle.svg

Obtuse Angle

  • an angle is said to be obtuse if it measures between 90 and 180 degrees, exclusive.

Obtuse Angle

Angular Radian

A radian is the angle subtended at the centre of a circle by an arc of its circumference equal in length to the radius of the circle. Since we know that that the formula for the circumference of a circle is we can determine that there are radians in a circle. We abbreviate radians as rad.

Conversion Between Degrees and Radians

Mathematics requires us to use radians for most angular measurements. Therefore we need to know how to convert from degrees to radians Since we know that there are degrees or radians in a circle. We can determine these equations:

So we can write these general formulae.

Here is an example convert into radians

Convert into degrees.

Arc Length

In most cases it is very difficult to measure the length of an arc with a ruler. Therefore we need to use a formula in order to determine the length of the arc. The formula that we use is:

in symbols this is . Note: θ need to be in radians

Here is an example, determine the length of the arc created by a sector with a 6 cm radius and an angle of .

The first thing we need to do is convert θ from degrees to radians.

Now we can calcuate the length of the arc.

Area of a Sector

The area of a sector can be found using this formula:

Note: θ need to be in radians.

Calculate the area of a sector with a 3 cm radius and an angle of 2π.

The unit circle

The center of the unit circle is the origin , point . Creating line segments starting from point to on the -axis will create two line segments. From this, we learn that, in terms of , point and other properties.

A circle with the equation is called a unit circle. Imagine a circle with center at the origin of a Cartesian coordinate system.

Rotating a ray from the direction of the positive half of the x-axis by an angle (counterclockwise for and clockwise for ) yields intersection points of this ray with the unit circle: , and, by extending the ray to a line if necessary, with the and with the The tangent line to the unit circle in point A, which is orthogonal to this ray, intersects the y- and x-axis at points and . The coordinate values of these points give all the existing values of the trigonometric functions for arbitrary real values of in the following manner:

Trigonometric functions and the unit circle
Function Right-triangle definition Unit circle definition

The importance of the unit circle is that it expands the definitions of trigonometric functions. Before, those values are constrained within a right triangle. Now, the functions can be used on any radian as their input.

Resources

Licensing

Content obtained and/or adapted from: