A circle is unique because it does not have any corners or angles, which makes it different from other figures such as triangles, rectangles, and triangles. But specific properties can be explored in detail by introducing angles inside a circle. For instance, the simplest way to create an angle inside a circle is by drawing two chords such that they start at the same point. This might seem unnecessary at first, but by doing so, we can employ many rules of trigonometry and geometry, thus exploring circle properties in more detail.
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Jetzt kostenlos anmeldenA circle is unique because it does not have any corners or angles, which makes it different from other figures such as triangles, rectangles, and triangles. But specific properties can be explored in detail by introducing angles inside a circle. For instance, the simplest way to create an angle inside a circle is by drawing two chords such that they start at the same point. This might seem unnecessary at first, but by doing so, we can employ many rules of trigonometry and geometry, thus exploring circle properties in more detail.
Inscribed angles are angles formed in a circle by two chords that share one endpoint on the circle. The common endpoint is also known as the vertex of the angle. This is shown in figure 1, where two chords and form an inscribed angle , where the symbol ‘' is used to describe an inscribed angle.
The other endpoints of the two chords form an arc on the circle, which is the arc AC shown below. There are two kinds of arcs that are formed by an inscribed angle.
When the measure of the arc is less than a semicircle or , then the arc is defined as a minor arc which is shown in figure 2a.
When the measure of the arc is greater than a semicircle or , then the arc is defined as a major arc which is shown in figure 2b.
But how do we create such an arc? By drawing two cords, as we discussed above. But what exactly is a chord? Take any two points on a circle and join them to make a line segment:
A chord is a line segment that joins two points on a circle.
Now that a chord has been defined, what can one build around a chord? Let‘s start with an arc, and as obvious as it sounds, it is a simple part of the circle defined below:
An arc of a circle is a curve formed by two points in a circle. The length of the arc is the distance between those two points.
The length of an arc can be measured using the central angle in both degrees or radians and the radius as shown in the formula below, where θ is the central angle, and π is the mathematical constant. At the same time, r is the radius of the circle.
Several types of inscribed angles are modeled by various formulas based on the number of angles and their shape. Thus a generic formula cannot be created, but such angles can be classified into certain groups.
Let's look at the various Inscribed Angle Theorems.
The inscribed angle theorem relates the measure of the inscribed angle and its intercepted arc.
It states that the measure of the inscribed angle in degrees is equal to half the measure of the intercepted arc, where the measure of the arc is also the measure of the central angle.
When two inscribed angles intercept the same arc, then the angles are congruent. Congruent angles have the same degree measure. An example is shown in figure 4, where and m<ABC are equal as they intercept the same arc AC:
When an inscribed angle intercepts an arc that is a semicircle, the inscribed angle is a right angle equal to . This is shown below in the figure, where arc is a semicircle with a measure of and its inscribed angle is a right angle with a measure of .
If a quadrilateral is inscribed in a circle, which means that the quadrilateral is formed in a circle by chords, then its opposite angles are supplementary. For example, the following diagram shows an inscribed quadrilateral, where is supplementary to and is supplementary to :
Find angles and if the central angle shown below is .
Solution:
Since angles and intercept the same arc , then they are congruent.
Using the inscribed angle theorem, we know that the central angle is twice the inscribed angle that intercepts the same arc.
Hence the angle is .
What is the measure of angle in the circle shown below if is ?
Solution:
As angles and intercept the same arc , then they are equal . Hence, if is then must also be .
To solve any example of inscribed angles, write down all the angles given. Recognize the angles given by drawing a diagram if not given. Let’s look at some examples.
Find if its intercepted arc has a measure of .
Solution:
Using the inscribed angle theorem, we derive that the inscribed angle equals half of the central angle.
Find and in the inscribed quadrilateral shown below.
Solution:
As the quadrilateral shown is inscribed in a circle, its opposite angles are complementary.
Then we substitute the given angles into the equations, and we re-arrange the equations to make the unknown angle the subject.
Find , , and in the diagram below.
Solution:
Inscribed angles and intercept the same arc . Hence they are equal, therefore
Angle is inscribed in a semicircle. Hence <c must be a right angle.
As quadrilateral is inscribed in a circle, its opposite angles must be supplementary.
An inscribed angle is an angle that is formed in a circle by two chords that have a common end point that lies on the circle.
A central angle is formed by two line segments that are equal to the radius of the circle and inscribed angles are formed by two chords, which are line segments that intersect the circle in two points.
Inscribed angles can be solved using the various inscribed angles theorem, depending on the angle, number of angles and the polygons formed in the circle.
There is not a general formula for calculating inscribed angles. Inscribed angles can be solved using the various inscribed angles theorem, depending on the angle, number of angles and the polygons formed in the circle.
A typical example would be a quadrilateral inscribed in a circle where the angles formed at the corners are inscribed angles.
Find the length of an arc if the central angle is 100 ͦ and the radius is 5cm.
8.726 cm
Find the length of an arc if the central angle is 2.53 radians and the radius is 7cm.
17.71 cm
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