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Copyright © Cengage Learning. All rights reserved. Circles 6 6 Chapter.

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Presentation on theme: "Copyright © Cengage Learning. All rights reserved. Circles 6 6 Chapter."— Presentation transcript:

1 Copyright © Cengage Learning. All rights reserved. Circles 6 6 Chapter

2 Copyright © Cengage Learning. All rights reserved. Line and Segment Relationships in the Circle 6.3

3 3 Line and Segment Relationships in the Circle Theorem 6.3.1 If a line is drawn through the center of a circle perpendicular to a chord, then it bisects the chord and its arc. Theorem 6.3.2 If a line through the center of a circle bisects a chord other than a diameter, then it is perpendicular to the chord.

4 4 Line and Segment Relationships in the Circle Figure 6.39 (a) illustrates the following theorem. Theorem 6.3.3 The perpendicular bisector of a chord contains the center of the circle. Figure 6.39 (a)

5 5 Example 1 Given: In Figure 6.40, O has a radius of length 5 at B and OB = 3 Find: CD Figure 6.40

6 6 Example 1 – Solution Draw radius. By the Pythagorean Theorem, (OC) 2 = (OB) 2 + (BC) 2 5 2 = 3 2 + (BC) 2 25 = 9 + (BC) 2 (BC) 2 = 16 BC = 4 We know that CD = 2  BC; then it follows that CD = 2  4 = 8.

7 7 CIRCLES THAT ARE TANGENT

8 8 Circles that are Tangent In this section, we assume that two circles are coplanar. Although concentric circles do not intersect, they do share a common center. For the concentric circles shown in Figure 6.41, the tangent of the smaller circle is a chord of the larger circle. Figure 6.41

9 9 Circles that are Tangent If two circles touch at one point, they are tangent circles. In Figure 6.42(a), circles P and Q are internally tangent; in Figure 6.42(b), circles O and R are externally tangent. Figure 6.42 (a) (b)

10 10 Circles that are Tangent Definition For two circles with different centers, the line of centers is the line (or line segment) containing the centers of both circles. As the definition suggests, the line segment joining the centers of two circles is also commonly called the line of centers of the two circles. In Figure 6.43, or is the line of centers for circles A and B. Figure 6.43

11 11 COMMON TANGENT LINES TO CIRCLES

12 12 Common Tangent Lines to Circles A line, line segment, or ray that is tangent to each of two circles is a common tangent for these circles. If the common tangent does not intersect the line segment joining the centers, it is a common external tangent.

13 13 Common Tangent Lines to Circles In Figure 6.44(a), circles P and Q have one common external tangent, ; in Figure 6.44(b), circles A and B have two common external tangents, and. Figure 6.44 (a) (b)

14 14 Common Tangent Lines to Circles If the common tangent for two circles does intersect the line of centers for these circles, it is a common internal tangent for the two circles. In Figure 6.45 (a), is a common internal tangent for externally tangent circles O and R; in Figure 6.45(b), and are common internal tangents for M and N. Figure 6.45 (a) (b)

15 15 Common Tangent Lines to Circles Theorem 6.3.4 The tangent segments to a circle from an external point are congruent.

16 16 Example 2 A belt used in an automobile engine wraps around two pulleys with different lengths of radii. Explain why the straight pieces named and have the same length. Figure 6.47

17 17 Example 2 – Solution Pulley centered at O has the larger radius length, so we extend and to meet at point E. Because E is an external point to both O and P, we know that EB = ED and EA = EC by Theorem 6.3.4. By subtracting equals from equals, EA – EB = EC – ED. Because EA – EB = AB and EC – ED = CD, it follows that AB = CD.

18 18 LENGTHS OF LINE SEGMENTS IN A CIRCLE

19 19 Lengths of Line Segments in a Circle To complete this section, we consider three relationships involving the lengths of chords, secants, or tangents. Theorem 6.3.5 If two chords intersect within a circle, then the product of the lengths of the segments (parts) of one chord is equal to the product of the lengths of the segments of the other chord.

20 20 Example 4 In Figure 6.50, HP = 4, PJ = 5, and LP = 8. Find PM. Solution: Applying Theorem 6.3.5, we have HP  PJ = LP  PM. Then 4  5 = 8  PM 8  PM = 20 PM = 2.5 Figure 6.50

21 21 Lengths of Line Segments in a Circle Theorem 6.3.6 If two secant segments are drawn to a circle from an external point, then the products of the length of each secant with the length of its external segment are equal. Theorem 6.3.7 If a tangent segment and a secant segment are drawn to a circle from an external point, then the square of the length of the tangent equals the product of the length of the secant with the length of its external segment.

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