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Transcript
Geometry 10.2 Arcs and Chords Geometry Mrs. Spitz Spring 2005 Geometry Objectives/Assignment • Use properties of arcs of circles, as applied. • Use properties of chords of circles. • Assignment: pp. 607-608 #3-47 • Reminder Quiz after 10.3 and 10.5 Geometry Using Arcs of Circles • In a plane, an angle whose vertex is the center of a circle is a central angle of the circle. If the measure of a central angle, APB is less than 180°, then A and B and the points of P central angle A major arc minor arc P B C Geometry Using Arcs of Circles • in the interior of APB form a minor arc of the circle. The points A and B and the points of P in the exterior of APB form a major arc of the circle. If the endpoints of an arc are the endpoints of a diameter, then the arc is a semicircle. central angle A major arc minor arc P B C Naming Arcs Geometry G • Arcs are named by their endpoints. For example, the minor arc associated with APB above is AB. Major arcs and semicircles are named by their endpoints and by a point on the arc. 60° 60° E H F E 180° Naming Arcs Geometry G • For example, the major arc associated with APB is ACB . EGFhere on the right is a semicircle. The measure of a minor arc is defined to be the measure of its central angle. 60° 60° E H F E 180° Geometry Naming Arcs • For instance, m GF= mGHF = 60°. • m GF is read “the measure of arc GF.” You can write the measure of an arc next to the arc. The measure of a semicircle is always 180°. G 60° 60° E H F E 180° Geometry Naming Arcs G • The measure of a GF major arc is defined as the difference between E 360° and the measure of its associated minor arc. For example, m GEF = 360° - 60° = 300°. The measure of the whole circle is 360°. 60° 60° H F E 180° Geometry Ex. 1: Finding Measures of Arcs • Find the measure of each arc of R. a. MN b. MPN c. PMN N 80° R M P Geometry Ex. 1: Finding Measures of Arcs • Find the measure of each arc of R. a. MN b. MPN c. PMN Solution: MN is a minor arc, so m MN = mMRN = 80° N 80° R M P Geometry Ex. 1: Finding Measures of Arcs • Find the measure of each arc of R. a. MN b. MPN c. PMN Solution: MPN is a major arc, so m MPN = 360° – 80° = 280° N 80° R M P Geometry Ex. 1: Finding Measures of Arcs • Find the measure of each arc of R. a. MN b. MPN c. PMN Solution: PMN is a semicircle, so m PMN = 180° N 80° R M P Note: C Geometry A • Two arcs of the same circle are adjacent if they intersect at exactly one point. You can add the measures of adjacent areas. • Postulate 26—Arc Addition Postulate. The measure of an arc formed by two adjacent arcs is the sum of the measures of the two arcs. B m ABC = m AB+ m BC Geometry Ex. 2: Finding Measures of Arcs • G Find the measure of each arc. a. GE b. G EF c. GF m GE = m GH + m HE = 40° + 80° = 120° H 40° 80° R 110° F E Geometry Ex. 2: Finding Measures of Arcs • G Find the measure of each arc. a. GE b. G EF c. GF m G EF = m GE + m EF 120° + 110° = 230° H 40° 80° R 110° = F E Geometry Ex. 2: Finding Measures of Arcs • G Find the measure of each arc. a. GE b. G EF c. GF m GF = 360° - m G EF = 360° - 230° = 130° H 40° 80° R 110° F E Geometry Ex. 3: Identifying Congruent Arcs • Find the measures of the blue arcs. Are the arcs congruent? • AB and DC are in the same circle and m AB = m DC= 45°. So, AB DC A D B 45° 45° C Geometry Ex. 3: Identifying Congruent Arcs • Find the measures of the blue arcs. Are the arcs congruent? • PQ and RS are in congruent circles and m PQ = m RS = 80°. So, PQ RS 80° Q P 80° S R Geometry Ex. 3: Identifying Congruent Arcs • Find the measures of the blue arcs. Are the arcs congruent? Z X • m XY = m ZW = 65°, but XYand ZW are not arcs of the same circle or of congruent circles, so XY and ZW are NOT congruent. 65° Y W Geometry Using Chords of Circles • A point Y is called the midpoint of if XY YZ . Any line, segment, or ray that contains Y bisects XYZ . Geometry Theorem 10.4 • In the same circle, or in congruent circles, two minor arcs are congruent if and only if their corresponding chords are congruent. AB BC if and only if AB BC A C B Geometry Theorem 10.5 • If a diameter of a circle is perpendicular to a chord, then the diameter bisects the chord and its arc. F E G DE EF , DG GF D Geometry Theorem 10.5 • If one chord is a perpendicular bisector of another chord, then the first chord is a diameter. J M JK is a diameter of the circle. K L Ex. 4: Using Theorem 10.4 Geometry (x + 40)° • You can use Theorem 10.4 to find m AD . C A • Because AD DC, and AD DC . So, m AD = m DC 2x = x + 40 x = 40 2x° B Substitute Subtract x from each side. Geometry Ex. 5: Finding the Center of a Circle • Theorem 10.6 can be used to locate a circle’s center as shown in the next few slides. • Step 1: Draw any two chords that are not parallel to each other. Geometry Ex. 5: Finding the Center of a Circle • Step 2: Draw the perpendicular bisector of each chord. These are the diameters. Geometry Ex. 5: Finding the Center of a Circle • Step 3: The perpendicular bisectors intersect at the circle’s center. center Geometry Ex. 6: Using Properties of Chords • Masonry Hammer. A masonry hammer has a hammer on one end and a curved pick on the other. The pick works best if you swing it along a circular curve that matches the shape of the pick. Find the center of the circular swing. Geometry Ex. 6: Using Properties of Chords • Draw a segment AB, from the top of the masonry hammer to the end of the pick. Find the midpoint C, and draw perpendicular bisector CD. Find the intersection of CD with the line formed by the handle. So, the center of the swing lies at E. Geometry Theorem 10.7 • In the same circle, or in congruent circles, two chords are congruent if and only if they are equidistant from the center. • AB CD if and only if EF EG. C G D E B F A Geometry Ex. 7: Using Theorem 10.7 AB = 8; DE = 8, and CD = 5. Find CF. A 8 F B C E 5 8 G D Geometry Ex. 7: Using Theorem 10.7 Because AB and DE are congruent chords, they are equidistant from the center. So CF CG. To find CG, first find DG. CG DE, so CG bisects DE. Because DE = 8, 8 DG = 2 =4. A 8 F B C E 5 8 G D Geometry Ex. 7: Using Theorem 10.7 Then use DG to find CG. DG = 4 and CD = 5, so ∆CGD is a 3-4-5 right triangle. So CG = 3. Finally, use CG to find CF. Because CF CG, CF = CG =3 A 8 F B C E 5 8 G D Geometry Reminders: • Quiz after 10.3 • Last day to check Vocabulary from Chapter 10 and Postulates/Theorems from Chapter 10.
