Determine whether it is possible to form a triangle with side lengths 5, 7, and 8. A. yes B. no 5-Minute Check 1.

Slides:

Advertisements

Similar presentations

Parallel Lines and Proportional Parts

Advertisements

Copyright © 2009 Pearson Addison-Wesley Trigonometric Functions.

(5.1) Midsegments of Triangles

7.4 Parallel Lines and Proportional Parts

Midterm Review Project [NAME REMOVED] December 9, rd Period.

Chapter 7: Proportions and Similarity

7-4 Parallel Line and Proportional Parts. You used proportions to solve problems between similar triangles. Use proportional parts within triangles. Use.

Splash Screen. Lesson Menu Five-Minute Check (over Lesson 7–3) CCSS Then/Now New Vocabulary Theorem 7.5: Triangle Proportionality Theorem Example 1: Find.

Similar Figures Notes. Solving Proportions Review  Before we can discuss Similar Figures we need to review how to solve proportions…. Any ideas?

Objective: Students will use proportional parts of triangles and divide a segment into parts. S. Calahan 2008.

Example 4-1a From the Triangle Proportionality Theorem, In and Find SU. S.

EXAMPLE 3 Use Theorem 6.6 In the diagram, 1, 2, and 3 are all congruent and GF = 120 yards, DE = 150 yards, and CD = 300 yards. Find the distance HF between.

EXAMPLE 3 Use Theorem 6.6 In the diagram, 1, 2, and 3 are all congruent and GF = 120 yards, DE = 150 yards, and CD = 300 yards. Find the distance HF between.

 If three sides of one triangle are congruent to the three sides of another triangle, then the two triangles are congruent.  If AB = DE, BC = EF, AC.

Welcome to Interactive Chalkboard Glencoe Geometry Interactive Chalkboard Copyright © by The McGraw-Hill Companies, Inc. Developed by FSCreations, Inc.,

MID-SEGMENT & TRIANGLE PROPORTIONALITY Day 8.  A midsegment of a triangle is a segment that connects the midpoints of two sides of a triangle. In the.

6.6 Use Proportionality Theorems. Objectives  Use proportional parts of triangles  Divide a segment into parts.

Over Lesson 7–3 Complete the proportion. Suppose DE=15, find x. Suppose DE=15, find EG. Find the value of y. FE Ch 9.5  D F G E H x 28 DG =

12.5 Proportions & Similar Triangles. Triangle Proportionality Theorem If a line parallel to one side of a triangle intersects the other two sides, then.

Proportions and Similar Triangles Section 7.5. Objectives Use the Triangle Proportionality Theorem and its converse.

Properties of Tangents

4-6 Isosceles And Equilateral Triangles

8.6 Proportions & Similar Triangles

4.3 Warm Up Are the triangles similar? If so, which theorem justifies your answer.

Applying Properties of Similar Triangles

1. Give the postulate or theorem that justifies why the triangles are similar. ANSWER AA Similarity Postulate 2. Solve = .

Proving Triangles Congruent

7.5 ESSENTIAL QUESTION: How do you use the Triangle Proportionality Theorem and its Converse in solving missing parts?

Parallel Lines and Proportional Parts and Parts of Similar Triangles

Parallel Lines and Proportional Parts

Bellwork Determine whether the triangles are similar. A B.

Section 6.6: Using Proportionality Theorems

Do Exploring Midsegments Activity

Parallel Lines and Proportional Parts

Chapter 7: Proportions and Similarity Proportions Make a Frayer foldable 7.1 Ratio and Proportion.

Objectives Students will learn to how to apply Triangle Proportionality theorem to find segment lengths.

Find m1. A. 115 B. 105 C. 75 D Minute Check 1.

Geometry 7.4 Parallel Lines and Proportional Parts

LEARNING OBJECTIVE Definition figure out

D. N. A. Are the following triangles similar? If yes, state the appropriate triangle similarity theorem. 9 2) 1) ) Find the value of x and the.

PARALLEL LINES AND PROPORTIONAL PARTS

8.6 Proportions & Similar Triangles

If QT = 5, TR = 4, and US = 6, find QU.

Parallel Lines and Proportional Parts

Warm Up #24 1. If ∆QRS  ∆ZYX, identify the pairs of congruent angles and the pairs of congruent sides. Solve each proportion Q  Z; R.

6.4 Parallel Lines and Proportional Parts

5.1 Congruence and Triangles Day 2

8.6 Proportions & Similar Triangles

Introduction Archaeologists, among others, rely on the Angle-Angle (AA), Side-Angle-Side (SAS), and Side-Side-Side (SSS) similarity statements to determine.

Geometry 7.4 Parallel Lines and Proportional Parts

7.4 Parallel Lines and Proportional Parts

Class Greeting.

Parallel Lines and Proportional Parts

5-Minute Check on Lesson 7-3

Parallel Lines and Proportional Parts

Find m1. A. 115 B. 105 C. 75 D Minute Check 1.

Parts of Similar Triangles

The Triangle Inequality

Introduction Archaeologists, among others, rely on the Angle-Angle (AA), Side-Angle-Side (SAS), and Side-Side-Side (SSS) similarity statements to determine.

Determine whether the triangles are similar. Justify your answer.

Parallel Lines and Proportional Parts

Five-Minute Check (over Lesson 7–5) Mathematical Practices Then/Now

Lesson 5-4: Proportional Parts

5-Minute Check on Lesson 6-3

Presentation transcript:

Determine whether it is possible to form a triangle with side lengths 5, 7, and 8. A. yes B. no 5-Minute Check 1

Determine whether it is possible to form a triangle with side lengths 4.2, 4.2, and 8.4. A. yes B. no 5-Minute Check 2

Determine whether it is possible to form a triangle with side lengths 3, 6, and 10. A. yes B. no 5-Minute Check 3

Find the range for the measure of the third side of a triangle if two sides measure 4 and 13. B. 6 < n < 16 C. 8 < n < 17 D. 9 < n < 17 5-Minute Check 4

Find the range for the measure of the third side of a triangle if two sides measure 8.3 and 15.6. B. 9.1 < n < 22.7 C. 7.3 < n < 23.9 D. 6.3 < n < 18.4 5-Minute Check 5

Write an inequality to describe the length of MN. ___ A. 12 ≤ MN ≤ 19 B. 5 < MN < 19 C. 5 < MN < 12 D. 7 < MN < 12 5-Minute Check 6

Use proportional parts within triangles. Use proportional parts with parallel lines. Then/Now

Concept

Find the Length of a Side Example 1

Substitute the known measures. Find the Length of a Side Substitute the known measures. Cross Products Property Multiply. Divide each side by 8. Simplify. Example 1

A. 2.29 B. 4.125 C. 12 D. 15.75 Example 1

Concept

In order to show that we must show that Determine if Lines are Parallel In order to show that we must show that Example 2

Since the sides are proportional. Determine if Lines are Parallel Since the sides are proportional. Answer: Since the segments have proportional lengths, GH || FE. Example 2

A. yes B. no C. cannot be determined Example 2

Concept

A. In the figure, DE and EF are midsegments of ΔABC. Find AB. Use the Triangle Midsegment Theorem A. In the figure, DE and EF are midsegments of ΔABC. Find AB. Example 3

ED = AB Triangle Midsegment Theorem 1 2 5 = AB Substitution 1 2 Use the Triangle Midsegment Theorem ED = AB Triangle Midsegment Theorem __ 1 2 5 = AB Substitution __ 1 2 10 = AB Multiply each side by 2. Answer: AB = 10 Example 3

B. In the figure, DE and EF are midsegments of ΔABC. Find FE. Use the Triangle Midsegment Theorem B. In the figure, DE and EF are midsegments of ΔABC. Find FE. Example 3

FE = BC Triangle Midsegment Theorem Use the Triangle Midsegment Theorem __ 1 2 FE = BC Triangle Midsegment Theorem FE = (18) Substitution __ 1 2 FE = 9 Simplify. Answer: FE = 9 Example 3

C. In the figure, DE and EF are midsegments of ΔABC. Find mAFE. Use the Triangle Midsegment Theorem C. In the figure, DE and EF are midsegments of ΔABC. Find mAFE. Example 3

By the Triangle Midsegment Theorem, AB || ED. Use the Triangle Midsegment Theorem By the Triangle Midsegment Theorem, AB || ED. AFE  FED Alternate Interior Angles Theorem mAFE = mFED Definition of congruence mAFE = 87 Substitution Answer: mAFE = 87 Example 3

A. In the figure, DE and DF are midsegments of ΔABC. Find BC. Example 3

B. In the figure, DE and DF are midsegments of ΔABC. Find DE. Example 3

C. In the figure, DE and DF are midsegments of ΔABC. Find mAFD. Example 3

Concept

Use Proportional Segments of Transversals MAPS In the figure, Larch, Maple, and Nuthatch Streets are all parallel. The figure shows the distances in between city blocks. Find x. Example 4

Triangle Proportionality Theorem Use Proportional Segments of Transversals Notice that the streets form a triangle that is cut by parallel lines. So you can use the Triangle Proportionality Theorem. Triangle Proportionality Theorem Cross Products Property Multiply. Divide each side by 13. Answer: x = 32 Example 4

In the figure, Davis, Broad, and Main Streets are all parallel In the figure, Davis, Broad, and Main Streets are all parallel. The figure shows the distances in between city blocks. Find x. A. 4 B. 5 C. 6 D. 7 Example 4

Concept

2x – 7 = 5 Subtract x from each side. 2x = 12 Add 7 to each side. Use Congruent Segments of Transversals ALGEBRA Find x and y. To find x: 3x – 7 = x + 5 Given 2x – 7 = 5 Subtract x from each side. 2x = 12 Add 7 to each side. x = 6 Divide each side by 2. Example 5

Use Congruent Segments of Transversals To find y: The segments with lengths 9y – 2 and 6y + 4 are congruent since parallel lines that cut off congruent segments on one transversal cut off congruent segments on every transversal. Example 5

9y – 2 = 6y + 4 Definition of congruence Use Congruent Segments of Transversals 9y – 2 = 6y + 4 Definition of congruence 3y – 2 = 4 Subtract 6y from each side. 3y = 6 Add 2 to each side. y = 2 Divide each side by 3. Answer: x = 6; y = 2 Example 5

Find a and b. A. ; B. 1; 2 C. 11; D. 7; 3 __ 2 3 Example 5