* Your assessment is very important for improving the workof artificial intelligence, which forms the content of this project
Download polygon - Mona Shores Blogs
Survey
Document related concepts
Shapley–Folkman lemma wikipedia , lookup
Tessellation wikipedia , lookup
Multilateration wikipedia , lookup
Rational trigonometry wikipedia , lookup
Integer triangle wikipedia , lookup
Steinitz's theorem wikipedia , lookup
Trigonometric functions wikipedia , lookup
Euler angles wikipedia , lookup
Atiyah–Singer index theorem wikipedia , lookup
History of geometry wikipedia , lookup
History of trigonometry wikipedia , lookup
Noether's theorem wikipedia , lookup
Riemann–Roch theorem wikipedia , lookup
Four color theorem wikipedia , lookup
Euclidean geometry wikipedia , lookup
Transcript
Chapter 6 Quadrilaterals Chapter Objectives Define a polygon and its characteristics Identify a regular polygon Interior Angles of a Quadrilateral Theorem Properties of Parallelograms Using coordinate geometry to prove parallelograms Compare rhombuses, rectangles, and squares Identify trapezoids and kites Midsegment Theorem for Trapezoids Calculate area of trapezoids, kites, rhombuses, rectangles, and squares Lesson 6.1 Polygons Lesson 6.1 Objectives Identify a figure to be a polygon. Recognize the different types of polygons based on the number of sides. Identify the components of a polygon. Use the sum of the interior angles of a quadrilateral. Definition of a Polygon A polygon is plane figure (two-dimensional) that meets the following conditions. 1. It is formed by three or more segments called sides. 2. The sides must be straight lines. 3. Each side intersects exactly two other sides, one at each endpoint. 4. The polygon is closed in all the way around with no gaps. 5. Each side must end when the next side begins. No tails. Polygons Not Polygons Polygon Parts Each segment that is used to close a polygon in is called a side. Where each side ends is called a vertex. A vertex is simply a corner of the polygon. vertices sides Types of Polygons Number of Sides 3 4 5 6 7 8 9 10 12 n Type of Polygon Triangle Quadrilateral Pentagon Hexagon Heptagon Octagon Nonagon Decagon Dodecagon n-gon Concave v Convex A polygon is convex if no line that contains a side of the polygon contains a point in the interior of the polygon. Take any two points in the interior of the polygon. If you can draw a line between the two points that never leave the interior of the polygon, then it is convex. A polygon is concave if a line that contains a side of the polygon contains a point in the interior of the polygon. Take any two points in the interior of the polygon. If you can draw a line between the two points that does leave the interior of the polygon, then it is concave. Concave polygons have dents in the sides, or you could say it caves in. Example 1 Determine if the following are polygons or not. If it is a polygon, classify it as concave or convex. No! Yes Yes Concave Convex Regular Polygons A polygon is equilateral if all of its sides are congruent. A polygon is equiangular if all of its interior angles are congruent. A polygon is regular if it is both equilateral and equiangular. The best way to draw these is to label each sides and angle with the proper congruent marks. Diagonals of a Polygon A diagonal of a polygon is a segment that joins two nonconsecutive vertices. A diagonal does not go to the point next to it. That would make it a side! Diagonals cut across the polygon to all points on the other side. There is typically more than one diagonal. Theorem 6.1: Interior Angles of a Quadrilateral Theorem The sum of the measures of the interior angles of a quadrilateral is 360o. 4 3 1 2 m 1 +m 2 + m 3 + m 4 = 360o Homework 6.1 In Class 1-11 p325-328 HW 12-46, Due 54-59 Tomorrow Lesson 6.2 Properties of Parallelograms Lesson 6.2 Objectives Define a parallelogram Identify properties of parallelograms Use properties of parallelograms to determine unknown quantities of the parallelogram Definition of a Parallelogram A parallelogram is a quadrilateral with both pairs of opposite sides parallel. Theorem 6.2: Congruent Sides of a Parallelogram If a quadrilateral is a parallelogram, then its opposite sides are congruent. Theorem 6.3: Opposite Angles of a Parallelogram If a quadrilateral is a parallelogram, then its opposite angles are congruent. Example 2 Find the missing variables in the parallelograms. x = 11 y=8 d = 53 d + 15 = 68 c – 5 = 20 c = 25 m = 101 Theorem 6.4: Consecutive Angles of a Parallelogram If a quadrilateral is a parallelogram, then its consecutive angles are supplementary. Q R P S m P + m S = 180o m Q + m R = 180o m P + m Q = 180o m R + m S = 180o Theorem 6.5: Diagonals of a Parallelogram If a quadrilateral is a parallelogram, then its diagonals bisect each other. Remember that means to cut into two congruent segments. Example 3 Find the indicated measure in HIJK a) HI 16 a) a) Theorem 6.2 GH b) 8 b) b) Theorem 6.6 KH c) 10 c) c) Theorem 6.2 HJ d) 16 d) d) Theorem 6.6 & Seg Add Post m KIH e) 28o e) e) AIA Theorem m JIH f) 96o f) Theorem 6.4 f) m KJI g) g) 84o g) Theorem 6.3 Homework 6.2 HW p333-336 20-37, 47-54, 60, 61 Due Tomorrow Quiz Wednesday Lessons 6.1-6.3 Lesson 6.3 Proving Quadrilaterals are Parallelograms Lesson 6.3 Objectives Verify that a quadrilateral is a parallelogram. Utilize coordinate geometry with parallelograms Theorem 6.6: Congruent Sides of a Parallelogram Converse If both pairs of opposite sides are congruent, then it is a parallelogram. Theorem 6.7: Opposite Angles of a Parallelogram Converse If both pairs of opposite angles are congruent, then it is a parallelogram. Theorem 6.8: Consecutive Angles of a Parallelogram Converse If an angle of a quadrilateral is supplementary to its consecutive angles, then it is a parallelogram. Q R P S m P + m S = 180o m Q + m R = 180o m P + m Q = 180o m R + m S = 180o Theorem 6.9: Diagonals of a Parallelogram Converse If the diagonals of a quadrilateral bisect each other, then it is a parallelogram. Theorem 6.10: Opposite Sides of a Parallelogram If one pair of opposite sides of a quadrilateral are congruent and parallel, then the quadrilateral is a parallelogram. Example 4 Which theorem would you use to show the following are parallelograms? Theorem 6.10 Theorem 6.9 Theorem 6.6 Theorem 6.6 or Theorem 6.10 Theorem 6.7 Theorem 6.8 or Theorem 6.7 Homework 6.3 In Class 1-7 p342-345 HW 9-29, 45-47 skip 15-16 Due Tomorrow Quiz Friday Lessons 6.1-6.3 Lesson 6.4 Rhombuses, Rectangles, and Squares Lesson 6.4 Objectives Identify characteristics of a rhombus. Identify characteristics of a rectangle. Identify characteristics of a square. Rhombus A rhombus is a parallelogram with four congruent sides. The rhombus corollary states that a quadrilateral is a rhombus if and only if it has four congruent sides. Theorem 6.11: Perpendicular Diagonals A parallelogram is a rhombus if and only if its diagonals are perpendicular. Theorem 6.12: Opposite Angle Bisector A parallelogram is a rhombus iff each diagonal bisects a pair of opposite angles. Rectangle A rectangle is a parallelogram with four congruent angles. The rectangle corollary states that a quadrilateral is a rectangle iff it has four right angles. Theorem 6.13: Four Congruent Diagonals A parallelogram is a rectangle iff all four segments of the diagonals are congruent. Square A square is a parallelogram with four congruent sides and four congruent angles. Square Corollary A quadrilateral is a square iff it s a rhombus and a rectangle. So that means that all the properties of rhombuses and rectangles work for a square at the same time. Example 5 Classify the parallelogram. Explain your reasoning. Must be supplementary Rhombus Square Rectangle Diagonals are perpendicular. Theorem 6.11 Square Corollary Diagonals are congruent. Theorem 6.13 Homework 6.4 In Class 1, 3-11 p351-354 HW 12-46 Due evens, 55-58, 66, 67 Tomorrow Lesson 6.5 Trapezoids and Kites Lesson 6.5 Objectives Identify properties of a trapezoid. Recognize an isosceles trapezoid. Utilize the midsegment of a trapezoid to calculate other quantities from the trapezoid. Identify a kite. Trapezoid A trapezoid is a quadrilateral with exactly one pair of parallel sides. The parallel sides are called the bases. The nonparallel sides are called legs. The angles formed by the bases are called the base angles. Isosceles Trapezoid If the legs of a trapezoid are congruent, then the trapezoid is an isosceles trapezoid. Theorem 6.14: Bases Angles of a Trapezoid If a trapezoid is isosceles, then each pair of base angles is congruent. That means the top base angles are congruent. The bottom base angles are congruent. But they are not all congruent to each other! Theorem 6.15: Base Angles of a Trapezoid Converse If a trapezoid has one pair of congruent base angles, then it is an isosceles trapezoid. Theorem 6.16: Congruent Diagonals of a Trapezoid A trapezoid is isosceles if and only if its diagonals are congruent. Notice this is the entire diagonal itself. Don’t worry about it being bisected cause it’s not!! Example 6 Find the measures of the other three angles. 127o 53o 127o Supplementary because of CIA 83o 97o 83o Supplementary because of CIA Midsegment The midsegment of a trapezoid is the segment that connects the midpoints of the legs of a trapezoid. Theorem 6.17: Midsegment Theorem for Trapezoids The midsegment of a trapezoid is parallel to each base and its length is one half the sum of the lengths of the bases. C It is the average of the base lengths! D N M MN = 1/2(AB + CD) A B Example 7 Find the length of the midsegment. RT = 1/2(WX + ZY) RT = 1/2(7 + 13) RT = 1/2(20) RT = 10 RT = 1/2(WX + ZY) RT = 1/2(9 + 12) RT = 1/2(21) RT = 10.5 Kite A kite is a quadrilateral that has two pairs of consecutive sides that are congruent, but opposite sides are not congruent. It looks like the kite you got for your birthday when you were 5! There are no sides that are parallel. Theorem 6.18: Diagonals of a Kite If a quadrilateral is a kite, then its diagonals are perpendicular. Theorem 6.19: Opposite Angles of a Kite If a quadrilateral is a kite, then exactly one pair of opposite angles are congruent. The angles that are congruent are between the two different congruent sides. You could call those the shoulder angles. NOT Example 8 Find the missing angle measures. 64o 125o 88o 125o 60 + K + 50 + M = 360 88 + 120 + 88 + J = 360 60 + M + 50 + M = 360 296 + J = 360 110 + 2M = 360 J = 64 2M = 250 M = 125 K = 125 But K M Use Pythagorean Theorem! Example 9 Cause the diagonals are perpendicular!! a2 + b2 = c2 Find the lengths of all the sides of the kite. Round your answer to the nearest hundredth. a2 + b2 = c2 52 + 52 = c2 25 + 25 = c2 7.07 7.07 50 = c2 a2 + b2 = c2 52 + 122 = c2 25 + 144 = c2 c = 7.07 13 13 169 = c2 c = 13 Homework 6.5 In Class 3-9 p359-362 HW 10-39, 51, 52, 57-64 Due Tomorrow Test Monday November 12 Lesson 6.6 Special Quadrilaterals Lesson 6.6 Objectives Create a hierarchy of polygons Identify special quadrilaterals based on limited information Polygon Hierarchy Polygons Triangles Parallelogram Rhombus Quadrilaterals Trapezoid Rectangle Square Pentagons Kite Isosceles Trapezoid NEVER How to Read the Hierarchy Polygons Parallelogram Rhombus Quadrilaterals Trapezoid Rectangle Square So that means that a square is always a rhombus, a parallelogram, a quadrilateral, and a polygon. Pentagons Kite Isosceles Trapezoid But a parallelogram is sometimes a rhombus and sometimes a square. However, a parallelogram is never a trapezoid or a kite. SOMETIMES ALWAYS Triangles Using the Hierarchy Remember that a square must fit all the properties of its “ancestors.” That means the properties of a rhombus, rectangle, parallelogram, quadrilateral, and polygon must all be true! So when asked to identify a figure as specific as possible, test the properties working your way down the hierarchy. As soon as you find a figure that doesn’t work any more you should be able to identify the specific name of that figure. Homework 6.6 In Class 2-7 p367-370 HW 8-35, 55-65 Due Tomorrow Test Friday November 7 Lesson 6.7 Areas of Triangles and Quadrilaterals Lesson 6.7 Objectives Find the area of any type of triangle. Find the area of any type of quadrilateral. Postulate 22: Area of a Square Postulate The area of a square is the square of the length of its side. A = s2 s Area Postulates Postulate 23: Area Congruence Postulate If two polygons are congruent, then they have the same area. Postulate 24: Area Addition Postulate The area of a region is the sum of the areas of its nonoverlapping parts. Theorem 6.20: Area of a Rectangle The area of a rectangle is the product of a base and its corresponding height. Corresponding height indicates a segment perpendicular to the base to the opposite side. A = bh h b Theorem 6.21: Area of a Parallelogram The area of a parallelogram is the product of a base and its corresponding height. Remember the height must be perpendicular to one of the bases. The height will be given to you or you will need to find it. To find it, use Pythagorean Theorem a2 + b2 = c2 A = bh h b Theorem 6.22: Area of a Triangle The area of a triangle is one half the product of the base and its corresponding height. The base for this formula is the segment that is perpendicular to the height. It may be a side of the triangle, it may not! h h h b b b Theorem 6.23: Area of a Trapezoid The area of a trapezoid is one half the product of the height and the sum of the bases. The height is the perpendicular segment between the bases of the trapezoid. A = ½ h (b1+b2) b1 h b2 Theorem 6.24: Area of a Kite The area of a kite is one half the product of the lengths of the diagonals. A = ½ d1d2 d1 d2 Theorem 6.25: Area of a Rhombus The area of a rhombus is equal to one half the product of the lengths of the diagonals. d A = ½ d1d2 1 d2 Homework 6.7 In Class 3-13 p376-380 HW 14-38 evens, 50-52, 60, 61 Due Tomorrow Test Monday November 12