Polygon Investigation

Slides:

Advertisements

Similar presentations

£1 Million £500,000 £250,000 £125,000 £64,000 £32,000 £16,000 £8,000 £4,000 £2,000 £1,000 £500 £300 £200 £100 Welcome.

Advertisements

Generalizations and Extensions to the Hexagon Train Task.

8.6 Perimeters and Areas of Similar Figures (1 card)

Area of Regular Polygons. We will determine the area of regular polygons using notes.

Geometry 5 Level 1. Interior angles in a triangle.

Regular Polygons. Introduction A Polygon is a many-sided shape. A Regular Polygon is a many-sided shape with all sides and angles the same. An important.

10-4 Perimeters and Areas of Similar Figures

Students will name two dimensional figures (9-4).

Polygons and Polygon Angle Measures

The distance around the outside of a shape.

8.6:Perimeters and Areas of Similar Figures

All about Shapes Ask Boffin!.

Section 11-3 Perimeters and Areas of Similar Figures.

11.5 Area of Regular Polygons. Theorem 106 Theorem 106: The area of an equilateral triangle equals the product of one- fourth the square of a side and.

Objective: After studying this section, you will be able to recognize regular polygons and use a formula to find the measure of an exterior angle of an.

Geometry Review AREA 1. Find the measure of each interior angle of the regular polygon shown below. 2.

Shape and Space INTERNAL ANGLES. POLYGON (REGULAR). A polygon is a two dimensional shape with straight sides. There are two types of polygon, regular.

Polygons Lesson What is a polygon? A polygon is a simple, closed, two-dimensional figure formed by three or more line segments (sides). Closed?

All you need for almost any angle problem

Areas of Regular Polygons Section Theorem 11.3 Area of an Equilateral Triangle: The area of an EQUILATERAL triangle is one fourth the square of.

Shapes and their properties. What am I? I have 2 pairs of equal sides I have 2 pairs of parallel sides I have 0 lines of symmetry I have no right-angles.

Area of regular polygons

Notes Over Classifying Polygons A polygon with three sides is a _____________. Classifying triangles by angles. Acute Triangle 3 acute angles Right.

11.3 Perimeters and Area of Similar Figures

How do you determine the number of lines of symmetry for this regular polygon?

 Are patterns of shapes that fit together without any gaps  Way to tile a floor that goes on forever  Puzzles are irregular tessellations  Artists.

Polygons Shapes with many sides! Two-dimensional Shapes (2D) These shapes are flat and can only be drawn on paper. They have two dimensions – length.

POLYGONS A polygon is a closed plane figure that has 3 or more sides.

5.1 Polygon Sum Conjecture

+ Introduction to Shapes Squares and Rectangles. + Do Now: Chalk Talk.

The area of the isosceles triangle is 31 in2. Find the perimeter.

AREA OF A REGULAR POLYGON SECTION FIND THE AREA OF THE TRIANGLE BELOW 6 in.

Circles, Polygons and Area WHAT CAN YOU DEDUCE, GIVEN VERY LITTLE INFORMATION?

Area of regular polygons

 Given a regular polygon, you can find its area by dividing the polygon into congruent, non- overlapping, equilateral triangles.

Rolling Polygons A dynamic PowerPoint introduction to the “Rolling Polygons Investigation” created by Mrs A. Furniss.

CHAPTER 11.1 Angle Measures in Polygons. Sum of the Measures of the Interior Angles of a Convex Polygon… (n-2) * 180.

Area of Regular Polygons Terms Radius – segment joining the center of the polygon to the vertex of the polygon. All radii of a polygon are equal. When.

The Interior Angles of Polygons. Sum of the interior angles in a polygon We’ve seen that a quadrilateral can be divided into two triangles … … and a pentagon.

No rotational Symmetry

Name _____ 6__ Lesson 7 - Perimeters of Apr.__ Polygons.

11.2 Areas of Regular Polygons Geometry. Find the area of the triangle below.

J.Byrne Types of Triangles pg 1  The sum of the angles in any triangle is 180°  Equilateral Triangle  3 sides and 3 angles are equal  Isosceles.

Area of Regular Polygons

2.3 Problem Solving Using Inequalities

Find the area of the triangle. POLYGONS Find the area of the triangle.

Geometry Shapes J.Byrne 2017.

Interior angles in a triangle

Types of Polygons Polygon- a flat closed figure made of straight line segments Circle the figures that are polygons. Cross out the figures  that are.

11.6 Perimeters and Areas of Similar Figures

Area of Shapes.

11.1 Angles Measures in a Polygon

7.4 Regular polygons Objective:

11.3 Areas of Regular Polygons and Circles

Calculate the size of the interior angles in a regular hexagon

Cincinnati’s Proof Given an equilateral triangle and any interior point, the perpendicular segments from the point to any sides sum will be constant.

Exploring Polygons.

Solving Problems Involving Geometry

11.3 Perimeters and Area of Similar Figures

11.3 Perimeters and Area of Similar Figures

Line Symmetry © 2004 All rights reserved

ACE problems Extension 17.

Attributes Straight sides Closed figure 3 or more sides

7.7 Perimeters and Area of Similar Figures

Perimeter word problem

Book of Geometric Figures - Project Grade

11.7 Perimeters and Areas of Similar Figures

Presentation transcript:

Polygon Investigation By Jennifer and Brandon

The Problem If you line up 100 equilateral triangles in a row, what will the perimeter be? Find a rule for any number of triangles. What if you lined up: Squares? Regular Pentagons? Regular Hexagons? n-sided Polygons?

Our Mathematical Process End + Middles + End # of Sides Each End Contributes Middles Contribute 3 3-1 3-2 4 4-1 4-2 5 5-1 5-2 6 6-1 6-2 n n-1 n-2

Our Generalized Claim Visually: (using squares) Algebraically: p = (n-2)(s-2) + 2(s-1) Verbally: Separating the row of polygons into middle and end polygons, the perimeter equals the number of middle polygons times the amount contributed to the perimeter by each of the middle polygons, plus the amount contributed by the two end polygons. Each end contributes 3 sides The number of middle squares (2 less than the total) Each middle contributes 2 sides

Our Evidence Still using squares to visually support our evidence: Our variables represent: p= perimeter of total s= # of sides (squares have 4) n= the # of squares

Our Evidence 4-1 4-1 (n-2) equals the number of middle polygons (in this case there are 5-2 middle squares) (s-2) equals the amount of sides each middle polygon contributes to the perimeter (in this case each square in the middle contributes 2--one top and one bottom side) 2(s-1) equals the two end polygons--each contributing the # of sides minus 1 to the perimeter (in this case each end square contributes 4-1--the 3 sides forming a cap

Our Conclusion Our claim that p=(n-2)(s-2) + 2(s-1) is supported by our evidence to show that for any number of polygons lined up in a row, our rule works. Any questions?