Geometry 3 Dimension. Classify three-dimensional figures according to their properties. Use nets and cross sections to analyze three- dimensional figures

Geometry 3 Dimension

Classify three-dimensional figures according to their properties. Use nets and cross sections to analyze three- dimensional figures. Objectives

face edge vertex prism cylinder pyramid cone cube net cross section Vocabulary

Three-dimensional figures, or solids, can be made up of flat or curved surfaces. Each flat surface is called a face. An edge is the segment that is the intersection of two faces. A vertex is the point that is the intersection of three or more faces.

A cube is a prism with six square faces. Other prisms and pyramids are named for the shape of their bases.

Example 1A: Classifying Three-Dimensional Figures Classify the figure. Name the vertices, edges, and bases. cube vertices: A, B, C, D, E, F, G, H bases: ABCD, EFGH, ABFE, DCGH, ADHE, BCGF edges:

Example 1B: Classifying Three-Dimensional Figures Classify the figure. Name the vertices, edges, and bases. pentagonal pyramid vertices: A, B, C, D, E, F base: ABCDE edges:

Example 1c Classify the figure. Name the vertices, edges, and bases. vertex: N cone edges: none base: M M

Example 1d Classify the figure. Name the vertices, edges, and bases. triangular prism bases: TUV, WXY vertices: T, U, V, W, X, Y edges:

A net is a diagram of the surfaces of a three-dimensional figure that can be folded to form the three-dimensional figure. To identify a three-dimensional figure from a net, look at the number of faces and the shape of each face.

Example 2A: Identifying a Three-Dimensional Figure From a Net Describe the three-dimensional figure that can be made from the given net. The net has six congruent square faces. So the net forms a cube.

Example 2B: Identifying a Three-Dimensional Figure From a Net Describe the three-dimensional figure that can be made from the given net. The net has one circular face and one semicircular face. These are the base and sloping face of a cone. So the net forms a cone.

Example 2c Describe the three-dimensional figure that can be made from the given net. The net has four congruent triangular faces. So the net forms a triangular pyramid.

Example 2d Describe the three-dimensional figure that can be made from the given net. The net has two circular faces and one rectangular face. These are the bases and curved surface of a cylinder. So the net forms a cylinder.

A cross section is the intersection of a three-dimensional figure and a plane.

Example 3A: Describing Cross Sections of Three-Dimensional Figures Describe the cross section. The cross section is a point.

Example 3B: Describing Cross Sections of Three-Dimensional Figures Describe the cross section. The cross section is a pentagon.

Example 3c Describe the cross section. The cross section is a hexagon.

Example 3d Describe the cross section. The cross section is a triangle.

Example 4A: Food Application A piece of cheese is a prism with equilateral triangular bases. How can you slice the cheese to make each shape? an equilateral triangle Cut parallel to the bases.

Example 4B: Food Application A piece of cheese is a prism with equilateral triangular bases. How can you slice the cheese to make each shape? a rectangle Cut perpendicular to the bases.

Example 4c How can a chef cut a cube-shaped watermelon to make slices with triangular faces? Cut through the midpoints of 3 edges that meet at 1 vertex.

Question 1 1. Classify the figure. Name the vertices, edges, and bases. triangular prism; vertices: A, B, C, D, E, F; bases: ABC and DEF edges:

2. Describe the three-dimensional figure that can be made from this net. square pyramid Question 2

3. Describe the cross section. a rectangle Question 3

Draw representations of three-dimensional figures. Recognize a three dimensional figure from a given representation. Objectives

orthographic drawing isometric drawing perspective drawing vanishing point horizon Vocabulary

There are many ways to represent a three dimensional object. An orthographic drawing shows six different views of an object: top, bottom, front, back, left side, and right side.

Example 1: Drawing Orthographic Views of an Object Draw all six orthographic views of the given object. Assume there are no hidden cubes.

Example 1 Continued Draw all six orthographic views of the given object. Assume there are no hidden cubes. Bottom

Example 1 Continued Draw all six orthographic views of the given object. Assume there are no hidden cubes.

Example 1B Draw all six orthographic views of the given object. Assume there are no hidden cubes.

Example 1B Continued

Isometric drawing is a way to show three sides of a figure from a corner view. You can use isometric dot paper to make an isometric drawing. This paper has diagonal rows of dots that are equally spaced in a repeating triangular pattern.

Example 2: Drawing an Isometric View of an Object Draw an isometric view of the given object. Assume there are no hidden cubes.

Example 2 B Draw an isometric view of the given object. Assume there are no hidden cubes.

In a perspective drawing, nonvertical parallel lines are drawn so that they meet at a point called a vanishing point. Vanishing points are located on a horizontal line called the horizon. A one-point perspective drawing contains one vanishing point. A two-point perspective drawing contains two vanishing points.

In a one-point perspective drawing of a cube, you are looking at a face. In a two- point perspective drawing, you are looking at a corner. Helpful Hint

Example 3A: Drawing an Object in Perspective Draw the block letter in one-point perspective. Draw a horizontal line to represent the horizon. Mark a vanishing point on the horizon. Then draw a shape below the horizon. This is the front of the.

Example 3A Continued Draw the block letter in one-point perspective. From each corner of the, lightly draw dashed segments to the vanishing point.

Example 3A Continued Draw the block letter in one-point perspective. Lightly draw a smaller with vertices on the greyed segments. This is the back of the.

Example 3A Continued Draw the block letter in one-point perspective. Draw the edges of the, using dashed segments for hidden edges. Erase any segments that are not part of the.

Draw the block letter in two-point perspective. Example 3B: Drawing an Object in Perspective Draw a horizontal line to represent the horizon. Mark two vanishing points on the horizon. Then draw a vertical segment below the horizon and between the vanishing points. This is the front edge of the. Lightly mark a point of the way down the segment, for the lower part of the shape.

From the marked point and the endpoints of the segment, lightly draw dashed segments to each vanishing point. Draw vertical segments connecting the dashed lines. These are other vertical edges of the. Example 3B Continued

Lightly draw dashed segments from the endpoints of each new vertical segment to the vanishing points. Example 3B Continued

Draw the edges of the, using dashed segments for hidden edges. Erase any segments that are not part of the. Example 3B Continued

Draw the block letter L in one-point perspective. Draw a horizontal line to represent the horizon. Mark a vanishing point on the horizon. Then draw a L shape below the horizon. This is the front of the L. Example 3C

From each corner of the L, lightly draw dashed segments to the vanishing point. Draw the block letter L in one-point perspective. Example 3C Continued

Lightly draw a smaller L with vertices on the dashed segments. This is the back of the L. Draw the block letter L in one-point perspective. Example 3C Continued

Draw the edges of the L, using dashed segments for hidden edges. Erase any segments that are not part of the L. Draw the block letter L in one-point perspective. Example 3C Continued

Draw the block letter L in two-point perspective. Draw a horizontal line to represent the horizon. Mark two vanishing points on the horizon. Then draw a vertical segment below the horizon and between the vanishing points. This is the front edge of the L. Lightly mark a point of the way down the segment, for the lower part of the L shape. Example 3D

From the marked point and the endpoints of the segment, lightly draw dashed segments to each vanishing point. Draw vertical segments connecting the dashed lines. These are other vertical edges of the L. Example 3D Continued Draw the block letter L in two-point perspective.

Lightly draw dashed segments from the endpoints of each new vertical segment to the vanishing points. Example 3D Continued Draw the block letter L in two-point perspective.

Draw the edges of the L, using dashed segments for hidden edges to the vanishing points. Example 3D Continued Draw the block letter L in two-point perspective.

Erase any segments that are not part of the L. Example 3D Continued Draw the block letter L in two-point perspective.

Example 4A: Relating Different Representations of an Object Determine whether the drawing represents the given object. Assume there are no hidden cubes. No; the base has one cube too many.

Example 4B: Relating Different Representations of an Object Determine whether the drawing represents the given object. Assume there are no hidden cubes. Yes; the drawing is a two-point perspective view of the object.

Example 4C: Relating Different Representations of an Object Determine whether the drawing represents the given object. Assume there are no hidden cubes. Yes; the drawing is an isometric view of the object.

Example 4D: Relating Different Representations of an Object Determine whether the drawing represents the given object. Assume there are no hidden cubes. Yes; the drawing shows the six orthographic views of the object.

Example 4E Determine whether the drawing represents the given object. Assume there are no hidden cubes. no

A 1. Draw all six orthographic views of the object. Assume there are no hidden cubes.

2. Draw an isometric view of the object. A

3. Determine whether each drawing represents the given object. Assume there are no hidden cubes. yes no A

Warm Up Find the unknown lengths. 1. the diagonal of a square with side length 5 cm 2. the base of a rectangle with diagonal 15 m and height 13 m 3. the height of a trapezoid with area 18 ft 2 and bases 3 ft and 9 ft 7.5 m 3 ft

Apply Eulers formula to find the number of vertices, edges, and faces of a polyhedron. Develop and apply the distance and midpoint formulas in three dimensions. Objectives

polyhedron space Vocabulary

polyhedron - formed by four or more polygons that intersect only at their edges. Prisms and pyramids are polyhedrons, but cylinders and cones are not.

Example 1A: Using Eulers Formula Find the number of vertices, edges, and faces of the polyhedron. Use your results to verify Eulers formula. V = 12, E = 18, F = 8 Use Eulers Formula. Simplify. 12 18 + 8 = 2 ? 2 = 2

Example 1B: Using Eulers Formula Find the number of vertices, edges, and faces of the polyhedron. Use your results to verify Eulers formula. V = 5, E = 8, F = 5 Use Eulers Formula. Simplify. 5 8 + 5 = 2 ? 2 = 2

Example 1C Find the number of vertices, edges, and faces of the polyhedron. Use your results to verify Eulers formula. V = 6, E = 12, F = 8 Use Eulers Formula. Simplify. 2 = 2 6 12 + 8 = 2 ?

Example 1D Find the number of vertices, edges, and faces of the polyhedron. Use your results to verify Eulers formula. V = 7, E = 12, F = 7 Use Eulers Formula. Simplify. 2 = 2 7 12 + 7 = 2 ?

A diagonal of a three-dimensional figure connects two vertices of two different faces. Diagonal d of a rectangular prism is shown in the diagram. By the Pythagorean Theorem, 2 + w 2 = x 2, and x 2 + h 2 = d 2. Using substitution, 2 + w 2 + h 2 = d 2. Box Problem

Solution

Example 2A: Using the Pythagorean Theorem in Three Dimensions Find the unknown dimension in the figure. the length of the diagonal of a 6 cm by 8 cm by 10 cm rectangular prism Substitute 6 for l, 8 for w, and 10 for h. Simplify.

Example 2B: Using the Pythagorean Theorem in Three Dimensions Find the unknown dimension in the figure. the height of a rectangular prism with a 12 in. by 7 in. base and a 15 in. diagonal 225 = 144 + 49 + h 2 h 2 = 32 Substitute 15 for d, 12 for l, and 7 for w. Square both sides of the equation. Simplify. Solve for h 2. Take the square root of both sides.

Example 2C Find the length of the diagonal of a cube with edge length 5 cm. d 2 = 25 + 25 + 25 d 2 = 75 Substitute 5 for each side. Square both sides of the equation. Simplify. Solve for d 2. Take the square root of both sides.

Space is the set of all points in three dimensions. Three coordinates are needed to locate a point in space. A three-dimensional coordinate system has 3 perpendicular axes: the x-axis, the y-axis, and the z-axis. An ordered triple (x, y, z) is used to locate a point. To locate the point (3, 2, 4), start at (0, 0, 0). From there move 3 units forward, 2 units right, and then 4 units up.

Example 3A: Graphing Figures in Three Dimensions Graph a rectangular prism with length 5 units, width 3 units, height 4 units, and one vertex at (0, 0, 0). The prism has 8 vertices: (0, 0, 0), (5, 0, 0), (0, 3, 0), (0, 0, 4), (5, 3, 0), (5, 0, 4), (0, 3, 4), (5, 3, 4)

Example 3B: Graphing Figures in Three Dimensions Graph a cone with radius 3 units, height 5 units, and the base centered at (0, 0, 0) Graph the center of the base at (0, 0, 0). Since the height is 5, graph the vertex at (0, 0, 5). The radius is 3, so the base will cross the x-axis at (3, 0, 0) and the y-axis at (0, 3, 0). Draw the bottom base and connect it to the vertex.

Example 3C Graph a cone with radius 5 units, height 7 units, and the base centered at (0, 0, 0). Graph the center of the base at (0, 0, 0). Since the height is 7, graph the vertex at (0, 0, 7). The radius is 5, so the base will cross the x-axis at (5, 0, 0) and the y-axis at (0, 5, 0). Draw the bottom base and connect it to the vertex.

You can find the distance between the two points (x 1, y 1, z 1 ) and (x 2, y 2, z 2 ) by drawing a rectangular prism with the given points as endpoints of a diagonal. Then use the formula for the length of the diagonal. You can also use a formula related to the Distance Formula. (See Lesson 1-6.) The formula for the midpoint between (x 1, y 1, z 1 ) and (x 2, y 2, z 2 ) is related to the Midpoint Formula. (See Lesson 1-6.)

Example 4A: Finding Distances and Midpoints in Three Dimensions Find the distance between the given points. Find the midpoint of the segment with the given endpoints. Round to the nearest tenth, if necessary. (0, 0, 0) and (2, 8, 5) distance:

Example 4A Continued midpoint: M(1, 4, 2.5) Find the distance between the given points. Find the midpoint of the segment with the given endpoints. Round to the nearest tenth, if necessary. (0, 0, 0) and (2, 8, 5)

Example 4B: Finding Distances and Midpoints in Three Dimensions Find the distance between the given points. Find the midpoint of the segment with the given endpoints. Round to the nearest tenth, if necessary. (6, 11, 3) and (4, 6, 12) distance:

Example 4B Continued midpoint: Find the distance between the given points. Find the midpoint of the segment with the given endpoints. Round to the nearest tenth, if necessary. (6, 11, 3) and (4, 6, 12) M(5, 8.5, 7.5)

Example 4C Find the distance between the given points. Find the midpoint of the segment with the given endpoints. Round to the nearest tenth, if necessary. (0, 9, 5) and (6, 0, 12) distance:

midpoint: Find the distance between the given points. Find the midpoint of the segment with the given endpoints. Round to the nearest tenth, if necessary. (0, 9, 5) and (6, 0, 12) Example 4C Continued M(3, 4.5, 8.5)

Example 4D Find the distance between the given points. Find the midpoint of the segment with the given endpoints. Round to the nearest tenth, if necessary. (5, 8, 16) and (12, 16, 20) distance:

midpoint: Example 4D extended Find the distance between the given points. Find the midpoint of the segment with the given endpoints. Round to the nearest tenth, if necessary. (5, 8, 16) and (12, 16, 20) M(8.5, 12, 18)

Example 5: Recreation Application Trevor drove 12 miles east and 25 miles south from a cabin while gaining 0.1 mile in elevation. Samira drove 8 miles west and 17 miles north from the cabin while gaining 0.15 mile in elevation. How far apart were the drivers? The location of the cabin can be represented by the ordered triple (0, 0, 0), and the locations of the drivers can be represented by the ordered triples (12, 25, 0.1) and ( 8, 17, 0.15).

Example 5 Continued Use the Distance Formula to find the distance between the drivers.

Example 6 If both divers swam straight up to the surface, how far apart would they be? Use the Distance Formula to find the distance between the divers.

A 1. Find the number of vertices, edges, and faces of the polyhedron. Use your results to verify Eulers formula. V = 8; E = 12; F = 6; 8 12 + 6 = 2

B Find the unknown dimension in each figure. Round to the nearest tenth, if necessary. 2. the length of the diagonal of a cube with edge length 25 cm 3. the height of a rectangular prism with a 20 cm by 12 cm base and a 30 cm diagonal 4. Find the distance between the points (4, 5, 8) and (0, 14, 15). Find the midpoint of the segment with the given endpoints. Round to the nearest tenth, if necessary. 43.3 cm 18.9 cm d 12.1 units; M (2, 9.5, 11.5)

Learn and apply the formula for the surface area of a prism. Learn and apply the formula for the surface area of a cylinder. Objectives

lateral face lateral edge right prism oblique prism altitude surface area lateral surface axis of a cylinder right cylinder oblique cylinder Vocabulary

Prisms and cylinders have 2 congruent parallel bases. A lateral face is not a base. The edges of the base are called base edges. A lateral edge is not an edge of a base. The lateral faces of a right prism are all rectangles. An oblique prism has at least one nonrectangular lateral face.

An altitude of a prism or cylinder is a perpendicular segment joining the planes of the bases. The height of a three-dimensional figure is the length of an altitude. Surface area is the total area of all faces and curved surfaces of a three-dimensional figure. The lateral area of a prism is the sum of the areas of the lateral faces.

The net of a right prism can be drawn so that the lateral faces form a rectangle with the same height as the prism. The base of the rectangle is equal to the perimeter of the base of the prism.

The surface area of a right rectangular prism with length , width w, and height h can be written as S = 2w + 2wh + 2h.

The surface area formula is only true for right prisms. To find the surface area of an oblique prism, add the areas of the faces. Caution!

Example 1A: Finding Lateral Areas and Surface Areas of Prisms Find the lateral area and surface area of the right rectangular prism. Round to the nearest tenth, if necessary. L = Ph = 32(14) = 448 ft 2 S = Ph + 2B = 448 + 2(7)(9) = 574 ft 2 P = 2(9) + 2(7) = 32 ft

Example 1B: Finding Lateral Areas and Surface Areas of Prisms Find the lateral area and surface area of a right regular triangular prism with height 20 cm and base edges of length 10 cm. Round to the nearest tenth, if necessary. L = Ph = 30(20) = 600 ft 2 S = Ph + 2B P = 3(10) = 30 cm The base area is

Example 1C Find the lateral area and surface area of a cube with edge length 8 cm. L = Ph = 32(8) = 256 cm 2 S = Ph + 2B = 256 + 2(8)(8) = 384 cm 2 P = 4(8) = 32 cm

The lateral surface of a cylinder is the curved surface that connects the two bases. The axis of a cylinder is the segment with endpoints at the centers of the bases. The axis of a right cylinder is perpendicular to its bases. The axis of an oblique cylinder is not perpendicular to its bases. The altitude of a right cylinder is the same length as the axis.

Example 2A: Finding Lateral Areas and Surface Areas of Right Cylinders Find the lateral area and surface area of the right cylinder. Give your answers in terms of . L = 2 rh = 2 (8)(10) = 160 in 2 The radius is half the diameter, or 8 ft. S = L + 2 r 2 = 160 + 2 (8) 2 = 288 in 2

Example 2B: Finding Lateral Areas and Surface Areas of Right Cylinders Find the lateral area and surface area of a right cylinder with circumference 24 cm and a height equal to half the radius. Give your answers in terms of . Step 1 Use the circumference to find the radius. C = 2 r Circumference of a circle 24 = 2 r Substitute 24 for C. r = 12 Divide both sides by 2 .

Example 2B Continued Step 2 Use the radius to find the lateral area and surface area. The height is half the radius, or 6 cm. L = 2 rh = 2 (12)(6) = 144 cm 2 S = L + 2 r 2 = 144 + 2 (12) 2 = 432 in 2 Lateral area Surface area Find the lateral area and surface area of a right cylinder with circumference 24 cm and a height equal to half the radius. Give your answers in terms of .

Example 2C Find the lateral area and surface area of a cylinder with a base area of 49 and a height that is 2 times the radius. Step 1 Use the circumference to find the radius. A = r 2 49 = r 2 r = 7 Area of a circle Substitute 49 for A. Divide both sides by and take the square root.

Step 2 Use the radius to find the lateral area and surface area. The height is twice the radius, or 14 cm. L = 2 rh = 2 (7)(14)=196 in 2 S = L + 2 r 2 = 196 + 2 (7) 2 =294 in 2 Lateral area Surface area Find the lateral area and surface area of a cylinder with a base area of 49 and a height that is 2 times the radius. Example 2C Continued

Example 3: Finding Surface Areas of Composite Three-Dimensional Figures Find the surface area of the composite figure.

Example 3 Continued Two copies of the rectangular prism base are removed. The area of the base is B = 2(4) = 8 cm 2. The surface area of the rectangular prism is.. A right triangular prism is added to the rectangular prism. The surface area of the triangular prism is

The surface area of the composite figure is the sum of the areas of all surfaces on the exterior of the figure. Example 3 Continued S = (rectangular prism surface area) + (triangular prism surface area) 2(rectangular prism base area) S = 52 + 36 2(8) = 72 cm 2

Example 3B Find the surface area of the composite figure. Round to the nearest tenth.

Example 3B Continued Find the surface area of the composite figure. Round to the nearest tenth. The surface area of the rectangular prism is S =Ph + 2B = 26(5) + 2(36) = 202 cm 2. The surface area of the cylinder is S =Ph + 2B = 2 (2)(3) + 2 (2) 2 = 20 62.8 cm 2. The surface area of the composite figure is the sum of the areas of all surfaces on the exterior of the figure.

S = (rectangular surface area) + (cylinder surface area) 2(cylinder base area) S = 202 + 62.8 2( )(2 2 ) = 239.7 cm 2 Example 3B Continued Find the surface area of the composite figure. Round to the nearest tenth.

Always round at the last step of the problem. Use the value of given by the key on your calculator. Remember!

Example 4: Exploring Effects of Changing Dimensions The edge length of the cube is tripled. Describe the effect on the surface area.

Example 4 Continued original dimensions:edge length tripled: Notice than 3456 = 9(384). If the length, width, and height are tripled, the surface area is multiplied by 3 2, or 9. S = 6 2 = 6(8) 2 = 384 cm 2 S = 6 2 = 6(24) 2 = 3456 cm 2 24 cm

Example 4B The height and diameter of the cylinder are multiplied by. Describe the effect on the surface area.

original dimensions:height and diameter halved: S = 2 (11 2 ) + 2 (11)(14) = 550 cm 2 S = 2 (5.5 2 ) + 2 (5.5)(7) = 137.5 cm 2 11 cm 7 cm Example 4B Continued Notice than 550 = 4(137.5). If the dimensions are halved, the surface area is multiplied by

Example 5: Recreation Application A sporting goods company sells tents in two styles, shown below. The sides and floor of each tent are made of nylon. Which tent requires less nylon to manufacture?

Example 5 Continued Pup tent: Tunnel tent: The tunnel tent requires less nylon.

Example 5B A piece of ice shaped like a 5 cm by 5 cm by 1 cm rectangular prism has approximately the same volume as the pieces below. Compare the surface areas. Which will melt faster? The 5 cm by 5 cm by 1 cm prism has a surface area of 70 cm 2, which is greater than the 2 cm by 3 cm by 4 cm prism and about the same as the half cylinder. It will melt at about the same rate as the half cylinder.

C Find the lateral area and the surface area of each figure. Round to the nearest tenth, if necessary. 1.a cube with edge length 10 cm 2. a regular hexagonal prism with height 15 in. and base edge length 8 in. 3. a right cylinder with base area 144 cm 2 and a height that is the radius L = 400 cm 2 ; S = 600 cm 2 L = 720 in 2 ; S 1052.6 in 2 L 301.6 cm 2 ; S = 1206.4 cm 2

C 4.A cube has edge length 12 cm. If the edge length of the cube is doubled, what happens to the surface area? 5. Find the surface area of the composite figure. The surface area is multiplied by 4. S = 3752 m 2

Practice Find the missing side length of each right triangle with legs a and b and hypotenuse c. 1. a = 7, b = 24 2. c = 15, a = 9 3. b = 40, c = 41 4. a = 5, b = 5 5. a = 4, c = 8 c = 25 b = 12 a = 9

Learn and apply the formula for the surface area of a pyramid. Learn and apply the formula for the surface area of a cone. Objectives

vertex of a pyramid regular pyramid slant height of a regular pyramid altitude of a pyramid vertex of a cone axis of a cone right cone oblique cone slant height of a right cone altitude of a cone Vocabulary

The vertex of a pyramid is the point opposite the base of the pyramid. The base of a regular pyramid is a regular polygon, and the lateral faces are congruent isosceles triangles. The slant height of a regular pyramid is the distance from the vertex to the midpoint of an edge of the base. The altitude of a pyramid is the perpendicular segment from the vertex to the plane of the base.

The lateral faces of a regular pyramid can be arranged to cover half of a rectangle with a height equal to the slant height of the pyramid. The width of the rectangle is equal to the base perimeter of the pyramid.

Example 1A: Finding Lateral Area and Surface Area of Pyramids Find the lateral area and surface area of a regular square pyramid with base edge length 14 cm and slant height 25 cm. Round to the nearest tenth, if necessary. Lateral area of a regular pyramid P = 4(14) = 56 cm Surface area of a regular pyramid B = 14 2 = 196 cm 2

Example 1B: Finding Lateral Area and Surface Area of Pyramids Step 1 Find the base perimeter and apothem. Find the lateral area and surface area of the regular pyramid. The base perimeter is 6(10) = 60 in. The apothem is, so the base area is

Example 1B Continued Step 2 Find the lateral area. Lateral area of a regular pyramid Substitute 60 for P and 16 for . Find the lateral area and surface area of the regular pyramid.

Example 1B Continued Step 3 Find the surface area. Surface area of a regular pyramid Substitute for B. Find the lateral area and surface area of the regular pyramid.

Example 1C Find the lateral area and surface area of a regular triangular pyramid with base edge length 6 ft and slant height 10 ft. Step 1 Find the base perimeter and apothem. The base perimeter is 3(6) = 18 ft. The apothem is so the base area is

Example 1C Continued Find the lateral area and surface area of a regular triangular pyramid with base edge length 6 ft and slant height 10 ft. Step 2 Find the lateral area. Lateral area of a regular pyramid Substitute 18 for P and 10 for .

Step 3 Find the surface area. Surface area of a regular pyramid Example 1C Continued Find the lateral area and surface area of a regular triangular pyramid with base edge length 6 ft and slant height 10 ft. Substitute for B.

The vertex of a cone is the point opposite the base. The axis of a cone is the segment with endpoints at the vertex and the center of the base. The axis of a right cone is perpendicular to the base. The axis of an oblique cone is not perpendicular to the base.

The slant height of a right cone is the distance from the vertex of a right cone to a point on the edge of the base. The altitude of a cone is a perpendicular segment from the vertex of the cone to the plane of the base.

Example 2A: Finding Lateral Area and Surface Area of Right Cones Find the lateral area and surface area of a right cone with radius 9 cm and slant height 5 cm. L = r Lateral area of a cone = (9)(5) = 45 cm 2 Substitute 9 for r and 5 for . S = r + r 2 Surface area of a cone = 45 + (9) 2 = 126 cm 2 Substitute 5 for and 9 for r.

Example 2B: Finding Lateral Area and Surface Area of Right Cones Find the lateral area and surface area of the cone. Use the Pythagorean Theorem to find . L = r = (8)(17) = 136 in 2 Lateral area of a right cone Substitute 8 for r and 17 for . S = r + r 2 Surface area of a cone = 136 + (8) 2 = 200 in 2 Substitute 8 for r and 17 for .

Example 2C Find the lateral area and surface area of the right cone. Use the Pythagorean Theorem to find . L = r = (8)(10) = 80 cm 2 Lateral area of a right cone Substitute 8 for r and 10 for . S = r + r 2 Surface area of a cone = 80 + (8) 2 = 144 cm 2 Substitute 8 for r and 10 for .

Example 3: Exploring Effects of Changing Dimensions The base edge length and slant height of the regular hexagonal pyramid are both divided by 5. Describe the effect on the surface area.

3 in. 2 in. Example 3 Continued original dimensions: base edge length and slant height divided by 5: S = P + B 1212 1212 in

Example 3 Continued original dimensions: base edge length and slant height divided by 5: 3 in. 2 in. Notice that. If the base edge length and slant height are divided by 5, the surface area is divided by 5 2, or 25. in 2

Example 3B The base edge length and slant height of the regular square pyramid are both multiplied by. Describe the effect on the surface area.

Example 3B Continued original dimensions:multiplied by two-thirds: By multiplying the dimensions by two-thirds, the surface area was multiplied by. 8 ft 10 ft S = P + B 1212 = 260 cm 2 S = P + B 1212 = 585 cm 2 ft 2

Example 4: Finding Surface Area of Composite Three-Dimensional Figures Find the surface area of the composite figure. The lateral area of the cone is L = r l = (6)(12) = 72 in 2. Left-hand cone: Right-hand cone: Using the Pythagorean Theorem, l = 10 in. The lateral area of the cone is L = r l = (6)(10) = 60 in 2.

Example 4 Continued Composite figure: S = (left cone lateral area) + (right cone lateral area) Find the surface area of the composite figure. = 60 in 2 + 72 in 2 = 132 in 2

Example 4B Find the surface area of the composite figure. Surface Area of Cube without the top side: S = 4wh + B S = 4(2)(2) + (2)(2) = 20 yd 2

Example 4b Continued Surface Area of Pyramid without base: Surface Area of Composite: Surface of Composite = SA of Cube + SA of Pyramid

Example 5: Manufacturing Application If the pattern shown is used to make a paper cup, what is the diameter of the cup? The radius of the large circle used to create the pattern is the slant height of the cone. The area of the pattern is the lateral area of the cone. The area of the pattern is also of the area of the large circle, so

Example 5 Continued Substitute 4 for , the slant height of the cone and the radius of the large circle. r = 2 in. Solve for r. The diameter of the cone is 2(2) = 4 in. If the pattern shown is used to make a paper cup, what is the diameter of the cup?

5B Find the lateral area and surface area of each figure. Round to the nearest tenth, if necessary. 1. a regular square pyramid with base edge length 9 ft and slant height 12 ft 2. a regular triangular pyramid with base edge length 12 cm and slant height 10 cm L = 216 ft 2 ; S = 297 ft 2 L = 180 cm 2 ; S 242.4 cm 2

4. A right cone has radius 3 and slant height 5. The radius and slant height are both multiplied by. Describe the effect on the surface area. 5. Find the surface area of the composite figure. Give your answer in terms of . The surface area is multiplied by. S = 24 ft 2 5C

Practice Find the volume of each figure. Round to the nearest tenth, if necessary. 1. a square prism with base area 189 ft 2 and height 21 ft 2. a regular hexagonal prism with base edge length 24 m and height 10 m 3. a cylinder with diameter 16 in. and height 22 in. 3969 ft 3 14,964.9 m 3 4423.4 in 3

Learn and apply the formula for the volume of a pyramid. Learn and apply the formula for the volume of a cone. Objectives

The volume of a pyramid is related to the volume of a prism with the same base and height. The relationship can be verified by dividing a cube into three congruent square pyramids, as shown.

The square pyramids are congruent, so they have the same volume. The volume of each pyramid is one third the volume of the cube.

Example 1A: Finding Volumes of Pyramids Find the volume a rectangular pyramid with length 11 m, width 18 m, and height 23 m.

Example 1B: Finding Volumes of Pyramids Find the volume of the square pyramid with base edge length 9 cm and height 14 cm. The base is a square with a side length of 9 cm, and the height is 14 cm.

Example 1C: Finding Volumes of Pyramids Find the volume of the regular hexagonal pyramid with height equal to the apothem of the base Step 1 Find the area of the base. Area of a regular polygon Simplify.

Example 1C Continued Step 2 Use the base area and the height to find the volume. The height is equal to the apothem,. Volume of a pyramid. = 1296 ft 3 Find the volume of the regular hexagonal pyramid with height equal to the apothem of the base Simplify.

Example 1D Find the volume of a regular hexagonal pyramid with a base edge length of 2 cm and a height equal to the area of the base. Step 1 Find the area of the base. Area of a regular polygon Simplify.

Example 1D Continued Step 2 Use the base area and the height to find the volume. Volume of a pyramid Find the volume of a regular hexagonal pyramid with a base edge length of 2 cm and a height equal to the area of the base. = 36 cm 3 Simplify.

An art gallery is a 6-story square pyramid with base area of acre (1 acre = 4840 yd 2, 1 story 10 ft). Estimate the volume in cubic yards and cubic feet. Example 2: Architecture Application First find the volume in cubic yards. Volume of a pyramid The base is a square with an area of about 2420 yd 2. The base edge length is. The height is about 6(10) = 60 ft or about 20 yd.

Example 2 Continued Substitute 2420 for B and 20 for h. 16,133 yd 3 16,100 yd 3 Volume of a pyramid Then convert your answer to find the volume in cubic feet. The volume of one cubic yard is (3 ft)(3 ft)(3 ft) = 27 ft 3. Use the conversion factor to find the volume in cubic feet.

Example 2B What if? What would be the volume of the Rainforest Pyramid if the height were doubled? Volume of a pyramid. Substitute 70 for B and 66 for h. = 107,800 yd 3 or 107,800(27) = 2,910,600 ft 3

= 245 cm 3 769.7 cm 3 Example 3A: Finding Volumes of Cones Find the volume of a cone with radius 7 cm and height 15 cm. Give your answers both in terms of and rounded to the nearest tenth. Volume of a pyramid Substitute 7 for r and 15 for h. Simplify.

Example 3B: Finding Volumes of Cones Find the volume of a cone with base circumference 25 in. and a height 2 in. more than twice the radius. Step 1 Use the circumference to find the radius. Step 2 Use the radius to find the height. h = 2(12.5) + 2 = 27 in. The height is 2 in. more than twice the radius. 2 r = 25 Substitute 25 for the circumference. r = 12.5 Solve for r.

Example 3B Continued Step 3 Use the radius and height to find the volume. Volume of a pyramid. Substitute 12.5 for r and 27 for h. = 1406.25 in 3 4417.9 in 3 Simplify. Find the volume of a cone with base circumference 25 in. and a height 2 in. more than twice the radius.

Example 3C: Finding Volumes of Cones Find the volume of a cone. Step 1 Use the Pythagorean Theorem to find the height. 16 2 + h 2 = 34 2 Pythagorean Theorem h 2 = 900 Subtract 16 2 from both sides. h = 30 Take the square root of both sides.

Example 3C Continued Step 2 Use the radius and height to find the volume. Volume of a cone Substitute 16 for r and 30 for h. 2560 cm 3 8042.5 cm 3 Simplify. Find the volume of a cone.

Example 3D Find the volume of the cone. Volume of a cone Substitute 9 for r and 8 for h. 216 m 3 678.6 m 3 Simplify.

Example 4: Exploring Effects of Changing Dimensions original dimensions: radius and height divided by 3: Notice that. If the radius and height are divided by 3, the volume is divided by 3 3, or 27. The diameter and height of the cone are divided by 3. Describe the effect on the volume.

Example 4B original dimensions: radius and height doubled: The volume is multiplied by 8. The radius and height of the cone are doubled. Describe the effect on the volume.

Example 5: Finding Volumes of Composite Three-Dimensional Figures Find the volume of the composite figure. Round to the nearest tenth. The volume of the upper cone is

Example 5: Finding Volumes of Composite Three-Dimensional Figures The volume of the cylinder is The volume of the lower cone is The volume of the figure is the sum of the volumes. Find the volume of the composite figure. ound to the nearest tenth. V cylinder = r 2 h = (21) 2 (35)=15,435 cm 3. V = 5145 + 15,435 + 5,880 = 26,460 83,126.5 cm 3

Example 5B Find the volume of the composite figure. The volume of the rectangular prism is V = wh = 25(12)(15) = 4500 ft 3. The volume of the pyramid is The volume of the composite is the rectangular prism subtract the pyramid. 4500 1500 = 3000 ft 3

5C Find the volume of each figure. Round to the nearest tenth, if necessary. 1. a rectangular pyramid with length 25 cm, width 17 cm, and height 21 cm 2. a regular triangular pyramid with base edge length 12 in. and height 10 in. 3. a cone with diameter 22 cm and height 30 cm 4. a cone with base circumference 8 m and a height 5 m more than the radius 2975 cm 3 207.8 in 3 V 3801.3 cm 3 V 117.3 m 2

5D 5. A cone has radius 2 in. and height 7 in. If the radius and height are multiplied by, describe the effect on the volume. 6. Find the volume of the composite figure. Give your answer in terms of . The volume is multiplied by. 10,800 yd 3

Practice Find each measurement. 1. the radius of circle M if the diameter is 25 cm 2. the circumference of circle X if the radius is 42.5 in. 3. the area of circle T if the diameter is 26 ft 4. the circumference of circle N if the area is 625 cm 2 12.5 cm 85 in. 169 ft 2 50 cm

Learn and apply the formula for the volume of a sphere. Learn and apply the formula for the surface area of a sphere. Objectives

sphere center of a sphere radius of a sphere hemisphere great circle Vocabulary

A sphere is the locus of points in space that are a fixed distance from a given point called the center of a sphere. A radius of a sphere connects the center of the sphere to any point on the sphere. A hemisphere is half of a sphere. A great circle divides a sphere into two hemispheres

The figure shows a hemisphere and a cylinder with a cone removed from its interior. The cross sections have the same area at every level, so the volumes are equal by Cavalieris Principle. Y The height of the hemisphere is equal to the radius.

V(hemisphere) = V(cylinder) V(cone) The volume of a sphere with radius r is twice the volume of the hemisphere, or.

Example 1A: Finding Volumes of Spheres Find the volume of the sphere. Give your answer in terms of . = 2304 in 3 Simplify. Volume of a sphere.

Example 1B: Finding Volumes of Spheres Find the diameter of a sphere with volume 36,000 cm 3. Substitute 36,000 for V. 27,000 = r 3 r = 30 d = 60 cm d = 2r Take the cube root of both sides. Volume of a sphere.

Example 1C: Finding Volumes of Spheres Find the volume of the hemisphere. Volume of a hemisphere Substitute 15 for r. = 2250 m 3 Simplify.

Example 1D Find the radius of a sphere with volume 2304 ft 3. Volume of a sphere Substitute for V. r = 12 ftSimplify.

Example 2: Sports Application A sporting goods store sells exercise balls in two sizes, standard (22- in. diameter) and jumbo (34-in. diameter). How many times as great is the volume of a jumbo ball as the volume of a standard ball? standard ball: jumbo ball: A jumbo ball is about 3.7 times as great in volume as a standard ball.

Example 2B A hummingbird eyeball has a diameter of approximately 0.6 cm. How many times as great is the volume of a human eyeball as the volume of a hummingbird eyeball? hummingbird: human: The human eyeball is about 72.3 times as great in volume as a hummingbird eyeball.

In the figure, the vertex of the pyramid is at the center of the sphere. The height of the pyramid is approximately the radius r of the sphere. Suppose the entire sphere is filled with n pyramids that each have base area B and height r.

4 r 2 nB If the pyramids fill the sphere, the total area of the bases is approximately equal to the surface area of the sphere S, so 4 r 2 S. As the number of pyramids increases, the approximation gets closer to the actual surface area.

Example 3A: Finding Surface Area of Spheres Find the surface area of a sphere with diameter 76 cm. Give your answers in terms of . S = 4 r 2 S = 4 (38) 2 = 5776 cm 2 Surface area of a sphere

Example 3B: Finding Surface Area of Spheres Find the volume of a sphere with surface area 324 in 2. Give your answers in terms of . Substitute 324 for S. 324 = 4 r 2 r = 9Solve for r. Substitute 9 for r. The volume of the sphere is 972 in 2. S = 4 r 2 Surface area of a sphere

Example 3C: Finding Surface Area of Spheres Find the surface area of a sphere with a great circle that has an area of 49 mi 2. Substitute 49 for A. 49 = r 2 r = 7 Solve for r. S = 4 r 2 = 4 (7) 2 = 196 mi 2 Substitute 7 for r. A = r 2 Area of a circle

Example 3D Find the surface area of the sphere. Substitute 25 for r. S = 2500 cm 2 S = 4 r 2 S = 4 (25) 2 Surface area of a sphere

Example 4: Exploring Effects of Changing Dimensions The radius of the sphere is multiplied by. Describe the effect on the volume. original dimensions: radius multiplied by : Notice that. If the radius is multiplied by, the volume is multiplied by, or.

Example 4 The radius of the sphere is divided by 3. Describe the effect on the surface area. original dimensions: dimensions divided by 3: The surface area is divided by 9. S = 4 r 2 = 4 (3) 2 = 36 m 3 S = 4 r 2 = 4 (1) 2 = 4 m 3

Example 5: Finding Surface Areas and Volumes of Composite Figures Find the surface area and volume of the composite figure. Give your answer in terms of . Step 1 Find the surface area of the composite figure. The surface area of the composite figure is the sum of the curved surface area of the hemisphere, the lateral area of the cylinder, and the base area of the cylinder.

Example 5 Continued The surface area of the composite figure is L(cylinder) = 2 rh = 2 (6)(9) = 108 in 2 B(cylinder) = r 2 = (6) 2 = 36 in 2 72 + 108 + 36 = 216 in 2. Find the surface area and volume of the composite figure. Give your answer in terms of .

Step 2 Find the volume of the composite figure. Example 5 Continued Find the surface area and volume of the composite figure. Give your answer in terms of . The volume of the composite figure is the sum of the volume of the hemisphere and the volume of the cylinder. The volume of the composite figure is 144 + 324 = 468 in 3.

Example 5B Find the surface area and volume of the composite figure. Step 1 Find the surface area of the composite figure. The surface area of the composite figure is the sum of the curved surface area of the hemisphere, the lateral area of the cylinder, and the base area of the cylinder.

Example 5 Continued The surface area of the composite figure is Find the surface area and volume of the composite figure. L(cylinder) = 2 rh = 2 (3)(5) = 30 ft 2 B(cylinder) = r 2 = (3) 2 = 9 ft 2 18 + 30 + 9 = 57 ft 2.

Step 2 Find the volume of the composite figure. Find the surface area and volume of the composite figure. Example 5 Continued The volume of the composite figure is the volume of the cylinder minus the volume of the hemisphere. V = 45 18 = 27 ft 3

B Find each measurement. Give your answers in terms of . 1. the volume and surface area of the sphere 2. the volume and surface area of a sphere with great circle area 36 in 2 3. the volume and surface area of the hemisphere V = 36 cm 3 ; S = 36 cm 2 V = 288 in 3 ; S = 144 in 2 V = 23,958 ft 3 ; S = 3267 ft 2

C 4. A sphere has radius 4. If the radius is multiplied by 5, describe what happens to the surface area. 5. Find the volume and surface area of the composite figure. Give your answer in terms of . The surface area is multiplied by 25. V = 522 cm 3 ; S = 267 cm 2

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Geometry 3 Dimension. Classify three-dimensional figures according to their properties. Use nets and cross sections to analyze three- dimensional figures