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9.06 Geometric modeling (M)

Introduction

We have practiced modeling throughout Geometry, and while there are similarities to modeling in Algebra 1, the modeling we have been doing should seem different, since we're not regularly focused on functions in this course. This lesson utilizes geometric modeling to focus on the interpreting and reporting stages of the modeling cycle.

When creating a geometric model, we will need to:

A modeling cycle. Starting with the phrase Identify the problem inside a circle. An arrow pointing to the right where the phrase Create a model is inside a rectangle. Next is an arrow pointing downward where the phrase Apply and analyze is inside a rectangle. Then, an arrow pointing to the right where the phrase Interpret results is inside a rectangle. Next is an arrow pointing upward where the phrase Verify the model is inside a triangle. Then, an arrow pointing to the right where the phrase Report findings is inside a circle. There is an arrow pointing to the left from the phrase Verify the model to Create a model.
  1. Identify the essential features of the problem

  2. Create a model using a diagram, graph, table, equation or expression, or statistical representation

  3. Analyze and use the model to find solutions

  4. Interpret the results in the context of the problem

  5. Verify that the model works as intended and improve the model as needed

  6. Report on our findings and the reasoning behind them

Interpret and report with geometric modeling

After analyzing and applying a model to find solutions with geometric modeling, we need to interpret our results to verify the model. Then we need to report our results in a clear and concise manner.

When interpreting results, we should ask ourselves:

  • Does my model make mathematical sense?

  • Can I create a physical prototype of my model to confirm that using it for this project makes sense?

  • Do my solutions make sense for the context?

  • What types of recommendations should I make based on my model?

With geometric modeling and reporting results, we should ask ourselves:

  • Have I interpreted the results of my model enough to convey what I know about the mathematics?

  • Am I being clear and concise in my report?

  • What are the potential costs or considerations involved with my recommendations?

Examples

Example 1

The designers working on a contract for an amusement park are designing a facade for the entrance to a ride. The structure needs roof tiles that are sold per square foot. Suppose that the structure has two regular-pentagonal pyramids connected by a flat rectangular roof.

The measurements that are given from the surveyor are the base length of each side of the pentagonal roof, the perpendicular height of each pyramid, the distance from the center of the base of the pyramid to the midpoint of each edge, and the length of the flat rectangular roof between the pyramids. The surveyor reports the lengths in yards.

a

Create a model and use it to develop a plan that can be used to calculate the cost of the roof tiles for the structure.

Worked Solution
Create a strategy

Draw a diagram of the structure and label it with the following dimensions: b= the base length of each pyramid, p= the perpendicular height of each pyramid, r= the distance from the center of the pyramid's base to an edge, and l= the length of the flat rectangular roof between the pyramids.

A diagram with labels will help us develop a plan for calculating the area of the roof, which is needed to find the cost of the roof tiles.

Apply the idea

A drawing of the structure with the lengths that the surveyor provides follows:

In order to calculate the cost of the roof tiles, we need the area of the roof that will be covered with the tiles. First, we will need the lateral surface area of each pentagonal pyramid, which we will assume are the same size. The lateral surface area is calculated by multiplying the area of the face of each side of the pyramid by 5.

To calculate the area of one lateral face, we need the base and height of the triangular face. Since we only know the base and the perpendicular height of the pyramid, we can use the Pythagorean theorem to calculate the height of the triangular face, as it represents the hypotenuse of the right triangle drawn from the center of the pyramid:

The length of the hypotenuse of the right triangle can be calculated as follows:

\displaystyle r^2+p^2\displaystyle =\displaystyle \text{Hypotenuse}^2Pythagorean theorem
\displaystyle \sqrt{r^2 + p^2}\displaystyle =\displaystyle \text{Hypotenuse}Evaluate the square root of both sides

The area of each face of the pentagonal pyramids is calculated as A= \dfrac{1}{2}bh, or A=\dfrac{1}{2}b \left( \sqrt{r^2 + p^2} \right) after substituting the base and height of each triangular face. The lateral surface area of each pyramid is 5 \cdot \dfrac{1}{2}b \left( \sqrt{r^2 + p^2} \right), so the lateral surface area of both pyramids is 5b \left( \sqrt{r^2 + p^2} \right).

Then, to calculate the area of the flat rectangular roof, we can multiply the length and width of the rectangle:

The area of the flat rectangular roof is calculated as A=lw, or A=lb.

Finally, the area of the roof in square yards that will need roof tiles is represented by the following equation: S = 5b \left( \sqrt{r^2 + p^2} \right) + lb

Since the roof tiles are sold by the square foot, we will need to convert the square yards, then we can multiply the square footage of the roof by the cost of the roof tiles per square foot.

b

Suppose the surveyor provides the following dimensions of the parts of the structure:

  • Base length of each side of the pyramids: 3 \frac{3}{4} \text{ yds}

  • Perpendicular height of each pyramid: 2 \frac{1}{4} \text{ yds}

  • Distance from the center of the pyramid's base to the midpoint of one edge: 2 \frac{29}{50} \text{ yds}

  • Length of flat rectangular roof: 6 \frac{1}{2} \text{ yds}

If the cost per square foot of roof tile is \$9.66 / \text{sq ft}, find the total cost of the tile for the roof.

Worked Solution
Create a strategy

Substitute the dimensions into the equation for the area of the roof from part (a), then multiply the total area by the cost per square foot after confirming that units are aligned.

Apply the idea

The following diagram will allow us to align the measurements to the variables we laid out in part (a):

Based on the diagram, we can note what the following variables represent:

  • b= 3 \frac{3}{4}

  • p= 2 \frac{1}{4}

  • r= 2 \frac{29}{50}

  • l= 6 \frac{1}{2}

The lateral surface area of each pyramid is calculated using the expression 5 \cdot \dfrac{1}{2}b \left( \sqrt{r^2 + p^2} \right). By subsituting the lengths of the structure, we have 5 \cdot \dfrac{1}{2} \left(3 \frac{3}{4} \right) \left( \sqrt{\left( 2 \frac{29}{50} \right)^2 + \left( 2 \frac{1}{4} \right)^2} \right)= 32.09 \text{ sq yds}.

The area of the rectangular roof is calculated using the expression lb. By substituting the lengths of the structure, we have lb = \left(6 \frac{1}{2} \right) \left( 3 \frac{3}{4} \right) = 24.38 \text{ sq yds}.

In order to calculate the cost of the roof tiles, we need to convert the areas to square feet: \text{ Pyramid roof: } 32.09 \text{ sq yds} \times \dfrac{9 \text{ sq ft}}{1 \text{ sq yd}}= 288.81 \text{ sq ft} \\ \text{ Rectangular roof: } 24.38 \text{ sq yds} \times \dfrac{9 \text{ sq ft}}{1 \text{ sq yd}}= 219.42 \text{ sq ft}

Now, we can multiply the square footage by the cost per square foot: 288.81 \text{ sq ft} \times \$9.66 \text{/sq ft} = \$2\,789.90 \\ \text{ Cost for the rectangular roof: } 219.42 \text{ sq ft} \times \$9.66 \text{/sq ft} = \$2\,119.60

The total cost of the roof tiles for the structure will be \$2\,789.90 + \$2\,789.90 + \$2\,119.60 = \$7\,699.40

c

Provide a report to the director of the project with the relevant information.

Worked Solution
Create a strategy

The report for the director of the project for the roof should be clear, so providing a labeled model of the structure will be important. We can also include a table of the areas and costs for each part of the project for thee director to make decisions about whether the roofing will be within budget, or where costs can be cut.

Apply the idea

The cost for the roof tiles on the structure can be broken down in the following table for review:

Square feetTotal cost
Pyramid roof 1288.81\$2\,789.90
Pyramid roof 2288.81\$2\,789.90
Rectangular roof219.42\$2\,119.60

The total cost of the tile for the roof of the structure is \$ 7 \,699.40.

If this amount is beyond the expected budget without the cost of installation taken into account, we might consider a cheaper roof tile for the rectangular part of the roof, since it is flat and customers won't even be able to see that part of the structure. Suppose we purchase a tile for the flat roof that costs \$2 per square foot, then the cost of the tile for the flat roof would decrease by over \$1\,500 to \$438.84.

Reflect and check

As a rule of thumb, contractors will purchase more material than they actually need for a project to account for materials breaking, for human error in measuring, or based on the amount of material that can be purchased from the manufacturer. This means that the total cost would likely be higher than the given amount because of our precise measurements and because more roof tile than what is needed would likely need to be purchased.

Example 2

An ice cream store has two different types of cones. One type uses a conical-shaped cone while the other type is cylindrical with a flat base. Both types have the same size hemispherical scoop on top and are filled with ice cream, but the cylindrical cone is shorter than the pointy cone. The diagram that follows shows the two ice cream cones:

a

The store manager wants each of the cones to be filled with approximately 400 \text{ cm}^3 of ice cream. Design cones that meet the given parameters.

Worked Solution
Create a strategy

Research on various cones will give us an idea of the dimensions of a standard sugar cone, waffle cone, or cake cone. We can start by testing out measurements we find online and determine dimensions that will give us 400 \text{ cm}^3 of ice cream.

Create a table for each ice cream cone to keep track of dimensions for the cones, then create a model with the dimensions of the cones that best fit the parameters.

Apply the idea

For the volume of the hemispherical ice cream scoop, we will use the formula for half the volume of a sphere: \frac{1}{2}SV=\frac{1}{2} \cdot \frac{4}{3} \pi r^3, where SV is the sphere volume and r is the radius, which is half the length of the diameter of the cone.

For the volume of the ice cream in the conical and cylindrical ice cream cones, we will use the formulas for the volume of a cone and the volume of a cylinder, PV=\frac{1}{3} \pi r^2 h and CV=\pi r^2 h, respectively. PV is the pointy cone volume, CV is the cylindrical cone volume, and r is the radius of each cone.

Since some conical-shaped ice cream cones have a diameter of about 5 \text{ cm} and a height of about 11 \text{ cm}, we can use those dimensions as our starting point.

Cone diameter (cm)Cone height (cm)Scoop volume (cubic cm)Conical cone volume (cubic cm)Total volume (cubic cm)
5116572137
612113113226
713180167347
814268235533
813268218486
714180180360
715180192372
716180205385

By using an ice cream scoop with a diameter of 7 \text{ in}, we will use the same diameter for the flat-based cone as follows:

Cone diameter (cm)Cone height (cm)Scoop volume (cubic cm)Cylindrical cone volume (cubic cm)Total volume (cubic cm)
711180423603
710180385565
79180346526
78180308488
77180269449
76180231411

By starting with ice cream cone dimensions that are standard sizes and making adjustments, we can calculate the volume of ice cream needed. A model for the ice cream cones is shown below:

Reflect and check

The parameters for the ice cream cones are given, so we have the essential features of the problem. While a diagram is shown, the model we created for the problem must have actual dimensions. A tabular model also helped us to sort out information and possibly look for potential patterns in how the volume changes as the scoop and cone change.

Note that there are other approaches to the problem, and other choices we could make for radius and height to meet the volume requirements.

b

Consider the dimensions you chose for the cones you created in part (a). Think of what it would be like to hold each cone in your hands. Are your dimensions practical?

Worked Solution
Create a strategy

One way to interpret the practicality of our model is to measure out and create a physical model of the cones. We can do this using scissors, paper, and a ruler. Since both hemispheres on top of the cones are the same, we can just examine the cone sizes.

Apply the idea

With a physical model, we can discuss the practicality or relate the model to our experiences. With our models, the cylindrical flat-based cone feels more like a cup that ice cream would be served in. The pointy cone needs to be very large to fit the ice cream needed, and it has the feel of a waffle cone.

Reflect and check

Interpreting our models helps us to make better decisions about the math and determine how we will improve or report our findings.

c

Provide a report to the store manager with recommendations for the dimensions of the cones if they want each to have approximately 400 \text{ cm}^3 of ice cream in each. Include both practical and mathematical considerations, and make any suggestions you think might be helpful for the manager's plans.

Worked Solution
Apply the idea

The following ice cream containers can be offered to customers with approximately 400 \text{ cm}^3 of ice cream in each:

Due to the sizes of the cones, we can refer to the cylindrical cone as a bowl and continue to call the conical cone a cone. The bowl holds approximately 411 \text{ cm}^3 of ice cream while the cone holds 385 \text{ cm}^3.

By calling our cylindrical vessel a bowl instead of a cone, we can market this option at a different cost than the cone. Even though both vessels will hold approximately the same amount of ice cream, we can make a profit based on how much ice cream is perceived to be in each container.

Reflect and check

After interpreting the solutions from our model, our report should also be practical. In this situation, we are creating two containers that hold the same amount of ice cream. The purpose for the manager should be to improve their business in some way, so just offering a variety of containers that will earn the same amount of money may not be worth the effort.

There could be other valid recommendations that could be made in the report. For example, we could have recommended that the manager create a cylindrical cone with a longer height and more volume, so it looks more like a cone that customers expect. Then, charge a price for both cones that covers the cylindrical cone's volume, increasing the profit on each conical cone sold.

Idea summary

When interpreting and reporting results in geometric modeling, it is important to consider the practicality of the mathematics we're suggesting for a real-world application of geometry.

Outcomes

G.MG.A.1

Use geometric shapes, their measures, and their properties to describe objects.

G.MG.A.2

Apply concepts of density based on area and volume in modeling situations.

G.MG.A.3

Apply geometric methods to solve design problems.

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