Photo by Bredgur

Let’s develop a math project to challenge students who have demonstrated a mastery of multiplication and are ready to explore its applications.

Previously, I wrote about constructing math projects with four criteria:

- Authentic Data
- Interesting Conflict
- Think Like An Expert
- Awesome Product

### Authentic Data

Good projects start with perplexing seeds that draw out questions that are answered with math.

A practical application of multiplication is to quickly count large numbers of objects arranged in a pattern. And where do we see large numbers of objects arranged in an array? How about parking lots?

As a Californian, the parking lot that stands out to me is Disneyland’s enormous “Mickey and Friends” structure.

I fired up Google Maps, Bing Maps, and Google Earth and searched for the best imagery of Disneyland’s parking structure.

If Disneyland doesn’t suit your needs, here’s a list of other large parking lots.

### Get Them Talking

First, let’s be a bit theatrical and show a mysterious picture to get them talking:

What is this? What’s its purpose? Where is it? Let them ask and guess. Draw them into the mystery. Encourage curiosity, even if it’s not directly related to the eventual lesson.

Then reveal the next image:

Can anyone figure it out now? More guesses.

It’s where everyone parks when they go to Disneyland!

Elapsed time: 3 minutes or so and they should be pretty engaged.

### Interesting Conflict

Now reveal the detailed image of the parking lot (Here’s a much larger version).

Set up the conflict that everyone’s thinking:

How many cars can park in this structure!?

Use number eight of Dan Meyer’s ten principles for engaging math tasks: “Ask for guesses.” Write their guesses down for later. We’re increasing students’ stake in the process. You might also ask: What’s too small? What’s too big?

Then get down to brass tacks and ask students *how* they’d solve this. Strategies may include:

- Count them all
- Count per row and multiply by the number of rows
- Use the light posts to set up regions, count, then multiply by number of regions
- Use the big white lines to divide the regions
- And so on…

### On With The Show

Group students (or let them work alone) and give out copies of the image of the structure.

Depending on ability, ask them to solve using two or three different strategies. This sets up the later question: “Which strategy was best, easiest, or most accurate?”

Give them some structure as they work:

Method | Evidence | Solution | Pros/Cons |
---|---|---|---|

Counted rows | 160 × 10 | 1600 | rows are long and difficult to count |

Counted sections within white lines | 6 × 290 | 1750 | sections at the ends are not equal |

*Here’s a blank PDF of this table.*

Walk around and monitor, probing when someone goes astray. Work with groups that you know need help. Note that the requiring different methods is a way to differentiate. If a group struggles with multiplying these larger numbers, just ask for one method.

### Three Dimensions!

Once everyone has at least one solution, introduce the next piece of information:

Ask them what important detail they need to consider now. There are *six levels* to the structure! We’ve only calculated part of the solution! Time to multiply again!

### You’ve Gotta Know the Answer!

#### Math Curiosities!

26 delightful mathematical curiosities - simple enough for elementary students, yet rich with deep possibilities. Learn more...

As we approach the conclusion, make sure you know the real answer. Otherwise, it’s the ultimate anti-climax! The the contractor has the exact answer: 10,242 cars!

### But! That’s Not What We Got!?

Did anyone hit the bullseye? Maybe not. But that means we can ask: “Why didn’t we get the answer perfectly?”

Let students think about it.

- Maybe the floors we can’t see are a bit different than the roof?
- Maybe there are certain spots that aren’t “parkable”?
- Maybe floor one is completely different, since it’s the entrance to the lot?

Discuss the accuracy and usefulness of each strategy.

### Extend It: Economist’s Perspective

We can extend this further by applying an economist’s points of view.

How much money does Disneyland make off its parking structure when it’s full? At 50%? And so on.

I even dug up the original cost of the structure: $90 million. With this information, we can ask about the profitability of the parking structure.

How many days of a full parking structure would be required to pay off the $90 million dollar price tag? What if the lot was only 75% full?

Going further: What range of *people* could the lot hold? Consider motorcycles through vans. How much money in ticket sales would the lot generate?

As an economist, was the initial investment into this parking structure worth it?

### Product

Students could develop:

- An attack ad, criticizing the expensive project
- A recommendation for Disney to change pricing to reach profitability faster
- An brochure offering information and graphs about the structure for Disney investors

As always, products should tap into students’ natural talents and interests.

### Your Thoughts

*I’d really appreciate your feedback on this. Try it out with your students and let me know how it went: ian@byrdseed.com*

### Get creative ideas in your inbox.

I'll send you one or two emails a month to help you better understand and differentiate for gifted students.

Get free resources now!