How to Teach Averages (Arithmetic Mean) to a Teenager?

Question

Suppose you had to teach averages to a teenager. For arguments sake let the question be;

Find the mean of $2, 3, 4, 7$

Of course the simple answer is $\frac{2+3+4+7}{4}=4$ but in my experience the student only reinforces their addition and division skills and is left bereft of any conceptual understanding of mean.

Context and comparison helps;

The length of male mice tails are $2cm,3cm,4cm,7cm$

The mean average female tail is $3.9cm$.

Compare the mice tails.

I would like to know ways in which I can instill conceptual understanding of averages. I'm always left with a feeling students just calculate and don't really understand why they are doing it.

Perhaps worse is range. Practically all students will tell be it's highest take lowest but almost never attach any sensible meaning to it.

How do you teach averages and not the simple calculations?

Answer 1

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Answer 2

Another interpretation that can help make the formula meaningful is "equal redistribution". Say a group of 4 friends have (respectively) \$2, \$3, \$4, and \$7. How much money would they each have, if they all had the same amount of money as each other without changing the total?

Or: Tom makes hand-made wooden spoons, which he sells at a local farmer's market. At the most recent market he sold 2 spoons in the first hour, 3 in the second hour, 4 in the third hour and 7 in the fourth (and last) hour. If you imagine all of those spoons being sold at a steady rate over the course of the market, how many would be sold per hour?

In both cases you find the answer by summing the number of "things" (dollars or spoons) and dividing by the number of "places" (people or hours), and end up calculating the mean. The idea that underlies both of these examples is "uniformization" -- you take some distribution of stuff that has an irregular pattern to it, and describe what it would be like if things were equally distributed.

Answer 3

Once upon a time, I designed some versions of the following task to bring about the algebraic nature of 100 number grid. But, @mweiss answer gave me the idea of the possibility of using it for what you've asked for. Thus, it is clear that I've never used it to teach the "average", but I thought it is worth sharing.

Suppose three children are standing on different numbers on a 100 number grid (if you are a school teacher you can indeed make such a suitable-for-standing number grid in schoolyard). The task for them is to move to and meet at the same cell of the number grid without changing the initial sum of the three numbers they were standing on.

It is only work when the average is a natural number. But, it is nice to see that to solve the problem both the smallest number and the biggest number should "move" towards the number that later on will be called mean. As a result, your students may also experience some aspects of "range" as well.

PS. Of course, you can easily use this idea with paper number gird and counters.