{"id":658,"date":"2015-03-10T00:01:35","date_gmt":"2015-03-10T04:01:35","guid":{"rendered":"http:\/\/blogs.ams.org\/matheducation\/?p=658"},"modified":"2015-03-06T22:11:35","modified_gmt":"2015-03-07T03:11:35","slug":"one-reason-fractions-and-many-other-topics-are-hard-equivalence-relations-up-and-down-the-mathematics-curriculum","status":"publish","type":"post","link":"https:\/\/blogs.ams.org\/matheducation\/2015\/03\/10\/one-reason-fractions-and-many-other-topics-are-hard-equivalence-relations-up-and-down-the-mathematics-curriculum\/","title":{"rendered":"One Reason Fractions (and Many Other Topics) Are Hard: Equivalence Relations Up and Down the Mathematics Curriculum"},"content":{"rendered":"

By Art Duval,\u00a0Contributing Editor<\/a>, University of Texas at El Paso\u00a0<\/em><\/p>\n

Why are fractions hard to learn for so many people? \u00a0There are many reasons for this, but I like to think about one in particular, a mathematical idea hiding in plain sight, from elementary school to college: equivalence relations. \u00a0Consider the fraction sum 2\/3 + 1\/5, which we of course compute by using 2\/3=10\/15 and 1\/5=3\/15, arriving at an answer of 13\/15. \u00a0This raises a whole host of fundamental questions about equality: \u00a0If 2\/3 equals 10\/15, why can we use one but not the other in evaluating the sum? \u00a0Does this mean something is wrong with our idea of “equals”? \u00a0Could we have used something else besides 10\/15; or, in the other extreme, should we always use 10\/15? \u00a0This shows that often when we say “equals”, what we really mean is “equivalent”. \u00a0Equivalence introduces a number of useful mathematical connections, but we must be careful in how we handle it with our students who just want to know, for instance, how to add two fractions.<\/p>\n

We’ll see in a bit how these same ideas arise in mathematical topics from elementary school through college, and what potential difficulties they may cause. \u00a0I\u2019ll conclude by sharing some specific examples of what I do in my classes to confront these issues.<\/p>\n

But first, a very quick primer for readers who haven’t seen how to define rational numbers with mathematical rigor: Declare two fractions<\/i> a\/b and c\/d (a,b,c,d integers, b, d not 0) to be equivalent<\/i> if ad=bc. \u00a0We then verify this relation really is an equivalence relation (a relation satisfying the familiar reflexive, symmetric, and transitive properties of equality), which also means this relation partitions all the fractions into equivalence classes. \u00a0It’s those equivalence classes that are the rational numbers. \u00a0So the rational number 2\/3 is actually the equivalence class of all fractions that are equivalent to the fraction 2\/3<\/b>, by our usual method of reducing to lowest common denominator.<\/p>\n

We should also verify that this relation behaves nicely with respect to operations such as addition (defined<\/i> by the formula we get from using common denominators: a\/b + c\/d = \u00a0(ad + bc)\/bd) so that anything equivalent to 2\/3 plus anything equivalent to 1\/5 gives something equivalent to 13\/15.<\/p>\n

All of this is more meaningful (and the proofs are much more straightforward) if we define two fractions to be equivalent if they correspond to the same length on a number line. \u00a0Indeed, this more natural way to define the equivalence is why we care about it in the first place. \u00a0But that doesn’t help when we want to do exact calculations, or when our fractions contain algebraic expressions. \u00a0Then we really are confronted with issues of equivalence:<\/p>\n