Taking the Fear out of Math next #7 3 13 1 22 Dividing Mixed Numbers © Math As A Second Language All Rights Reserved next As in our previous discussions with mixed numbers, let’s begin with a “real world” example… What is the cost per pound if 33/4 pounds of pears cost $4.50? © Math As A Second Language All Rights Reserved next 33/4 pounds is the same amount as 15 fourths of a pound. If 15 fourths of a pound cost $4.50 (that is, 450 cents), then each fourth of a pound costs… 450 cents ÷ 15 (or 30 cents). And since there are 4 fourths of a pound in a pound, each pound of pears costs 4 × 30 cents or $1.20. © Math As A Second Language All Rights Reserved next The cost per pound in dollars is given by the formula… dollars per pound = total cost in dollars ÷ number of pounds. This formula is the same whether we are dealing with whole numbers, common fractions or mixed numbers. © Math As A Second Language All Rights Reserved next Rewriting $4.50 as $41/2, our answer takes the form… cost per pound = 41/2 dollars ÷ 33/4 pounds which can be rewritten as… cost per pound = (41/2 ÷ 33/4) dollars per pound © Math As A Second Language All Rights Reserved next If you are uncomfortable using mixed numbers to perform the division, you may use improper fractions and rewrite the above computation in the form… cost per pound = (9/2 ÷ 15/4) dollars per pound © Math As A Second Language All Rights Reserved next From our study of fractions we know that… 41/2 ÷ 33/4 dollars per pound = 9/2 ÷ 15/4 dollars per pound = 9/2 × 4/15 dollars per pound = 36/30 dollars per pound = 6/5 dollars per pound = 11/5 dollars per pound © Math As A Second Language All Rights Reserved next And since there are 100 cents per dollar… 1/ of 5 a dollar = 100 cents ÷ 5 = 20 cents and therefore… 11/5 dollars per pound = $1.20 per pound which agrees with our previous answer. © Math As A Second Language All Rights Reserved next As we shall show later in this presentation, it is possible to divide mixed numbers without having to first convert them to improper fractions. However, this can be quite tedious. So while the idea of converting mixed numbers to improper fractions is quite common, it is especially useful when we deal with division. © Math As A Second Language All Rights Reserved next However, converting the division of mixed numbers to division of improper fractions tends to obscure what is actually happening. For example, suppose we want to divide 41/2 by 21/2 , We could begin by rewriting 41/2 ÷ 21/2 as 9/2 ÷ 5/2. We would then use the “invert and multiply” rule to obtain 9/ × 2/ or 9/ . Finally, we divide 9 by 5 2 5 5 and obtain 14/5 as the answer. © Math As A Second Language All Rights Reserved next Notes Since the definition of division hasn’t changed 41/2 ÷ 21/2 means the number we must multiply by 2 1/2 to obtain 41/2 as the product. A quick check shows that this is the case… 21/2 × 14/5 = 5/ 2 © Math As A Second Language × 9/5 = 9/ = 2 41/2 All Rights Reserved next Notes As a “reality check”, it is helpful to estimate an answer before proceeding with the actual computation. Noticing that 41/2 is “around” 4 and 21/2 is “around” 2, we can estimate that the answer should be “around” 4 ÷ 2 or 2. Actually, since 5 ÷ 21/2 is exactly 2, 41/2 ÷ 21/2 must be a “little less” than 2. Thus, 14/5 is a plausible answer. © Math As A Second Language All Rights Reserved next Notes In terms of relative size, what the quotient tells us is that not only is 41/2 almost twice as much as 21/2 but it’s exactly 14/5 times as much. As a practical application, suppose we can buy 21/2 pounds of cheese for $ 41/2. Then the price per pound (that is, “dollars per pound”) is obtained by dividing $41/2 by 2 1/2 pounds. The quotient tells us that the cost of the cheese is $14/5 or $1.80 per pound. © Math As A Second Language All Rights Reserved next For additional practice, let’s use the above method to express 6 1/3 ÷ 13/4 as a mixed number. 61/3 ÷ 13/4 = 19/3 ÷ 7/4 = 19/3 × 4/7 = 76/21 = 76 ÷ 21 = 313/21 © Math As A Second Language All Rights Reserved next Notes To check that our answer is at least reasonable, we observe that rounded off to the nearest whole number 61/3 = 6 and 13/4 = 2. Hence, our answer should be “reasonably close to” 6 ÷ 2 or 3. However, once we obtain our answer, we can check to see if it’s correct by remembering that 61/3 ÷ 13/4 = 313/21 means that 313/21 × 13/4 = 61/3. © Math As A Second Language All Rights Reserved next Thus, to check our answer we compute the value of 313/21 × 13/4 to verify that it is equal to 61/3. 313/21 × 13/4 = 76/21 × 7/4 = (76 × 7)/(21 ×4) = (19 × 2 × 2 × 7)/(3 × 7 × 2 × 2) = 19/3 = 61/3 © Math As A Second Language All Rights Reserved next As we mentioned earlier, while converting mixed numbers to improper fractions gives us the desired result when we divide two mixed numbers, the fact is that it doesn’t give us much insight as to what is actually happening. From a mathematical perspective, it would be nice to know that the arithmetic of mixed numbers is self-contained (at least in the sense that we aren’t forced to rewrite mixed numbers as improper fraction in order to do the arithmetic). © Math As A Second Language All Rights Reserved next From a teaching point of view, we might want to illustrate how we can divide mixed numbers in ways that may be more intuitive to students. Using Mixed Numbers as Adjectives Modifying the Same Noun. To divide 41/2 by 21/2, think of both mixed numbers as modifying, say, “a carton of books” where each carton contains 2 books1 note 1 More generally, we would use the (least) common multiple of both denominators. For example, had the problem been 41/3 ÷ 25/7 , we would have assumed that each carton contained 21 books and then multiplied both the dividend and the divisor by 21. © Math As A Second Language All Rights Reserved next In this case, 41/2 cartons is another name for 9 books and 21/2 cartons is another name for 5 books. Therefore, we may visualize the problem in terms of the following steps… 41/2 ÷ 21/2 = 41/2 cartons ÷ 21/2 cartons = 9 books ÷ 5 books = 9 ÷ 5 = 14/5 © Math As A Second Language All Rights Reserved next Multiplying Both Numbers in a Ratio by the Same Number Students might find it interesting to see that we can divide mixed numbers by “translating” the problem into an equivalent whole number problem without having to refer to such things as books and cartons. The key is that it is still a fact that we do not change a quotient when we multiply both the dividend and the divisor by the same (non zero) whole number. © Math As A Second Language All Rights Reserved next To this end, if we are given the division problem 41/2 ÷ 21/2, we simply multiply both numbers by 2…2 and obtain… 41/2 ÷ 21/2 = (41/2 × 2) ÷ (21/2 × 2) =9÷5 = 14/5 note 2 When we multiply a mixed number by the denominator of its fractional part we always obtain a whole number. For example, 5 × 42/5 = 5 × (4 + 2 2/5) = (5 × 4) + (5 × 2/5) = 20 + 2 = 22. © Math As A Second Language All Rights Reserved next We can now use the above method to write 61/3 ÷ 23/5 as a mixed number. Since the denominators are 3 and 5, we can eliminate them by multiplying both numbers by 15. 15 × 61/3 = (15 × 6) + (15 × 1/ ) 3 = 90 + 5 = 95 © Math As A Second Language All Rights Reserved 15 × 23/5 = (15 × 2) + (15 × 3/5) = 30 + 9 = 39 next Since… 15 × 61/3 = 95 and 15 × 23/5 = 39 …then, 61/3 ÷ 23/5 = 95 ÷ 39 = 217/39 © Math As A Second Language All Rights Reserved next As a check we see that… 217/39 × 23/5 = 95/39 × 13/ 5 = (95 ×13)/(39 × 5) = (19 × 5 × 13)/(3 × 13 × 5) = 19/3 = 61/3 © Math As A Second Language All Rights Reserved next Notes In terms of relative size, the above result tells us that 61/3 is approximately 21/2 times as great as 23/5. (It is actually 217/39 times as great.) We don’t usually think about using common denominators when we want to divide two fractions, but we can. The denominator of a fraction is the noun and when we divide two numbers that modify the same noun, the nouns “cancel”. © Math As A Second Language All Rights Reserved next Thus, if we decide to rewrite the mixed numbers as improper fractions, we obtain… 61/3 ÷ 23/5 = 19/3 ÷ 13/ 5 = (19 × 5) /(3 × 5) ÷ (13 × 3)/(5 × 3) = 95/15 ÷ 39/15 = 95 fifteenths ÷ 39 fifteenths = 95 ÷ 39 = 217/39 © Math As A Second Language All Rights Reserved next While the topic might be beyond the scope of the elementary school student, it is interesting to note that the long division algorithm for whole numbers, as a form of rapid subtractions, also applies to the division of mixed number. For example, 61/3 ÷ 23/5 = ( ) means the same thing 23/5 × ( ) = 61/3. © Math As A Second Language All Rights Reserved next Using trial-and error to solve this equation we see that… 23/5 × 1 = 23/5 23/5 × 2 = 46/5 = 51/5 less than 61/3 In other words, 61/3 is more than twice as big as 23/5 but less than three times as big. 23/5 × 3 = 69/5 = 74/5 © Math As A Second Language All Rights Reserved greater than 61/3 next The difference between 61/3 and 51/5 is 61/3 – 51/5 = 65/15 – 53/15 = 12/15. Hence, if we use the long division algorithm we see that… 2 R 23/5 61/3 51/5 122/15 15 …and if we now write the remainder over the divisor, we see that… © Math As A Second Language All Rights Reserved 61/3 ÷ 23/5 = 2/ 1 15 2 + 23/5 next 12/15 23/5 We can simplify the complex fraction above by multiplying numerator and denominator by 15. 15 × 12/15 = (15 × 1) + (15 × 2/15) = 15 × 2 = 17 © Math As A Second Language All Rights Reserved 15 × 23/5 = (15 × 2) + (15 × 3/ ) 5 = 30 + 9 = 39 next Therefore… 23/5 61/3 12/15 = 3 2 /5 17/ 39 61/3 ÷ 23/5 2/ 1 15 =2 + 23/5 = 2 + 17/39 = 217/39 © Math As A Second Language All Rights Reserved next 4/ 5 × 100 = 80% © Math As A Second Language This completes our discussion of the four basic operations of arithmetic using mixed numbers, and in our next presentation we shall introduce the notion of percents. All Rights Reserved