Multiplication is repeated addition. Division is the opposite of multiplication. You can think of division as repeated subtraction.
Example. Bag 771 apples so there are 3 apples in one bag. How many bags are needed? You can start by putting 3 apples to one bag, which leaves you 768 apples. Then for each bag you subtract 3 apples and keep counting the bags you use, until you hit zero apples.
It just takes quite a long time, doesn't it? Instead you can take a 'shortcut' and initially subtract 300 apples (taking 100 bags) or some other big multiple of 3.
Let's figure it out and keep count of the bags as we subtract (put in bags) the apples.
So total needed 200 + 50 + 7 = 257 bags to bag all the apples. And it all went even - no apples left over! In other words, 771 ÷ 3 = 257. |
Example 4. You have 646 apples. If you put 8 apples in one bag, how many bags will you need?
In other words, 686 ÷ 8 = ______, R 6. |
Example 5. It won't matter even if you do the subtracting in smaller steps. Compare the two ways to do the division 795 ÷ 3 by subtracting repeatedly. You can think in terms of bagging apples if it helps.
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Example problems
1. Fill in the bags/fruits at each step of bagging.a. Bag 610 apples; 5 apples in each bag.
| b. Bag 852 kiwis; 3 kiwis in each bag.
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e. Bag 162 pears; 6 pears in each bag. f. Bag 495 cherries; 9 cherries in each bag. g. Bag 429 mangos; 3 mangos in each bag. | h. Bag 164 pineapples; 2 pineapples in each bag. i. Bag 4613 guavas; 7 guavas in each bag. j. Bag 1098 bananas; 9 in each bag. |
2. Do the divisions using the repeated subtraction. You can still think in terms of bagging fruit if it helps you. Also, you are encouraged to even try doing it mentally. Note: some of these divisions are even, some have remainder.
a. 555 ÷ 3 b. 750 ÷ 5 c. 257 ÷ 5 d. 464 ÷ 8 | m. 472 ÷ 5 n. 340 ÷ 2 o. 537 ÷ 9 p. 994 ÷ 7 | q. 670 ÷ 5 r. 750 ÷ 6 s. 238 ÷ 9 t. 294 ÷ 7 |
Long division and why it works
The standard long division algorithmWe compare here the repeated subtraction of the previous lesson and the conventional long division 'corner'. The steps are the same, just written out differently. For clarity's sake, we will initially write out the subtracted numbers with all the zeros included. Also, for clarity and for easy comparison, we will write the parts of the quotient above each other. As an example, we study 789 ÷ 3. You can think of it as 789 apples that you are bagging in bags of 3 apples, wanting to know how many bags you need.
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Why it worksComparing the division to the continued subtraction probably has already let you see why it works. In the conventional way of writing the long division, it's not so easy to see the process. The key is that in each step, one does NOT actually divide by the actual divisor but by a multiple of it. Just like in the apples/bags examples, you don't start out by subtracting 3 apples each time, but first 'hit it hard' by subtracting multiples of 300 apples if possible, then multiples of 30, then 3. In essence, you first divide by 300, then by 30, then by 3.Also, in the conventional long division, you only place one digit into the quotient in each step, not with all the zeros. The digits shown in gray are not usually written out in the conventional long division algorithm.
The remainder from first step (what is left after subtraction) is in reality 189. But since the ones digit (9) won't be important in the next step (which deals with the tens digit), in the traditional way, you only subtract 7-6 and then you 'drop' down the tens digit 8 from the dividend. To get the tens digit, similarly one asks the question: "How many times does 30 go into 189", or does the division 189 ÷ 30. Again, since you're dividing by a multiple of ten, the ones digit '9' in the 189 does not affect the division at all. The important thing is to look at the whole tens in the number 189, which is 180. So to find the answer to the division 189 ÷ 30, you can think of the division 180 ÷ 30, which is the same as thinking 18 ÷ 3: "How many times does 3 go into 18?" The last step is simple since it is dealing with ones digits, how many times does 3 go into 9. |
Examples of long division
These examples show how long division is done, with all of the dropping down of digits and such. It is important to keep the rows and columns lined up. 850 ÷ 2 = ?
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Study also the following examples with your teacher.
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1. Divide using long division. Check by multiplication.
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Do you remember?
How do we check the division if it is not exact? Look at the pictures above. If we end up with 3 people each having 4 bananas and 2 bananas left over, then the total amount of bananas is 3 × 4 + 2 = 14. Or if 5 people have 2 carrots each and there are 4 carrots left over, then all together we have 5 × 2 + 4 = 14 carrots. So to check the division that was not exact, multiply your result by the divisor as normal, and then ADD THE REMAINDER. You should get the original dividend. |
When using long division, the division is not always exact either.
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Example problems
1. Do these problems in your notebook. Write down here the result and the remainder. Check each division by multiplying and then adding the remainder. 321 ÷ 2 = 532 ÷ 9 = | 221 ÷ 3 = 922 ÷ 6 = | 490 ÷ 4 = 324 ÷ 6 = |
2. Do the word problems in your notebook.
a. While playing with matches, Annie had 204 matches. She divided them into piles of 8 matches. How many piles dud she make? How many matches were left over? |
b. If she divides them into piles of 20, how many piles does she get now? Don't use long division but just think (or use real matches to help). |
3. Remember? Multiply by 10, and make a division sentence.
10 × 21 = ___ ÷ 10 = 21 | 10 × 90 = ___ ÷ 10 = ___ | 10 × 87 = ___ ÷ 10 = ___ |
4. Based on the previous exercise, divide the following numbers by 10.
780 ÷ 10 = ___ 150 ÷ 10 = ___ | 450 ÷ 10 = ___ 120 ÷ 10 = ___ | 460 ÷ 10 = ___ 440 ÷ 10 = ___ |
5. Based on the previous exercise, divide the following numbers by 10 and indicate the remainder.
787 ÷ 10 = 151 ÷ 10 = | 452 ÷ 10 = 126 ÷ 10 = | 463 ÷ 10 = 982 ÷ 10 = |
Long division is one of my least favorite things to teach, but as I tell my children, “It doesn’t have to be fun, it just has to be done.”
So, I charge ahead every couple of years showing one of my fresh faced offspring the maze of steps.
One of the difficulties for them is remembering what step to do next.
Here is a handy little rhyme to remind them of the order:
Daddy, Mother, Sister, Brother
I point out that the beginning letters will remind them to
1)Divide 2)Multiply 3)Subtract 4)Bring Down
For example:
Let’s start with this simple problem.
Since “Daddy” comes first, we divide first.
Next comes “Mother”, so we multiply.
“Sister” means we subtract.
Last comes “Brother”, so we bring down and start the process again.
If that helps just one other person get through the grueling process of teaching long division, then it was worth every head banging, hair pulling, tear inducing minute.