Representing Algorithms K 2

Representing Algorithms K –2

(ADDITION)

Concrete / Pictorial Representation / Verbalization / Tabular (Abstract)
Addition (with like things)

/  +  / Two soccer ballsplusfour more soccer balls give a total of six soccer balls. / 2 + 4 = 6
Addition (with different things)

/  +  / Two soccer ballsplusfour pumpkins give a total of six things. / 2 + 4 = 6

PONDER:

Are there other representations? I mean, what if you have 2 soccer balls and 4 people, would we say that we have 6? Six what?
How does this relate to the Commutative Property of Addition (turn-around facts)?
How might young children get confused when learning about addition? How might multiple representations help such confusions?
How might students connect these representations to algebra thinking?

NOTES:

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Representing Algorithms K – 2

(SUBTRACTION)

Concrete / Pictorial Representation / Verbalization / Tabular (Abstract)
Subtraction(Take-away)

/
 / I have three soccer balls. I take away two. I have three left. / 5 – 2 = 3
Subtraction as a Comparison (Difference)
Bills Soccer Balls

Toms Soccer Balls / Bills Soccer Balls



Toms Soccer Balls / Bill has five soccer balls. Tom has tow soccer balls. Bill has three more soccer balls than Tom. / 5 – 2 = 3

PONDER:

Are there other representations? I mean, what if the question where: How many more balls does Tom need to equal the number of balls that Bill has?
Why doesn’t subtraction have a Commutative Property (turn-around facts)?
How might young children get confused when learning about subtraction? How might multiple representations help such confusions?

NOTES:

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Representing Algorithms2 – 3

(ADDITION & SUBTRACTION w/ REGROUPING)

Concrete / Pictorial Representation / Verbalization / Tabular (Abstract)
Addition

      /
100 + 20 + 20 + 3 + 8
  
 
+10 +10
+2 +5 +1
123 133 143 145 150 151 / 123 plus 28 is 100plus 20, plus 20 to give 140. Then 3 plus 8 is 11, which is 10 plus 1.So 140, plus 10 is 150. And 150, plus 1 is 151.
(Verbalization of the Concrete Representation) / 123 + 28 = 151
1
123
+ 28
151
Subtraction


    
    
/ - 10
-2
-2 -2 -2

105 113 123

100 + 20 + 3

    
    
100 + 10 + 5 = 105 / To solve 123 take away 18, I took 10 from the 20 in the tens place and added it to the 3 ones. So now I have 13 ones and I have to take away 8 ones, which is a difference of 5. In the tens place I have a 10 and have to take away 10, so I have zero in the ones place. In the hundreds place I have 100 and nothing to take away, so I still have 100. / 13
123
- 18
105

PONDER:

Are there other representations? We have used an open number line and base-10 representations, what else might we us?
Can you develop an alternative method for solving and showing how you can solve regrouping problems? How might you solve regrouping problems without regrouping? What does regrouping mean?
How might young children get confused when learning about regrouping? How can you connect the decomposition of numbers to regrouping?

NOTES:

Representing Algorithms3 – 4

(MULTIPLICATION)

Concrete / Pictorial Representation / Verbalization / Tabular (Abstract)
Multiplication

/ 

XXX XXX / Two groups of three soccer balls produce six soccer balls. / 2 x 3 = 6
Multiplication

25¢ 25¢ 25¢ 25¢ 25¢ 25¢
25¢ 25¢ 25¢ 25¢ 25¢ 25¢ /
/ Twelve groups of 25 things (cents) will produce 200 + 40 + 50 + 10 or 300 things (cents). / 12 x 25
1
12
x 25
60
+240
300

PONDER:

Are there other representations? How does the partial products algorithm relate to the traditional algorithm?
How is the Distributive Property of Multiplication modeled by the traditional algorithm or array model?
Is 12 x 25 the same as 25 x 12? Why or why not?

NOTES:

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Representing Algorithms4 – 5

(DIVISION)

Concrete / Pictorial Representation / Verbalization / Tabular (Abstract)
Division

       

         

         

    
/ 20
5
0.2
0.2 / 20
5
0.2
0.2 / 20
5
0.2
0.2 / 20
5
0.2
0.2 / 20
5
0.2
0.2
25.4 per group
or
/ I looked at the number 127 and saw 100+20+7 and said, “Each of these numbers has to be shared equally into 5 groups.” So I split the 100 into twenties. I had 27 left. I turned that into 25 + 2. I split the 25 into 5s. I have a remainder of 2, so I looked at it like money and asked, “If I had $2.00, could I split it into 5 groups?” I could not figure that out, so I asked the same question for a dollar. And yes, each section got 0.2 or 20 cents. And I did the same thing for the last dollar I had. Within each group I have 25.4 things. / 127  5 = 25.4
or
25 R 2 or 25

PONDER:

Are there other representations? Is the partial quotients model represented here?
How are multiplication and division related?
Why doesn’t division have a Commutative Property (turn-around facts)? Does 30  5 = 6 mean 5 groups with 6 things in each or 30 things split into in 5 things per group making 6 groups in all?
How might students get confused when learning about division? How might multiple representations help such confusions?

NOTES:

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Representing Operations6 - 7

(Order of Operations)

Concrete / Pictorial Representation / Verbalization / Tabular (Abstract) / Symbolic (Abstract)

/ with the same items

/ with the same items:
Two soccer balls plus three groups of five soccer balls equals seventeen soccer balls. / with the same items:
2 + 3 * 5
3 * 5 = 15
2+ 15 = 17 / 2s + 15s = 17s
2s + 3(5s)

/ with different items

/ with different items:
Two soccer balls added to three groups of five pumpkins equals seventeen things. / 2 + 3 * 5
3 * 5 = 15
2+ 15 = 17 / 2s + 15p
2s + 3(5p)