1. Teaching the Arithmetic Facts Using
Strategies and Games
by Joan A. Cotter, Ph.D.
JoanCotter@RightStartMath.com
MCTM
May 4, 2012
Duluth, Minnesota
7 3 8 16 24 32 40
PowerPoint Presentation & Handout
RightStartMath.com >Resources © Joan A. Cotter, Ph.D., 2012

2. Learning the Facts
© Joan A. Cotter, Ph.D., 2012

3. Learning the Facts
Limited success when:
• Based on counting.
Whether dots, fingers, number lines, or
counting words.
© Joan A. Cotter, Ph.D., 2012

4. Learning the Facts
Limited success when:
• Based on counting.
Whether dots, fingers, number lines, or
counting words.
• Based on rote memory.
Whether by flash cards or timed tests.
© Joan A. Cotter, Ph.D., 2012

5. Learning the Facts
Limited success when:
• Based on counting.
Whether dots, fingers, number lines, or
counting words.
• Based on rote memory.
Whether by flash cards or timed tests.
• Based on skip counting for multiplication facts.
© Joan A. Cotter, Ph.D., 2012

6. Counting Model
From a child's perspective
© Joan A. Cotter, Ph.D., 2012

7. Counting Model
From a child's perspective
Because we’re so familiar with 1, 2, 3, we’ll use letters.
A=1
B=2
C=3
D=4
E = 5, and so forth
© Joan A. Cotter, Ph.D., 2012

8. Counting Model
From a child's perspective
F
+E
© Joan A. Cotter, Ph.D., 2012

9. Counting Model
From a child's perspective
F
+E
A
© Joan A. Cotter, Ph.D., 2012

10. Counting Model
From a child's perspective
F
+E
A B
© Joan A. Cotter, Ph.D., 2012

11. Counting Model
From a child's perspective
F
+E
A B C
© Joan A. Cotter, Ph.D., 2012

12. Counting Model
From a child's perspective
F
+E
A B C D E F
© Joan A. Cotter, Ph.D., 2012

13. Counting Model
From a child's perspective
F
+E
A B C D E F A
© Joan A. Cotter, Ph.D., 2012

14. Counting Model
From a child's perspective
F
+E
A B C D E F A B
© Joan A. Cotter, Ph.D., 2012

15. Counting Model
From a child's perspective
F
+E
A B C D E F A B C D E
© Joan A. Cotter, Ph.D., 2012

16. Counting Model
From a child's perspective
F
+E
A B C D E F A B C D E
What is the sum?
(It must be a letter.)
© Joan A. Cotter, Ph.D., 2012

17. Counting Model
From a child's perspective
F
+E
K
A B C D E F G H I J K
© Joan A. Cotter, Ph.D., 2012

18. Counting Model
From a child's perspective
E
+G
Add with your fingers.
© Joan A. Cotter, Ph.D., 2012

19. Counting Model
From a child's perspective
H
+D
Add without your fingers.
© Joan A. Cotter, Ph.D., 2012

20. Counting Model
From a child's perspective
Now memorize the facts!!
G
+D
© Joan A. Cotter, Ph.D., 2012

21. Counting Model
From a child's perspective
Now memorize the facts!!
H
+
G
F
+D
© Joan A. Cotter, Ph.D., 2012

22. Counting Model
From a child's perspective
Now memorize the facts!!
H
+
G
F
+D
D
+C
© Joan A. Cotter, Ph.D., 2012

23. Counting Model
From a child's perspective
Now memorize the facts!!
H
+
G
F
+D
D C
+C +G
© Joan A. Cotter, Ph.D., 2012

24. Counting Model
From a child's perspective
Now memorize the facts!!
H
E
+
G
I
F
+
+D
D C
+C +G
© Joan A. Cotter, Ph.D., 2012

25. Counting Model
From a child's perspective
H
–E
Subtract with your fingers.
© Joan A. Cotter, Ph.D., 2012

26. Counting Model
From a child's perspective
J
–F
Subtract without using your fingers.
© Joan A. Cotter, Ph.D., 2012

27. Counting Model
From a child's perspective
Try skip counting by B’s to T:
B, D, . . . T.
© Joan A. Cotter, Ph.D., 2012

28. Counting Model
From a child's perspective
Try skip counting by B’s to T:
B, D, . . . T.
What is D x E?
© Joan A. Cotter, Ph.D., 2012

29. Memorizing Math
© Joan A. Cotter, Ph.D., 2012

30. Memorizing Math
Some research:
Percentage Recall
Immediately After 1 day After 4 wks
Rote 32 23 8
Concept 69 69 58
© Joan A. Cotter, Ph.D., 2012

31. Memorizing Math
Some research:
Percentage Recall
Immediately After 1 day After 4 wks
Rote 32 23 8
Concept 69 69 58
© Joan A. Cotter, Ph.D., 2012

32. Memorizing Math
Some research:
Percentage Recall
Immediately After 1 day After 4 wks
Rote 32 23 8
Concept 69 69 58
© Joan A. Cotter, Ph.D., 2012

33. Memorizing Math
Some research:
Percentage Recall
Immediately After 1 day After 4 wks
Rote 32 23 8
Concept 69 69 58
© Joan A. Cotter, Ph.D., 2012

34. Memorizing Math
Some research:
Percentage Recall
Immediately After 1 day After 4 wks
Rote 32 23 8
Concept 69 69 58
© Joan A. Cotter, Ph.D., 2012

35. Memorizing Math
Some research:
Percentage Recall
Immediately After 1 day After 4 wks
Rote 32 23 8
Concept 69 69 58
© Joan A. Cotter, Ph.D., 2012

36. Memorizing Math
Some research:
Percentage Recall
Immediately After 1 day After 4 wks
Rote 32 23 8
Concept 69 69 58
© Joan A. Cotter, Ph.D., 2012

37. Memorizing Math 9
+7
Flash cards:
© Joan A. Cotter, Ph.D., 2012

38. Memorizing Math 9
+7
Flash cards:
• Are often used to teach rote.
© Joan A. Cotter, Ph.D., 2012

39. Memorizing Math 9
+7
Flash cards:
• Are often used to teach rote.
• Are liked by those who don’t need them.
© Joan A. Cotter, Ph.D., 2012

40. Memorizing Math 9
+7
Flash cards:
• Are often used to teach rote.
• Are liked by those who don’t need them.
• Don’t work for those with learning disabilities.
© Joan A. Cotter, Ph.D., 2012

41. Memorizing Math 9
+7
Flash cards:
• Are often used to teach rote.
• Are liked by those who don’t need them.
• Don’t work for those with learning disabilities.
• Give the false impression that math isn’t about
thinking.
© Joan A. Cotter, Ph.D., 2012

42. Memorizing Math 9
+7
Flash cards:
• Are often used to teach rote.
• Are liked by those who don’t need them.
• Don’t work for those with learning disabilities.
• Give the false impression that math isn’t about
thinking.
• Often produce stress – children under stress stop
learning.
© Joan A. Cotter, Ph.D., 2012

43. Memorizing Math 9
+7
Flash cards:
• Are often used to teach rote.
• Are liked by those who don’t need them.
• Don’t work for those with learning disabilities.
• Give the false impression that math isn’t about
thinking.
• Often produce stress – children under stress stop
learning.
• Are not concrete – they use abstract symbols.
© Joan A. Cotter, Ph.D., 2012

44. AN ALTERNATIVE:
SUBITIZING
and
GAMES
© Joan A. Cotter, Ph.D., 2012

45. Subitizing Quantities
Identifying without counting
© Joan A. Cotter, Ph.D., 2012

46. Subitizing Quantities
Identifying without counting
• Five-month-old infants can subitize to 3.
© Joan A. Cotter, Ph.D., 2012

47. Subitizing Quantities
Identifying without counting
• Five-month-old infants can subitize to 3.
• Three-year-olds can subitize to 5.
© Joan A. Cotter, Ph.D., 2012

48. Subitizing Quantities
Identifying without counting
• Five-month-old infants can subitize to 3.
• Three-year-olds can subitize to 5.
• Five-year-olds can subitize 6 to 10 by
using five as a subbase.
© Joan A. Cotter, Ph.D., 2012

49. Adding
Name the quantity (practice subitizing).
© Joan A. Cotter, Ph.D., 2012

50. Adding
Name the quantity (practice subitizing).
© Joan A. Cotter, Ph.D., 2012

51. Adding
Name the quantity (practice subitizing).
© Joan A. Cotter, Ph.D., 2012

52. Adding
4+3=
© Joan A. Cotter, Ph.D., 2012

53. Adding
4+3=
© Joan A. Cotter, Ph.D., 2012

54. Adding
4+3=
© Joan A. Cotter, Ph.D., 2012

55. Adding
4+3=7
© Joan A. Cotter, Ph.D., 2012

56. Adding
4+3=
© Joan A. Cotter, Ph.D., 2012

57. Characteristics of a Good Game
© Joan A. Cotter, Ph.D., 2012

58. Characteristics of a Good Game
• Produces learning through playing.
© Joan A. Cotter, Ph.D., 2012

59. Characteristics of a Good Game
• Produces learning through playing.
• Incorporates manipulatives.
© Joan A. Cotter, Ph.D., 2012

60. Characteristics of a Good Game
• Produces learning through playing.
• Incorporates manipulatives.
• Teaches strategies.
© Joan A. Cotter, Ph.D., 2012

61. Characteristics of a Good Game
• Produces learning through playing.
• Incorporates manipulatives.
• Teaches strategies.
• Encourages mental work.
© Joan A. Cotter, Ph.D., 2012

62. Characteristics of a Good Game
• Produces learning through playing.
• Incorporates manipulatives.
• Teaches strategies.
• Encourages mental work.
• Detects errors; provides continuous assessment.
© Joan A. Cotter, Ph.D., 2012

63. Characteristics of a Good Game
• Produces learning through playing.
• Incorporates manipulatives.
• Teaches strategies.
• Encourages mental work.
• Detects errors; provides continuous assessment.
• Is enjoyable.
© Joan A. Cotter, Ph.D., 2012

64. Go to the Dump Game
Objective:
To learn the facts that total 10:
1+9
2+8
3+7
4+6
5+5
© Joan A. Cotter, Ph.D., 2012

65. Go to the Dump Game
Objective:
To learn the facts that total 10:
1+9
2+8
3+7
4+6
5+5
Object of the game:
To collect the most pairs that equal ten.
© Joan A. Cotter, Ph.D., 2012

66. Go to the Dump Game
6+ = 10
© Joan A. Cotter, Ph.D., 2012

67. Go to the Dump Game
6+ = 10
© Joan A. Cotter, Ph.D., 2012

68. Go to the Dump Game
6 + 4 = 10
© Joan A. Cotter, Ph.D., 2012

69. Go to the Dump Game
Starting
© Joan A. Cotter, Ph.D., 2012

70. Go to the Dump Game
72 7 9 5
72 1 3 8 4 6 34 9
Starting
© Joan A. Cotter, Ph.D., 2012

71. Go to the Dump Game
72 7 9 5
72 1 3 8 4 6 34 9
Finding pairs
© Joan A. Cotter, Ph.D., 2012

72. Go to the Dump Game
72 7 9 5
72 1 3 8 4 6 34 9
Finding pairs
© Joan A. Cotter, Ph.D., 2012

73. Go to the Dump Game
72 7 9 5
72 1 3 8 4 6 34 9
Finding pairs
© Joan A. Cotter, Ph.D., 2012

74. Go to the Dump Game
72 7 9 5
4 6
72 1 3 8 34 9
Finding pairs
© Joan A. Cotter, Ph.D., 2012

75. Go to the Dump Game
72 7 9 5
4 6
72 1 3 8 34 9
Finding pairs
© Joan A. Cotter, Ph.D., 2012

76. Go to the Dump Game
72 7 9 5
4 6
72 1 3 8 34 9
Finding pairs
© Joan A. Cotter, Ph.D., 2012

77. Go to the Dump Game
72 7 9 5
7 3 4 6
2 1 8 34 9
Finding pairs
© Joan A. Cotter, Ph.D., 2012

78. Go to the Dump Game
72 7 9 5
2 8 4 6
1 34 9
Finding pairs
© Joan A. Cotter, Ph.D., 2012

79. Go to the Dump Game
72 7 9 5
2 8 4 6
1 34 9
Playing
© Joan A. Cotter, Ph.D., 2012

80. Go to the Dump Game
BlueCap, do you
have an3?
have a 3?
72 7 9 5
2 8 4 6
1 34 9
Playing
© Joan A. Cotter, Ph.D., 2012

81. Go to the Dump Game
BlueCap, do you
have an3?
have a 3?
72 7 9 5 3
2 8 4 6
1 4 9
Playing
© Joan A. Cotter, Ph.D., 2012

82. Go to the Dump Game
7 3 BlueCap, do you
have an3?
have a 3?
2 7 9 5
2 8 4 6
1 4 9
Playing
© Joan A. Cotter, Ph.D., 2012

83. Go to the Dump Game
7 3 BlueCap, do you
have an3?
have a 8?
2 7 9 5
2 8 4 6
1 4 9
Playing
© Joan A. Cotter, Ph.D., 2012

84. Go to the Dump Game
7 3 BlueCap, do you
have an3?
have a 8?
2 7 9 5
2 8 4 6
1 4 9
Go to the dump.
Playing
© Joan A. Cotter, Ph.D., 2012

85. Go to the Dump Game
7 3 BlueCap, do you
have an3?
have a 8?
2 2 7 9 5
2 8 4 6
1 4 9
Go to the dump.
Playing
© Joan A. Cotter, Ph.D., 2012

86. Go to the Dump Game
7 3
2 2 7 9 5
2 8 4 6
1 4 9
Playing
© Joan A. Cotter, Ph.D., 2012

87. Go to the Dump Game
7 3
2 2 7 9 5
2 8 4 6
1 4 9
PinkCap, do you
Playing have a 6?
© Joan A. Cotter, Ph.D., 2012

88. Go to the Dump Game
7 3
2 2 7 9 5
2 8 4 6
1 4 9
PinkCap, do you
Go to the dump.
Playing have a 6?
© Joan A. Cotter, Ph.D., 2012

89. Go to the Dump Game
7 3
2 2 7 9 5
2 8 4 6
1 5 4 9
Playing
© Joan A. Cotter, Ph.D., 2012

90. Go to the Dump Game
7 3
2 2 7 9 5
2 8 4 6
1 5 4 9
Playing
© Joan A. Cotter, Ph.D., 2012

91. Go to the Dump Game
7 3
2 2 7 9 5
2 8 4 6
1 5 4 9
YellowCap, do
you have a 9? Playing
© Joan A. Cotter, Ph.D., 2012

92. Go to the Dump Game
7 3
2 2 7 5
2 8 4 6
1 5 4 9
YellowCap, do
you have a 9? Playing
© Joan A. Cotter, Ph.D., 2012

93. Go to the Dump Game
7 3
2 2 7 5
2 8 4 6
19 5 4 9
YellowCap, do
you have a 9? Playing
© Joan A. Cotter, Ph.D., 2012

94. Go to the Dump Game
7 3
2 2 7 5
2
1 8
9 4 6
5 4 9
Playing
© Joan A. Cotter, Ph.D., 2012

95. Go to the Dump Game
7 3
2 2 7 5
2
1 8
9 4 6
2 9 1 7 7 5 4 9
Playing
© Joan A. Cotter, Ph.D., 2012

96. Go to the Dump Game
9 1
4 6 5 5
Winner?
© Joan A. Cotter, Ph.D., 2012

97. Go to the Dump Game
9
1
4
6 5
Winner?
© Joan A. Cotter, Ph.D., 2012

98. Go to the Dump Game
9
1
4
6 5
Winner?
© Joan A. Cotter, Ph.D., 2012

99. Go to the Dump Game
Play it again.
© Joan A. Cotter, Ph.D., 2012

100. Fact Strategies
© Joan A. Cotter, Ph.D., 2012

101. Fact Strategies
• A strategy is a way to learn a new fact or
recall a forgotten fact.
© Joan A. Cotter, Ph.D., 2012

102. Fact Strategies
• A strategy is a way to learn a new fact or
recall a forgotten fact.
• A visualizable representation is part of a
powerful strategy.
© Joan A. Cotter, Ph.D., 2012

103. Fact Strategies
Complete the Ten
9+5=
© Joan A. Cotter, Ph.D., 2012

104. Fact Strategies
Complete the Ten
9+5=
© Joan A. Cotter, Ph.D., 2012

105. Fact Strategies
Complete the Ten
9+5=
© Joan A. Cotter, Ph.D., 2012

106. Fact Strategies
Complete the Ten
9+5=
Take 1 from
the 5 and give
it to the 9.
© Joan A. Cotter, Ph.D., 2012

107. Fact Strategies
Complete the Ten
9+5=
Take 1 from
the 5 and give
it to the 9.
© Joan A. Cotter, Ph.D., 2012

108. Fact Strategies
Complete the Ten
9+5=
Take 1 from
the 5 and give
it to the 9.
© Joan A. Cotter, Ph.D., 2012

109. Fact Strategies
Complete the Ten
9 + 5 = 14
Take 1 from
the 5 and give
it to the 9.
© Joan A. Cotter, Ph.D., 2012

110. Fact Strategies
Two Fives
8+6=
© Joan A. Cotter, Ph.D., 2012

111. Fact Strategies
Two Fives
8+6=
© Joan A. Cotter, Ph.D., 2012

112. Fact Strategies
Two Fives
8+6=
© Joan A. Cotter, Ph.D., 2012

113. Fact Strategies
Two Fives
8+6=
© Joan A. Cotter, Ph.D., 2012

114. Fact Strategies
Two Fives
8+6=
10 + 4 = 14
© Joan A. Cotter, Ph.D., 2012

115. Fact Strategies
Two Fives
7+5=
© Joan A. Cotter, Ph.D., 2012

116. Fact Strategies
Two Fives
7+5=
© Joan A. Cotter, Ph.D., 2012

117. Fact Strategies
Two Fives
7 + 5 = 12
© Joan A. Cotter, Ph.D., 2012

118. Fact Strategies
Going Down
15 – 9 =
© Joan A. Cotter, Ph.D., 2012

119. Fact Strategies
Going Down
15 – 9 =
© Joan A. Cotter, Ph.D., 2012

120. Fact Strategies
Going Down
15 – 9 =
Subtract 5;
then 4.
© Joan A. Cotter, Ph.D., 2012

121. Fact Strategies
Going Down
15 – 9 =
Subtract 5;
then 4.
© Joan A. Cotter, Ph.D., 2012

122. Fact Strategies
Going Down
15 – 9 =
Subtract 5;
then 4.
© Joan A. Cotter, Ph.D., 2012

123. Fact Strategies
Going Down
15 – 9 = 6
Subtract 5;
then 4.
© Joan A. Cotter, Ph.D., 2012

124. Fact Strategies
Subtract from 10
15 – 9 =
© Joan A. Cotter, Ph.D., 2012

125. Fact Strategies
Subtract from 10
15 – 9 =
Subtract 9
from 10.
© Joan A. Cotter, Ph.D., 2012

126. Fact Strategies
Subtract from 10
15 – 9 =
Subtract 9
from 10.
© Joan A. Cotter, Ph.D., 2012

127. Fact Strategies
Subtract from 10
15 – 9 =
Subtract 9
from 10.
© Joan A. Cotter, Ph.D., 2012

128. Fact Strategies
Subtract from 10
15 – 9 = 6
Subtract 9
from 10.
© Joan A. Cotter, Ph.D., 2012

129. Fact Strategies
Going Up
15 – 9 =
© Joan A. Cotter, Ph.D., 2012

130. Fact Strategies
Going Up
15 – 9 =
Start with 9;
go up to 15.
© Joan A. Cotter, Ph.D., 2012

131. Fact Strategies
Going Up
15 – 9 =
Start with 9;
go up to 15.
© Joan A. Cotter, Ph.D., 2012

132. Fact Strategies
Going Up
15 – 9 =
Start with 9;
go up to 15.
© Joan A. Cotter, Ph.D., 2012

133. Fact Strategies
Going Up
15 – 9 =
Start with 9;
go up to 15.
© Joan A. Cotter, Ph.D., 2012

134. Fact Strategies
Going Up
15 – 9 =
1+5=6
Start with 9;
go up to 15.
© Joan A. Cotter, Ph.D., 2012

135. Rows and Columns Game
Objective:
To find a total of 15 by adding 2, 3, or 4
cards in row or column.
© Joan A. Cotter, Ph.D., 2012

136. Rows and Columns Game
Objective:
To find a total of 15 by adding 2, 3, or 4
cards in row or column.
Object of the game:
To collect the most cards.
© Joan A. Cotter, Ph.D., 2012

137. Rows and Columns Game
8 7 1 9
6 4 3 3
2 2 5 6
6 3 8 8
© Joan A. Cotter, Ph.D., 2012

138. Rows and Columns Game
8 7 1 9
6 4 3 3
2 2 5 6
6 3 8 8
© Joan A. Cotter, Ph.D., 2012

139. Rows and Columns Game
8 7 1 9
6 4 3 3
2 2 5 6
6 3 8 8
© Joan A. Cotter, Ph.D., 2012

140. Rows and Columns Game
1 9
6 4 3 3
6 3 8 8
© Joan A. Cotter, Ph.D., 2012

141. Rows and Columns Game
7 6 1 9
6 4 3 3
2 1 5 1
6 3 8 8
© Joan A. Cotter, Ph.D., 2012

142. Rows and Columns Game
7 6 1 9
6 4 3 3
2 1 5 1
6 3 8 8
© Joan A. Cotter, Ph.D., 2012

143. Rows and Columns Game
7 6 1 9
6 4 3 3
2 1 5 1
6 3 8 8
© Joan A. Cotter, Ph.D., 2012

144. Rows and Columns Game
1
6 4 3 3
1 5 1
3 8 8
© Joan A. Cotter, Ph.D., 2012

145. Rows and Columns Game
© Joan A. Cotter, Ph.D., 2012

146. Multiplication Strategies
Basic facts
© Joan A. Cotter, Ph.D., 2012

147. Multiplication Strategies
Basic facts
6× 4=
(6 taken 4 times)
© Joan A. Cotter, Ph.D., 2012

148. Multiplication Strategies
Basic facts
6× 4=
(6 taken 4 times)
© Joan A. Cotter, Ph.D., 2012

149. Multiplication Strategies
Basic facts
6× 4=
(6 taken 4 times)
© Joan A. Cotter, Ph.D., 2012

150. Multiplication Strategies
Basic facts
6× 4=
(6 taken 4 times)
© Joan A. Cotter, Ph.D., 2012

151. Multiplication Strategies
Basic facts
6× 4=
(6 taken 4 times)
© Joan A. Cotter, Ph.D., 2012

152. Multiplication Strategies
Basic facts
9× 3=
© Joan A. Cotter, Ph.D., 2012

153. Multiplication Strategies
Basic facts
9× 3=
© Joan A. Cotter, Ph.D., 2012

154. Multiplication Strategies
Basic facts
9× 3=
30
© Joan A. Cotter, Ph.D., 2012

155. Multiplication Strategies
Basic facts
9× 3=
30 – 3 = 27
© Joan A. Cotter, Ph.D., 2012

156. Multiplication Strategies
Basic facts
4× 8=
© Joan A. Cotter, Ph.D., 2012

157. Multiplication Strategies
Basic facts
4× 8=
© Joan A. Cotter, Ph.D., 2012

158. Multiplication Strategies
Basic facts
4× 8=
© Joan A. Cotter, Ph.D., 2012

159. Multiplication Strategies
Basic facts
4× 8=
20 + 12 = 32
© Joan A. Cotter, Ph.D., 2012

160. Multiplication Strategies
Basic facts
7× 7=
© Joan A. Cotter, Ph.D., 2012

161. Multiplication Strategies
Basic facts
7× 7=
© Joan A. Cotter, Ph.D., 2012

162. Multiplication Strategies
Basic facts
7× 7=
25
© Joan A. Cotter, Ph.D., 2012

163. Multiplication Strategies
Basic facts
7× 7=
25 + 10 + 10
© Joan A. Cotter, Ph.D., 2012

164. Multiplication Strategies
Basic facts
7× 7=
25 + 10 + 10
+ 4 = 49
© Joan A. Cotter, Ph.D., 2012

165. Multiples Patterns
Twos
2 4 6 8 10
12 14 16 18 20
© Joan A. Cotter, Ph.D., 2012

166. Multiples Patterns
Twos
2 4 6 8 10
12 14 16 18 20
The ones repeat in the second row.
© Joan A. Cotter, Ph.D., 2012

167. Multiples Patterns
Fours
4 8 12 16 20
24 28 32 36 40
The ones repeat in the second row.
© Joan A. Cotter, Ph.D., 2012

168. Multiples Patterns
Sixes and Eights
6 12 18 24 30
36 42 48 54 60
8 16 24 32 40
48 56 64 72 80
© Joan A. Cotter, Ph.D., 2012

169. Multiples Patterns
Sixes and Eights
6 12 18 24 30
36 42 48 54 60
8 16 24 32 40
48 56 64 72 80
© Joan A. Cotter, Ph.D., 2012

170. Multiples Patterns
Sixes and Eights
6 12 18 24 30
36 42 48 54 60
8 16 24 32 40
48 56 64 72 80
© Joan A. Cotter, Ph.D., 2012

171. Multiples Patterns
Sixes and Eights
6 12 18 24 30
36 42 48 54 60
8 16 24 32 40
48 56 64 72 80
The ones in the 8s show the multiples of 2.
© Joan A. Cotter, Ph.D., 2012

172. Multiples Patterns
Sixes and Eights
6 12 18 24 30
36 42 48 54 60
8 16 24 32 40
48 56 64 72 80
The ones in the 8s show the multiples of 2.
© Joan A. Cotter, Ph.D., 2012

173. Multiples Patterns
Sixes and Eights
6 12 18 24 30
36 42 48 54 60
8 16 24 32 40
48 56 64 72 80
The ones in the 8s show the multiples of 2.
© Joan A. Cotter, Ph.D., 2012

174. Multiples Patterns
Sixes and Eights
6 12 18 24 30
36 42 48 54 60
8 16 24 32 40
48 56 64 72 80
The ones in the 8s show the multiples of 2.
© Joan A. Cotter, Ph.D., 2012

175. Multiples Patterns
Sixes and Eights
6 12 18 24 30
36 42 48 54 60
8 16 24 32 40
48 56 64 72 80
The ones in the 8s show the multiples of 2.
© Joan A. Cotter, Ph.D., 2012

176. Multiples Patterns
Sixes and Eights
6 12 18 24 30 6× 4
36 42 48 54 60
8 16 24 32 40
48 56 64 72 80
6 × 4 is the fourth number (multiple).
© Joan A. Cotter, Ph.D., 2012

177. Multiples Patterns
Sixes and Eights
6 12 18 24 30
36 42 48 54 60
8 16 24 32 40
48 56 64 72 80 8× 7
8 × 7 is the seventh number (multiple).
© Joan A. Cotter, Ph.D., 2012

178. Multiples Patterns
Nines
9 18 27 36 45
90 81 72 63 54
The second row is written in reverse order.
Also the digits in each number add to 9.
© Joan A. Cotter, Ph.D., 2012

179. Multiples Patterns
Threes
3 6 9
2 15 18
21 24 27
30
The 3s have several patterns:
Observe the ones.
© Joan A. Cotter, Ph.D., 2012

180. Multiples Patterns
Threes
3 6 9
2 15 18
21 24 27
30
The 3s have several patterns:
Observe the ones.
© Joan A. Cotter, Ph.D., 2012

181. Multiples Patterns
Threes
3 6 9
2 15 18
21 24 27
30
The 3s have several patterns:
Observe the ones.
© Joan A. Cotter, Ph.D., 2012

182. Multiples Patterns
Threes
3 6 9
12 15 18
21 24 27
30
The 3s have several patterns:
Observe the ones.
© Joan A. Cotter, Ph.D., 2012

183. Multiples Patterns
Threes
3 6 9
12 15 18
21 24 27
30
The 3s have several patterns:
Observe the ones.
© Joan A. Cotter, Ph.D., 2012

184. Multiples Patterns
Threes
3 6 9
12 15 18
21 24 27
30
The 3s have several patterns:
Observe the ones.
© Joan A. Cotter, Ph.D., 2012

185. Multiples Patterns
Threes
3 6 9
12 15 18
21 24 27
30
The 3s have several patterns:
Observe the ones.
© Joan A. Cotter, Ph.D., 2012

186. Multiples Patterns
Threes
3 6 9
12 15 18
21 24 27
30
The 3s have several patterns:
Observe the ones.
© Joan A. Cotter, Ph.D., 2012

187. Multiples Patterns
Threes
3 6 9
12 15 18
21 24 27
30
The 3s have several patterns:
Observe the ones.
© Joan A. Cotter, Ph.D., 2012

188. Multiples Patterns
Threes
3 6 9
12 15 18
21 24 27
30
The 3s have several patterns:
Observe the ones.
© Joan A. Cotter, Ph.D., 2012

189. Multiples Patterns
Threes
3 6 9
12 15 18
21 24 27
30
The 3s have several patterns:
Observe the ones.
© Joan A. Cotter, Ph.D., 2012

190. Multiples Patterns
Threes
3 6 9
12 15 18
21 24 27
30
The 3s have several patterns:
The tens are the same in each row.
© Joan A. Cotter, Ph.D., 2012

191. Multiples Patterns
Threes
3 6 9
12 15 18
21 24 27
30
The 3s have several patterns:
Add the digits in the columns.
© Joan A. Cotter, Ph.D., 2012

192. Multiples Patterns
Threes
3 6 9
12 15 18
21 24 27
30
The 3s have several patterns:
Add the digits in the columns.
© Joan A. Cotter, Ph.D., 2012

193. Multiples Patterns
Threes
3 6 9
12 15 18
21 24 27
30
The 3s have several patterns:
Add the digits in the columns.
© Joan A. Cotter, Ph.D., 2012

194. Multiples Patterns
Threes
3 6 9
12 15 18
21 24 27
30
The 3s have several patterns:
Add the “opposites.”
© Joan A. Cotter, Ph.D., 2012

195. Multiples Patterns
Threes
3 6 9
12 15 18
21 24 27
30
The 3s have several patterns:
Add the “opposites.”
© Joan A. Cotter, Ph.D., 2012

196. Multiples Patterns
Threes
3 6 9
12 15 18
21 24 27
30
The 3s have several patterns:
Add the “opposites.”
© Joan A. Cotter, Ph.D., 2012

197. Multiples Patterns
Threes
3 6 9
12 15 18
21 24 27
30
The 3s have several patterns:
Add the “opposites.”
© Joan A. Cotter, Ph.D., 2012

198. Multiples Patterns
Sevens
7 14 21
28 35 42
49 56 63
70
The 7s have the 1, 2, 3… pattern.
© Joan A. Cotter, Ph.D., 2012

199. Multiples Patterns
Sevens
7 14 21
28 35 42
49 56 63
70
The 7s have the 1, 2, 3… pattern.
© Joan A. Cotter, Ph.D., 2012

200. Multiples Patterns
Sevens
7 14 21
28 35 42
49 56 63
70
The 7s have the 1, 2, 3… pattern.
© Joan A. Cotter, Ph.D., 2012

201. Multiples Patterns
Sevens
7 14 21
28 35 42
49 56 63
70
The 7s have the 1, 2, 3… pattern.
© Joan A. Cotter, Ph.D., 2012

202. Multiples Patterns
Sevens
7 14 21
28 35 42
49 56 63
70
Look at the tens.
© Joan A. Cotter, Ph.D., 2012

203. Multiples Patterns
Sevens
7 14 21
28 35 42
49 56 63
70
Look at the tens.
© Joan A. Cotter, Ph.D., 2012

204. Multiples Patterns
Sevens
7 14 21
28 35 42
49 56 63
70
Look at the tens.
© Joan A. Cotter, Ph.D., 2012

205. Multiples Memory
© Joan A. Cotter, Ph.D., 2012

206. Multiples Memory
Objective:
To help the players learn the
multiples patterns.
© Joan A. Cotter, Ph.D., 2012

207. Multiples Memory
Objective:
To help the players learn the multiples patterns.
Object of the game:
To be the first player to collect all ten
cards of a multiple in order.
© Joan A. Cotter, Ph.D., 2012

208. Multiples Memory
7 14 21
28 35 42
49 56 63
70
The 7s envelope contains 10 cards,
each with one of the numbers listed.
© Joan A. Cotter, Ph.D., 2012

209. Multiples Memory
8 16 24 32 40
48 56 64 72 80
The 8s envelope contains 10 cards,
each with one of the numbers listed.
© Joan A. Cotter, Ph.D., 2012

210. Multiples Memory
7 14 21
28 35 42 8 16 24 32 40
49 56 63 48 56 64 72 80
70
7 14 21 8 16 24 32 40
28 35 42 48 56 64 72 80
49 56 63
70
© Joan A. Cotter, Ph.D., 2012

211. Multiples Memory
7 14 21
28 35 42 8 16 24 32 40
49 56 63 48 56 64 72 80
70
7 14 21 8 16 24 32 40
28 35 42 48 56 64 72 80
49 56 63
70
© Joan A. Cotter, Ph.D., 2012

212. Multiples Memory
7 14 21
28 35 42
49 56 63
70
7 14 21 8 16 24 32 40
28 35 42 48 56 64 72 80
49 56 63
70
© Joan A. Cotter, Ph.D., 2012

213. Multiples Memory
7 14 21
28 35 42
49 56 63
70
7 14 21 8 16 24 32 40
28 35 42 48 56 64 72 80
49 56 63 14
70
© Joan A. Cotter, Ph.D., 2012

214. Multiples Memory
7 14 21
28 35 42
49 56 63
70
7 14 21 8 16 24 32 40
28 35 42 48 56 64 72 80
49 56 63
70
© Joan A. Cotter, Ph.D., 2012

215. Multiples Memory
8 16 24 32 40
48 56 64 72 80
7 14 21 8 16 24 32 40
28 35 42 48 56 64 72 80
49 56 63
70
© Joan A. Cotter, Ph.D., 2012

216. Multiples Memory
8 16 24 32 40
48 56 64 72 80
7 14 21 8 16 24 32 40
28 35 42 48 56 64 72 80
49 56 63
70
40
© Joan A. Cotter, Ph.D., 2012

217. Multiples Memory
8 16 24 32 40
48 56 64 72 80
7 14 21 8 16 24 32 40
28 35 42 48 56 64 72 80
49 56 63
70
© Joan A. Cotter, Ph.D., 2012

218. Multiples Memory
7 14 21
28 35 42
49 56 63
70
7 14 21 8 16 24 32 40
28 35 42 48 56 64 72 80
49 56 63
70
© Joan A. Cotter, Ph.D., 2012

219. Multiples Memory
7 14 21
28 35 42
49 56 63
70
7 14 21 8 16 24 32 40
28 35 42 48 56 64 72 80
49 56 63
70
8
© Joan A. Cotter, Ph.D., 2012

220. Multiples Memory
7 14 21
28 35 42
49 56 63
70
7 14 21 8 16 24 32 40
28 35 42 48 56 64 72 80
49 56 63
70
© Joan A. Cotter, Ph.D., 2012

221. Multiples Memory
8 16 24 32 40
48 56 64 72 80
7 14 21 8 16 24 32 40
28 35 42 48 56 64 72 80
49 56 63
70
© Joan A. Cotter, Ph.D., 2012

222. Multiples Memory
8 16 24 32 40
48 56 64 72 80
7 14 21 8 16 24 32 40
28 35 42 48 56 64 72 80
49 56 63
70
8
© Joan A. Cotter, Ph.D., 2012

223. Multiples Memory
8 16 24 32 40
48 56 64 72 80
7 14 21 8 16 24 32 40
28 35 42 48 56 64 72 80
49 56 63
70 8
© Joan A. Cotter, Ph.D., 2012

224. Multiples Memory
8 16 24 32 40
48 56 64 72 80
7 14 21 8 16 24 32 40
28 35 42 48 56 64 72 80
49 56 63 56
70 8
© Joan A. Cotter, Ph.D., 2012

225. Multiples Memory
8 16 24 32 40
48 56 64 72 80
7 14 21 8 16 24 32 40
28 35 42 48 56 64 72 80
49 56 63
70 8
© Joan A. Cotter, Ph.D., 2012

226. Multiples Memory
7 14 21
28 35 42
49 56 63
70
7 14 21 8 16 24 32 40
28 35 42 48 56 64 72 80
49 56 63
70 8
© Joan A. Cotter, Ph.D., 2012

227. Multiples Memory
7 14 21
28 35 42
49 56 63
70
7
7 14 21 8 16 24 32 40
28 35 42 48 56 64 72 80
49 56 63
70 8
© Joan A. Cotter, Ph.D., 2012

228. Multiples Memory
7 14 21
28 35 42
49 56 63
70
7 14 21 8 16 24 32 40
28 35 42 48 56 64 72 80
49 56 63
70 8
7
© Joan A. Cotter, Ph.D., 2012

229. Multiples Memory
7 14 21
28 35 42
49 56 63
70
7 14 21 8 16 24 32 40
28 35 42 48 56 64 72 80
49 56 63 14
70 8
7
© Joan A. Cotter, Ph.D., 2012

230. Multiples Memory
7 14 21
28 35 42
49 56 63
70
7 14 21 8 16 24 32 40
28 35 42 48 56 64 72 80
49 56 63
70 8
7 14
© Joan A. Cotter, Ph.D., 2012

231. Multiples Memory
7 14 21
28 35 42
49 56 63
70
24
7 14 21 8 16 24 32 40
28 35 42 48 56 64 72 80
49 56 63
70 8
7 14
© Joan A. Cotter, Ph.D., 2012

232. Multiples Memory
7 14 21
28 35 42 8 16 24 32 40
49 56 63 48 56 64 72 80
70
7 14 21 8 16 24 32 40
28 35 42 48 56 64 72 80
49 56 63
70 8
7 14
© Joan A. Cotter, Ph.D., 2012

233. Multiples Memory
7 14 21
28 35 42 8 16 24 32 40
49 56 63 48 56 64 72 80
70
7 14 21 8 16 24 32 40
28 35 42 48 56 64 72 80
49 56 63
70
© Joan A. Cotter, Ph.D., 2012

234. Multiplication Memory
Objective:
To help the players master the
multiplication facts.
© Joan A. Cotter, Ph.D., 2012

235. Multiplication Memory
Objective:
To help the players master the
multiplication facts.
Object of the game:
To collect the most cards by matching
the multiplier with the product.
© Joan A. Cotter, Ph.D., 2012

236. Multiplication Memory
Materials Needed:
© Joan A. Cotter, Ph.D., 2012

237. Multiplication Memory
1 2 3 4 5
6 7 8 9 10
Materials Needed:
• Ten basic cards, numbered 1 to 10
© Joan A. Cotter, Ph.D., 2012

238. Multiplication Memory
3
1 2 3 4 5
3 6 9
12 15 18
6 7 8 9 10 21 24 27
30
Materials Needed:
• Ten basic cards, numbered 1 to 10
• A set of product cards (3s used here)
© Joan A. Cotter, Ph.D., 2012

239. Multiplication Memory
3
1 2 3 4 5 3x
3 6 9
12 15 18
6 7 8 9 10 21 24 27
30
Materials Needed:
• Ten basic cards, numbered 1 to 10
• A set of product cards (3s used here)
• A stickie note with “3 x” written on it
© Joan A. Cotter, Ph.D., 2012

240. Multiplication Memory
3
1 2 3 4 5 3x
3 6 9
12 15 18
6 7 8 9 10 21 24 27
30 =
Materials Needed:
• Ten basic cards, numbered 1 to 10
• A set of product cards (3s used here)
• A stickie with “3 x” written on it
• A stickie with “=” written on it
© Joan A. Cotter, Ph.D., 2012

241. Multiplication Memory
3
1 2 3 4 5 3x
3 6 9
12 15 18
6 7 8 9 10 21 24 27
30 =
Materials Needed:
• Ten basic cards, numbered 1 to 10
• A set of product cards (3s used here)
• A stickie with “3 x” written on it
• A stickie with “=” written on it
• A manipulative with groups of five
© Joan A. Cotter, Ph.D., 2012

242. Multiplication Memory
3x =
3 6 9
12 15 18
21 24 27
30
© Joan A. Cotter, Ph.D., 2012

243. Multiplication Memory
3x =
3 6 9
12 15 18
21 24 27
30
© Joan A. Cotter, Ph.D., 2012

244. Multiplication Memory
5
3x =
3 6 9
12 15 18
21 24 27
30
© Joan A. Cotter, Ph.D., 2012

245. Multiplication Memory
5
3x =
3 6 9
12 15 18
21 24 27
30
© Joan A. Cotter, Ph.D., 2012

246. Multiplication Memory
5
3x =
3 6 9
12 15 18
21 24 27
30
© Joan A. Cotter, Ph.D., 2012

247. Multiplication Memory
5
3x =
3 taken 5 times
equals 15.
3 6 9
12 15 18
21 24 27
30
© Joan A. Cotter, Ph.D., 2012

248. Multiplication Memory
5 21
3x =
3 taken 5 times
equals 15.
3 6 9
12 15 18
21 24 27
30
© Joan A. Cotter, Ph.D., 2012

249. Multiplication Memory
3x =
3 6 9
12 15 18
21 24 27
30
© Joan A. Cotter, Ph.D., 2012

250. Multiplication Memory
3x =
3 6 9
12 15 18
21 24 27
30
© Joan A. Cotter, Ph.D., 2012

251. Multiplication Memory
3x =
7
3 6 9
12 15 18
21 24 27
30
© Joan A. Cotter, Ph.D., 2012

252. Multiplication Memory
3x =
7
3 6 9
12 15 18
21 24 27
30
© Joan A. Cotter, Ph.D., 2012

253. Multiplication Memory
3x =
7
3 6 9
12 15 18
21 24 27
30
© Joan A. Cotter, Ph.D., 2012

254. Multiplication Memory
3x =
7
3 taken 7 times
equals 21.
3 6 9
12 15 18
21 24 27
30
© Joan A. Cotter, Ph.D., 2012

255. Multiplication Memory
21
3x =
7
3 taken 7 times
equals 21.
3 6 9
12 15 18
21 24 27
30
© Joan A. Cotter, Ph.D., 2012

256. Multiplication Memory
3x =
3 taken 7 times
equals 21.
3 6 9
12 15 18 7 21
21 24 27
30
© Joan A. Cotter, Ph.D., 2012

257. Multiplication Memory
3x =
2
3 6 9
12 15 18 7 21
21 24 27
30
© Joan A. Cotter, Ph.D., 2012

258. Multiplication Memory
3x =
2
3
3 6 9
12 15 18 7 21
21 24 27
30
© Joan A. Cotter, Ph.D., 2012

259. Multiplication Memory
3x =
2
3
3 6 9
12 15 18 7 21
21 24 27
30
© Joan A. Cotter, Ph.D., 2012

260. Multiplication Memory
3x =
2
3
3 taken 3 times
equals 9.
3 6 9
12 15 18 7 21
21 24 27
30
© Joan A. Cotter, Ph.D., 2012

261. Multiplication Memory
3x =
2
3 12
3 taken 3 times
equals 9.
3 6 9
12 15 18 7 21
21 24 27
30
© Joan A. Cotter, Ph.D., 2012

262. Multiplication Memory
3x =
3 6 9
12 15 18 7 21
21 24 27
30
© Joan A. Cotter, Ph.D., 2012

263. Multiplication Memory
3x =
3 6 9
12 15 18 7 21
21 24 27
30
© Joan A. Cotter, Ph.D., 2012

264. Multiplication Memory
5
3x =
3 6 9
12 15 18 7 21
21 24 27
30
© Joan A. Cotter, Ph.D., 2012

265. Multiplication Memory
5
3x =
3 6 9
12 15 18 7 21
21 24 27
30
© Joan A. Cotter, Ph.D., 2012

266. Multiplication Memory
5
3x =
3 taken 5 times
equals 15.
3 6 9
12 15 18 7 21
21 24 27
30
© Joan A. Cotter, Ph.D., 2012

267. Multiplication Memory
5
3x =
15
3 taken 5 times
equals 15.
3 6 9
12 15 18 7 21
21 24 27
30
© Joan A. Cotter, Ph.D., 2012

268. Multiplication Memory
3x =
3 taken 5 times
equals 15.
5 15
3 6 9
12 15 18 7 21
21 24 27
30
© Joan A. Cotter, Ph.D., 2012

269. Multiplication Memory
3x =
5 15
3 6 9
12 15 18 7 21
21 24 27
30
© Joan A. Cotter, Ph.D., 2012

270. Multiplication Memory
3x =
8 24
3 6 9
12 15 18 1 3
21 24 27
30
© Joan A. Cotter, Ph.D., 2012

271. Framing the Future of Mathematics in
Minnesota
Math in Minnesota starts with the youngest.
Let’s build on their natural ability to subitize.
Keep joy in math; use games, not flash cards.
Help them to use their minds to visualize.
© Joan A. Cotter, Ph.D., 2012

272. Teaching the Arithmetic Facts Using
Strategies and Games
by Joan A. Cotter, Ph.D.
JoanCotter@RightStartMath.com
MCTM
May 4, 2012
Duluth, Minnesota
7 3 8 16 24 32 40
PowerPoint Presentation & Handout
RightStartMath.com >Resources © Joan A. Cotter, Ph.D., 2012