Post on 20-Jan-2016
Belize Revised Curriculum
Patterns and Pre-Algebra
Infant 1 – Standard 1
1
Why Teach Patterns and Pre-Algebra?
Simple Patterns Are Everywhere
There Are Different Types of Patterns—Numerical/Non-numerical
The Same Pattern Can Be Expressed in Different Ways
There Are Different Types of Patterns—Repeating and Increasing/Decreasing
Pattern Rules Generalize Relationships
Equations Express Relationships Between Numbers
Agenda
2
Why Teach Patterns and Pre-Algebra?
Working with patterns enables students to make connections both within and
beyond mathematics.
Through the study of patterns, students come to interpret their world mathematically and value
mathematics as a useful tool.
3
Why Teach Patterns and Pre-Algebra?
By generalizing patterns, students develop strategies that can be used to solve a wide range of problems.
Mathematics is seen as reasoning rather than solving one unrelated problem after another.
10
Exploring patterns and pre-algebra in elementary school lays the foundation for the study of formal algebra. Rather than a
new topic, algebra becomes a natural extension of the elementary curriculum
and is often defined as generalized arithmetic and geometry.3 + = 5
4
• Think for 20 seconds
• Write and draw silently for 60 seconds
• Switch papers with another table
• Start again
5
Learning Task - Predictable Stories
Note: From Crystal Cochrane, St. Leo Catholic Elementary School, Grade 1, Edmonton, AB, 2006. 6
Infant 1 – actions, sound, colour, size, shape, orientation
Infant 2 – add diagrams and events
Standard 1 – focus on attributes and numbers
Standard 2 – expressed as concrete, pictorial, symbolic
7
Learning Tasks
Chairs
8
Pattern Puzzles
•Select an attribute card
•Make a core unit with 3–5 elements, using this attribute
(big, big, small)
(square, triangle, triangle)
(yellow, blue, red)
•Repeat the pattern 2 more times
•Ask your partner to describe your pattern
Learning Tasks
9
Non-numerical patterns can be translated into a letter code (ABBA)
and then extended to make predictions and solve problems.
A AB B
10
Learning Tasks – Translating Patterns
Mix and Match
•Create a 2- to 4-element core, using your choice of materials; e.g., colour, orientation, size.
•Extend your pattern 2 more times.
•Find someone else in the room with the same pattern code.
These are both AABB patterns.
11
Patterns can be repeating and made up of a core set of elements—a core unit that is iterated.
Patterns can be increasing or decreasing and created by orderly change.
9 7 5 3
32 16 8 4 212
Learning Tasks – Repeating Patterns
Cyclical Patterns
14
Learning Tasks
5
2 31
10 15
30 31 322515105 20
2 322717127 22
30 32 33 34 352515105 20
What would the 32nd shape be?
17
Learning Tasks
5
2 31
10 15
a) Create a pattern in which the 20th shape is a .b) Create a pattern in which the 12th shape is a .c) Create a pattern in which the 6th and 9th shapes are both .
Your Turn
18
Pattern rules reveal mathematical relationships.
Pattern rules describe how a pattern grows and can be used to make logical predictions.
What changes?
What stays the same?
24
A pattern rule must account for all elements of a pattern, including the first one.
Body Parts 4 7 10 13 ? ? ?
Age 1 2 3 4 5 10 100
Body parts: Start at 4 and add 3 each time
Age: Start at 1 and add 1 each time
Relationship: Body parts—3 times the age plus 125
26
Two of Everything by Lily Toy HongIllustrations on slides 27 to 36 and text on slides 28 to 34 are reproduced from Two of Everything by Lily Toy Hong. Copyright ©1993 by Lily Toy Hong. Excerpts reprinted by permission of Albert Whitman & Company. All rights reserved. 27
28
29
30
31
32
33
34
35
Would you rather have a doubling pot and a dollar coin, if you could only use the pot ten times, or…$1
000?Note: Excerpted and reprinted with permission from National Council of Teachers of Mathematics. (2003). Reflections. Retrieved November 20, 2006, from http://my.nctm.org/eresources/reflections, copyright 2003 by the National Council of Teachers of Mathematics. All rights reserved.
Create your own magic pot. Make up a pattern rule for your pot. Show
what happens on an in-out chart.Note: Adapted from Lessons for Algebraic Thinking: Grades K–2, by Leyani von Rotz and Marilyn Burns. Copyright © 2002 by Math Solutions Publications.
36
3 + 2 = 5
Equality (=) expresses a relationship of balance between numbers.
Inequality () expresses a relationship of imbalance.
3 + 1 ≠ 5
37
What do elementary
students think the equal sign
means?
38
Note: Excerpted and reprinted with permission from Fennel, F., & Rowan, T. (January 2001). Representation: An Important Process for Teaching and Learning Mathematics. Teaching Children Mathematics, 7(5), 288–292, copyright 2001 by the National Council of Teachers of Mathematics. All rights reserved.
39
Equality and inequality between quantities can be considered as:
• whole to whole relationships (5 = 5)• part–part to whole relationships (3 + 5 = 8)• whole to part–part relationships (8 = 5 + 3)• part–part to part–part relationships (4 + 4 = 3 + 5).
40
7 12 1712 and
17Other
Grades 1 and 2 5% 58% 13% 8% 16%
Grades 3 and 4 9% 49% 25% 10% 7%
Grades 5 and 6 2% 76% 21% 1% 0%
8 + 4 = + 5
Note: From Thinking Mathematically: Integrating Arithmetic & Algebra in Elementary School (p. 4), by T. P. Carpenter, M. L. Franke and L. Levi, 2003, Portsmouth, NH: Heinemann. Copyright 2003 by the authors. Reprinted with permission.
• The answer comes next: 8 + 4 = 12 + 5• Use all the numbers (overgeneralizing associative property): 8 + 4 = 17 + 5• Extending the problem: 8 + 4 = 12 + 5 = 17
41
Robin: Second-grade student
18 + 27 = + 29
“Twenty-nine is 2 more than 27, so the number in the box has to be 2 less than 18 to make the 2 sides equal. So it’s 16.”
Note: From Thinking Mathematically: Integrating Arithmetic & Algebra in Elementary School (p. 4), by T. P. Carpenter, M. L. Franke and L. Levi, 2003, Portsmouth, NH: Heinemann. Copyright 2003 by the authors. Reprinted with permission.
42
Mini Lessons – True/False
3 + 5 = 88 = 3 + 58 = 83 + 5 = 5 + 33 + 5 = 4 + 4
Developing an understanding of
the equal sign
Note: From Thinking Mathematically: Integrating Arithmetic & Algebra in Elementary School (p. 4), by T. P. Carpenter, M. L. Franke and L. Levi, 2003, Portsmouth, NH: Heinemann. Copyright 2003 by the authors. Reprinted with permission.
45
Other True/False Contexts
9 + 5 = 149 + 5 = 14 + 09 + 5 = 0 + 149 + 5 = 14 + 19 + 5 = 13 + 1
Using zero to introduce part-part = part-part
equations
How could you change the false statements so that they are true?
Place Value
56 = 50 + 687 = 7 + 8093 = 9 + 3094 = 80 + 1494 = 70 + 24
46
Very Able To Do Variables
+ = 12
+ = 12
+ = 129
+ = 12948
Join
Result Unknown
Connie had 15 marbles. Juan gave her 28 more marbles. How many marbles does Connie have altogether?
Change Unknown
Connie has 15 marbles. How many more marbles does she need to have 43 marbles altogether?
Start Unknown
Connie had some marbles. Juan gave her 15 more marbles. Now she has 43 marbles. How many marbles did Connie have to start with?
Separate
Connie had 43 marbles. She gave 15 to Juan. How many marbles does Connie have left?
Connie had 43 marbles. She gave some to Juan. Now she has 15 marbles left. How many marbles did Connie give to Juan?
Connie had some marbles. She gave 15 to Juan. Now she has 28 marbles left. How many marbles did Connie have to start with?
49
Learning Tasks – What’s In the Bag?
50
Learning Tasks – What’s In the Bag?
51
Equalization and
Compare
Difference Unknown
Connie has 43 marbles. Juan has 15 marbles. How many more marbles does Connie have than Juan? (Compare)How many more marbles does Juan need to have as many as Connie? (Equalize)
Quantity Unknown
Juan has 15 marbles. Connie has 28 more than Juan. How many marbles does Connie have?
Referent Unknown
Connie has 43 marbles. She has 15 more marbles than Juan. How many marbles does Juan have?
Part-Part-Whole
Quantity Unknown
Connie has 15 red marbles and 28 blue marbles. How many marbles does she have?
Part Unknown
Connie has 43 marbles. 15 are red and the rest are blue. How many blue marbles does Connie have?
52
Mini Lessons – Open Number Sentences
The teacher writes an open-number sentence on the board and asks the students how to make the statement true. Students can justify
their responses; e.g., using balance models, comparing distances on a number line.
3 + 5 = 8 = 3 + 8 = 3 + 5 = + 33 + 5 = + 4
53
Each problem that I solved became a rule which served afterwards
to solve other problems.
René Descartes
55
Lesson Planning
• Take the grade that you are going to teach and create a lesson plan for patterns and pre-algebra. Some of the tasks we did today could be incorporated into your lesson plan.