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Standard 4.3 Patterns and Algebra |
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Big Idea Algebra provides language through which we communicate the patterns in mathematics. |
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4.3.7 A. Patterns |
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Descriptive Statement: Algebra provides the language through which we communicate the patterns in mathematics. From the earliest age, students should be encouraged to investigate the patterns that they find in numbers, shapes, and expressions, and by doing so, to make mathematical discoveries. They should have opportunities to analyze, extend, and create a variety of patterns and to use pattern-based thinking to understand and represent mathematical and other real-world phenomena. |
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Essential Questions |
Enduring Understandings |
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- How can change be best represented
mathematically? (4.5C1; 4.5F1; 4.5F2; 4.5F3; 4.5F4) |
- The symbolic language of algebra is used to
communicate and generalize the patterns in mathematics. |
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Areas of Focus/Cumulative Progress Indicators |
Comments and Examples |
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· Descriptions using tables, verbal and symbolic rules, graphs, simple equations or expressions · Finite and infinite sequences · Generating sequences by using calculators to repeatedly apply a formula
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4.3.7 B. Functions and Relationships |
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Descriptive Statement: The function concept is one of the most fundamental unifying ideas of modern mathematics. Student begin their study of functions in the primary grades, as they observe and study patterns. As students grow and their ability to abstract matures, students form rules, display information in a table or chart, and write equations which express the relationships they have observed. In high school, they use the more formal language of algebra to describe these relationships. |
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Essential Questions |
Enduring Understandings |
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- How are patterns of change related to the behavior of functions? (4.5F1; 4.5F2; 4.5F3; 4.5F4) |
- Patterns and relationships can be represented graphically, numerically, symbolically, or verbally. (4.5E1) |
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Areas of Focus/Cumulative Progress Indicators |
Comments and Examples |
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1. Graph functions, and understand and describe their general behavior. |
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4.3.7 C. Modeling |
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Descriptive Statement: The function concept is one of the most fundamental unifying ideas of modern mathematics. Student begin their study of functions in the primary grades, as they observe and study patterns. As students grow and their ability to abstract matures, students form rules, display information in a table or chart, and write equations which express the relationships they have observed. In high school, they use the more formal language of algebra to describe these relationships. |
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Essential Questions |
Enduring Understandings |
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- How are mathematical models used to describe
physical relationships? (4.5E2) |
- Mathematical models can be used to describe and
quantify physical relationships. (4.5E2) |
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Areas of Focus/Cumulative Progress Indicators |
Comments and Examples |
| 1. Analyze functional relationships to explain how a change in one quantity can result in a change in another, using pictures, graphs, charts, and equations. | |
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2. Use patterns, relations, symbolic algebra, and linear functions to model situations. · Using manipulatives, tables, graphs, verbal rules, algebraic expressions/equations/inequalities |
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4.3.7 D. Procedures |
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Descriptive Statement: Techniques for manipulating algebraic expressions - procedures - remain important, especially for students who may continue their study of mathematics in a calculus program. Utilization of algebraic procedures includes understanding and applying properties of numbers and operations, using symbols and variables appropriately, working with expressions, equations, and inequalities, and solving equations and inequalities. |
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Essential Questions |
Enduring Understandings |
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- What makes an algebraic algorithm both effective and efficient? (4.5D1) |
- Algebraic and numeric procedures are
interconnected and build on one another to produce a coherent whole. |
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Areas of Focus/Cumulative Progress Indicators |
Comments and Examples |
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1. Use graphing techniques on a number line. · Arithmetic operations represented by vectors (arrows) (e.g., -3 + 6 is left 3, right 6) |
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2. Solve simple linear equations informally and graphically. · Multi-step, integer coefficients only (although answers may not be integers) · Using paper-and-pencil, calculators, graphing calculators, spreadsheets, and other technology |
Sample Short Constructed Response (SCR) Item:
Mrs. Jones promised to pay Monica $8 per hour for helping her with
her vegetable garden. At the end of the week, Mrs. Jones paid Monica
the promised amount and, in addition, a $12 bonus. Altogether, she
paid Monica $104.
Use the following equation to determine h, the number of hours Monica must have worked in the garden. 8h + 12 = 104 ((Answer: 11 1/2 hours) |
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3. Create, evaluate, and simplify algebraic expressions involving variables. · Order of operations, including appropriate use of parentheses |
Instructional/Assessment Focus: "Create" implies within a problem-solving situation, consistent with 4.5A2 |
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4. Understand and apply the properties of operations, numbers, equations, and inequalities. · Additive inverse · Multiplicative inverse |
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