Curriculum & Algebra II. Martinsville City Public Schools Revised Summer Updated Summer 2012 tjv

Transcription

1 Curriculum & Grade 4: Pacing Mathematics Guide Algebra II Martinsville City Public Schools Revised Summer 011 Updated Summer 01 tjv

2 Martinsville City Public Schools Instructional Plan of Action The Martinsville City Public Schools Curriculum Guide was developed using the Standards of Learning for Virginia Public Schools and the State Curriculum Framework. Also, an emphasis was placed on the integration of 1 st Century Skills into all areas of K-1 education. Martinsville City Public Schools believes that to compete in a global community, all children must develop lifelong independent skills that demonstrate initiative, self direction, and the ability to problem-solve, innovate and create, and communicate by writing and speaking effectively. To provide an avenue for students to develop these important qualifications and provide a more rigorous learning environment, Martinsville City Public Schools encourages problem-based learning in all classrooms. The collaboration between students in this type of learning environment develops skills in leadership, accountability, social, and cross-cultural understanding as they communicate and think critically to problem-solve real world applications of the curriculum. Martinsville City Public Schools Core curriculum prepares students to achieve these 1 st Century skills through competent cross- curricular activities that apply knowledge of concepts learned in other areas of study and in the community. Standard benchmark assessments along with project-based assessments and end of year SOL tests are administered to ensure mastery of the concepts. PALS assessments are used to ensure proficiency in Reading for grades Pre-K through Eight. To further ensure that all students learn to the best of their abilities, a Response to Intervention (RtI) system, using STAR Math, STAR Reading and Algebra Readiness Diagnostic Test (ARDT), is in place to guide classroom instruction, screen and progress monitor students so that intervention and enrichment activities are scheduled based on the students individual needs throughout the year. Curriculum Guide OVERVIEW The Martinsville City Public Schools Curriculum Guide is designed to provide a reference document for each subject and grade level that indicates The Curriculum s Big Ideas, Instructional Strategies, Model lessons, & Assessment Instruments and suggested time frames to be used as a Guide for classroom instruction. In addition, Learning Targets at a Glance contains an overview of the curriculum taught for each grading period for each st subject and grade level. 1 Century Internet Safety procedures are listed, and for Grades Three through Twelve, an SOL Testing Blueprint Target is included to give insight to the strands that will receive the most focus on the SOL Assessments. Two symbols will be used to denote the 1st Century Focus: This symbol is used through to denote a 1 This symbol is used throughout to denote a 1 st Century Global Connection. st Century skill.

3 Learning Overview Algebra II students extend the concepts of Algebra I. A thorough study of advanced algebraic concepts is provided through the exploration of functions, polynomials, rational expressions, sequences and series, complex numbers, and matrices. Students will create graphs using translations, reflections, dilations, and rotations. Curriculum Big Ideas Instructional Strategies & Model Lessons Assessment Items The organizing topics, big ideas, or strands under which student learning is organized and the Essential Understandings, Knowledge and Skills students must develop in order to master these concepts (typically from the standards found in the VDOE curriculum framework). Essential Understandings what we want students to understand about this idea, topic, or concept Essential Knowledge What students must know in order to develop this understanding Essential Skills What students must be able to do in order to demonstrate that understanding Resources, strategies, and models for delivery of the curriculum. Includes suggested teaching strategies, links to model lesson plans links to frequently referenced online sites, and suggested teacher resources and where to find them (online and hard copy, such as texts, primary source documents, etc.) Examples of formative and summative assessments for measuring student mastery of the curriculum. Includes essential questions, writing prompts, sample test items, benchmark test links, model performance-based assessments, and other assessment resources. Standards of Learning that meet the criteria for 1 st Century skills will be identified by this symbol Standards of Learning that meet the 1st Century Learning of Global Connections will be designated with this symbol

4 Learning Targets at a Glance Algebra II First Quarter 8/13-10/15 Second Quarter 10/16-1/1 Third Quarter 1/8-3/13 Fourth Quarter 3/14-5/ A.4 Multistep Linear & Quadratic Equations AII.4 Equations and Equalities A.5 Multistep Linear Inequalities AII.4 Absolute Value AII.6 Functions AII.7a Relations and Functions All.7c Identify x- and y- intercepts AII.7d,e Function intervals-increase/decrease AII.7f Function behavior AII.4 Graphing Transformations AII.1d Factoring AII.1b Radical Expressions AII.1c Rational Exponents AII.4d Radical Equations AII.3 Complex Numbers AII.7b Graphing Quadratics AII.8 Graphing Quadratics AII.6 Functions AII.7a Relations and Functions All.7c Identify x- and y- intercepts AII.7d,e Function intervals-increase/decrease AII.7f Function behavior AII.1d Factoring AII.4b Quadratic Factoring AII.5 Linear-Quadratic/Quadratic-Quadratic AII.6 Polynomial Function Families (Square/Cube root,exponential, logarithmic) AII.7a Relations and Functions (Square/Cube root,exponential, logarithmic) All.7c Identify x- and y- intercepts AII.7d,e Function intervals-increase/decrease AII.7f Function behavior AII.7g Inverse Functions & Relations AII.6 Polynomial Function Families AII.7a Polynomial Function Families All.7c Identify x- and y- intercepts AII.7d,e Function intervals- Vertical/Horizontal Asymptotes AII.7f Function behavior AII.1a Add/Subt/Mult/Divide Rational Expressions AII.4c Solve Rational Equations AII. Sequences and Series AII.10 AII.1 AII.9 AII.11 Variations Permutations & combinations Data Analysis Properties of Normal Distribution Algebra II Mathematics Test Blueprint Summary Table 50 question test Expressions and Operations Equations and Inequalities

5 Suggested Time Allocation for a 70 Minute Math Block 0 Minutes Bellringer 40 Minutes 10 Minutes Skill Lesson Practice/Small Group Instruction

6 1 st Century Internet Safety Procedures 1. Teachers should review all internet sites and links prior to using them in the classroom. During this review, teachers need to ensure the appropriateness of the content on the site. Checking for broken links and paying attention to inappropriate pop-ups or solicitations of information.. Teachers should circulate throughout the classroom while students are on the internet to make sure the students are on the appropriate site and are not minimizing other inappropriate sites. 3. Teachers should periodically check and update any web addresses that they have on their MCPS webpage. 4. Teachers should assure that the use of these websites correlate with the objectives of the lesson and provide students with the appropriate challenges.

7 Expressions and Operations Expressions and Operations Virginia SOL AII.1 The student, given rational, radical, or polynomial expressions will a. add, subtract, multiply, divide, and simplify rational algebraic expressions; b. add subtract, multiply, divide and simplify radical expressions containing rational numbers and variables, and expressions containing rational exponents; c. write radical expressions as expressions containing rational exponents and vice versa; and d. factor polynomials completely. Essential Knowledge and Skills Key Vocabulary The student will use problem solving, mathematical communication, mathematical reasoning, connections and representations to: Add, subtract, multiply, and divide rational algebraic expressions. Simplify a rational algebraic expression with common monomial or binomial factors. Recognize a complex algebraic fraction, and simplify it as a quotient or product of simple algebraic fractions. Simplify radical expressions containing positive rational numbers and variables. Convert from radical notation to exponential notation and vice versa. Add and subtract radical expressions. Multiply and divide radical expressions not requiring rationalizing the denominators. Multiply and divide radical expressions requiring rationalizing the denominators. Factor polynomials by applying general patterns including difference of squares, sum and difference of cubes, and perfect square trinomials. Factor polynomials completely over the integers. Verify polynomial identities including the difference of squares, sum and difference of cubes, and perfect square trinomials. Essential Questions What is a rational expression? How is a rational expression simplified? What is a radical expression? How are radical expressions simplified? How do radical expressions apply to real-life situations? How is conversion between radical and rational exponents completed? When is a polynomial completely factored? What are the patterns to investigate when factoring a polynomial? Essential Understandings Computational skills applicable to numerical fractions also apply to rational expressions involving variables. Radical expressions can be written and simplified using rational exponents. Only radicals with a common radicand and index can be added or subtracted. A relationship exists among arithmetic complex fractions, algebraic complex fractions, and rational numbers. The complete factorization of polynomials has occurred when each factor is a prime polynomial. Pattern recognition can be used to determine complete factorization of a polynomial. A polynomial is a sum and/or difference of terms. The complete factorization of polynomials has occurred when each factor is a prime polynomial. Pattern recognition can be used to determine the complete factorization of a polynomial. The following steps may be followed when factoring a polynomial: 1. Determine the greatest monomial factor (GCF) as a first step in complete factorization.. Check for special patterns - Difference of squares [e.g., (4x 5) = (x 5)(x+ 5) ] 3 - Sum of two cubes [e.g., ( x + 8) = ( x+ )( x x+ 4) ] 3 - Difference of two cubes [e.g., ( y 15) = ( y 5)( y + 5y+ 5) ] - Perfect square trinomials [e.g., ( y 1y+ 36) = ( y 6) ] - General trinomials [e.g., (6x 7x 5) = (x+ 1)(3 x 5) ] 3. If there are four or more terms, grouping should be tried. To check, the factors may be multiplied back together to see if the original polynomial results.

8 Expressions and Operations Expressions and Operations Virginia SOL AII.1 The student, given rational, radical, or polynomial expressions will a. add, subtract, multiply, divide, and simplify rational algebraic expressions; b. add subtract, multiply, divide and simplify radical expressions containing rational numbers and variables, and expressions containing rational exponents; c. write radical expressions as expressions containing rational exponents and vice versa; and d. factor polynomials completely. Essential Knowledge and Skills Key Vocabulary (continued) Key Vocabulary complex fraction difference of two cubes difference of squares index (indices) perfect square trinomial polynomial radical radical expression radicand rational expression restricted variable sum of two cubes (continued) To divide a polynomial by a binomial either factor or use long division. Factoring and simplifying is the preferred method but does not always work. In these cases, long division is used. Factoring Example: x x x x ( + 5)( + 3) = x+ 3 ( x+ 3) Long Division Example: a 4a 6 a + ( x+ 5)( x+ 3) = ( x + 3) = ( x + 5) a 6 a+ a 4a 6 + ( a a) 6a 6 6 a 6 + a + ( 6a 1) +6 A complex fraction is a fraction that has a fraction in its numerator or denominator or in both its numerator and denominator. A rational expression is a polynomial or the quotient of two polynomials. The denominator cannot be 0 (this is called a restricted variable). Rational expressions written as complex fractions can be written as a quotient or product of simple fractions. Rational expressions must be simplified. A simplified expression meets the following conditions: 1. It has no negative exponents.. It has no fractional exponents in the denominator. 3. It is not a complex fraction. Rational expressions can be added, subtracted, multiplied, and divided.

9 (continued) Expressions and Operations A radical expression is an expression that contains a radical and is in the form n a or 1 n a. 5 is called a radical. The number 5 under the radical sign is called the radicand. In 3 7, 3 is called the index. Expressions and Operations Virginia SOL AII.1 The student, given rational, radical, or polynomial expressions will a. add, subtract, multiply, divide, and simplify rational algebraic expressions; b. add subtract, multiply, divide and simplify radical expressions containing rational numbers and variables, and expressions containing rational exponents; c. write radical expressions as expressions containing rational exponents and vice versa; and d. factor polynomials completely. Radicals with common radicands and common indices are added, subtracted, or multiplied the same way monomials are added, subtracted, or multiplied. The following rules will aid in the multiplication and division of radicals: Product Property of Radicals For any real numbers a and b and any integer n, n > 1, 1. if n is even, then n ab = n a n b where a and b are both nonnegative, and. if n is odd, then n ab = n a n b. Quotient Property of Radicals For any real numbers a and b, where b 0, and for any integer n, where n > 1, Expressions containing radicals can be operated on and simplified. A radical expression is simplified when the following conditions are met: - the index, n, has the least value possible; - the radicand contains no factors (other than 1) that are n th powers of an integer or polynomial; - the radicand contains no fractions; and - no radicals appear in the denominator. n n m n m For any nonzero real number b, and any integers m and n, with n > 1, b = b = ( b) except when b < 0 and n is even. m n n a a =, if all roots are defined. n b b Rationalizing a denominator is a procedure for transforming a quotient with a radical in the denominator into an expression with no radical in the denominator. The following are examples of rationalizing the denominator of radical expressions. Example 1: x x 3 = x 3 = 3 3 x 3 = 3 (Multiply by 1.)

10 (continued) Expressions and Operations Example : 1 3 = (Use the conjugate of 1+ 5 to multiply by 1.) Expressions and Operations 3 = = = 1+ 3 Virginia SOL AII.1 The student, given rational, radical, or polynomial expressions will a. add, subtract, multiply, divide, and simplify rational algebraic expressions; b. add subtract, multiply, divide and simplify radical expressions containing rational numbers and variables, and expressions containing rational exponents; c. write radical expressions as expressions containing rational exponents and vice versa; and d. factor polynomials completely. Example 3: 3 3 = 3 3x 3x 3 x 3 3 = 3 3 = = = 3x 3 x 3 x 3 3x 3 x 3 18x 3 3 x x 3x 3 An equation that is true for all real numbers for which both sides are defined is called an identity. A polynomial identity is two equivalent polynomial expressions. To verify or prove polynomial identities, work with the expressions on each side of the equation until they are the same. The following are examples of proving polynomial identities. Example 1: Prove that x y = ( x y)( x+ y) = x + xy xy y = x y Students need multiple experiences simplifying radical expressions with and without radicals in the denominator.

11 Expressions and Operations Expressions and Operations (continued) ( a + b)( a ab + b ) = a + b Example : Prove that First multiply each term of the binomial (a + b). 3 3 a ab + b by the term a in the binomial (a + b), and then multiply each term of ( a + b)( a ab + b ) = a + b 3 3 a a b + ab + a b ab + b = 3 3 a a b + a b + ab ab + b = 3 3 a + b = 3 3 a ab + b by the term b in Virginia SOL AII.1 The student, given rational, radical, or polynomial expressions will a. add, subtract, multiply, divide, and simplify rational algebraic expressions; b. add subtract, multiply, divide and simplify radical expressions containing rational numbers and variables, and expressions containing rational exponents; c. write radical expressions as expressions containing rational exponents and vice versa; and d. factor polynomials completely. Example 3: Prove that ( ) ( ) First square each binomial. a+ b + a b = a + b ( ) ( ) a+ b + a b = a + b a + ab + b + a ab + b = a + a + ab ab + b + b = a + b = ( x + y ) = ( x y ) + ( xy) Example 4: Use polynomial identities to describe numerical relationships such as to generate Pythagorean triples. ( x + y ) = ( x y ) + ( xy) x + xy + xy + y = x xy xy + y + 4xy x + xy + y = x xy + y + 4xy x + xy + y = x + 4xy xy + y x + xy + y = x + xy + y

12 Resources Sample Instructional Strategies and Activities Expressions and Operations Expressions and Operations Virginia SOL AII.1 Foundational Objectives 8.1a The student will simplify numerical expressions involving positive exponents, using rational numbers, order of operations and properties of operations with real numbers. 8.5 The student will a. determine whether a given number is a perfect square; and b. find the two consecutive whole numbers between which a square root lies. A. The student will perform operations on polynomials, including a. applying the laws of exponents to perform operations on expressions; b. adding, subtracting, multiplying, and dividing polynomials; and c. factoring completely first- and seconddegree binomials and trinomials in one or two variables. Graphing calculators will be used as a tool for factoring and for confirming algebraic factorizations. A.3 Resources TI-84 Graphing Calculators VA. SOL Coach and Buckle Down Flanagan Test Project Graduation VDOE ESS AII.1 Rational Expressions AII.1 Exponents and Radicals AII.1 Factoring Math Dude: IXL.com Technology Glencoe Textbook Online: (AII.6) Chpts: -6, 6-6, 7-1, 7-9, 9-3, 9-5, 10-1 thru 10- Algebra I Online - Consider the activity "I have:... Who has...?" A sample card might say: I have x 4 Who has the factors of 6x 7x 5 The person having a card that says I have (x + 1) (3x 5) would then read their card. When making a set of cards, be sure that the answer to the question on the last card answer will be on the first card. This game can be used for many different types of problems (i.e., factoring polynomials; and adding, subtracting, multiplying, and dividing integers, rational numbers, complex numbers, etc.). Each student must work the problems to determine if they have the card with the correct answer. Students will be divided into cooperative groups of four and be given a pair of rational expressions to be added, to be subtracted, to be multiplied, and to be divided. They will, in turn, choose an operation, perform it and then explain it to the other group members. As a part of this process, the group members will correct each other's mistakes. Model problems containing roots such as ratios of areas and volumes. Divide the class into groups of four students. Give each group four problems that involve radicals. Each of the four operations should be used. Have each group explain how to do the problems step by step. The groups should make sure that every person in the group understands each problem before presenting them. The student will express the square roots and cube roots of whole numbers and the square root of a monomial algebraic expression in simplest radical form.

13 Functions Virginia SOL AII. The student will investigate and apply the properties of arithmetic and geometric sequences and series to solve real-world problems including writing the first n terms, th finding the n term, and evaluating summation formulas. Notation will include and. a n Essential Knowledge and Skills Key Vocabulary The student will use problem solving, mathematical communication, mathematical reasoning, connections and representations to: Distinguish between a sequence and a series. Generalize patterns in a sequence using explicit and recursive formulas. Use and interpret the notation: Σ, n, n th term, and a n. th Given the formula, find a n (the n term) for an arithmetic or a geometric sequence. Given formulas, write the first n terms and find the sum, S n, of the first n terms of an arithmetic or geometric series. Given the formula, find the sum of a convergent infinite series. Model real-world situations using sequences and series. Key Vocabulary arithmetic sequence common difference common ratio convergent divergent explicit formula geometric sequence recursive formula sequence series sigma notation (summation notation) Essential Questions What is the difference between a series and a sequence? What is the difference between arithmetic and geometric sequences and series? What is Sigma notation (Σ)? What real-world situations use sequences and series? Essential Understandings Sequences and series arise from real-world situations. The study of sequences and series is an application of the investigation of patterns. A sequence is a function whose domain is the set of natural numbers. Sequences can be defined explicitly and recursively. A sequence is a mathematical pattern of numbers. A series is an indicated sum of a sequence of terms. Both sequences and series may be finite or infinite. Two types of sequences are arithmetic and geometric. An arithmetic sequence is a sequence in which each term, after the first term, is found by repeated addition of a constant, called the common difference to the previous term. A geometric sequence is a sequence in which each term, after the first term, can be found by multiplying the preceding term by a nonzero constant, called the common ratio. The terms between any two nonconsecutive terms of a geometric/arithmetic sequence are called the geometric/arithmetic means. A series is the expression for the sum of the terms of a sequence. Finite sequences and series have terms that can be counted individually from 1 to a final whole number n. Infinite sequences and series continue without end. Infinite sequences or series are indicated with ellipsis points (3 dots indicating the missing part of a statement). Example: Finite sequence 4, 8, 1, 16, 0 Finite series Infinite sequence, 7, 1, 17, Infinite series

14 Functions Virginia SOL AII. The student will investigate and apply the properties of arithmetic and geometric sequences and series to solve real-world problems including writing the first n terms, finding the n term, and evaluating summation formulas. Notation will include and. a n th (continued) There are formulas that assist in determining elements of the sequence ( a n ) or sum of a series. The sigma notation or summation notation (Σ) is one way of writing a series. Σ is the Greek letter sigma, the equivalent of the English letter S (for summation). Use limits to indicate how many terms are added. Limits are the least and greatest integral values of n. Example: Use summation notation to write the series for 3 terms. 3 n= 1 (4 n) where 3 is the upper limit (greatest value of n), 1 is the lower limit (least value of n) and the explicit formula for the series is 4n. A recursive formula for a sequence describes how to find the n th term from the terms before it. A recursive formula defines the terms in a sequence by relating each term to the ones before it. An explicit formula expresses the n th term in terms of n. Arithmetic Sequence Formulas Recursive Formula a 1 = a given value, n n 1 Explicit Formula a = a + d a = a1 + ( n 1) d In these formulas, a n is the n th term, a 1 is the first term, n is the number of the term, and d is the common difference. Geometric Sequence Formulas n Recursive Formula = a given value, a = a r a 1 n n 1 Explicit Formula a = a r n 1 n 1 In these formulas, a n is the n th term, a 1 is the first term, n is the number of the term, and r is the common ratio. In some cases, an infinite geometric series can be evaluated. When divergent, or approaches no limit. r < 1, the series is convergent, or gets closer and closer to the sum S. When r 1, the series is Real-world applications such as fractals, growth, tax, and interest are solved using sequences and series

15 (continued) Sum of a Finite Arithmetic Series The Sn of a finite arithmetic series a1+ a + a an number of terms. is n Sn = ( a1 + an) where a1 is the first term, an is the nth term, and n is the Functions Virginia SOL AII. The student will investigate and apply the properties of arithmetic and geometric sequences and series to solve real-world problems including writing the first n terms, finding the nth term, and evaluating summation formulas. Notation will include and a n. n Sn = [ a1 + ( n 1) d] Another formula for the sum of a finite arithmetic series is the number of terms. Sum of a Finite Geometric Series The Sn of a finite geometric series a1+ a + a a S n, r 1, is the number of terms. n where a1 is the first term, an is the nth term, and n is (1 n a ) 1 r = 1 r where a1 is the first term, r is the common ratio, and n is Sum of an Infinite Geometric Series An infinite geometric series with a1 r < 1 S = converges to the sum 1 r where a1 is the first term and r is the common ratio.

16 Resources Sample Instructional Strategies and Activities Functions Virginia SOL AII. Foundational Objectives 6.17 The student will identify and extend geometric and arithmetic sequences. 7. The student will describe and represent, arithmetic and geometric sequences using variable expressions The student will make connections between any two representations (tables, graphs, words, and rules) of a given relationship. Resources TI-84 Graphing Calculators VA. SOL Coach and Buckle Down Flanagan Test Project Graduation VDOE ESS AII. Arithmetic and Geometric Sequences and Operations Math Dude: IXL.com Technology Glencoe Textbook Online: (AII.6) Chpts: -6, 6-6, 7-1, 7-9, 9-3, 9-5, 10-1 thru 10- Algebra I Online Model real-life situations with arithmetic sequences, such as increasing lengths of rows in some concert halls. Model real-life situations with geometric sequences, such as revenues that increase at a constant percent. Model a real-life situation with geometric series, such as total distance traveled by a bouncing ball. Assign groups of students to make up a geometric series and write it in sigma notation. Groups exchange problems and find the sum of the geometric series. Return the results to the original group to check accuracy. For a geometric series, students are offered a penny for the first day of the month, to be doubled everyday there after for the month. Have students determine the amount on the 30 th day and the total for the thirty days. Compare and contrast between arithmetic and geometric series: Students are offered two jobs one with a constant annual raise verses a percentage raise. Which job will have the highest salary after twenty years?

17 Expressions and Operations Expressions and Operations Virginia SOL AII.3 The student will perform operations on complex numbers, express the results in simplest form using patterns of the powers of i, and identify field properties that are valid for the complex numbers. Essential Knowledge and Skills Key Vocabulary The student will use problem solving, mathematical communication, mathematical reasoning, connections and representations to: Recognize that the square root of 1 is represented as i. Determine which field properties apply to the complex number system. Simplify radical expressions containing negative rational numbers and express in a+bi form. Simplify powers of i. Add, subtract, and multiply complex numbers. Place the following sets of numbers in a hierarchy of subsets; complex, pure imaginary, real, rational, irrational, integers, whole, and natural. Write a real number in a+bi form. Write a pure imaginary number in a+bi form. Key Vocabulary complex number conjugate imaginary number Essential Questions How are real, imaginary, and complex numbers related? What properties extend from the real numbers to the complex numbers? What is the relationship between a complex number and its conjugate? What are the patterns of the powers of i? Essential Understandings Complex numbers are organized into a hierarchy of subsets. A complex number multiplied by its conjugate is a real number. Equations having no real number solutions may have solutions in the set of complex numbers. Field properties apply to complex numbers as well as real numbers. All complex numbers can be written in the form a+bi where a and b are real numbers and i is 1. Complex numbers are a superset of real numbers and, as a system, contain solutions for equations that are not solvable over the set of real numbers. Complex numbers are organized into a hierarchy of subsets with properties applicable to each subset. Complex Numbers (a + bi) Real Numbers ( b = 0) Imaginary Numbers Rational Numbers Irrational Numbers (b 0) Integers Whole Numbers Natural Numbers Pure Imaginary Numbers (a = 0)

18 Expressions and Operations Expressions and Operations Virginia SOL AII.3 The student will perform operations on complex numbers, express the results in simplest form using patterns of the powers of i, and identify field properties that are valid for the complex numbers. (continued) A complex number (the sum of a real number and an imaginary number) can be written in the form a + bi where a and b are real numbers and i = 1. An imaginary number (the square root of a negative number) is a complex number (a +bi) where b 0, and i = 1. An imaginary number where a = 0 is called a pure imaginary number. The set of complex numbers form a field (Properties of closure, associative, commutative, inverse, and identity of addition and multiplication with the distributive property are valid.). Operations of addition, subtraction, and multiplication of complex numbers are performed in the same manner as the respective operations for radicals. The conjugate (expressions that differ only in the sign of the second term) of a + bi is a bi. When dividing complex numbers the conjugate of the denominator must be used to simplify the expression. Examples of axioms of equality (reflexive, symmetric, transitive, substitution, addition, and multiplication) and examples of axioms of inequality and order (trichotomy, transitive, addition, and multiplication) can be identified using the set of complex numbers. Trichotomy is the property of the real line, that given elements x and y, exactly one of the following is true: x< y, y < x, x = y. Real numbers are not adequate to determine the solutions of an equation such as x + 1= 0, because there is no real number x that can be squared to produce 1. With the definition of i = 1, and i = 1, the sets of imaginary and complex numbers are created. The standard form of any complex number is a + bi with ab R., Operations of addition, subtraction, and multiplication are performed in the same manner as the respective operations for radicals. All 3 4 answers must be simplified to standard form using the pattern of the powers of i (e.g., i = i, i = 1 ).

19 Resources Sample Instructional Strategies and Activities Expressions and Operations Expressions and Operations Resources TI-84 Graphing Calculators VA. SOL Coach and Buckle Down Flanagan Test Project Graduation Teachers and students, beginning with natural numbers and progressing to complex numbers, use flow charts and Venn Diagrams, as classroom activities. Make a set of about 30 cards, one per card, i to a certain power. Pair the students and have them write on a white board the simplified result. After completing the cards, students should be able to generalize how to simplify i raised to a power. Virginia SOL AII.3 Foundational Objectives 8. VDOE ESS AII.3 Complex Numbers The student will describe orally and in writing the relationships between the subsets of the real number system. Math Dude: IXL.com Technology 8.15c The student will identify properties of operations used to solve an equation. A.4b The student will solve multi-step linear and quadratic equations in two variables, including justifying steps used in simplifying expressions and solving equations, using field properties and axioms of equality that are valid for the set of real numbers and its subsets. Glencoe Textbook Online: (AII.6) Chpts: -6, 6-6, 7-1, 7-9, 9-3, 9-5, 10-1 thru 10- Algebra I Online

20 Equations and Inequalities Equations and Inequalities Virginia SOL AII.4 The student will solve, algebraically and graphically, a. absolute value equations and inequalities; b. quadratic equations over the set of complex numbers; c. equations containing rational algebraic expressions; and d. equations containing radical expressions. Graphing calculators will be used for solving and for confirming the algebraic solutions. Essential Knowledge and Skills Key Vocabulary The student will use problem solving, mathematical communication, mathematical reasoning, connections and representations to: Solve absolute value equations and inequalities algebraically and graphically. Write absolute value equations or inequalities for given graphs. Solve quadratic equations over the set of complex numbers using an appropriate strategy. Calculate the discriminant of a quadratic equation to determine the number of real and complex solutions. Solve equations containing rational algebraic expressions with monomial or binomial denominators algebraically and graphically. Solve an equation containing a radical expression algebraically and graphically. Verify possible solutions to an equation containing rational or radical expressions. Apply an appropriate equation to solve a realworld problem. Recognize that the quadratic formula can be derived by applying the completion of squares to any quadratic equation in standard form. Key Vocabulary absolute value equations and inequalities completing the square compound sentence extraneous solution quadratic equation radical expression rational expression Essential Questions What are the characteristics of an absolute value function? Why can an absolute value equation take on more than one solution? What are the methods used to solve quadratic equations? How is the discriminant of a quadratic equation calculated and what is its significance? How does a graphing calculator confirm algebraic solutions of quadratic equation? What is a real-world example for a quadratic, absolute value, radical, or rational equation? When working with a real-world problem, how are solution(s) verified? How is an equation containing rational expressions solved? How is an equation containing radical expressions solved? What are the possible number of solutions for each type of equation? How is an absolute value equation solved? How can the solution for an absolute value inequality be described? Essential Understandings Equations can be solved in a variety of ways. The quadratic formula can be used to solve any quadratic equation. A quadratic function whose graph does not intersect the x-axis has roots with imaginary components. The value of the discriminant of a quadratic equation can be used to describe the number of real and complex solutions. The definition of absolute value (for any real numbers a and b, where b 0, if a = b, then a = b or a = b ) is used in solving absolute value equations and inequalities. Absolute value inequalities can be solved graphically or by using a compound statement. Real-world problems can be interpreted, represented, and solved using equations and inequalities. The process of solving radical or rational equations can lead to extraneous solutions. Set builder notation may be used to represent solution sets of equations and inequalities. When solving equations it is important to check possible solutions in the original equation as one or more may be an extraneous solution. An extraneous solution is a solution of an equation derived from an original equation that is not a solution of the original equation. Absolute value, radical, and rational equations may have extraneous solution

21 Equations and Inequalities Equations and Inequalities Virginia SOL AII.4 The student will solve, algebraically and graphically, a. absolute value equations and inequalities; b. quadratic equations over the set of complex numbers; c. equations containing rational algebraic expressions; and d. equations containing radical expressions. Graphing calculators will be used for solving and for confirming the algebraic solutions. (continued) Absolute value equations and inequalities can be used to model problems dealing with a range of acceptable measurements. The absolute value of a number x is the distance the number is from zero on a number line. When solving absolute value equations (equations that contain absolute values), the expression inside the absolute value symbol can be any real number. An absolute value equation may have two solutions. An absolute value inequality may be solved by transforming the inequality into a compound sentence using the words and or or. Generally, in an absolute value inequality if it is a less than statement it is and and if it is a greater than statement it is or. The sketch of absolute value inequalities and functions presents an opportunity to picture the absolute value relationship. The graphing calculator illustrates various transformations and aids in the solution of absolute value equations and inequalities. A quadratic equation is a polynomial equation containing a variable to the second degree. The standard form of a quadratic equation is y = ax + bx + c, where a, b, and c are real numbers and a 0. The graph of a quadratic function is called a parabola. Quadratic functions can be written in the form y= ax ( h) + k to facilitate graphing by transformations and finding maxima and minima. Quadratic equations can be solved by factoring, graphing, using the quadratic formula, and completing the square. They can have real or complex solutions. Graphing calculators should be used as a primary tool in solving quadratics and aid in visualizing or confirming solutions. Calculators can also be used to determine a quadratic equation that best fits a data set. b ± b 4ac The quadratic formula is x =. a The discriminant of a quadratic equation, b 4ac, provides information about the nature and number of roots of the equation. The following table summarizes all possibilities. Value of b 4ac Discriminant a perfect square? Nature of Roots Nature of Graph > 0 Yes real, rational Intersects x-axis twice > 0 No real, irrational Intersects x-axis twice < imaginary Doesn t intersect x-axis = real Intersects x-axis once

22 Equations and Inequalities Equations and Inequalities (continued) A rational expression is written as a quotient of polynomials in simplest form; the divisor is never zero. Equations containing rational expressions can be solved by finding the least common denominator. A radical expression is an expression that contains a square root. Equations with variables in the radicals are called radical equations. To solve this type of equation, isolate the radical and then raise each side of the equation to a power that equals the root of the equation. For example, if the root index is 3, then each side of the equation needs to be raised to the 3rd power. If the root index is 4, then each side is raised to the 4th power. A solution of an equation makes the equation true for a given value or set of values. Equations containing rational expressions can be solved in a variety of ways. Virginia SOL AII.4 The student will solve, algebraically and graphically, a. absolute value equations and inequalities; b. quadratic equations over the set of complex numbers; c. equations containing rational algebraic expressions; and d. equations containing radical expressions. Graphing calculators will be used for solving and for confirming the algebraic solutions. The solution of an equation in one variable can be found by graphing each member of the equation separately and noting the x-coordinate of the point of intersection. Set builder notation is used to represent solutions. For example, if the solution is y = 10 then in set notation the answer is written {y: y = 10}. Graphing calculators are powerful tools for solving and confirming algebraic solutions. Practical problems can be interpreted, represented, and solved using equations. Completing the square is the process of finding the last term of a perfect square trinomial. If one side of an equation is not a perfect square trinomial, it can be converted into a perfect square trinomial by rewriting the constant term. b b x + bx + = x + Use the relationship to find the term that will complete the square. Example: Solve by completing the square. x + 10x 9 = 0 10 b = 5 Find x + 10x = 9 Rewrite so all terms containing x are on one side. x + 10x+ 5 = Complete the square by adding 5 to each side. ( x + 5) = 34 Factor the perfect square trinomial. x + 5 = ± 34 Find the square root of each side. x = 5 ± 34 Solve for x. Conjugate is an adjective used to describe two items having features in common but inverses or opposites in some aspect. Number pairs of the form a+ b and a b are conjugates. Complex solutions occur in pairs (conjugates).

23 Resources Sample Instructional Strategies and Activities Equations and Inequalities Equations and Inequalities Virginia SOL AII.4 Foundational Objectives 8.15 The student will a. solve multi-step linear equations in one variable on one and two sides of the equation; b. solve two-step linear inequalities and graph the results on a number line; and A. The student will perform operations on polynomials, including a. applying the laws of exponents to perform operations on expressions; b. adding, subtracting, multiplying, and dividing polynomials; and c. factoring completely first- and seconddegree binomials and trinomials in one or two variables. A.3 The student will express the square roots and cube roots of whole numbers and the square root of a monomial algebraic expression in simplest radical form. A.4 The student will solve multi-step linear and quadratic equations in two variables, including c. solving quadratic equations algebraically and graphically; d. solving multi-step linear equations algebraically and graphically; and f. solving real-world problems involving equations and systems of equations. A.5a The student will solve multi-step linear inequalities in two variables, including solving multi-step linear inequalities algebraically and graphically. Resources TI-84 Graphing Calculators VA. SOL Coach and Buckle Down Lesson 7 Flanagan Test A.4 Project Graduation Lessons: 5, 7, 9 VDOE ESS A.4 Solve for The Unknown A Mystery to Solve Cover-Up The Problem Algebra Tiles and Equation Solving AII.4 AII.4 Absolute Value Equations and Inequalities AII.4 Quadratic Equations AII.4 Rational Equations AII.4 Radical Equations Technology Math Dude: Unit IXL.com A.4 a, b, d, f A.5 Glencoe Textbook Online: (A.4) Chpt: 3-1 thru 3-6, 3-8 (AII.4) Chpts. 1-3 thru 1-6, 5-8 thru 5-9, 6-1 thru 6-5, 9-6 Algebra I Online Equations (Lessons 1-6) Solving Inequalities (Lessons 1-3) Systems of Equations (Lesson 1-5) Working in cooperative groups, students discover, by point plotting, the "and/or concept" of absolute value. Students, working in cooperative groups of four, write a type of equation (absolute value, quadratic, rational, and radical). Collect and redistribute to different groups. Next, students solve, discuss, and graph the solution. Choose spokesperson to present findings to the class. Teach the concept of absolute value, beginning with simplest equation and progressing systematically until complex forms are presented. As a cooperative learning activity, students will solve the quadratic equation, ax + bx + c = 0, by using the completion of the square method to derive the quadratic formula. Students, working in cooperative groups, solve x 5x+ 6= 0 in three different ways. Compare and contrast the methods and use the graphing calculator to verify the roots of the equation. Consider the activity "I have Who has?" Last card answer will be on the first card. This game can be used for many different types of equations. Each student must work the problems to determine if they have the card with the correct answer. Working in cooperative groups, ask students to discuss an appropriate method for solving equations involving two radicals. Students will verbalize each step needed and discuss the proper steps needed.

24 Equations and Inequalities Equations and Inequalities Virginia SOL AII.5 The student will solve nonlinear systems of equations, including linearquadratic and quadratic-quadratic, algebraically and graphically. Graphing calculators will be used as a tool to visualize graphs and predict the number of solutions. Essential Knowledge and Skills Key Vocabulary The student will use problem solving, mathematical communication, mathematical reasoning, connections and representations to: Predict the number of solutions to a nonlinear system of two equations. Solve a linear-quadratic system of two equations algebraically and graphically. Solve a quadratic-quadratic system of two equations algebraically and graphically. Key Vocabulary linear-quadratic equations nonlinear systems of equations quadratic-quadratic equations Essential Questions What is a linear function? In what form(s) can it be written? What is a quadratic function? In what form(s) can it be written? How does a graphing calculator confirm algebraic solutions of quadratic functions? What is a real-world example of a non-linear system of equations? What are the different ways that the graph of a line and a quadratic can intersect? What are the different ways that the graphs of two quadratics can intersect? Essential Understandings Solutions of a nonlinear system of equations are numerical values that satisfy every equation in the system. The coordinates of points of intersection in any system of equations are solutions to the system. Real-world problems can be interpreted, represented, and solved using systems of equations. An equation in which one or more terms have a variable of degree or higher is called a nonlinear equation. A nonlinear system of equations contains at least one nonlinear equation. A system of equations is a set of two or more equations that use the same variable. If the graph of each equation in a system of two variables is a line, then the system is a linear system. Nonlinear systems of equations can be classified as linear-quadratic or quadratic-quadratic. Both systems can be solved algebraically and graphically. Solutions of a nonlinear system of equations are values that satisfy every equation in the system. Points of intersection in nonlinear systems are solutions to the system. Each point of intersection of the graphs of the equations in a system represents a real solution of the system. A linear-quadratic system of equations has two solutions, one solution or no solution. A quadratic-quadratic system of equations has four solutions, three solutions, two solutions, one solution, or no solution. Graphing calculators can be used to visualize a nonlinear system of two equations and predict the number of solutions. (continued)

25 Resources Sample Instructional Strategies and Activities Equations and Inequalities Equations and Inequalities Virginia SOL AII.5 Foundational Objectives A.4e, f The student will solve multi-step linear and quadratic equations in two variables, including e. solving systems of two linear equations in two variables algebraically and graphically; and f. solving real-world problems involving equations and systems of equations. A.5 The student will solve multi-step linear inequalities in two variables, including a. solving multi-step linear inequalities algebraically and graphically; b. justifying steps used in solving inequalities, using axioms of inequality and properties of order that are valid for the set of real numbers and its subsets; c. solving real-world problems involving inequalities; and d. solving systems of inequalities. A.6 The student will graph linear equations and linear inequalities in two variables, including a. determining the slope of a line when given an equation of the line, the graph of the line, or two points on the line. Slope will be described as rate of change and will be positive, negative, zero, or undefined; and b. writing the equation of a line when given the graph of the line, two points on the line, or the slope and a point on the line. G.1 The student, given the coordinates of the center of a circle and a point on the circle, will write the equation of the circle. Resources TI-84 Graphing Calculators VA. SOL Coach and Buckle Down Flanagan Test Project Graduation VDOE ESS AII.5 Nonlinear Systems of Equations Math Dude: IXL.com Technology Glencoe Textbook Online: (AII.6) Chpts: -6, 6-6, 7-1, 7-9, 9-3, 9-5, 10-1 thru 10- Algebra I Online Working in cooperative groups, ask students to discuss an appropriate method for solving a given system. Students will verbalize each step needed and discuss the proper steps needed. In order to show students the relationship between the different ways in which two second degree equations can intersect and the number of real solutions, have students draw a circle on graph paper and a parabola on patty paper. Tell students such a system can have zero, one, two, three, or four real solutions. Instruct them to hold the circle stationary and move the parabola to illustrate each number of possible solutions.

26 Functions Virginia SOL AII.6 The student will recognize the general shape of function (absolute value, square root, cube root, rational, polynomial, exponential, and logarithmic) families and will convert between graphic and symbolic forms of functions. A transformational approach to graphing will be employed. Graphing calculators will be used as a tool to investigate the shapes and behaviors of these functions. The student will use problem solving, mathematical communication, mathematical reasoning, connections and representations to: Recognize graphs of parent functions. Given a transformation of a parent function, identify the graph of the transformed function. Given the equation and using a transformational approach, graph a function. Given the graph of a function, identify the parent function. Given the graph of a function, identify the transformations that map the preimage to the image in order to determine the equation of the image. Using a transformational approach, write the equation of a function given its graph. Key Vocabulary absolute value function cube root function cubic function dilation exponential function family of functions logarithmic function parabola parent function polynomial function quartic function rational function reflection square root function transformations of graphs translation (vertical and horizontal) Essential Questions What are different representations of functions? What is the transformational approach to graphing? What is the connection between the algebraic and graphical representation of a transformation? What is the relationship between exponential and logarithmic functions? How can the calculator be used to investigate these functions (absolute value, square root, cube root, rational, polynomial, exponential, and logarithmic)? Essential Understandings The graphs/equations for a family of functions can be determined using a transformational approach. A parent graph is an anchor graph from which other graphs are derived with transformations. Transformations of graphs include translations, reflections, and dilations. A function is a correspondence in which values of one variable determine the values of another. It is a rule of correspondence between two sets such that there is a unique element in one set assigned to each element in the other. A polynomial function is a function of one variable whose exponents are natural numbers. The degree of a polynomial function determines its graphing behavior. A polynomial function is linear, quadratic, cubic, quartic, etc., according to its degree, 1,, 3, 4,, respectively. The degree of the polynomial will help determine the graph of the polynomial function. The graphs and/or equations for a family of functions can be determined using a transformational approach. A family of functions is a group of functions with common characteristics. A parent function is the simplest function with these characteristics. A parent function and one or more transformations make up a family of functions. Shapes and behavior of graphs of polynomials can be determined by analyzing transformations of parent functions. The following is one example of a parent function and family of functions. Parent Function Family of Functions f( x) = x f( x) = 3( x 4) + 5 f x ( ) = ( x+ 1) 7 (continued)

27 Functions (continued) A quadratic equation is a polynomial equation containing a variable to the second degree. The standard form of a quadratic equation is y = ax + bx + c, where a, b, and c are real numbers and a 0. The graph of a quadratic function is called a parabola. Parabolas have an axis of symmetry, a line that divides the parabola into two parts that are mirror images of each other. The vertex of a parabola is either the lowest point on the graph or the highest point on the graph. Quadratic functions can be written in the form y= ax ( h) + k to facilitate graphing by transformations and finding maxima and minima. The chart below summarizes the characteristics of the graph of y= ax ( h) + k. Virginia SOL AII.6 The student will recognize the general shape of function (absolute value, square root, cube root, rational, polynomial, exponential, and logarithmic) families and will convert between graphic and symbolic forms of functions. A transformational approach to graphing will be employed. Graphing calculators will be used as a tool to investigate the shapes and behaviors of these functions. y ax ( h) k = + a is positive a is negative Vertex (h, k) (h, k) Axis of Symmetry x = h x = h Direction of Opening upward (minima) downward (maxima) As the value of the absolute value of a increases, the graph of y ax ( h) k = + narrows. x An exponential function is a function of the form y = a, where a is a positive constant not equal to one. Population growth and viral growth are among examples of exponential functions. Logarithmic functions are inverses of exponential functions. A function is continuous if the graph can be drawn without lifting the pencil from the paper. A graph is discontinuous if it has jumps, breaks, or holes in it. Px ( ) A rational function f(x) can be written as f( x) =, where P(x) and Q(x) are polynomial functions and Q(x) 0. Qx ( ) A radical function is a function that is defined by a radical expression. The square root of a number, x, is a number that when multiplied by itself produces the given = x, number, x. Since the domain of a function is the set of all real number values of x for which a function, f, is defined, the domain of the square root function, f( x) does not include negative numbers. A function f is called a cube root function if f( x) 3 = x for all real numbers. A u-turn in a graph occurs when the function values change from increasing to decreasing or vice versa and indicates either a local maximum or a local minimum. The number of u-turns in a graph is no greater than 1 less than the degree of the function.

28 (continued) A cubic function is of degree three and a quartic function is of degree four. Absolute value function is a function described by f( x) = x. The graph of the absolute value function has a characteristic V-shape. Functions Virginia SOL AII.6 The student will recognize the general shape of function (absolute value, square root, cube root, rational, polynomial, exponential, and logarithmic) families and will convert between graphic and symbolic forms of functions. A transformational approach to graphing will be employed. Graphing calculators will be used as a tool to investigate the shapes and behaviors of these functions. Experiences with shapes and transformations of functions should include the following: Quadratic Cubic Quartic Square Root f( x) = x 3 f( x) = x 3x 1 f( x) = x x + x = 1 y = x y x y x y x 4 - y 4 6 Rational Exponential Logarithmic Absolute Value 4 f( x) = 1.5 x 3 f( x ) = x f( x) = log x f( x) = x 8 y y 8 4 y 8 y x x x 1 x x

29 Functions (continued) A transformation of a function is an alteration of the function rule that results in an alteration of its graph. If y = f( x), then y = f( x) + k gives a vertical translation of the graph of f. The translation is k units up for k > 0 and k units down for k < 0. If y = f( x), then y = f( x h) gives a horizontal translation of the graph of f. The translation is h units to the right for h > 0 and h units to the left for h < 0. Virginia SOL AII.6 If y = f( x), then y = f( x) graph of f across the y-axis. gives a reflection of the graph of f across the x-axis. If y = f( x), then y = f( x) gives a reflection of the The student will recognize the general shape of function (absolute value, square root, cube root, rational, polynomial, exponential, and logarithmic) families and will convert between graphic and symbolic forms of functions. A transformational approach to graphing will be employed. Graphing calculators will be used as a tool to investigate the shapes and behaviors of these functions. A curve s shape is determined by the rule or relation which defines it. Very often multiplication or division is involved. A line s slope and a parabola s stretch or compression is attributed to dilation expansion, growing or shrinking, multiplication. If y = f( x), then y = af ( x) gives a vertical stretch or vertical compression of the graph of f. If a > 1, the graph is stretched vertically by a factor of a. If 0 < a < 1, the graph is compressed vertically by a factor of a. If y = f( x), then y = f ( bx) gives a horizontal stretch or horizontal compression of the 1 1 graph of f. If b > 1, the graph is compressed horizontally by a factor of b. If 0 < b < 1, the graph is stretched horizontally by a factor of b.

30 Resources Sample Instructional Strategies and Activities Functions Virginia SOL AII.6 Foundational Objectives A.4c The student will solve multi-step linear and quadratic equations in two variables, including solving quadratic equations algebraically and graphically. Resources TI-84 Graphing Calculators VA. SOL Coach and Buckle Down Flanagan Test Project Graduation VDOE ESS AII.6 Transformational Graphing The students are divided into small groups and given graph representations of the following functions: absolute value, square root, cube root, rational, polynomial, exponential, and logarithmic. They must identify the graph representations and explain the transformations from the basic graph of each function. Each group must verify their answers on the graphing calculator. Use compound interest, population growth, and/or rate of decay as examples of exponential functions. A.6 The student will graph linear equations and linear inequalities in two variables, including a. determining the slope of a line when given an equation of the line, the graph of the line, or two points on the line. Slope will be described as rate of change and will be positive, negative, zero, or undefined; and b. writing the equation of a line when given the graph of the line, two points on the line, or the slope and a point on the line. Math Dude: IXL.com Technology Glencoe Textbook Online: (AII.6) Chpts: -6, 6-6, 7-1, 7-9, 9-3, 9-5, 10-1 thru 10- Algebra I Online

31 Functions Virginia SOL AII.7 The student will investigate and analyze functions algebraically and graphically. Key concepts include a. domain and range, including limited and discontinuous domains and ranges; b. zeros; c. x-and y-intercepts; d. intervals in which a function is increasing or decreasing; e. asymptotes; f. end behavior; g. inverse of a function; and h. composition of multiple functions. Graphing calculators will be used as a tool to assist in investigation of functions. (continued) Essential Knowledge and Skills Key Vocabulary The student will use problem solving, mathematical communication, mathematical reasoning, connections and representations to: Identify the domain, range, zeros, and intercepts of a function presented algebraically or graphically. Describe restricted/discontinuous domains and ranges. Given the graph of a function, identify intervals on which the function is increasing and decreasing. Find the equations of vertical and horizontal asymptotes of functions. Describe the end behavior of a function. Find the inverse of a function. Graph the inverse of a function as a reflection across the line y = x. Investigate exponential and logarithmic functions using the graphing calculator. Convert between logarithmic and exponential forms of an equation with bases consisting of natural numbers. Find the composition of two functions. Use composition of functions to verify two functions are inverses. (continued) Essential Questions What is a function? What is the relationship between domain and range? What is the relationship between a function and its inverse? What is a zero of a function? What operations can be performed on functions? What is meant by composition of functions? What is the relationship between the degree of a function and the graph of a function? What is the relationship between exponential and logarithmic functions? How can the calculator be used to investigate the shape and behavior of polynomial, exponential, and logarithmic functions? How are the x- and y-intercepts determined? What is an asymptote? What role do asymptotes have in graphing functions? What is meant by the end behavior of a function? How can a hole in the graph of a function be determined? What is meant by the turning points of a function and how are they found? Essential Understandings Functions may be used to model real-world situations. The domain and range of a function may be restricted algebraically or by the real-world situation modeled by the function. A function can be described on an interval as increasing, decreasing, or constant. Asymptotes may describe both local and global behavior of functions. End behavior describes a function as x approaches positive and negative infinity. A zero of a function is a value of x that makes f(x) equal zero. If (a, b) is an element of a function, then (b, a) is an element of the inverse of the function. Exponential (y = a x ) and logarithmic (y = log a x) functions are inverses of each other. Functions can be combined using composition of functions. Functions describe the relationship between two variables. A function is continuous if the graph can be drawn without lifting the pencil from the paper. A graph is discontinuous if it has jumps, breaks, or holes in it. Each function, whether continuous or discontinuous, has a distinct domain, range, zero(s), y-intercept, and inverse. (continued)

32 Essential Knowledge and Skills Key Vocabulary Functions Virginia SOL AII.7 The student will investigate and analyze functions algebraically and graphically. Key concepts include a. domain and range, including limited and discontinuous domains and ranges; b. zeros; c. x-and y-intercepts; d. intervals in which a function is increasing or decreasing; e. asymptotes; f. end behavior; g. inverse of a function; and h. composition of multiple functions. Key Vocabulary asymptotes composition of functions continuous decreasing discontinuous domain end behavior increasing intercepts (x and y) inverse of a function polynomial function range strictly decreasing strictly increasing zero(s) (continued) (continued) The domain is the set of all possible values for the first coordinate of a function. The range of a function is the set of all possible values for the second coordinate of a function. The x-intercept is the x-coordinate of the point where the graph crosses the x-axis. The y-intercept is the y-coordinate of the point where the graph crosses the y-axis. An asymptote is a line that a graph approaches as x or y increases in absolute value. An asymptote of a curve is a line such that the distance between the curve and the line approaches zero as it tends to infinity. If x b is a factor of the numerator and the denominator of a rational function, then there is a hole in the graph of the function when x = b unless x = b is a vertical asymptote. The domain of every polynomial function is the set of all real numbers. As a result, the graph of a polynomial function extends infinitely. What happens to a polynomial function as its domain values get very small and very large is called the end behavior of a polynomial function. A polynomial function is a function of one variable whose exponents are natural numbers. The graph of a polynomial function can be generated by a table or a transformation of the parent function. The degree of a polynomial function determines its graphing behavior. A polynomial is linear, quadratic, cubic, quartic, etc., according to its degree, 1,, 3, 4, respectively. The degree of the polynomial will help determine the graph of a polynomial function. Graphing calculators will be used as a tool to assist in investigation of functions. n n 1 If a polynomial function is written in standard form, f( x) = ax n + an 1x ax 1 + a0, the leading coefficient is a n. The leading coefficient is the coefficient of the term of greatest degree in the polynomial. a n and n determine the end behavior of the graph of any polynomial function. - When the degree of the function is odd and the leading coefficient is positive, the graph falls on the left and rises on the right. - When the degree of the function is odd and the leading coefficient is negative, the graph rises on the left and falls on the right. - When the degree of the function is even and the leading coefficient is positive, the graph rises on the left and on the right. - When the degree of the function is even and the leading coefficient is negative, the graph falls on the left and the right.

33 Functions Virginia SOL AII.7 The student will investigate and analyze functions algebraically and graphically. Key concepts include a. domain and range, including limited and discontinuous domains and ranges; b. zeros; c. x-and y-intercepts; d. intervals in which a function is increasing or decreasing; e. asymptotes; f. end behavior; g. inverse of a function; and h. composition of multiple functions. Graphing calculators will be used as a tool to assist in investigation of functions. (continued) The points on the graph of a polynomial function that correspond to local maxima and local minima are called turning points. Functions can be combined through addition, subtraction, multiplication, division, and composition. The inverse of a function consisting of the ordered pairs (x, y) is the set of all ordered pairs (y, x). The domain of the inverse is the range of the original relation. The range of the inverse is the domain of the original relation. Graphs of functions that are inverses of each other are reflections across the line y = x. Graphing calculators are used to assist in the investigation of functions. Composition of functions refers to the forming of a new function h (the composite function) from given functions g and f by the rule: hx ( ) = g( f( x)) or hx ( ) = ( g f)( x) for all x in the domain of f for which f(x) is in the domain of g. This function is read as g of f. The order in which functions are combined is important. The composition of a function and its inverse is the identity function. Exponential and logarithmic functions, inverses of each other, are either strictly increasing or strictly decreasing. Exponential and logarithmic functions have asymptotes. A function is increasing on an interval if its graph always rises as it moves from left to right over the interval. It is decreasing on an interval if its graph always falls as it moves from left to right over the interval. If a function is strictly increasing or strictly decreasing no flatness is allowed. For a function y = f( x) : - When x1 < x, then f( x1) f( x) the function is increasing. - When x1 < x, then f( x1) < f( x) the function is strictly increasing. - When x1 > x, then f( x1) f( x) the function is decreasing. - When x1 > x, then f( x1) > f( x) the function is strictly decreasing. A function is constant on an interval if its graph is horizontal over the interval. For any x1 and x in the interval, where x1 < x, then f( x1) = f( x)

34 Functions Virginia SOL AII.7 The student will investigate and analyze functions algebraically and graphically. Key concepts include a. domain and range, including limited and discontinuous domains and ranges; b. zeros; c. x-and y-intercepts; d. intervals in which a function is increasing or decreasing; e. asymptotes; f. end behavior; g. inverse of a function; and h. composition of multiple functions. Graphing calculators will be used as a tool to assist in investigation of functions. (continued) Example: This function is constant on the interval [-5, ], decreasing on the interval (, 3), and increasing on the interval [3, ). y x

35 Resources Sample Instructional Strategies and Activities Functions Virginia SOL AII.7 Foundational Objectives A.4 The student will solve multi-step linear and quadratic equations in two variables, including c. solving quadratic equations algebraically and graphically; d. solving multi-step linear equations algebraically and graphically; A.7 The student will investigate and analyze function (linear and quadratic) families and their characteristics both algebraically and graphically, including a. determining whether a relation is a function; b. domain and range; c. zeros of a function; d. x- and y-intercepts; e. finding the values of a function for elements in its domain; and f. making connections between and among multiple representations of functions including concrete, verbal, numeric, graphic, and algebraic. Resources TI-84 Graphing Calculators VA. SOL Coach and Buckle Down Flanagan Test Project Graduation VDOE ESS AII.7 Rational Functions Intercept Asymototes AII.7 Functions: Domain, Range, End Behavior AII.7 Inverse Functions AII.7 Composition of Function Math Dude: IXL.com Technology Glencoe Textbook Online: (AII.6) Chpts: -6, 6-6, 7-1, 7-9, 9-3, 9-5, 10-1 thru 10- Algebra I Online Students, working in small groups, will be given several selective polynomial functions. They will use the graphing calculator to categorize these functions. Next, each group will draw conclusions about the general shape, end behavior, zeros, and y-intercept of the functions. Students, working in small groups, will be given several selective logarithmic and exponential functions. They will use the graphing calculator to categorize these functions. Next, each group will draw conclusions about the general shape and end behavior of the functions. On cards write 0 functions beginning with a(x), b(x), c(x). Mix the cards and select two at random. Have students write the composition of the two functions [e.g., a(d(x))]. Using the same functions have students reverse the order [e.g., (d(a(x))]. Is composition of functions commutative? Use the same cards and have students perform the four operations.

36 Functions Virginia SOL AII.8 The student will investigate and describe the relationships among solutions of an equation, zeros of a function, x-intercepts of a graph, and factors of a polynomial expression. Essential Knowledge and Skills Key Vocabulary The student will use problem solving, mathematical communication, mathematical reasoning, connections and representations to: Describe the relationships among solutions of an equation, zeros of a function, x-intercepts of a graph, and factors of a polynomial expression. Define a polynomial function, given its zeros. Determine a factored form of a polynomial expression from the x-intercepts of the graph of its corresponding function. For a function, identify zeros of multiplicity greater than 1 and describe the effect of those zeros on the graph of the function. Given a polynomial equation, determine the number of real solutions and non-real solutions. Key Vocabulary factor multiplicity root solution x-intercept zero of a function Essential Questions What is a polynomial function? What theorems assist in investigating the behavior of polynomial functions? What is the relationship between the solution of an equation, zeros of a function, x- intercepts of a graph, and factors of a polynomial expression? What is meant by the multiplicity of a zero and how does that affect the graph of the function? Essential Understandings The Fundamental Theorem of Algebra states that, including complex and repeated solutions, an nth degree polynomial equation has exactly n roots (solutions). The following statements are equivalent: - k is a zero of the polynomial function, f ; - (x k) is a factor of f( x ) ; - k is a solution of the polynomial equation f( x ) = 0 ; - k is an x-intercept for the graph of y = f( x) ; and - k is a root of the polynomial function f( x ). A polynomial function is a function of one variable whose exponents are natural numbers. The graph of a polynomial function can be generated by a table of values. The degree of a polynomial function determines its graphing behavior. A factor is a number or expression that is multiplied by one or more other numbers or expressions to yield a product. A factor of a polynomial is a polynomial by which a given polynomial is divisible. A root is a solution to an equation. A solution is a value that can replace the variable that makes an equation or inequality true. The x-intercept is the x-coordinate of the point where the graph crosses the x-axis. The zero of a function is any number x such that f( x ) = 0. The real zeros of a polynomial function correspond to the x-intercepts of the graph of the function.

37 Functions Virginia SOL AII.8 The student will investigate and describe the relationships among solutions of an equation, zeros of a function, x-intercepts of a graph, and factors of a polynomial expression. (continued) The relationship among the zeros of the polynomial function, the factors of the polynomial, and the solutions to the accompanying polynomial equation should be demonstrated graphically and algebraically. If a linear factor of a polynomial is repeated, then the zero is repeated. A repeated zero is called a multiple zero. A multiple zero has a multiplicity equal to the number of times the zero occurs. Multiplicity is the number of times that a factor is repeated in the factorization of a polynomial expression. Equivalent Statements about Polynomials - (x + 4) is a factor of x + 3x 4-4 is a solution of x + 3x 4= 0-4 is an x-intercept of the graph of f x x x - 4 is a zero of f( x) = x + 3x 4-4 is a root of f( x) = x + 3x 4 ( ) = Theorems that assist in explaining the relationships are: Factor Theorem, Remainder Theorem, Fundamental Theorem of Algebra, Rational Root Theorem, Complex Conjugates Theorem, and the Zero Product Property. Division may also be used to obtain a rational root. - Factor Theorem: The expression s a is a linear factor of a polynomial if and only if the value a is a zero or the related polynomial function. - Remainder Theorem: If a polynomial P(x) of degree n 1 is divided by (x a). where a is a constant, then the remainder is P(a). - Rational Root Theorem: If p q is in simplest form and is a rational root of the polynomial equation with integer coefficients, the p must be a factor of the constant and q must be a factor of the leading coefficient. - Complex Conjugates Theorem: If the imaginary number a + bi is a root of a polynomial equation with real coefficients, then the conjugate a bi also is a root. - Zero Product Property: If ab = 0, a = 0 and/or b = 0. Synthetic division, a shorten form of long division with polynomials, may be used to obtain a rational root. In synthetic division variables and exponents are not written. Synthetic division can be used to divide a polynomial only by a linear binomial of the form x r. When dividing by nonlinear divisors, long division is used.

38 Resources Sample Instructional Strategies and Activities Functions Virginia SOL AII.8 Foundational Objectives A.c The student will perform operations on polynomials, including factoring completely first- and second-degree binomials and trinomials in one or two variables. A.4c The student will solve multi-step linear and quadratic equations in two variables, including solving quadratic equations algebraically and graphically. A.7 The student will investigate and analyze function (linear and quadratic) families and their characteristics both algebraically and graphically, including c. zeros of a function; d. x- and y-intercepts; and e. finding the values of a function for elements in its domain. Resources TI-84 Graphing Calculators VA. SOL Coach and Buckle Down Flanagan Test Project Graduation VDOE ESS AII.8 Factors, Zeros, and Solutions Math Dude: IXL.com Technology Glencoe Textbook Online: (AII.6) Chpts: -6, 6-6, 7-1, 7-9, 9-3, 9-5, 10-1 thru 10- Algebra I Online The graphing calculator should be integrated throughout the study of polynomials for predicting solutions, determining the reasonableness of solutions, and exploring the behavior of polynomials.

39 Statistics Virginia SOL AII.9 The student will collect and analyze data, determine the equation of the curve of best fit, make predictions, and solve real-world problems using mathematical models. Mathematical models will include polynomial, exponential, and logarithmic functions. Essential Knowledge and Skills Key Vocabulary The student will use problem solving, mathematical communication, mathematical reasoning, connections and representations to: Collect and analyze data. Investigate scatterplots to determine if patterns exist and then identify the patterns. Find an equation for the curve of best fit for data using a graphing calculator. Models will include polynomial, exponential, and logarithmic functions. Make predictions using data, scatterplots, or the equation of the curve of best fit. Given a set of data, determine the model that would best describe the data. Key Vocabulary curve of best fit mathematical model scatterplot Essential Questions How do various algebraic equations fit real world data? How can the curve-of-best-fit help predict trends of data? How are the equations-of-best-fit determined on a graphing calculator? Essential Understandings Data and scatterplots may indicate patterns that can be modeled with an algebraic equation. Graphing calculators can be used to collect, organize, picture, and create an algebraic model of the data. n n 1 Data that fit polynomial ( f( x) = ax n + an 1x ax 1 + a0, where n is a nonnegative x integer, and the coefficients are real numbers), exponential ( y = b ), and logarithmic ( y = log b x ) models arise from real-world situations. In Algebra I objective 11, students collected and analyzed data and determined the equation of the curve of best fit in order to make predictions, and solve real-world problems using models which included linear and quadratic functions. A mathematical model usually describes a system by a set of variables and a set of equations that establish relationships between the variables. Data that fit polynomial, exponential, and logarithmic models arise from practical situations. The analyzing of data to determine a curve of best fit has numerous real-world applications such as oceanography, business, economics, and agriculture. A scatterplot visually shows the nature of a relationship and both its shape and dispersion. A curve of best fit may be drawn to show the approximate relationship formed by the plotted points. The use of scatterplots on a graphing calculator will determine if the relationship is polynomial, exponential, or logarithmic. Graphing calculators can be used to collect, organize, picture and create an algebraic model of the data.

40 Resources Sample Instructional Strategies and Activities Statistics Virginia SOL AII.9 Foundational Objectives A.11 The student will collect and analyze data, determine the equation of the curve of best fit in order to make predictions, and solve real-world problems, using mathematical models. Mathematical models will include linear and quadratic functions. Resources TI-84 Graphing Calculators VA. SOL Coach and Buckle Down Flanagan Test Project Graduation VDOE ESS AII.9 Curve of Best Fit Collect information from students on how many miles they drove that week and how many gallons of gasoline they used. Draw a scatterplot and make a prediction about how much gasoline they will use each year. Next, students will estimate the amount of money they will spend on gas this year, if gasoline cost $ 3.89 per gallon. Students try to determine how tall a person is whose femur is 17 inches long. They measure their own femurs and their heights and enter the data into a graphing calculator or computer to get a scatterplot. Find the equation for the curve of best fit and use it to make predictions. Math Dude: Technology IXL.com Glencoe Textbook Online: (AII.6) Chpts: -6, 6-6, 7-1, 7-9, 9-3, 9-5, 10-1 thru 10- Algebra I Online

41 Statistics Virginia SOL AII.10 The student will identify, create, and solve real-world problems involving inverse variation, joint variation, and a combination of direct and inverse variations. Essential Knowledge and Skills Key Vocabulary The student will use problem solving, mathematical communication, mathematical reasoning, connections and representations to: Translate y varies jointly as x and z as y = kxz. Translate y is directly proportional to x as y = kx. Translate y is inversely proportional to k x as y =. x Given a situation, determine the value of the constant of proportionality. Set up and solve problems, including real-world problems, involving inverse variation, joint variation, and a combination of direct and inverse variations. Key Vocabulary combined variation constant of proportionality direct variation inverse variation joint variation proportional Essential Questions What is the difference between direct and inverse variation? What is joint variation? What is combined variation? Essential Understandings Real-world problems can be modeled and solved by using inverse variation, joint variation, and a combination of direct and inverse variations. Joint variation is a combination of direct variations. Two variable quantities are proportional if one of them is always the product of the other and a constant quantity. Rational equations, to include direct and inverse variation, can be solved algebraically. Direct variation: When two variables are related so that their ratio remains constant, one of the variables is said to vary directly to the other variables or the variables are said to vary proportionately. A linear function defined by an equation of the form y = kx, where k 0, represents direct variation. The constant of variation (constant of proportionality) is k. For a linear function to be a direct variation the graph must be a non-horizontal line through the origin. Inverse variation: When the ratio of one variable is constant to the reciprocal of the other variable, one of the variables is said to k vary inversely to the other variable. A function of the form y = or xy = k, where k 0, is an inverse x variation. The constant of variation (constant of proportionality) is k. Joint variation: If y = kxz then y varies jointly as x and z, and the constant of variation is k. In joint variation one quantity varies directly as two quantities. This is a combination of direct variations. For example: In a rectangular prism the equation for volume is V = lwh. If h = 8 then the volume varies jointly as the length (l) and width (w). The constant of variation is 8. Combined variation: This involves both direct and inverse variations occurring in the same equation. Practical problems can be modeled and solved by using direct and/or inverse variations.

42 Resources Sample Instructional Strategies and Activities Resources TI-84 Graphing Calculators VA. SOL Coach and Buckle Down In groups have students develop problems that involve the different variations. Students explain how they know what type of variation this problem represents. Statistics Flanagan Test Project Graduation Virginia SOL AII.10 Foundational Objectives A.8 The student, given a situation in a real-world context, will analyze a relation to determine whether a direct or inverse variation exists, and represent a direct variation algebraically and graphically and an inverse variation algebraically. VDOE ESS AII.10 Types of Variations Math Dude: IXL.com Technology Glencoe Textbook Online: (AII.6) Chpts: -6, 6-6, 7-1, 7-9, 9-3, 9-5, 10-1 thru 10- Algebra I Online

43 Essential Knowledge and Skills Key Vocabulary Statistics Virginia SOL AII.11 The student will identify properties of a normal distribution and apply those properties to determine probabilities associated with areas under the standard normal curve. The student will use problem solving, mathematical communication, mathematical reasoning, connections and representations to: Identify the properties of a normal probability distribution. Describe how the standard deviation and the mean affect the graph of the normal distribution. Compare two sets of normally distributed data using a standard normal distribution and z-scores. Represent probability as area under the curve of a standard normal probability distribution. Use the graphing calculator or a standard normal probability table to determine probabilities or percentiles based on z-scores. Key Vocabulary area under a curve mean normal distribution curve normal probability distribution percentile population standard deviation standard normal curve z-score Essential Questions What is a normal distribution curve and how is the graph constructed? How can the amount of data that lies within 1,, 3, or k standard deviations of the mean be found? How does the standard normal distribution curve correspond to probability? How can the area under the standard normal curve be found? How is a standard normal probability table used and applied in problem solving? Essential Understandings A normal distribution curve is a symmetrical, bell-shaped curve defined by the mean and the standard deviation of a data set. The mean is located on the line of symmetry of the curve. Areas under the curve represent probabilities associated with continuous distributions. The normal curve is a probability distribution and the total area under the curve is 1. For a normal distribution, approximately 68 percent of the data fall within one standard deviation of the mean, approximately 95 percent of the data fall within two standard deviations of the mean, and approximately 99.7 percent of the data fall within three standard deviations of the mean. The mean of the data in a standard normal distribution is 0, and the standard deviation is 1. The standard normal curve allows for the comparison of data from different normal distributions. A z-score is a measure of position derived from the mean and standard deviation of data. A z-score expresses, in standard deviation units, how far an element falls from the mean of the data set. A z-score is a derived score from a given normal distribution. A standard normal distribution is the set of all z-scores. Statistics is the science of collecting, analyzing, and drawing conclusions from data. Methods for organizing and summarizing data make up the branch of statistics called descriptive statistics. Measures of dispersion indicate the extent to which values are spread around a central value such as the mean when doing standard deviation or the median when doing boxand-whisker plots. (continued)

44 (continued) Differences from the mean, x - µ, are called deviations. The deviation of an entry x in a population data set is the difference between the entry and the mean µ of the data set. The mean is the balance point of the distribution, so the set of deviations from the mean will always add to zero. Statistics The following technical assistance is provided by the VDOE for use with Algebra I, objective 9. This objective is intended to extend the study of descriptive statistics beyond the measures of center studied during the middle grades. Although calculation is included in this objective, instruction and assessment emphasis should be on understanding and interpreting statistical values associated with a data set including standard deviation, mean absolute deviation, and z-score. While not explicitly included in this objective, the arithmetic mean will be integral to the study of descriptive statistics. Virginia SOL AII.11 The student will identify properties of a normal distribution and apply those properties to determine probabilities associated with areas under the standard normal curve. The study of statistics includes gathering, displaying, analyzing, interpreting, and making predictions about a larger group of data (population) from a sample of those data. Data can be gathered through scientific experimentation, surveys, and/or observation of groups or phenomena. Numerical data gathered can be displayed numerically or graphically (examples would include line plots, histograms, and stem-and-leaf plots). Methods for organizing and summarizing data make up the branch of statistics called descriptive statistics. Sample vs. Population Data Sample data can be collected from a defined statistical population. Examples of a statistical population might include SOL scores of all Algebra I students in Virginia, the heights of every U.S. president, or the ages of every mathematics teacher in Virginia. Sample data can be analyzed to make inferences about the population. A data set, whether a sample or population, is comprised of individual data points referred to as elements of the data set. An element of a data set will be represented as x i, where i represents the i th term of the data set. When beginning to teach this standard, start with small, defined population data sets of approximately 30 items or less to assist in focusing on development of understanding and interpretation of statistical values and how they are related to and affected by the elements of the data set. Related to the discussion of samples versus populations of data are discussions about notation and variable use. In formal statistics, the arithmetic mean (average) of a population is represented by the Greek letter μ (mu), while the calculated arithmetic mean of a sample is represented by x, read x bar. The arithmetic mean of a data set will be represented by μ. Only population data sets (not sample data sets) will be used in the statistics units of study in Algebra I and Algebra II. The formulas provided by the state in the Technical Assistance Manuals for Algebra I and Algebra II and SOL formula sheets use n to represent population size. Typically this is represented by N. On both brands of approved graphing calculators in Virginia, the calculated arithmetic mean of a data set is represented by x.

45 Statistics (continued) Mean Absolute Deviation vs. Variance and Standard Deviation Statisticians like to measure and analyze the dispersion (spread) of the data set about the mean in order to assist in making inferences about the population. One measure of spread would be to find the sum of the deviations between each element and the mean; however, this sum is always zero. There are two methods to overcome this mathematical dilemma: 1) take the absolute value of the deviations before finding the average or ) square the deviations before finding the average. The mean absolute deviation uses the first method and the variance and standard deviation uses the second. If either of these measures is to be computed by hand, do not require students to use data sets of more than about 10 elements. NOTE: Students have not been introduced to summation notation prior to Algebra I. An introductory lesson on how to interpret the notation will be necessary. Virginia SOL AII.11 The student will identify properties of a normal distribution and apply those properties to determine probabilities associated with areas under the standard normal curve. Examples of summation notation: 5 i= 1 i = i= 1 x = x + x + x + x i Mean Absolute Deviation Mean absolute deviation is one measure of spread about the mean of a data set, as it is a way to address the dilemma of the sum of the deviations of elements from the mean being equal to zero. The mean absolute deviation is the arithmetic mean of the absolute values of the deviations of elements from the mean of a data set. n xi µ i= 1 = Mean absolute deviation n, where µ represents the mean of the data set, n represents the number of elements in the data set, and xi represents the ith element of the data set. The mean absolute deviation is less affected by outlier data than the variance and standard deviation. Outliers are elements that fall at least 1.5 times the interquartile range (IQR) below the first quartile (Q1) or above the third quartile (Q3). Graphing calculators identify Q1 and Q3 in the list of computed 1-varible statistics. Mean absolute deviation cannot be directly computed on the graphing calculator as can the standard deviation. The mean absolute deviation must be computed by hand or by a series of keystrokes using computation with lists of data (See examples of calculator keystrokes in the Algebra I Curriculum Guide.). Variance The second way to address the dilemma of the sum of the deviations of elements from the mean being equal to zero is to square the deviations prior to finding the arithmetic mean. The average of the squared deviations from the mean is known as the variance, and is another measure of the spread of the elements in a data set. (continued)

46 Statistics (continued) n ( xi µ ) i= 1 Variance ( σ ) = n, where µ represents the mean of the data set, n represents the number of elements in the data set, and x i represents the i th element of the data set. The differences between the elements and the arithmetic mean are squared so that the differences do not cancel each other out when finding the sum. When squaring the differences, the units of measure are squared and larger differences are weighted more heavily than smaller differences. In order to provide a measure of variation in terms of the original units of the data, the square root of the variance is taken, yielding the standard deviation. Standard Deviation The standard deviation is the positive square root of the variance of the data set. The greater the value of the standard deviation, the more spread out the data are about the mean. The lesser (closer to 0) the value of the standard deviation, the closer the data are clustered about the mean. Virginia SOL AII.11 The student will identify properties of a normal distribution and apply those properties to determine probabilities associated with areas under the standard normal curve. ( xi µ ) i= 1 Standard deviation ( σ ) = n, where µ represents the mean of the data set, n represents the number of elements in the data set, and x i represents the i th element of the data set. To find standard deviation: - Find the mean of the data set µ. - Find the difference between each value and the mean: x µ - Square each difference: ( x µ ) - Find the mean of these squares (also referred to as the variance): - Take the square root to find the standard deviation: n i= 1 σ = n i= 1 σ = ( x µ ) n ( x µ ) n If the difference between mean absolute deviation and standard deviation is large, then the data has a great amount of variability.

47 Statistics Virginia SOL AII.11 The student will identify properties of a normal distribution and apply those properties to determine probabilities associated with areas under the standard normal curve. (continued) Often, textbooks will use two distinct formulas for standard deviation. In these formulas, the Greek letter σ, written and read sigma, represents the standard deviation of a population, and s represents the sample standard deviation. The population standard deviation can be estimated by calculating the sample standard deviation. The formulas for sample and population standard deviation look very similar except that in the sample standard deviation formula, n 1 is used instead of n in the denominator. The reason for this is to account for the possibility of greater variability of data in the population than what is seen in the sample. When n 1 is used in the denominator, the result is a larger number. So, the calculated value of the sample standard deviation will be larger than the population standard deviation. As sample sizes get larger (n gets larger), the difference between the sample standard deviation and the population standard deviation gets smaller. The use of n 1 to calculate the sample standard deviation is known as Bessel s correction. Use the formula for standard deviation with n in the denominator as noted previously. When using Casio or Texas Instruments (TI) graphing calculators to compute the standard deviation for a data set, two computations for the standard deviation are given, one for a population (using n in the denominator) and one for a sample (using n 1 in the denominator). Students should be asked to use the computation of standard deviation for population data in instruction and assessments. On a Casio calculator, it is indicated with xσ n and on a TI graphing calculator as σ x. More information (keystrokes and screenshots) on using graphing calculators to compute this can be found in the Algebra I Curriculum Guide in objective nine. z-scores A z-score, also called a standard score, is a measure of position derived from the mean and standard deviation of the data set. In Algebra I, the z-score will be used to determine how many standard deviations an element is above or below the mean of the data set. It can also be used to determine the value of the element, given the z-score of an unknown element and the mean and standard deviation of a data set. The z-score has a positive value if the element lies above the mean and a negative value if the element lies below the mean. A z-score associated with an element of a data set is calculated by subtracting the mean of the data set from the element and dividing the result by the standard deviation of the data set. x µ ( z) = z-score σ, where x represents an element of the data set, µ represents the mean of the data set, and σ represents the standard deviation of the data set. A z-score can be computed for any element of a data set; however, they are most useful in the analysis of data sets that are normally distributed. In Algebra II, z-scores will be used to determine the relative position of elements within a normally distributed data set, to compare two or more distinct data sets that are distributed normally, and to determine percentiles and probabilities associated with occurrence of data values within a normally distributed data set. (continued)

48 Statistics Virginia SOL AII.11 The student will identify properties of a normal distribution and apply those properties to determine probabilities associated with areas under the standard normal curve. (continued) The following technical assistance is provided by the VDOE for use with Algebra II, Objective 11. In Algebra I SOL A.9, students study descriptive statistics through exploration of standard deviation, mean absolute deviation, and z-scores of data sets. Students compute these values for small defined populations, and the focus of instruction is on interpretation of these descriptive statistics. Algebra II, Objective 11 continues the study of descriptive statistics as students analyze properties of normal distributions and apply those properties to determine probabilities associated with areas under the standard normal curve. Students will be provided with the mean, standard deviation, and/or elements of samples or populations of normal distributions and asked to apply the properties of normal distributions to calculate probabilities associated with given elements of the data set. Normal Distributions Students examine many sets of data in their study of statistics. Some data have been provided to them and some data they have collected through surveys, experiments, or observations. Representation of data can take on many forms (line plots, stem-and-leaf plots, box-and-whisker plots, bar graphs, circle graphs, and histograms). Often teachers try to describe the physical shape of these representations in words or by using measures such as the arithmetic mean, the balance point of the data, or the median, the point at which the data is split into two equal amounts of data points. Another useful type of graphical representation is called a density curve, which models the pattern of a distribution. The distribution of certain types of data take on the appearance of a bell-shaped density curve called a normal curve. These collections of data are often naturally-occurring data or data produced by repetition in a mechanical process. Examples of data that can be modeled by normal distributions include: heights of corn stalks in similar growing environments; heights of 16-year-old girls; blood pressures of 18-year-old males; weights of pennies in a given production year; lifespan of a specific electric motor; and standardized test scores like the ACT or SAT. (continued)

49 Statistics Virginia SOL AII.11 The student will identify properties of a normal distribution and apply those properties to determine probabilities associated with areas under the standard normal curve. (continued) Standard Deviation The standard deviation (σ) of a data set is a measure of the spread of data about the mean. The greater the value of the standard deviation, the more spread out the data are about the mean. The lesser (closer to 0) the value of the standard deviation, the closer the data are clustered about the mean. Properties of normal distributions (normal probability distribution for continuous data) Normal distributions are represented by a family of symmetric, bell-shaped curves called normal curves. Normal curves are defined by the mean and standard deviation of the data set. The arithmetic mean is located on the line of symmetry of the curve. In a normal distribution, the arithmetic mean is equivalent to the median and mode of the data set. Approximately 68 percent of the data values fall within one standard deviation (σ) of the mean (μ), approximately 95 percent of the data values fall within two standard deviations of the mean, and approximately 99.7 percent of the data values fall within three standard deviations of the mean. This is often referred to as the rule. Figure 1 Figure 1 shows the approximate percentage of observations that fall within different partitions of the normal distribution. In normal distributions, the total area under the curve is always equal to 1. The mean and standard deviation of a normal distribution affect the location and shape of the curve. The vertical line of symmetry of the normal distribution falls at the mean and the width or spread of the curve is determined by the standard deviation. The greater the standard deviation, the wider ( flatter or less peaked ) the distribution of the data. (continued)

50 Statistics (continued) Summary of the Properties of the Normal Distribution - The curve is bell shaped. - The mean, median, and mode are equal and located at the center. - The curve is unimodal, it has only one mode. - The curve is symmetric about the mean. - The curve is continuous. - The curve never touches the x-axis, which is the asymptote to the curve. - The total area under the curve is equal to 1.00 or 100%. - The area which lies within one standard deviation is 68%, two standard deviations is 95%, and three standard deviations is 99.7%. Virginia SOL AII.11 Figure The student will identify properties of a normal distribution and apply those properties to determine probabilities associated with areas under the standard normal curve. Figure shows how mean (μ) and standard deviation (σ) affect the graph of the normal distribution. (continued)

51 (continued) A normal distribution with μ = 5 and σ = 1.5 can be graphed on a graphing calculator. Texas Instruments (TI-83/84) Calculator function parameters - normalpdf(x, µ, σ) Statistics 1. Press Y = nd VARS (to get to the distribution menu). Select "1:normalpdf(" or press ENTER 3. Press X, T, θ, n, 5, 1. 5 ) ENTER 4. Set the window as follows: Virginia SOL AII.11 The student will identify properties of a normal distribution and apply those properties to determine probabilities associated with areas under the standard normal curve. 1 Hint: When graphing normal distributions, set Ymax = σ. 5. Press GRAPH and TRACE (to see the function and values) (continued)

52 Statistics Virginia SOL AII.11 The student will identify properties of a normal distribution and apply those properties to determine probabilities associated with areas under the standard normal curve. (continued) Casio (9750/9850/9860) NOTE: Casio calculators will not graph a normal distribution given only the mean and standard deviation. An element (x) of the data set must also be entered in order to enable the graphing feature. 1. From the menu screen select and press EXE. Pres F5 (to choose "DIST") 3. Press F1 (to choose "NORM") 4. Press F1 (to choose "Npd") 5. Enter the values for x, µ, and σ 6. Arrow down and highlight "Execute" 7. Press F6 (to choose "DRAW") (continued)

53 Statistics Virginia SOL AII.11 The student will identify properties of a normal distribution and apply those properties to determine probabilities associated with areas under the standard normal curve. (continued) Determining probabilities associated with normal distributions The cumulative probability of a specified range of values can be represented as the area under a normal distribution curve between the lower and upper bounds. When the range of values is an interval with lower and upper bounds equal to the mean or mean plus or minus one, two, or three standard deviations, the rule can be used to determine probabilities. Graphing calculators can also be used to compute and graph the areas under normal curves. Example 1 Given a normally distributed data set of 500 observations measuring tree heights in a forest, what is the approximate number of observations that fall within two standard deviations from the mean? Solution A quick sketch of the normal distribution will assist in solving this problem (refer to Figure 1). We know from the rule that 95 percent of the data falls within two standard deviations from the mean. Therefore, approximately = 475 of the trees height observations fall within two standard deviations from the mean. Example A normally distributed data set containing the number of ball bearings produced during a specified interval of time has a mean of 150 and a standard deviation of 10. What percentage of the observed values fall between 140 and 160? Solution From the sketch of a normally distributed data set, 140 is one standard deviation below the mean while 160 is one standard deviation above the mean. Therefore, approximately 34.1% % = 68.% of the data in this distribution falls between 140 and 160. Example 3 Donna s boss asked her to purchase a large number of 0-watt florescent light bulbs for their company. She has narrowed her search to two companies offering 0-watt bulbs for the same price. The Bulb Emporium and Lights-R-Us each claim that the mean lifespan for their 0-watt bulbs is 10,000 hours. The lifespan of light bulbs has a distribution that is approximately normal. The Bulb Emporium s distribution of the lifespan for 0-watt bulbs has a standard deviation of 1,000 hours and Lights-R-Us distribution of the lifespan of 0-watt bulbs has a standard deviation of 750 hours. Donna s boss asked her to use probabilities associated with these normal distributions to make a purchasing decision. (continued)

54 Statistics (continued) Donna decided that she would compare the proportion of light bulbs from each company that would be expected to last for different intervals of time. She started with calculating the probability that a light bulb would be expected to last less than or equal to 9,000 hours. Letting x represent the lifespan of a light bulb, P(x 9,000 hours) represents the probability that the lifespan of a light bulb would fall less than or equal to 9,000 hours in its normal distribution. Donna continued by finding P(9,000 x 11,000 hours) and P(x 11,000 hours) for each company. Virginia SOL AII.11 The student will identify properties of a normal distribution and apply those properties to determine probabilities associated with areas under the standard normal curve. There are two ways to find the cumulative probability within a range of values on TI graphing calculators. The probability can be computed by finding the area under the curve bounded by a range of values using the ShadeNorm function, or it can be directly computed using the normalcdf function. Texas Instruments (TI-83/84) Computing probabilities using the ShadeNorm function: Calculator function parameters - normalpdf(x, μ, σ) ShadeNorm(lowerbound,upperbound, μ, σ) 1. Graph the normal distribution of the lightbulbs using the function Y1= normalpdf(x,10000,1000) and the window shown. NOTE: The calculator automatically converts very small numbers to scientific notation. To shade and compute the area under the curve for P(x 9,000 hours). nd VARS to select "Draw" 3. Choose "ShadeNorm("or press ENTER 4. Press 0, , , ) ENTER (continued)

55 (continued) Statistics Virginia SOL AII.11 The student will identify properties of a normal distribution and apply those properties to determine probabilities associated with areas under the standard normal curve. The area under the curve is equal to To shade and compute the area under the curve for P(9,000 x 11,000 hours), use ShadeNorm(9000,11000,10000,1000) to get NOTE: Use the ClrDraw function (nd PRGM 1 ENTER ) to clear graph shading between each shading. To shade and compute the area under the curve for P(x 11,000 hours), use ShadeNorm(11000,50000,10000,1000) to get Computing probabilities using the normalcdf function Calculator function parameters - normalcdf(lowerbound,upperbound, µ, σ) To compute P(x 9,000 hours) 1. Press nd VARS (to bring "normalcdf(" to the home screen). Press 0, , , ) ENTER P(x 9,000 hours) = (continued)

56 (continued) To compute P((9,000 x 11,000 hours) = 0.687, use the syntax below. Statistics Virginia SOL AII.11 The student will identify properties of a normal distribution and apply those properties to determine probabilities associated with areas under the standard normal curve. To compute P(x 11,000 hours) = , use the syntax below. Note: When computing cumulative probabilities greater than a value using the normalcdf function, the upper bound should be at least µ+ 4σ. On Casio graphing calculators, a feature similar to the TI s ShadeNorm is only available in terms of the standard normal distribution using z-scores (see Example 4, Solution B on page 60). The cumulative probabilities within a range of values can be computed on Casio graphing calculators. (continued)

57 Statistics Virginia SOL AII.11 The student will identify properties of a normal distribution and apply those properties to determine probabilities associated with areas under the standard normal curve. (continued) Casio (9750/9850/9860) Computing probabilities using the Ncd function To compute P(x 9,000 hours) 1. From the menu screen select and press EXE. Press F5 (to choose "DIST") 3. Press F1 (to choose "NORM") 4. Press F (to choose "Ncd") 5. Enter values Lower bound = 9000 Upper bound = σ = 1000 µ = 10, Arrow down to highlight "Execute" 7. Press F1 (to choose "CALC") NOTE: For information on what "z:" means, see section on standard normal distribution and z-scores. After recording the probabilities for the Bulb Emporium as shown in Figure 3, Donna calculated the same interval probabilities for Lights- R-Us and recorded them. Figure 3 Bulb Emporium (σ = 1000) Lights-R-Us (σ = 750) P(x 9,000 hours) P(9,000 x 11,000 hours) P(x 11,000 hours) (continued)

58 Statistics Virginia SOL AII.11 The student will identify properties of a normal distribution and apply those properties to determine probabilities associated with areas under the standard normal curve. (continued) In analyzing her data, Donna noticed that a lightbulb at Bulb Emporium had a higher probability of lasting less than 9,000 hours than a bulb at Lights-R-Us. However, a lightbulb at Bulb Emporium also had a higher probability of lasting longer than 11,000 hours than a bulb at Lights-R-Us. She determined that these two statistical probabilities offset one another. The middle interval of data showed that a bulb at Bulb Emporium had a lower probability of lasting between 9,000 and 11,000 hours, inclusively, than a bulb at Lights-R-Us. She therefore chose to purchase lightbulbs from Lights-R-Us. z-scores A z-score, also called a standard score, is a measure of position derived from the mean and standard deviation of the data set. The z-score is a measure of how many standard deviations an element falls above or below the mean of the data set. The z-score has a positive value if the element lies above the mean and a negative value if the element lies below the mean. A z-score associated with an element of a data set is calculated by subtracting the mean of the data set from the element and dividing the result by the standard deviation of the data set. z-score ( z) = x µ σ where x represents an element of the data set, μ represents the mean of the data set, and σ represents the standard deviation of the data set. The standard normal curve is a normal distribution that has a mean of 0 and a standard deviation of 1. It is used to model z-scores obtained from normally distributed data. Prior to calculator technologies that can determine probabilities associated with normal distributions, the table of Standard Normal Probabilities, commonly referred to as a z-table was used to determine normal distribution probabilities. See pages 63 and 64 for a copy of the table of Standard Normal Probabilities provided for the Algebra II End-of-Course (EOC) SOL test. Given a z-score (z), the table of Standard Normal Probabilities shows the area under the curve to the left of z. This area represents the proportion of observations with a z-score less than the one specified. Table rows show the z-score s whole number and tenths place. Table columns show the hundredths place. In the table of Standard Normal Probabilities provided for the state EOC SOL test in Algebra II, the cumulative probability from negative infinity to the z-score appears in table cells. Other tables of Standard Normal Probabilities show probabilities from the mean to the z-score. (continued)

59 Statistics Virginia SOL AII.11 The student will identify properties of a normal distribution and apply those properties to determine probabilities associated with areas under the standard normal curve. (continued) Interpreting values from the table of Standard Normal Probabilities A z-score associated with an element of a normal distribution is computed to be 1.3. The probability from the table of Standard Normal Probabilities associated with a z-score of 1.3 can be determined as indicated in Figure 4. The probability can be used differently based upon the context of the question. - The probability that a data value will fall below the data value associated with a z-score of 1.3 is (89.07%). - The data value associated with a z-score of 1.3 falls in the 89th percentile. This means that 89 percent of the data in the distribution fall below the value associated with a z-score of The probability that a value from the data set will fall above this value is = (10.93%). Figure 4 Figure 4 shows the cumulative probability associated with a z-score of 1.3 using the table of standard normal probabilities.