AF Math Algebra 1 Unit 2 UNIT OVERVIEW Unit Title Function Modeling Unit Designers Approximate Length IA Period 16 days 1 Stage 1: Desired Results ENDURING UNDERSTANDINGS AND BIG IDEAS What do you want students to know in 10 years about this topic? Enduring understanding/Big idea What it looks like in this unit Algebraic expressions and equations are used to model and makeIn this unit, students will use functions to model a variety of sense of real-life problems and relationships. Many relationships dependent relationships. They will begin to distinguish between can be modeled linearly if there is a constant rate of change relationships that are best modeled linearly versus non-linear (in between the variables. Otherwise, a non-linear function such as a this unit, just exponential) relationships. quadratic or exponential can be used. Algebraic relationships can be represented in multiple, equivalent Students begin working with and seeing connections between ways (verbally, analytically, numerically, and graphically). Each multiple representations of functions. representation is useful for different types of analysis. In arithmetic, you calculate with numbers; in algebra, you reason Students will build on their knowledge of properties of numbers about numbers, however, the essential operations and properties when evaluating functions for given inputs and when combining of numbers are consistent. functions. An equation is a statement of equality between two expressions It is important for students to begin, in this unit, to see the whereas functions describe situations where one quantity connections between equations and functions. Though this will be determines another. However, expressions and equations can also more the focus of Unit 4 when students work with two-variable be viewed as defining functions if the input and output variables equations. are defined, and if there is just one output for each input. Solving problems algebraically typically involves transforming one equation to another equivalent equation, often in a standard form, in order to find the solution. ESSENTIAL QUESTIONS AF Math Algebra 1 Unit 2 What question(s) will guide this unit and focus learning and thinking? How is a function similar to and different from an equation or algebraic expression? o In one-variable equations, the variable represents a fixed quantity that can be determined by solving the equation. In a function such as f (x) = 2 x + 3 , f (x) represents a specific output value when the input value is x. In general, the function f as a whole defines the set of output values far all possible input values. An expression could also be defined as a function of x where the input value is the given value at which you are asked to evaluate the expression. o Students should be able to explain why they can’t “solve” the equation f (x) = 2 x + 3 but why they could solve the equation if they were given the input value and asked to find the output value or vice versa. This is all connected to and laying the foundation for two-variable equations in Unit 4. What can the graph of a function tell us? o Students should see the graph of a function as a different way of looking at the same relationship (rather than representing a different relationship) and that the graph provides a quick way to see trends of the function or to look for specific behaviors. For example, if you were looking for the x-intercept of a function, you could continue plugging in points until you found one where the output was zero, you could solve for the input value when the output is zero, or you could check the graph of the function and at least make a quick approximation. In order to make this point, students should use graphs to make approximations of key points of functions that they are not ready to find algebraically. In this unit, the idea of graphing and why it is useful is more important than having students create tables and plot points. o Be sure to also include key graph features that are outside of the normal viewing window of the calculator. How can you tell if a situation should be modeled linearly or exponentially? o Students should be able to look for non-linear trends in the data given either as a table or graph to identify that a non-linear model would be most appropriate. However, they should also be able to look for non-constant rates of change in a situation given in context. UNIT NARRATIVE What is the purpose of this unit? How does it fit in the broader context of the course? In earlier grades, students define, evaluate, and compare functions, and use them to model relationships between quantities. In this unit, students will learn function notation and develop the concepts of domain and range. They explore many examples of functions, including sequences; they interpret functions given graphically, numerically, symbolically, and verbally, translate between representations, and understand the limitations of various representations. AF Math Algebra 1 Unit 2 The goal of this unit is to develop students’ understanding of the broad themes of functions used to model real-life situations: the relationship between two quantities, the domain and range over which those quantities are defined, evaluating multiple representations of functions, and analyzing functions for given characteristics such as increasing rates of change, maximums and minimums, and intercepts. The focus of this unit should be on conceptual understanding of these ideas rather than on computation and procedural fluency. STANDARDS FOR MATHEMATICAL PRACTICE Which are the primary SMPs for this unit? How will they be incorporated and reinforced throughout this unit? In this unit, students will encounter challenging problems in which they must look for MP1 Make sense of problems and patterns, identify linear or exponential trends from context, and create and test (rather than persevere in solving them just identify) functions. MP2 is a huge focus of this unit since students are constantly going to be moving back and forth between verbal, algebraic, graphical, and numerical representations for the same MP2 Reason abstractly and quantitatively relationship. They should build on their work in the previous unit by continually considering the meaning of the numbers and letters in terms of the situation. Students will need to argue and defend their choices in this unit around whether or not a MP3 Construct viable arguments and relationship is a function, what makes sense as a reasonable domain for a given function, critique the reasoning of others and whether a linear or exponential model best fits a given relationship. Each lesson of this unit students should see functions that model real-life situations, MP4 Model with mathematics including functions which can’t easily be defined algebraically (e.g. the dollar-bill change machine or a soda vending machine). Students should be using their graphing calculator when necessary to represent functions MP5 Use appropriate tools strategically given algebraically and look for key features of the graph. The new notation and vocabulary gives students many opportunities to practice attending MP6 Attend to precision to precision. Students will analyze patterns and also look for structures (algebraic, verbal, and graphical) MP7 Look for and make use of structure that indicate whether a function is best represented linearly or exponentially. MP8 Look for and express regularity in repeated reasoning CONTENT STANDARDS Major: AF Math Algebra 1 Unit 2 Understand the concept of a function and use function notation. F-IF.1 Understand that a function from one set (called the domain) to another set (called the range) assigns to each element of the domain exactly one element of the range. If f is a function and x is an element of its domain, then f(x) denotes the output of f corresponding to the input x. The graph of f is the graph of the equation y = f(x). F-IF.2 Use function notation, evaluate functions for inputs in their domains, and interpret statements that use function notation in terms of a context. F-IF.3 Recognize that sequences are functions, sometimes defined recursively, whose domain is a subset of the integers. For example, the Fibonacci sequence is defined recursively by f(0) = f(1) = 1, f(n+1) = f(n) + f(n-1) for n ≥ 1 (n is greater than or equal to 1). Interpret functions that arise in applications in terms of the context. F-IF.4 For a function that models a relationship between two quantities, interpret key features of graphs and tables in terms of the quantities, and sketch graphs showing key features given a verbal description of the relationship. Key features include: intercepts; intervals where the function is increasing, decreasing, positive, or negative; relative maximums and minimums; symmetries; end behavior; and periodicity.* F-IF.5 Relate the domain of a function to its graph and, where applicable, to the quantitative relationship it describes. For example, if the function h(n) gives the number of person-hours it takes to assemble n engines in a factory, then the positive integers would be an appropriate domain for the function.* F-IF.9 Compare properties of two functions each represented in a different way (algebraically, graphically, numerically in tables, or by verbal descriptions). For example, given a graph of one quadratic function and an algebraic expression for another, say which has the larger maximum. Build a function that models a relationship between two quantities. F-BF.1 Write a function that describes a relationship between two quantities.* F-BF.1b Combine standard function types using arithmetic operations. For example, build a function that models the temperature of a cooling body by adding a constant function to a decaying exponential, and relate these functions to the model. Supporting: Construct and compare linear, quadratic, and exponential models and solve problems. F-LE.1 Distinguish between situations that can be modeled with linear functions and with exponential functions.* AF Math Algebra 1 Unit 2 F-LE.3 Observe using graphs and tables that a quantity increasing exponentially eventually exceeds a quantity increasing linearly, quadratically, or (more generally) as a polynomial function.* Interpret expressions for functions in terms of the situations they model. F-LE.5 Interpret the parameters in a linear or exponential function in terms of a context.* ESSENTIAL SKILLS AND PROCEDURAL KNOWLEDGE What do you want students to be able to do comfortably, accurately, and with flexibility? Evaluate a function given algebraically or graphically using function notation Identify the domain and range of a function given in any representation Identify key features of a graph such as x- and y-intercepts, increasing, decreasing, positive, and negative intervals Connect an algebraic representation to key features of the graph of the function Describe differences in growth and rates of change between linear and exponential functions Identify a recursive or explicit function that matches a given sequence UNIT VOCABULARY Vocabulary to Review (CC 8th grade math) Function Function model Initial value Input Linear Output Rate of change New Vocabulary Continuous Decreasing Discrete Domain Domain restriction Explicit formula Exponential decay Exponential growth Function notation Increasing Interval Negative Positive Range Reasonable domain AF Math Algebra 1 Unit 2 Recursive formula Relationship Sequence x-intercept y-intercept PREREQUISITE SKILLS What skills will students need in order to be successful with this unit? Students should be creating and interpreting exponential expressions and equations in this unit and therefore, they should be reviewing basic exponent skills throughout the first several units of the course. Meaning of exponents: x 2 = x × x Basic properties of exponents (meaning of negative and zero powers, multiplying terms with same base, dividing terms with same base, raising a power to a power) Graphing points on a coordinate plane AF Math Algebra 1 Unit 2 Stage 2: Acceptable Evidence W RITTEN ASSESSMENTS All topics: 1. Understand the concept of a function and use function notation 2. Interpret functions that arise in applications in terms of the context 3. Relate multiple representations of functions 4. Identify, analyze, and build a linear or exponential model Unit 1 Exam *There is currently no time allotted in the unit plan (14 teaching days) for a quiz on this unit given that the unit is relatively short and that time will be precious, particularly in this transition year to CC Algebra 1. (Students who have been through CC 8th grade will most likely be able to complete this unit in a shorter amount of time than that allotted.) However, if teachers feel compelled to give a quiz, there are some lessons that are spread over two days that could be compressed into a day and a half, for example, or perhaps a take-home quiz or other time during the school day could be utilized. PERFORMANCE ASSESSMENTS In this unit, several tasks are aligned in the learning plan. Most of these are meant to be instructional but some tasks or parts of some of the tasks could be turned in to more formal, individual performance assessments. OTHER EVIDENCE Exit tickets CFUs Informal interviews Homework AF Math Algebra 1 Unit 2 Stage 3: Learning Plan LEARNING PLAN Lesson # Standards 2.01 F-IF.1, F-IF.3 MP1, MP2, MP3, MP4, MP7, MP8 Aim/Exit Ticket SWBAT define a functional relationship Examine the tile pattern below. Topic 1: Understand the concept of a function and use function notation a. Sketch Figures 4 and 5. b. How does the pattern grow? Explain your thinking. c. How many tiles will there be in Figure 0 (the figure before Figure 1)? Explain how you know. d. Make a table showing the number of tiles for Figure 0 through Figure 9. Key Points, Resources and Notes An extra day is included at the beginning of this unit to provide time for students to work on an investigation and to begin exploring the properties of functions without getting into all of the vocabulary yet. One possible task is the Square Pool Problem (there are several versions of this problem but this one includes excellent extensions that could be brought back to have students discuss at the end of the unit) Students should be asked to create multiple representations of the functional relationship and to discuss questions such as: if you know the side length of a pool will you always know the number of tiles? Is it possible for a pool with a given side length to have more than one answer for the number of tiles around it? When you graph the points of the function should you connect the dots? Can you guess the rule of this function? If I gave you a square of side length x, could you say how many tiles would surround it? If a pool had 44 tiles around it, could you tell me the side length? Students can also draw this function as a function machine and should be able to define the input and output, if not the function rule. You might informally introduce function notation over these first few days but it will be formally used in Lesson 2.04. AF Math Algebra 1 Unit 2 2.02 F-IF.1, F-IF.2, F-IF.3 MP2, MP6 Topic 1: Understand the concept of a function and use function notation SWBAT use a functional relationship to identify input and output values 1. Zack charges $2.50 per hour for baby-sitting one child. He charges $.75 per hour for each additional child. Which table should represent Zack’s hourly charges for baby-sitting? Starting here and then throughout the unit, students should use function notation, see functions in multiple representations, work with sequences etc. A. The goal of this day is to get students more comfortable with some of the language and notation around functions. Guess my Rule (see misconceptions section) would be a good starting activity for this lesson. Students could also define and discuss and create multiple representations of a dollar bill change machine function. C. Core Connections Algebra by College Preparatory Mathematics has some great introductory activities using function machines. (See page 12, activity 1.2. You may want to adjust the functions, particularly if students haven’t been through CC 8th grade math.) 2. One wedding-cake design has a base layer that is 5 inches tall, and each additional layer is 3 inches tall. What is the height of a 4-layer cake made in this design? Throughout this unit, students might revisit unit conversions by building functions to convert units and then discussing domain, range, and graphical representations. AF Math Algebra 1 Unit 2 2.03 F-IF.1 MP3, MP6 Topic 1: Understand the concept of a function and use function notation SWBAT determine if a given relationship is a function 1. Decide whether each description represents a function. Explain your thinking. a. The input is a day of the year. The output is the average temperature in Barcelona on that day. b. The input is the speed of a car. The output is the time it takes for a car moving constantly at that speed to travel 100 miles. c. The input is a positive number. The output is a number whose absolute value is the input. d. The input is a year. The output is the population of the United States during that year. 2. Consider the relationship graphed below. a. Explain how you know that the relationship is a function of x. b. What point could you add to the relationship that would make it no longer a function? Explain your reasoning. The key question for students today is: is the output predictable? See the discussion of possible approaches to this lesson in the misconceptions section on the vertical line test. Aligned Tasks: The Customers (IM) AF Math Algebra 1 Unit 2 2.04 F-IF.2 MP2, MP3, MP4, MP6 SWBAT use and interpret function notation algebraically and in context Topic 2: Interpret functions that arise in applications in terms of the context 2. Wilson is buying a new television for $3750. To pay for the television, he makes an initial down payment and then pays off a certain amount each month. Let f (t) be the amount of money that he still owes after t months. Explain the meaning of each of the following statements in everyday language. a. f (0) = 3000 1. What is b. c. d. 2.05 F-IF.1, F-IF.2, F-IF.4 MP2, MP6 Topic 1: Understand the concept of a function and use function notation f (-2) for the function f (x) = -3x +8 ? b. c. Instead of just identifying or writing ideas using function notation, now students are given function notation and a context and asked to interpret the meaning. If they didn’t already, students could go back and interpret statements in function notation about the Square Pool Problem and the dollar bill change machine. f (2) > f (4) f (5) =1750 f (a) = 0 SWBAT use and interpret function notation graphically 1. Use the graph (for example, by marking specific points) to illustrate the statements in parts (a)-(c). if possible, label the coordinates of any points you draw. a. Aligned Tasks: The Random Walk (IM), Random Walk II (IM), Yam in the Oven (IM) f (-3) = f (3) = f (9) = 0 f (2) = g(2) g(x) > f (x) for x > 2 The goal of this lesson is for students to understand function notation in terms of the graph and be able to find both output and possible input values graphically. Students are going to learn a lot of new vocabulary around graphs in this unit and this day would be a good place to introduce some new terms such as x or y intercept, increasing interval, positive interval, etc. Make sure that some of the graphs students see have a context so that they can continue to make meaning out of the questions they are being asked. AF Math Algebra 1 Unit 2 2. On the coordinate plane below, sketch the graph of a function that meets all of the following criteria. The output values of the function f are positive for all input values. The function f has a maximum where f (2) = 5 . 2.06 F-IF.1, F-IF.3 MP2, MP6 Topic 1: Understand the concept of a function and use function notation f (0) = f (4) =1 The function is increasing for x <0. SWBAT identify the domain and range of a function 1. The tables below show three sets of input-output values. Table A Input Output 2 9 -3 ½ -1 100 4 8 12 3 4 7 Table B Input Output 4 13 7 -2 4 11 9 3 16 -4 9 0 a. Does each table define a function? Explain. Table C Input Output -1 0 1 4 -3 -1 1 2 3 4 5 6 Continue to bring in many different types of functions and many different representations, including sequences, functions that don’t have a clearly defined rule, and functions that are given solely verbally without an algebraic or graphical representation. If students have been consistently discussing input and output values then defining the domain as the set of all possible input values and the range as the resulting set of output values should be a smooth transition. Have students practice several methods of writing the domain and range. AF Math Algebra 1 Unit 2 b. For each table that defines a function, state the domain and range of the function. 2. On the coordinate grid below sketch a function that has: Domain: −2 ≤ 𝑥 ≤ 5 Range: 𝑦 ≤ 4 2.07 F-IF.1, F-IF.5 MP2, MP3, MP4, MP6 Topic 2: Interpret functions that arise in applications in terms of the context SWBAT identify the reasonable domain and associated range for a function in context 1. A balloon shaped like a sphere contained a volume of 8 liters of air. Over a period of 6 hours, all of the air leaked out of the balloon. In this situation, V, the volume in liters of the balloon, is a function of t, the number of hours. Which of these describes the range of the function? A 0£t B 0£t £6 Ensure to discuss that sequences are distinct from other continuous functions in that they have limited inputs. AF Math Algebra 1 Unit 2 C V £8 D 0 £V £8 2. An equilateral triangle is shown below. a. If l represents the length of one side of an equilateral triangle, write the equation for the perimeter, P of the triangle. 𝑃= b. If the perimeter of the triangle is 36 meters or less, give the domain and range for the perimeter function. c. Topic 2: Interpret functions that arise in applications in terms of the context SWBAT describe the graph of a function in context 1. A swimmer is at one end of a pool. She starts swimming at a constant rate, touches the other side of the pool, and then swims back at a constant rate. Sophie draws the graph below to represent the distance of the swimmer over time. Distance 2.08 F-IF.4 MP1, MP2, MP4 Is the perimeter function for an equilateral triangle a discrete or continuous function? How do you know? Aligned Tasks: Telling a Story with Graphs (IM) This lesson should connect back to the graph stories that students looked at in Unit 1. We are now just creating a way to communicate and analyze those graphs rather than just draw them. Make sure to continue talking about and having students discuss the meaning of increasing/decreasing intervals, positive/negative intervals and intercepts, and rate of change on a AF Math Algebra 1 Unit 2 given interval. Time Explain why this graph is not an accurate representation of the swimmer’s distance over time. Sketch a graph that would be an accurate representation. 2. The graph below shows the velocity of a car in meters per second as a function of time, measured in seconds. 2.09 F-IF.4, F-IF.9 MP2, MP5, MP6 Topic 3: Relate multiple representations of functions a. For approximately how long was the car traveling faster than 15 meters per second? Explain your reasoning. b. Over what interval of time is v(t) decreasing? Explain what this means in terms of the situation. c. Interpret the meaning of the point v(24) = 0 . SWBAT analyze and compare two functions presented in different ways Both Ronny and Tara are growing bean plants for their gardening club. Ronny wrote the following function to model his plant’s growth 𝑓(𝑡) = 2.5𝑡 + 4. Tara wrote the following table to model her plant’s growth: 0 1 2 3 4 t 5 7 9 11 13 f(t) Ronny and Tara noticed that their representations of their plant growth were different. What are two similarities and two differences they might These two days of lessons are intended to reinforce and connect together all that students have been learning in this unit. They should be comparing attributes of functions (see list from 2.08) given in many different representations, some with context and some without. Students should be making comparisons by using graphs and tables, by approximation, and by AF Math Algebra 1 Unit 2 find as they take a close look at their functions? Please be specific and use appropriate function vocabulary. 2.10 F-IF.4, F-IF.9 MP2, MP5, MP6 Topic 3: Relate multiple representations of functions 2.11 F-BF.1b, F-LE.1, F-LE.3, F-LE.5 MP1, MP2, MP4, MP7 Topic 4: Identify, analyze, and build a linear or exponential model calculating (for example, by solving to find the intercepts or plugging values to find the rate of change on a given interval). Students won’t be asked to find the y-intercept of a linear function given as a table of points where the intercept is not already provided in the table until the next unit. Although, if they are ready and time allows, that would be a great task for them here. SWBAT analyze and compare two functions presented in different ways Damian found the following graph of a function modeling how many seconds it took a group of high school sprinters to run 100 meters after being part of an intensive Olympic training program for many months. Damian’s friend Jorge says the function should be 𝑓(𝑚) = −0.5𝑚 + 20 if the runners could run 100 meters in 20 seconds at the beginning of the program. a. Compare the graph of the function Damian found to his friend George’s written function. Name two similarities and two differences in the functions. b. Which model do you think is more realistic? Why? SWBAT identify the best model (linear or exponential) for a given situation 1. For each part below, state whether the quantity is changing in a linear or exponential fashion. a. A savings account, which earns no interest, receives a deposit of $723 per month. b. The value of a machine depreciates by 17% per year. c. Every week, 9/10 of a radioactive substance remains from the Students should have seen both linear and exponential functions throughout the unit and in these two days will be adding vocabulary to communicating and analyzing the functions as well as working on identifying which function would make the best model for a given situation. AF Math Algebra 1 Unit 2 beginning of the week. d. A liter of water evaporates from a swimming pool every day. e. Every 124 minutes, ½ of a drug dosage remains in the body. Students should be able to identify that the rate of change of linear functions is constant while exponential functions have a non-constant and increasing or decreasing rate of change. They should also be able to distinguish that exponential functions grow much faster and will eventually, always, exceed linear functions. Students should look at multiple representations of functions, especially functions given verbally, in order to distinguish between linear and exponential models. Students should also discuss parameters of functions given algebraically in terms of the context that they represent. 2.12 F-BF.1b, F-LE.1, F-LE.3, F-LE.5 MP1, MP2, MP4, MP7 SWBAT identify the best model (linear or exponential for a given situation 1. The snowflake pattern shown below is called the Koch Snowflake. Level 0 Level 1 Topic 4: Identify, analyze, and build a linear or exponential model The snowflake pattern is generated by drawing an equilateral triangle, removing the middle third of each side, and replacing each of these middle thirds with two sides of an equilateral triangle. a. Draw the level 2 snowflake. b. Suppose the original triangle has a side length of 1 and a perimeter of 3. Find the perimeters of the level 1 and level 2 snowflakes. c. Is the function for the perimeter, P(l) where l is the level number, AF Math Algebra 1 Unit 2 a linear or exponential function? Explain your reasoning. 2. Ly is spending the day riding her bicycle in the countryside. She knows that she will travel 8 miles per hour on unpaved roads and will travel 12 miles per hour on paved roads. She plans to travel a total of 48 miles. a. If Ly travels x hours on unpaved roads, then ____x represents the distance she travels on unpaved roads. b. If Ly travels y hours on paved roads, then ____y represents the distance she travels on paved roads. c. Combine your answers to (a) and (b) to write an equation that models this situation, using the form 𝑎𝑥 + 𝑏𝑦 = 𝑐, where c is total miles traveled. 2.13 F-BF.1b, F-LE.1, F-LE.3, F-LE.5 MP1, MP2, MP4, MP7 Topic 4: Identify, analyze, and build a linear or exponential model SWBAT build an equation to represent a given functional situation 1. In the picture below, you see one paper cup and five paper cups that are stacked together. The table shows the heights of stacks with different numbers of cups. Aligned Tasks: A Sum of Functions (IM) Students will have more practice creating equations on their own in the next unit. The focus of this unit should still be more on getting students to understand what the different parts of a function represent in the problem situation and how combining those different parts builds a model of the whole problem. Connect this lesson to creating equations from the AF Math Algebra 1 Unit 2 Which function rule gives the height of a stack of cups, h, in terms of the number of cups in a stack, c? A B C D c = 2 +8h c = 8+ 2h h = 2 +8c h = 8+ 2c 2. City Bank pays a simple interest rate of 3% per year, meaning that each year the balance increases by 3% of the initial deposit. National Bank pays a compound interest rate of 2.6% per year, compounded monthly, meaning that each month the balance increases by one twelfth of 2.6% of the previous month’s balance. a. Which of these functions represents City Bank’s interest plan? Please circle your answer. i. 𝐶(𝑦) = 10,000 ( 1.03 𝑦 12 ) .03 𝑦 ii. 𝐶(𝑦) = 10,000 (1 + ) 12 iii. 𝐶(𝑦) = 10,000(1.03) 𝑦 b. Which of these functions represents National Bank’s interest plan? Please circle your answer. i. 𝑁(𝑚) = 10,000 ( 1.026 𝑚 12 ) .026 𝑚 ii. 𝑁(𝑚) = 10,000 (1 + ) 12 iii. 𝑁(𝑚) = 10,000(1.026)𝑚 c. Which bank will provide the largest balance if you plan to invest &10,000 for 10 years? For 15 years? last unit. If students are still working on identification from lessons 2.11 and 2.12, this lesson can become an extension of those two days by scaffolding the tasks (either by providing equations that students pick from or by looking for elements of linear or exponential functions as full credit without expecting complete accuracy). AF Math Algebra 1 Unit 2 2.14 F-IF.3, F-BF.1b, F-LE MP2, MP4, MP6 SWBAT identify the explicit or recursive formula for a given sequence 1. Which recursive formula is represented by the graph where n is an integer and g(0) =1? Topic 4: Identify, analyze, and build a linear or exponential model A g(n) = g(n -1)+1 B g(n) = g(n -1)+ 2 C g(n) = 2g(n -1) D g(n) = g(n -1)2 Given problems in context, introduce idea of explicit and recursive functions. include both linear and exponential sequences. Make sure to bring back the discussion of domain and have students practice writing domain restrictions. AF Math Algebra 1 Unit 2 2. The value of a certain antique appreciates (or increases) by 20% for every decade older that it gets. The value of the antique over the last several decades is shown in the table below. Year 1950 1960 1970 1980 1990 Value $80,000 $96,000 $115,200 $138,240 $165,888 Which explicit formula could be used to represent the value of the antique after n decades, assuming that 1950 is given by n = 0 . A f (n) = 80, 000(0.2)n B f (n) = 80, 000(1.2)n C f (n) = 80, 000 +1.2n D f (n) = 80, 000(0.2)(n)+80, 000 AF Math Algebra 1 Unit 2 Misconception It is only a function if it is written as f (x) . State if the graph is a function means: use the vertical line test. COMMON MISCONCEPTIONS What misconceptions will prevent scholars from reaching mastery? Clarification Students should certainly see functions with a variety of letters used to represent the input and output values. They should also understand that f (x) = 2 x + 3 and f (t) = 2t + 3 represent the same relationship. In addition, students should be exposed to and asked to analyze functions that can’t be clearly written in an algebraic formula. For example, when you press the brake pedal on a car (the input), the car slows down (the output). Students could discuss whether or not they thought this might be a linear relationship. (Or some other non-algebraic functions might be better since braking a car may not be relatable yet for students!) The Functions Progression emphasizes that while students still need to be able to define and identify a function as distinct from a non-functional relationship, this should not devolve into an exercise in searching lists of points for a repeated x value or in simply memorizing and universally applying the vertical line test. The scenario at the beginning of this article below gives an example of how the vertical line test can confuse students by over-simplification. To avoid this misconception, focus on the definition of a function as a predictable rule where each input value defines just one output value. Then have students apply this definition across a variety of settings and situations. For example, Guess My Rule (where teachers ask for input values and give the output value after a secret rule is applied; students are asked to figure out the rule) is a great activity to play with students as they are beginning to learn about functions and, once students get the hang of the game, can be followed by a Guess My Rule where the teacher doesn’t play fair and is giving different outputs for the same input which can then lead to a great discussion about why this is unfair. Or, students can think about a dollar-bill change machine that sometimes gives you 5 quarters when you put in a dollar and sometimes gives you 3 quarters when you put in a dollar. I have also found it helpful to draw every function as a function machine because the visual of the machine giving two outputs for the same input helps students identify the problem. Students can also look at graphs of a function of points and talk about why a certain relationship can’t be a function if graphically they can see that one input value leads to two different output values. In other words, they can learn the vertical line test in terms of the definition instead of learning it as “the vertical line test.” They could also be asked, if I defined the y-values as the input values and the x-values as the output values, would this still be a function? The key here is to have students always return to the definition in a variety of situations where they have to think flexibly so that they don’t get stuck in one way of identifying whether or not a given relationship is a AF Math Algebra 1 Unit 2 Functions that represent sequences are drawn continuously. A functional correspondence could be arbitrary and limited. function. Context is helpful here as well as a variety of functions in each lesson. For example, can I put a dollar and a half into the dollar bill change machine? So should I draw points in between one and two dollars? Not everything should be in context! While modeling is a focus of the course, students should also be exposed to functions that are just a defined set of points or that are defined graphically as just a few lines (connected or not). Students need to also understand that the mathematics applies even when a functional relationship is arbitrary and out-of-context. Monday 9/23/13 2.01 Tuesday 9/24/13 2.02 ANTICIPATED LESSON CALENDAR Wednesday 9/25/13 2.03 Thursday 9/26/13 2.04 Friday 9/27/13 2.05 9/30/13 2.06 10/1/13 2.07 10/2/13 2.08 10/3/13 2.09 10/4/13 2.10 10/7/13 2.11 10/8/13 PD Day 10/9/13 2.12 10/10/13 2.13 10/11/13 2.14 10/14/13 Holiday—No School 10/15/13 Flex/review Day 10/16/13 Unit 2 Exam