High School - Gateway 2

The materials reviewed for Big Ideas Learning AGA meet expectations for developing conceptual understanding of key mathematical concepts, especially where called for in specific standards or cluster headings. Many of the opportunities for conceptual understanding are in the Explore It, activities located at the beginning of every chapter. In the Teacher Edition, there are also additional opportunities for conceptual understanding given in Laurie’s Notes. 

Examples across the series that develop conceptual understanding include:  

• A-APR.2: In Algebra 2, Chapter 4, Section 3, Explore It, students use technology to explore the graph of $${{x}^{3}}+2{{x}^{2}}-x-2$$ divided by the binomial x+a for given values of a. Students develop conceptual understanding through making observations about the graphs and drawing conclusions about their observations. 

• G-SRT.6: In Geometry, Chapter 9, Section 4, Explore It, students use technology to construct a right scalene triangle with several perpendicular segments drawn to the base of the triangle. Students use the definition of tangent to write the tangent ratios for the acute angles and then compare the values. Students generalize their finding by determining if the size of the right triangle affects the tangent values or whether the angle measure affects the tangent ratios. In Geometry, Chapter 9, Section 4, students demonstrate understanding of tangent ratios by explaining how the tangent of an acute angle in a right triangle changes as the angle measure increases. 

• S-ID.6a: In Algebra 1, Chapter 4, Section 4, Explore It, students are given data from a survey of 179 married couples. Each person in the survey gave their age and the data collected was shown in a graph. Students develop conceptual understanding of linear functions suggested by the data to make observations, notice patterns in the data, and explain how patterns represent data. 

Examples across the series where students independently demonstrate conceptual understanding include: 

• N-RN.1: In Algebra 2, Chapter 5, Section 1, students are given the expressions $${{({{a}^{\frac {1} {n}}})}^{m}}$$, $${{({\sqrt[{n}] {a}})}^{m}}$$, $${{({\sqrt[{m}] {a}})}^{-n}}$$, and $${{a}^{\frac {m} {n}}}$$. Students must determine which expression does not belong and justify their decision. 

• A-REI.12: In Algebra 1, Chapter 5, Section 7, students are given a graph of two linear equations with five plotted points. Students must replace the equal sign in the two graphed linear equations with inequality symbols such that two of the plotted points are solutions.  

• G-CO.1: In Geometry, Chapter 1, Section 1, students develop conceptual understanding of parallelism by determining if parallel lines always, sometimes, or never intersect. Within the same sections, students also determine if two points always, sometimes, or never form a line.

The materials reviewed for Big Ideas Learning AGA meet expectations for providing intentional opportunities for students to develop procedural skills, especially where called for in specific content standards or clusters. Opportunities for students to independently develop procedural skills are located within the Self-Assessment exercises, the Practice exercises, the Review and Refresh exercises, and the supplemental resources. 

Examples of the materials developing procedural skills and students independently demonstrating procedural skills include:

• A-SSE.2: In Algebra 2, Chapter 6, Section 1, students justify the steps needed to rewrite an exponential function. In Algebra 2, Chapter 6, Section 3, students rewrite functions in exponential and logarithmic form. In Algebra 2, Chapter 6, Section 5, students rewrite logarithmic expressions by condensing or expanding them.

• A-APR.1: In Algebra 1, Chapter 7, Section 1, students independently calculate the sum and difference of polynomials. In Algebra 1, Chapter 7, Section 2, students independently calculate products of polynomials using the Distributive Property and a table. In Algebra 1, Chapter 7, Section 3, students independently calculate the products of polynomials. 

• F-BF.4a: In Algebra 2, Chapter 5, Section 7, students find inverses of linear, quadratic, cubic, square root, and cube root functions.

• G-GPE.4: In Geometry, Chapter 5, Section 8, students write coordinate proofs to prove geometric theorems. In Geometry, Chapter 10, Section 7, students use coordinates to prove or disprove whether a coordinate lies on a circle.

The materials reviewed for Big Ideas Learning AGA meet expectations that the three aspects of rigor are not always treated together and are not always treated separately. The three aspects are balanced with respect to the standards being addressed. The Explore It sections contain multiple aspects of rigor to develop students’ mathematical understanding while the independent practice sections are mainly procedural with a balance between conceptual understanding and application throughout the section. 

Application problems are presented throughout the materials in the Explore Its, Independent Practice, and Self-Assessments. Examples of procedural skills and conceptual understanding being presented independently throughout the materials include: 

• In Algebra 1, Chapter 7, Section 5, students develop procedural skills by factoring polynomials and solving polynomials by factoring (A-SSE.3a).

• In Algebra 2, Chapter 4, Section 1, Explore It, students develop conceptual understanding by identifying functions that are polynomials, graphing the polynomials, describing end behaviors, and determining the effects of exponents and leading coefficients. Students compare two graphs to determine if the graphs are cubic or quartic. Conceptual understanding is also developed when students generalize characteristics of cubic functions and quartic functions (F-IF.7c). 

Examples of multiple aspects of rigor being engaged simultaneously to develop students mathematical understanding of a single topic of study throughout the materials include: 

• In Algebra 1, Chapter 8, Section 6, Explore it, students develop conceptual understanding through an application problem involving three cars traveling at the same time at different speeds. Students develop conceptual understanding by determining which car has a constant speed and which car has the greatest acceleration (F-LE.3).

• In Geometry, Chapter 9, Section 6, Explore it, students develop procedural skills by calculating measure of an angle when given a trigonometric ratio. Students demonstrate conceptual understanding by explaining how technology can verify angle measures and explaining how to calculate the measures of two acute angles when given side lengths. Within the same section, students use procedural knowledge of trigonometry to calculate the acute angles in a right triangle created by leaning a firefighter ladder against a building (G-SRT.8). 

• In Algebra 2, Chapter 8, Section 3, Explore it, students develop procedural skills by determining different probabilities involving six pieces of paper numbered 1 through 6. Students develop conceptual understanding by comparing and contrasting the probabilities found. Within the same section students are given two events. Event A is the probability of the first number being divisible by 3 and Event B is the probability of the second number being greater than 2. Students calculate P(B|A), P(A and B), and P(A). Students develop conceptual understanding by using the previous probabilities to generalize a formula for P(B|A) in terms of P(A and B)and P(A) (S-CP.6).

The materials reviewed for Big Ideas Learning AGA meet expectations for supporting the intentional development of reasoning and explaining (MPs 2 and 3), in connection to the high school content standards. The majority of the time MP2 and MP3 are used to enrich the mathematical content and are intentionally developed to reach the full intent of the MPs. 

Examples of MP2 being used to enrich the mathematical content and intentionally developed to reach the full intent of the MP include: 

• Algebra 1, Chapter 3, Section 5, Example 3 provides the equation 6x+10y=180 to model the number of people that can sit at a small table and a large table at a banquet for 180 people. The material include a Mathematical Practice box asking students what the terms 6x and 10y represent in this context. Students are attending to the meaning of quantities. 

• In Geometry, Chapter 4, Section 3, students determine the coordinates of two endpoints after rotation 630 degrees and 900 degrees about the origin. Students reason abstractly to determine the new coordinate for the endpoints. 

• In Algebra 2, Chapter 5, Section 7, students are given the ordered pairs (-2, 5), (0, 1), (3, -6), and (7, n) and are told a function passes through the points. Students find values of n so that the inverse is a function and must explain their reasoning. 

Examples of MP3 being used to enrich the mathematical content and intentionally developed to reach the full intent of the MP include: 

• In Algebra 1, Chapter 7, Section 7, Exercise 41, students describe two methods use to simplify $${{(2x-5)}^{2}}-{{(x-4)}^{2}}$$. Then, students choose which of the two methods they would use to simplify the expression and provide an explanation about their choice. 

• In Geometry, Teacher Edition, Chapter 7, Section 2, Laurie’s Notes, students write a proof for the Parallelogram Opposite Sides Theorem. After writing the proof, students compare and critique proofs made by other students. 

• In Algebra 2, Chapter 9, Preparing for Chapter 9, students are given a table of results describing 3 different surveys used to determine if people would like more funding to monitor volcanic activity. Students collaborate with a partner to explain confidence levels in the conclusions of the results. Finally, students must write a survey question and sample to use for a valid conclusion.

The materials reviewed for Big Ideas Learning AGA meet expectations for supporting the intentional development of seeing structure and generalizing (MP7 and MP8), in connection to the high school content standards. The majority of the time MP7 and MP8 are used to enrich the mathematical content and are intentionally developed to reach the full intent of the MPs. 

Examples of MP7 being used to enrich the mathematical content and intentionally developed to reach the full intent of the MP include: 

• In Algebra 1, Chapter 11, Section 2, Explore It, students interpret two box-and-whisker plots. One box-and-whisker plot represents the body mass of a ninth-grade class and the other represents the height of roller coasters. Students are asked to determine what the box and length represent and what the whiskers and its length represent within the context of the data. 

• In Geometry, Chapter 7, Section 5, students use their understanding of the structure of trapezoids and mid-segments to write an equation and calculate the value of x.

• In Algebra 2, Chapter 1, Section 1, students are given the functions f(x)=|x-4| and g(x)=|x|-4. Students attend to structure by determining if the two functions are the same. 

Examples of MP8 being used to enrich the mathematical content and intentionally developed to reach the full intent of the MP include: 

• In Algebra 1, Chapter 6, Section 1, Explore It, students explore properties of exponent by choosing several values for variables to find a pattern for exponent properties. Students find patterns in order to generalize rules for the properties. 

• In Geometry, Chapter 13, Section 6, students complete a table calculating nPr and nCr when n=3and r=0,1,2,3. Students generalize their finding to write an inequality relating nPr and nCr for any value.

• In Algebra 2, Chapter 6, Preparing for Chapter 6, students are given a table representing the percentage of carbon-14 remaining after the death of an organism. Students must analyze the table to determine if calculations are repeated. Then, students write an equation using y to represent the amount of carbon-14 and t to represent years after death based on patterns discovered within the table.