The instructional materials reviewed partially meet the expectations for attending to the full intent of the mathematical content contained in the high school standards for all students. In general, the series included the majority of the non-plus standards, but there were some instances where the full intent of the standard was not met.

Examples where the full intent of the standards were met:

• N-RN.1: This series allows students to fully engage in this standard in Math 2, Module 3. On page 100, the lesson requires students to compare/contrast radicand restrictions on even and odd roots, as well as to reason about the order in which they should calculate the root or power of the base number. Teachers are provided with questioning strategies to help students analyze and reason with rational exponents in Math 2 TE on pages 99-100. In “Explain the Error and Communicate Mathematical Ideas” on page 105, students engage in higher-order thinking strategies through error analysis and abstract analysis.
• G-CO.9-11: The series allows students to fully engage in these standards in Math 2, Modules 14-16. Students complete multiple styles of proofs for theorems involving lines, triangles and parallelogram properties, including fill in the blank paragraph proofs, flow proofs, and 2-column proofs. Students are also given the opportunity to write a plan for various proofs of different theorems and to create their own proofs in various styles.

Examples where the full intent of the standards were not met:

• N-RN.3: This standard was addressed in Math 2, Module 3 on page 108. Students are required to identify whether the sum and product rules for two rational, two irrational, or one rational and one irrational number are sometimes, always, or never true. However, they are not required to explain why this is so as indicated by the standard.
• N-Q.2: This standard was addressed in Math 1 and Math 2 but was only partially met because there was no evidence found indicating students define their own quantities as called for in the standard. In Math 3, Module 19, on page 1111, one example asks students to define their own quantities, but students are provided with pre-labeled and numbered tables and charts thus taking away the opportunity to determine quantities.
• A-SSE.1 In Math 2, Lesson 4.1 places a considerable focus on mechanics and evaluating a polynomial expression to answer a real-world problem. This section does not address “interpreting its parts” as required by the standard nor is there evidence of this part of the standard being addressed in any other lessons/tasks within the series.
• A-SSE.3a,b: The standard is only partially addressed in Math 2, Module 9 on page 374. Evidence was not found that the materials require students to choose a form in order to reveal information. That is, students were directed to produce specific forms without opportunity for student choice.
• A-SSE.3c: The standard is identified in Math 3, Module 10; however, students do not need to use properties of exponents to transform any of the expressions. Students are identifying information or evaluating in the examples and problem set.
• F-IF.8a: In Math 2, Module 9, students are given ample opportunity to practice working with quadratic functions through completing the square with and without context. However, all context questions only asked students to find maximum values, not minimum values. Additionally, students do not use the processes of factoring or completing the square to show the symmetry of the graph.
• F-TF.2: Students did work with the concepts of the unit circle in Math 3, Module 18, on pages 927-940. The standard indicates that students should explain how the unit circle is an extension of the trigonometric functions, which was not found in this series.
• G-CO.10: Most of this standard is addressed in Math 2, Module 15, with the exception of Triangle Midpoint Theorem. Students do verify and work problems where the third side is parallel to the segment connecting the midpoints of the other two sides, but they do not find or work with the idea that the length of the segment connecting the midpoints of the other two sides is half the length of the third side.
• S-ID.4: This standard was addressed in Math 3, Module 21 on page 1057. Students were asked why standard deviation and mean are not appropriate statistics to use with skewed distributions, but students were not asked to determine if such procedures were or were not appropriate for the data sets, as indicated by the standard. Students were also limited in the exposure of technology, calculators only, used for this standard.
• S-CP.4: In Math 2, Module 22, the lesson places the focus on “finding the probability from a two-way table of data;” however, nowhere within this section are students prompted to “construct and interpret the two-way frequency table of data …” as indicated by the standard. It is not until Math 2, Module 23, that students are “involved” in creating such a table by being given a supporting matching activity on page 1254, but the students never fully construct a two-way table.
• S-IC.4: This standard is addressed in Math 3, Module 23 on page 1123. The definition and formulas of margin of error are introduced to students. In the work that immediately follows, the margin of error is given and then used to determine appropriate sample size. Then, in the Lesson Performance Task on page 1132, students are asked to find the margin of error but only after being given the formula. Students do not develop a margin of error from the use of simulation models as indicated by the standard.

The materials, when used as designed, partially meet the expectations for allowing students to fully learn each non-plus standard. Overall, the series addressed many of the standards in a way that would allow students to learn the standards fully. However, there are cases where the standards are not fully addressed or where the instructional time devoted to the standard was insufficient.

Throughout the series, students do not prove or derive theorems, properties, or formulas when required by the CCSSM. Students are routinely shown the process to derive, given fill-in-the-blank proofs, or just given the information, but students do not independently construct proofs or derive formulas without significant direct instruction or support. The following are examples where students are not able to fully learn the standard because they are not engaged in the process of proving or deriving as prescribed in the standards.

• G-C.5: Derive using similarity the fact that the length of the arc intercepted by an angle is proportional to the radius, and define the radian measure of the angle as the constant of proportionality; derive the formula for the area of a sector. Students were not given the opportunity to independently complete the derivation indicated by the standard.
• G-GPE.1: Derive the equation of a circle of given center and radius using the Pythagorean Theorem; complete the square to find the center and radius of a circle given by an equation. Students were not given the opportunity to independently complete the derivation indicated by the standard.
• G-GPE.2: Derive the equation of a parabola given a focus and directrix. Students followed a prescriptive, fill-in-the-blanks derivation provided by the book.
• A-REI.5: Students complete a fill-in-the-blank proof but are not required to do an independent proof of this standard.
• F-TF. 8: Math 2, Module 18 page 982, students are asked to confirm the Pythagorean identity using different values for theta, but they do not formally prove the Pythagorean Identity, as indicated by the standard. On page 990 in problem 19, students are asked to show the theorem is true, but not provide a formal proof.

The materials, when used as designed enable students to have exposure to each of the standards, but they do not always allow students to fully learn each standard. Examples of standards that are not fully developed within the curriculum include the following:

• N-RN.2: Math 2, Module 3 page 108, students are required to identify whether the sum and product rules for two rational, two irrational or one rational and one irrational number are sometimes, always or never true; however, they are not required to explain why this is so.
• F-IF.7c: Math 2, Lesson 7.2 lays the foundation for using zeros to plot x-intercepts and construct a rough graph (of a quadratic function). On page 270 of that lesson, the material notes a perfect square trinomial that could be used to introduce the concept of duplicity/multiplicity of a zero, but nothing is indicated in the facilitation notes to encourage such a discussion. Math 3, Lesson 5.4 on page 295, reinforces the connection between a zero and an x-intercept. The idea of duplicity is discussed in problem 3 on page 296. The remainder of the lesson does not relate the concepts of end behavior and the x-intercepts to sketch the rough graph; rather, the materials encourage students to develop a sign chart. While essential elements toward learning this standard are introduced, the series does not give students an opportunity to fully learn the standard.
• A-CED.4: Math 1 Lesson 2.3 focuses on the linear case- offering scaffolded (fill-in-the-blank) examples and 25 exercises. The series does not include any focus on this standard for the quadratic case.
• A-REI.10: In Math 1, Module 6 on page 202, students are not given opportunity to investigate the standard or to develop their own understanding that the graph of an equation in two variables is the set of all its solutions plotted in the coordinate plane, often forming a curve, but are instead told with an example.
• G-CO.1: Math 1 Lesson 16.2 focuses on “angle.” Although the materials appear to define angle at the top of page 790, the convex part of the angle is not noted. The definition is provided not giving students an opportunity to develop a precise definition. Attempts at defining “parallel lines” in Math 1 Lesson 17.1 and “perpendicular lines” in Math 1 Lesson 17.2 are not precise; rather, the material lists properties in place of a precise definition. Here, too, students are not encouraged to develop a precise definition. Thus, the series does not allow students to fully learn this standard.
• G-CO.4: In Math 1, Module 17, the definitions of rotations, reflections, and translations are given and used but not developed as required by the standards. For example, students are told to find the midpoint between image and pre-image points to find the line of reflection instead of using the line of reflection to confirm it is the midpoint and therefore proving it is a reflection. This is also seen with angles of rotations; students are told to use angles to make the rotations but are not asked to verify a rotation by measuring or finding angles.
• G-GPE.6: Math 3 Lesson 2.6 introduces examples on a number line and a coordinate plane. In each case, the approach involves partitioning a horizontal and/or vertical distance, applying the appropriate ratio, and determining the final point. A variety of ratios are used in examples and exercises. Students are also introduced to the concept of partitioning via constructions. Moreover, students are encouraged to confirm the point of partition using the distance formula. The series does not introduce the student to any algebraic/numerical approach and, in turn, does not ask the student to determine the ratio if given a partitioned segment.
• S-CP.3: Math 2, Lesson 23.1 addresses the standard although it is not indicated as such in the table of contents. While students engage in calculating conditional probabilities using formulas, there was not any evidence of attending to students “understanding” of the concept or why the formula works.

The materials partially meet the expectation for being mathematically coherent and making meaningful connections in a single course and throughout the series, where appropriate and where required by the standards. Although this is an integrated mathematics series, the books do not work to build connections between and amongst domains and clusters. Rather, topics are typically taught in isolation within the materials. Repeated lessons throughout the series do not build on or extend students knowledge to reach higher order thinking on the identified standards within these lessons. Repeated lessons detract from students’ learning as they are distracting and unnecessary.

However, a few standards were connected well through multiple books and modules, in a way that built upon itself and extended students to higher levels of thinking. These examples include:

• G-GPE.1,2: From Math 2 to Math 3, lessons build on one another to develop an understanding of not only circles but other conic sections as well.
• S-ID.6: From Math 1 to Math 3, students are expected to fit data with linear and exponential functions then extends fitting of data to include quadratic functions, with a final extension of this concept to fit data with sine functions.
• F-BF.2: In Math 1, students work with arithmetic sequences to prepare for lessons in the following module dealing with linear functions.
• F-LE.2: From Math 1 to Math 3, lessons are designed to build students’ abilities to work with geometric sequences and extend these ideas to geometric series, while preparing students to connect concepts to exponential functions.
• N-RN.1: From Math 2 to Math 3, lessons build on one another to help students understand and connect concepts of rational exponents and radicals.

Algebra and Functions standards, and occasionally Number and Quantity standards, are taught in conjunction with each other, but the book does not make a specific effort to draw attention to connections between the categories. Geometry and Statistics and Probability standards are normally taught in isolation. For example, in Math 2, two lessons were found that focus on concepts from Geometry and Algebra in the same lesson. The module performance tasks do combine multiple standards, but not to draw connections between the concepts; instead, they produce a culminating application of procedures covered in the module.

Examples of connections not made in the materials include:

• Math 1, Lesson 2.3, (A-CED.A.4) does not extend Properties of Equality from Lesson 1.1 and Lesson 2.2 where the emphasis was on solving equations. Instead the lesson focuses on "rearranging;" however, students are not "using the same reasoning as in solving equations," which is only introduced minimally in Lesson 2.3. Module 17 does not connect the concepts of functions and transformations as is done in the Geometry Progression. Making this connection in Math 1 would support students as they work with transformations of increasingly complex function transformations in Math 2 and Math 3.
• Math 3: Lesson 5.4 Explain 2 page 299 connects cubic functions to the volume formula again, this time through standard application of the volume of a prism. Again, this is presented as new material and not explicitly connected to the material in Math 2 Module 21. This is also a missed opportunity to connect quadratic functions to surface area from Module 3, Visualizing Solids.

Almost a quarter of the lessons in the series are exact repeats of each other. Students are not given the opportunity to build on foundations because the lessons that should provide foundation are just repeated from course to course, and careful connections are unable to be built. The following are lessons that are repeated across multiple courses along with the standards that they address:

• S-ID.6b: Math 1, 10.2 and Math 2, 10.2; Math 1, 15.2 and Math 2, 10.3
• A-REI.3: Math 1, 13.3 and Math 2, 2.2; Math 1, 13.4 and Math 2, 2.3
• F-IF.7e: Math 1, 14.4 and Math 2, 10.2
• G-CO.9: Math 1, 19.1 and Math 2, 14.1; Math 1, 19.2 and Math 2, 14.2; Math 1, 19.3 and Math 2, 14.3 and Math 3, 1.1; Math 1, 19.4 and Math 2, 14.4 and Math 3, 1.2
• G-CO.10: Math 1, 22.1 and Math 2, 15.1; Math 1, 22.2 and Math 2, 15.2; Math 2, 2.3 and Math 2, 15.3; Math 1, 23.1 and Math 2, 15.4; Math 1, 23.2 and Math 2, 15.5
• G-CO.11: Math 1, 24.1 and Math 2, 15.6 and Math 3, 1.4; Math 1, 24.2 and Math 2, 15.7; Math 1, 25.4 and Math 3, 2.4
• G-GPE.5: Math 1, 25.1 and Math 3, 2.1; Math 1, 25.2 and Math 3, 2.2
• G-GPE.4: Math 1, 25.3 and Math 3, 2.3
• G-GPE.7: Math 1, 25.2 and Math 3, 2.5
• G-GPE.6: Math 2, 17.2 and Math 3, 2.6
• G-GMD.3: Math 2, 21.5 and Math 3, 4.1
• G-C.2: Math 2, 19.1 and Math 3, 24.1; Math 2, 19.3 and Math 3, 24.3; Math 2, 19.4 and Math 3, 24.4; Math 2, 19.5 and Math 3, 24.5
• G-C.3: Math 2, 19.2 and Math 3, 24.2
• G-GMD.1: Math 2, 20.1 and Math 3, 25.1
• G-C.5: Math 2, 20.3 and Math 3, 25.3
• G-C.1: Math 2, 20.2 and Math 3, 25.2
• G-SRT.8: Math 2, 18.4 and Math 3, 17.1
• F-TF.8: Math 2, 18.5 and Math 3, 18.3