Given data in the form of a graph, the student will use the graph to interpret solutions to problems.

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In this topic, students explore a variety of different functions. The intent is merely to introduce these new functions, providing an overview but not a deep understanding at this point. The topic is designed to help students recognize that different function families have different key characteristics. In later study in this course, they will formalize their understanding of the defining characteristics of each type of function.

In this topic, students explore sequences represented as lists of numbers, in tables of values, by equations, and as graphs on the coordinate plane. Students move from an intuitive understanding of patterns to a more formal approach of representing sequences as functions. In the final lesson of the topic, students are introduced to the modeling process. Defined in four steps—Notice and Wonder, Organize and Mathematize, Predict and Analyze, and Test and Interpret—the modeling process gives students a structure for approaching real-world mathematical problems.

In this topic, students focus on the patterns that are evident in certain data sets and use linear functions to model those patterns. Using the informal knowledge of lines of best fit that was built in previous grades, students advance their statistical methods to make predictions about real-world phenomena. They differentiate between correlation and causation, recognizing that a correlation between two quantities does not necessarily mean that there is also a causal relationship. At the end of this topic, students will synthesize what they have learned to decide whether a linear model is appropriate.

Given problem situations that include pictorial representations of irrational numbers, the student will find the approximate value of the irrational numbers.

Given problem situations, the student will express numbers in scientific notation.

Given verbal and/or algebraic descriptions of situations involving systems of linear equations, the student will solve the system of equations using graphs.

Given verbal, graphical, or symbolic descriptions of the graph of y = ax^2 + c, the student will investigate, describe, and predict the effects on the graph when a is changed.

Given data in a verbal description, the student will use equations and tables to solve and interpret solutions to problems.

Given a quadratic equation, the student will use tiles to factor and solve the equation.

Given a quadratic equation, the student will solve the equation by factoring, completing the square, or by using the quadratic formula.

The student is expected to gather and record data & use data sets to determine functional relationships between quantities.

Given a coordinate plane, the student will graph dilations, reflections, and translations, and use those graphs to solve problems.

Given a coordinate plane or coordinate representations of a dilation, the student will graph dilations and use those graphs to solve problems.