Math I – Glossary | Open Up HS Math (CCSS), Student

A–F

acute angle

Unit 6 Lesson 2

An angle whose measure is between $0 °$ and $90 °$ .

$∠ A B C$ is an acute angle.

angle

Unit 6 Lesson 4

Two rays that share a common endpoint called the vertex of the angle.

angle of rotation

Unit 6 Lesson 4

The fixed point a figure is rotated about is called the center of rotation. If one connects a point in the pre-image, the center of rotation, and the corresponding point in the image, they can see the angle of rotation. A counterclockwise rotation is a rotation in a positive direction. Clockwise is a negative rotation.

arithmetic mean

Unit 1 Lesson 8

The arithmetic mean is also known as the average. The arithmetic mean between two numbers will be the number that is the same distance from each of the numbers. It is found by adding the two numbers and dividing by $2$ .

The arithmetic mean of several numbers is found by adding all of the numbers together and dividing by the number of items in the set:

Example: Find the arithmetic mean of ${5, 6, 7, 8} \Rightarrow \frac{5 + 6 + 7 + 8}{4} = \frac{26}{4} = 6.5$

arithmetic sequence

Unit 1 Lesson 2

The list of numbers $3 10 17 24 31$ represents an arithmetic sequence because, beginning with the first term, $3$ , the number $7$ has been added to get the next term. The next term in the sequence will be ( $31 + 7$ ) or $38$ .

The number being added each time is called the constant difference ( $d$ ).

The sequence can be represented by a recursive equation.

In words:

Name the $first term$ . $Next = Previous + d$

Using function notation:

An arithmetic sequence can also be represented with an explicit equation, often in the form $f (n) = d (n - 1) + f (1)$ where $d$ is the constant difference $(d)$ and $f (1)$ is the value of the first term.

The graph of the terms in an arithmetic sequence are arranged in a line.

associative property of addition or multiplication

Unit 4 Lesson 3, Unit 8 Lesson 6

See properties of operations for numbers in the rational, real, or complex number systems.

asymptote

Unit 2 Lesson 5

A line that a graph approaches, but does not reach. A graph will never touch a vertical asymptote, but it might cross a horizontal or an oblique (also called slant) asymptote.

Horizontal and oblique asymptotes indicate the general behavior of the ends of a graph in both positive and negative directions. If a rational function has a horizontal asymptote, it will not have an oblique asymptote.

Oblique asymptotes only occur when the numerator of $f (x)$ has a degree that is one higher than the degree of the denominator.

augmented matrix

Unit 5 Lesson 11

An augmented matrix for a system of equations is a matrix of numbers in which each row represents the constants from one equation (both the coefficients and the constant on the other side of the equal sign) and each column represents all the coefficients for a single variable.

Given the system:

$3 x + 1 y = 14$

$5 x - 3 y = 0$

Here is the augmented matrix for this system:

auxiliary line

Unit 7 Lesson 5

An extra line or line segment drawn in a figure to help with a proof.

$\overset{\leftrightarrow}{C D}$ is an auxiliary line (added to the diagram of $△ A B C)$ to help prove that the sum of the angles $(m ∠ 4 + m ∠ 2 + m ∠ 5) = 180 °$ .

average rate of change

Unit 2 Lesson 9

See rate of change.

bimodal distribution

Unit 9 Lesson 6

A bimodal distribution has two main peaks.

The data has two modes.

Output $f (n)$	$37$	$74$	$148$	$296$
Input $n$	$1$	$2$	$3$	$4$

Output $f (n)$	$19$	$25$	$31$	$37$
Input $n$	$1$	$2$	$3$	$4$

G–L

geometric sequence

Unit 1 Lesson 3

The list of numbers

represents a geometric sequence because, beginning with the first term, $3$ , each term is being multiplied by $5$ to get the next term in the sequence.

The next term in the sequence will be ( $1875 \times 5$ ) or $9375$ .

The number being multiplied each time is called the common ratio (r).

The sequence can be represented by a recursive equation.

In words:

Name the $first term$ . $Next = Previous \times r$

Using function notation:

A geometric sequence can also be represented with an explicit equation in the form $f (x) = a b^{n}$ , where $a$ is the first term, $b$ is the common ratio ( $r$ ) and $n$ is the input value.

The explicit equation for a geometric sequence is an exponential function.

The graph of the terms in a geometric sequence is arranged in a curve.

half-plane

Unit 5 Lesson 3

The part of the plane on one side of a straight line of infinite length in the plane.

The points in a half-plane are solutions to an inequality.

hexagon

Unit 6 Lesson 5

A six-sided polygon.

histogram

Unit 9 Lesson 6

A graphical display of univariate data. The data is grouped into equal ranges and then plotted as bars. The height of each bar shows how many are in each range.

The graph shows the heights of $25$ students in a math class.

horizontal asymptote

Unit 2 Lesson 5

A line that the graph approaches but does not reach. Exponential functions have a horizontal asymptote. The horizontal asymptote is the value the function approaches as $x$ either gets infinitely larger or smaller. An asymptote is an imaginary line, but it is often shown as a dotted line on the graph.

$f (x) = 2^{x}$

As $x$ gets smaller, the graph of $f (x)$ approaches the horizontal asymptote, $y = 0$ .

$h (x) = 2^{- x}$

As $x$ gets larger, the graph of $h (x)$ approaches the horizontal asymptote, $y = 0$ .

$g (x) = 2^{x} - 3$

As $x$ gets smaller, the graph of $g (x)$ approaches the horizontal asymptote, $y = - 3$ .

M–R

magnitude of a vector

Unit 8 Lesson 5

The length of a vector.

See vector.

marginal frequency

Unit 9 Lesson 9

See two-way tables.

matrix (matrices)

Unit 4 Lesson 7

A matrix is a rectangular array of data. Each piece of data in a matrix represents two characteristics, one by virtue of the row it is located in and one by virtue of the column it is in.

matrix (properties of operations)

Unit 4 Lesson 7, Unit 8 Lesson 6

Associative Property of Addition

$(a + b) + c = a + (b + c)$

Examples with Real Numbers

$\begin{aligned} (2 + 5) + 3 & = 2 + (5 + 3) \\ 7 + 3 & = 2 + 8 \\ 10 & = 10 \end{aligned}$