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	Arithmetic Operations with Numerical Fractions
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	Solving Linear Equations
	Solving Inequalities
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	Solving Systems of Equations Using Substitution
	Simplifying Fractions 3
	Factoring quadratics
	Special Products
	Writing Fractions as Percents
	Using Patterns to Multiply Two Binomials
	Adding and Subtracting Fractions
	Solving Linear Inequalities
	Adding Fractions
	Solving Systems of Equations -
	Exponential Functions
	Integer Exponents
	Example 6
	Dividing Monomials
	Multiplication can Increase or Decrease a Number
	Graphing Horizontal Lines
	Simplification of Expressions Containing only Monomials
	Decimal Numbers
	Negative Numbers
	Factoring
	Subtracting Polynomials
	Adding and Subtracting Fractions
	Powers of i
	Multiplying and Dividing Fractions
	Simplifying Complex Fractions
	Finding the Coordinates of a Point
	Fractions and Decimals
	Rational Expressions
	Solving Equations by Factoring
	Slope of a Line
	Percent Introduced
	Reducing Rational Expressions to Lowest Terms
	The Hyperbola
	Standard Form for the Equation of a Line
	Multiplication by 75
	Solving Quadratic Equations Using the Quadratic Formula
	Raising a Product to a Power
	Solving Equations with Log Terms on Each Side
	Monomial Factors
	Solving Inequalities with Fractions and Parentheses
	Division Property of Square and Cube Roots
	Multiplying Two Numbers Close to but less than 100
	Solving Absolute Value Inequalities
	Equations of Circles
	Percents and Decimals
	Integral Exponents
	Linear Equations - Positive and Negative Slopes
	Multiplying Radicals
	Factoring Special Quadratic Polynomials
	Simplifying Rational Expressions
	Adding and Subtracting Unlike Fractions
	Graphuing Linear Inequalities
	Linear Functions
	Solving Quadratic Equations by Using the Quadratic Formula
	Adding and Subtracting Polynomials
	Adding and Subtracting Functions
	Basic Algebraic Operations and Simplification
	Simplifying Complex Fractions
	Axis of Symmetry and Vertices
	Factoring Polynomials with Four Terms
	Evaluation of Simple Formulas
	Graphing Systems of Equations
	Scientific Notation
	Lines and Equations
	Horizontal and Vertical Lines
	Solving Equations by Factoring
	Solving Systems of Linear Inequalities
	Adding and Subtracting Rational Expressions with Different Denominators
	Adding and Subtracting Fractions
	Solving Linear Equations
	Simple Trinomials as Products of Binomials
	Solving Nonlinear Equations by Factoring
	Solving System of Equations
	Exponential Functions
	Computing the Area of Circles
	The Standard Form of a Quadratic Equation
	The Discriminant
	Dividing Monomials Using the Quotient Rule
	Squaring a Difference
	Changing the Sign of an Exponent
	Adding Fractions
	Powers of Radical Expressions
	Steps for Solving Linear Equations
	Quadratic Expressions Complete Squares
	Fractions 1
	Properties of Negative Exponents
	Factoring Perfect Square Trinomials
	Algebra
	Solving Quadratic Equations Using the Square Root Property
	Dividing Rational Expressions
	Quadratic Equations with Imaginary Solutions
	Factoring Trinomials Using Patterns

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Graphing Systems of Equations

Objective Understand the geometric interpretation of systems of two linear equations in two variables, and in solving them graphically.

This chapter provides a great opportunity for you to discover ideas about systems of equations. Make sure that you graph several systems by yourself, at least one of which has no solution, and at least one of which has infinitely many solutions.

Systems of Linear Equations

Key Idea

A pair of linear equations like A + O = 5 and 2A + 3O = 12 is called a system of linear equations. Its solution set is the set of all values of the two variables that satisfy both equations.

So, let us solve the following system of linear equations:

A + O = 5 and 2A + 3O = 12

That is to say, A and O must satisfy the equations simultaneously. A good way to understand the solution to a system of equations is to graph both equations on the same axes, as shown at the right.

What information can be found from this graph?

First, the set of points on the graph of A + O = 5 is the set of all points that satisfy that equation, or the set of all ordered pairs (A , O ) for which the equation holds true. In the same way, the graph of 2A + 3O = 12 is the set of all points for which that equation holds true. Therefore, the solution to the system of equations is the set of all ordered pairs (A , O ) for which both equations hold true. The solution to the system must correspond to a point that lies on both graphs, or that lies on the intersection of the graphs.

There is only one intersection point, a point that lies on both graphs. It is the point with coordinates (3, 2), or A = 3 and O = 2.

You should graph these lines and find the coordinates of the intersection point yourself.

Exercise

Solve graphically the system x + 2y = 1 and 2x + y = 5.

In this case also, there is only one solution.

Is there always only one solution to a system of linear equations?

Think about the problem graphically. A system of linear equations corresponds to a pair of straight lines. When there are two straight lines, there are three possibilities.

(1) The lines intersect in exactly one point.	(2) The lines are parallel, and do not intersect at all.	(3) The lines are actually the same line.

In this case, there is exactly one solution, corresponding to the point of intersection.	In this case, there are no solutions, since the graphs do not meet.	In this case, there are infinitely many solutions, since every point on one of the lines lies on both lines.

The following exercises provide practice in solving each of the three types of systems.

Exercises

Determine whether each system has one solution, no solution, or infinitely many solutions by graphing. If the system has one solution, name it.

y = 2x + 4	y = -x - 3	x + 4y = -8
y = 2x + 1	y = x + 3
no solution	(-3, 0)	infinitely many solutions