Systems of Linear Equations: Two Variables: Fresh Take

  • Find solutions to systems of equations by drawing their graphs and finding where they cross
  • Solve systems of equations by replacing one variable with an expression from another equation
  • Solve systems of equations by adding equations to eliminate a variable
  • Figure out when systems of equations have no solution or infinitely many solutions

Solutions of Systems Overview

The Main Idea

  • System Definition and Purpose:
    • A system contains two or more linear equations with two or more variables
    • All equations must be satisfied simultaneously for a solution
    • Solution requires finding specific values for all variables
  • Types of Solutions:
    • Independent systems: Exactly one solution (lines intersect at one point)
    • Inconsistent systems: No solution (parallel lines)
    • Dependent systems: Infinite solutions (same line)
  • Solution Requirements:
    • Need at least as many equations as variables for a unique solution
    • This alone doesn’t guarantee a unique solution
    • Solution must satisfy ALL equations in the system
  • Solution Verification:
    • Substitute proposed solution into ALL equations
    • Must get true statements for each equation
    • Graphically, solution point lies on all lines
  • A consistent system of equations has at least one solution.
  • A consistent system is considered an independent system if it has a single solution.
    • Example: Two lines with different slopes intersect at one point in the plane.
  • A consistent system is considered a dependent system if the equations have the same slope and the same y-intercepts.
    • The lines coincide, representing the same line.
    • Every point on the line satisfies the system, so there are an infinite number of solutions.
  • An inconsistent system is one in which the equations represent two parallel lines.
    • The lines have the same slope but different [latex]y[/latex]-intercepts.
    • There are no points common to both lines, so there is no solution to the system.
Determine whether the ordered pair [latex]\left(8,5\right)[/latex] is a solution to the following system.

[latex]\begin{gathered}5x - 4y=20\\ 2x+1=3y\end{gathered}[/latex]

Watch the following video for another example of how to verify whether an ordered pair is a solution to a system of equations.

You can view the transcript for “Determine if an Ordered Pair is a Solution to a System of Linear Equations” here (opens in new window).

Solving Systems of Equations by Graphing

The Main Idea

  • Graphical Approach Steps:
    • Graph both equations on the same coordinate plane
    • Find the point of intersection (if it exists)
    • Verify the solution algebraically
    • Identify the system type based on how lines intersect
  • System Types from Graphs:
    • Intersecting lines → One solution (independent)
    • Parallel lines → No solution (inconsistent)
    • Same line → Infinite solutions (dependent)
  • Graphing Techniques:
    • Solve for [latex]y[/latex] to get slope-intercept form
    • Use slope and [latex]y[/latex]-intercept method
    • Use [latex]x[/latex] and [latex]y[/latex] intercepts method
    • Plot strategic points
  • Solution Verification:
    • Always check intersection point in both equations
    • Both equations must be satisfied
    • Graphical solutions are approximate unless points are clearly identifiable
Solve the following system of equations by graphing.

[latex]\begin{gathered}2x - 5y=-25 \\ -4x+5y=35 \end{gathered}[/latex]

Watch the following video for an example of how to identify what type of system and solution are represented in the graph of a system.

You can view the transcript for “Determine the Number of Solutions to a System of Linear Equations From a Graph” here (opens in new window).

Watch the next video to see how to solve a system of equations by first graphing the lines and then identifying the type of solution.

You can view the transcript for “Ex 2: Solve a System of Equations by Graphing” here (opens in new window).

Solving Systems of Equations by Substitution

The Main Idea

  • Method Overview:
    • Solve one equation for one variable
    • Substitute that expression into other equation
    • Solve resulting equation for remaining variable
    • Back-substitute to find first variable
  • Advantages:
    • More precise than graphing
    • Works well with fractional/decimal solutions
    • Often simpler than other algebraic methods
  • Solution Analysis:
    • May reveal no solution (contradictory equations)
    • May reveal infinite solutions (identical equations)
    • Check final answer in both original equations
Solve the system of equations using substitution:

[latex]\begin{align} y &= 3x + 1 \ 2x - y &= 5 \end{align}[/latex]

In the following video, you will be given an example of solving a system of two equations using the substitution method.

You can view the transcript for “Ex 2: Solve a System of Equations Using Substitution” here (opens in new window).

The following video is ~10 minutes long and provides a mini-lesson on using the substitution method to solve a system of linear equations.  We present three different examples, and also use a graphing tool to help summarize the solution for each example.

You can view the transcript for “Solving Systems of Equations using Substitution” here (opens in new window).

Solving Systems of Equations by the Addition Method

The Main Idea

  • Method Fundamentals:
    • Also called elimination method
    • Add equations to eliminate one variable
    • Variables with opposite coefficients sum to zero
    • Goal is to isolate one variable
  • Key Steps:
    • Align like terms
    • Multiply equations if needed for elimination
    • Add equations to eliminate one variable
    • Solve for remaining variable
    • Back-substitute to find other variable
  • Strategic Planning:
    • Look for variables with opposite coefficients
    • Find LCM of coefficients if multiplication needed
    • Choose simpler variable to eliminate first
    • Clear fractions before adding if needed
  • When to Use:
    • Variables have coefficients that are opposites
    • Coefficients have a small LCM
    • Substitution would be too complex
Solve the system of equations by addition.

[latex]\begin{align}2x - 7y&=2\\ 3x+y&=-20\end{align}[/latex]

Solve the system of equations by addition.[latex]\begin{align}2x+3y&=8\\ 3x+5y&=10\end{align}[/latex]

In the following video, you will see another example of how to use the method of elimination to solve a system of linear equations.

You can view the transcript for “Ex 1: Solve a System of Equations Using the Elimination Method” here (opens in new window).

Below is another video example of using the elimination method to solve a system of linear equations when multiplication of one equation is required.

You can view the transcript for “Ex 2: Solve a System of Equations Using the Elimination Method” here (opens in new window).

In the following video, you will find one more example of using the elimination method to solve a system; this one has coefficients that are fractions.

You can view the transcript for “Ex: Solve a System of Equations Using Eliminations (Fractions)” here (opens in new window).

In the following video we present more examples of how to use the addition (elimination) method to solve a system of two linear equations.

You can view the transcript for “Solving Systems of Equations using Elimination” here (opens in new window).

Identifying Inconsistent Systems of Equations Containing Two Variables

The Main Idea

  • Understanding Inconsistent Systems:
    • Parallel lines that never intersect
    • Same slope but different [latex]y[/latex]-intercepts
    • No solution exists
    • Result in contradictory equations
  • Recognition Methods:
    • Converting to slope-intercept form reveals parallel lines
    • Solving leads to contradictory statement (e.g., [latex]5 = 8[/latex])
    • Algebraic solution gives impossible result
    • Graphing shows parallel lines
  • Verification Techniques:
    • Write equations in slope-intercept form
    • Compare slopes and [latex]y[/latex]-intercepts
    • Attempt algebraic solution
    • Graph equations to confirm parallel lines
Solve the following system of equations in two variables.

[latex]\begin{gathered}2y - 2x=2\\ 2y - 2x=6\end{gathered}[/latex]

In the next video, see another example of using substitution to solve a system that has no solution.

You can view the transcript for “Ex: Solve a System of Equations Using Substitution – No Solution” here (opens in new window).

Expressing the Solution of a System of Dependent Equations Containing Two Variables

The Main Idea

  • Understanding Dependent Systems:
    • Two equations represent the same line
    • Infinite number of solutions
    • All points on one line satisfy both equations
    • Solving yields identity (e.g., [latex]0 = 0[/latex])
  • Key Characteristics:
    • Same slope and same [latex]y[/latex]-intercept
    • One equation is multiple of the other
    • Equations reduce to identity
    • Lines are coincident (overlap completely)
  • Solution Format:
    • Written in parametric form: [latex](x, mx + b)[/latex]
    • [latex]x[/latex] can be any real number
    • [latex]y[/latex] is expressed in terms of [latex]x[/latex]
    • Represents all points on the line
  • Identification Methods:
    • Convert to slope-intercept form
    • Compare coefficients after simplification
    • Look for scalar multiples
    • Check if equations are equivalent
Solve the following system of equations in two variables.

[latex]\begin{gathered}y - 2x=5 \\ -3y+6x=-15 \end{gathered}[/latex]

Watch the next video for an example of a dependent system.

You can view the transcript for “Ex: Solve a System of Equations Using Substitution – Infinite Solutions” here (opens in new window).

Application Problems

You can view the transcript for “System of Equations App: Break-Even Point” here (opens in new window).

You can view the transcript for “Ex: Solve an Application Problem Using a System of Linear Equations (09x-43)” here (opens in new window).