1 : ConsistentDependentInconsistent One solution Lines intersect No solution Lines are parallel Infinite number of solutions Coincide-Same line

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Consistent DependentInconsistent

One solution

Lines intersect

No solution

Lines are parallel

Infinite number of solutions

Coincide-Same line

Three possible solutions to a linear system in two variables:

One solution: Independed system

No solutions: inconsistent system

Infinitely many solutions: dependent

Linear System in Two Variables

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2x – y = 2x + y = -2

2x – y = 2 -y = -2x + 2 y = 2x – 2

x + y = -2y = -x - 2

Different slope, different intercept!

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3x + 2y = 33x + 2y = -4

3x + 2y = 32y = -3x + 3y = -3/2 x + 3/2

3x + 2y = -42y = -3x -4y = -3/2 x - 2

Same slope, different intercept!!

x – y = -32x – 2y = -6

x – y = -3-y = -x – 3y = x + 3

2x – 2y = -6-2y = -2x – 6y = x + 3

Same slope, same intercept! Same equation!!

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Determine Without Graphing:•There is a somewhat shortened way to determine what type (one solution, no solutions, infinitely many solutions) of solution exists within a system.•Notice we are not finding the solution, just what type of solution. •Write the equations in slope-intercept form: y = mx + b.

(i.e., solve the equations for y, remember that m = slope, b = y - intercept).

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Determine Without Graphing:Once the equations are in slope-intercept form, compare the slopes and intercepts.

One solution – the lines will have different slopes.

No solution – the lines will have the same slope, but different intercepts.

Infinitely many solutions – the lines will have the same slope and the same intercept.

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Determine Without Graphing:Given the following lines, determine what type of solution exists, without graphing.

Equation 1: 3x = 6y + 5

Equation 2: y = (1/2)x – 3

Writing each in slope-intercept form (solve for y)

Equation 1: y = (1/2)x – 5/6

Equation 2: y = (1/2)x – 3

Since the lines have the same slope but different y-intercepts, there is no solution to the system of equations. The lines are parallel.

Substitution Method:Procedure for Substitution Method

1. Solve one of the equations for one of the variables.

2. Substitute the expression found in step 1 into the

other equation.

3. Now solve for the remaining variable.

4. Substitute the value from step 2 into the equation

written in step 1, and solve for the remaining variable.

Substitution Method:1. Solve the following system of equations by substitution.

5

3

yx

xy

5)3( xx

532 x

82 x4x

Step 1 is already completed.

Step 2:Substitute x+3 into 2nd equation and solve.

Step 3: Substitute –4 into 1st equation and solve.

1

34

3

y

y

xy

The answer: ( -4 , -1)

1) Solve the system using substitution

x + y = 5

y = 3 + xStep 1: Solve an equation

for one variable.

Step 2: Substitute

The second equation is

already solved for y!

x + y = 5x + (3 + x) = 5

Step 3: Solve the equation.

2x + 3 = 5

2x = 2

x = 1


x + y = 5

y = 3 + x

Step 4: Plug back in to find the other variable.

x + y = 5

(1) + y = 5

y = 4

Step 5: Check your solution.

(1, 4)

(1) + (4) = 5

(4) = 3 + (1)

The solution is (1, 4). What do you think the answer would be if you graphed the two equations?


3y + x = 7

4x – 2y = 0

Step 1: Solve an equation for one variable.

Step 2: Substitute

It is easiest to solve the

first equation for x.

3y + x = 7

-3y -3y

x = -3y + 7

4x – 2y = 0

4(-3y + 7) – 2y = 0


3y + x = 7

4x – 2y = 0

Step 4: Plug back in to find the other variable.

4x – 2y = 0

4x – 2(2) = 0

4x – 4 = 0

4x = 4

x = 1

Step 3: Solve the equation.

-12y + 28 – 2y = 0-14y + 28 = 0

-14y = -28y = 2


3y + x = 7

4x – 2y = 0

Step 5: Check your solution.

(1, 2)

3(2) + (1) = 7

4(1) – 2(2) = 0

Deciding whether an ordered pair is a solution of a linear system. The solution set of a linear system of equations contains all ordered pairs that satisfy all the equations at the same time.

Example 1: Is the ordered pair a solution of the given system? 2x + y = -6 Substitute the ordered pair into each equation.

x + 3y = 2 Both equations must be satisfied.

A) (-4, 2) B) (3, -12)2(-4) + 2 = -6 2(3) + (-12) = -6(-4) + 3(2) = 2 (3) + 3(-12) = 2

-6 = -6 -6 = -6 2 = 2 -33 -6

Yes No

Substitution Method

Example Solve the system.

Solution

4

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1

55

11623

11)3(23

3

y

y

x

x

xx

xx

xy Solve (2) for y.

Substitute y = x + 3 in (1).

Solve for x.

Substitute x = 1 in y = x + 3.

Solution set: {(1, 4)}

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1123

yx

yx (1)

(2)

Systems of Linear Equations in Two Variables

Solving Linear Systems by Graphing. One way to find the solution set of a linear system of equations is to graph each equation and find the point where the graphs intersect.

Example 1: Solve the system of equations by graphing.

A) x + y = 5 B) 2x + y = -5

2x - y = 4 -x + 3y = 6

Solution: {(3,2)} Solution: {(-3,1)}


Solving Linear Systems by Graphing. There are three possible solutions to a system of linear equations in two variables that have been graphed:

1) The two graphs intersect at a single point. The coordinates give the solution of the system. In this case, the solution is “consistent” and the equations are “independent”.

2) The graphs are parallel lines. (Slopes are equal) In this case the system is “inconsistent” and the solution set is 0 or null.

3) The graphs are the same line. (Slopes and y-intercepts are the same) In this case, the equations are “dependent” and the solution set is an infinite set of

ordered pairs.

4-1 Systems of Linear Equations in Two Variables

Solving Linear Systems of two variables by Method of Substitution.

Step 1: Solve one of the equations for either variable

Step 2: Substitute for that variable in the other equation

(The result should be an equation with just one variable)

Step 3: Solve the equation from step 2

Step 4: Substitute the result of Step 3 into either of the original equations and solve for the other value.

Step 6: Check the solution and write the solution set.

4-1 Systems of Linear Equations in Two Variables


Example 6: Solve the system : 4x + y = 52x - 3y =13

Step 1: Choose the variable y to solve for in the top equation:

y = -4x + 5Step 2: Substitute this variable into the bottom equation

2x - 3(-4x + 5) = 13 2x + 12x - 15 = 13Step 3: Solve the equation formed in step 2

14x = 28 x = 2Step 4: Substitute the result of Step 3 into either of the original equations and solve for the other value. 4(2) + y = 5

y = -3Solution Set: {(2,-3)}

Step 5: Check the solution and write the solution set.



Example 7: Solve the system :

y = -2x + 2

-2x + 5(-2x + 2) = 22 -2x - 10x + 10 = 22

-12x = 12 x = -1 2(-1) + y = 2

y = 4Solution Set: {(-1,4)}

1 1 1

2 4 22

1 1 1 rewrite as 4[ ] 2 2

2 4 2

: 2 2

-2 5 2

5 2

2

2

x y

x y

x y x y

Solve x y

x y

3x – y = 4x = 4y - 17

Your Turn:

Your Turn:

2x + 4y = 43x + 2y = 22

Clearing Fractions or Decimals

Systems without a Single Point Solution

0 = 4 untrue

Inconsistent Systems - how can you tell?An inconsistent system has no solutions. (parallel lines)Substitution Technique

ntinconsiste

xxxx

xyBxyA

072225

332353

23)(53)(

0 = 0 or n = n

Dependent Systems – how can you tell?A dependent system hasinfinitely many solutions. (it’s the same line!)Substitution Technique

dependentyy

yyAyxyxB

xyBxyA

666633

6)3(23)(324128)(

24812)(623)(

23

23

29

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Modeling Examples:The reason to learn about systems of equations is to learn how to solve real world problems.

Study Example 8 on page 360 in the text. Notice how the original equations are set up based on the data in the question.

Also note that we are trying to determine when the total cost at each garage will be the same. To do this, set the two cost equations equal to each other and solve. You will see this type of problem often.

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Modeling Examples:Study Example 9 on page 361 in the text. This is a mixture problem. Notice how the original equations are set up based on the data in the question.

Once the equations are set up, the 2nd equation is multiplied by 100 to remove the decimal. This is a common occurrence, so make sure you know how to do this.

Note: The example is solved using the addition method. It can also be solved by substitution.

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Modeling Examples:4. Read problem 40 on page 362 of the text – “basketball game”.

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First assign the variables:

let x = # of 2 point shots

let y = # of 3 point shots

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let x = # of 2 point shots

let y = # of 3 point shots

Writing the 1st equation:

They made 45 goals in a recent game

x + y = 45

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Modeling Examples:

4 continued.

Writing the 2nd equation:

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Modeling Examples:

4 continued.


Some 2 pointers, some 3 pointers, for a total score of 101 points

2x + 3y = 101

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Modeling Examples:

4 continued.


Some 2 pointers, some 3 pointers, for a total score of 101 points

2x + 3y = 101

In words, the equation says 2 times the number of 2 point shots plus 3 times the number of 3 point shots totals 101 points.

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Modeling Examples:

4 continued.

The two equations are:

x + y = 45

2x + 3y = 101

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Modeling Examples:

4 continued.


-2( x + y = 45 )

2x + 3y = 101

Lets eliminate x, multiply the entire 1st equation by –2.

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Modeling Examples:

4 continued.


-2( x + y = 45 )

2x + 3y = 101

-2x + -2y = -90

2x + 3y = 101

Lets eliminate x, multiply the entire 1st equation by –2.

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Modeling Examples:

4 continued.


-2( x + y = 45 )

2x + 3y = 101

-2x + -2y = -90

2x + 3y = 101

y = 11

Add down to eliminate x. Substitute y into the 1st equation. x + 11 = 45, so x = 34.

34 - 2 point shots and 11 - 3 point shots.

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Modeling Examples:5. Read problem 44 on page 363 in the text –

A Milk Mixture.

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A Milk Mixture.


let x = # gallons of 5% milk

let y = # gallons of skim (0%) milk

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A Milk Mixture.


let x = # gallons of 5% milk

let y = # gallons of skim (0%) milk


x + y = 100

This is because they want to make a mixture totaling 100 gallons of milk.

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Modeling Examples:5. Continued


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0.05x + 0.0y = 0.035(100)

Basically, we are multiplying the 1st equation by the percent butterfat of the milk. Our final mixture should be 3.5%, so we multiply 0.035(100), since we want 100 total gallons.

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x + y = 100

0.05x + 0.0y = 0.035(100)

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x + y = 100

0.05x + 0.0y = 0.035(100)

Next, multiply the 2nd equation by 1000 to remove the decimal. This gives us the following system of equations: x + y = 100

50x + 0y = 35(100)

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x + y = 100

0.05x + 0.0y = 0.035(100)

Next, multiply the 2nd equation by 1000 to remove the decimal. This gives us the following system of equations: x + y = 100

50x + 0y = 35(100)

Solve the system (use substitution since the 2nd equation has only one variable). The answer follows on the next slide.

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The answer is 70 gallons of 5% milk and 30 gallons of skim (0%) milk.

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Modeling Examples:6. Read problem 48 on page 363 in the text – School Play Tickets.

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let x = # of adult tickets sold ($5 per ticket)

let y = # of student tickets sold ($2 per ticket)

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let x = # of adult tickets sold ($5 per ticket)

let y = # of student tickets sold ($2 per ticket)


x + y = 250

Since a total of 250 tickets were sold.

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5x + 2y = 950

Basically, we multiplied the 1st equation by the price of the tickets, and set it equal to the amount of money collected.

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5x + 2y = 950

Basically, we multiplied the 1st equation by the price of the tickets, and set it equal to the amount of money collected.

Do you see how this is similar to example #4? The 2 and 3 point shots?

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x + y = 250

5x + 2y = 950

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x + y = 250

5x + 2y = 950

Can you solve the system using either substitution or addition? The answer follows on the next slide.

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The answer is 150 adult tickets were sold, and 100 student tickets were sold.

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Congratulations!

You have finished the PowerPoint slides for Chapter 7!

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Documents

1 : ConsistentDependentInconsistent One solution Lines intersect No solution Lines are parallel Infinite number of solutions Coincide-Same line