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College Algebra with Corequisite Support 2e

7.7 Solving Systems with Inverses

College Algebra with Corequisite Support 2e7.7 Solving Systems with Inverses

Learning Objectives

In this section, you will:

  • Find the inverse of a matrix.
  • Solve a system of linear equations using an inverse matrix.

Corequisite Skills

Learning Objectives

  • Evaluate the determinant of a 2×2 matrix (IA 4.6.1)
  • Evaluate the determinant of a 3x3 matrix (IA 4.6.2)

Objective 1: Evaluate the determinant of a 2×2 matrix (IA 4.6.1)

If a matrix has the same number of rows and columns, we call it a square matrix. Each square matrix has a real number associated with it called its determinant.

Determinant

The determinant of any square matrix abcdabcd , where a, b, c, and d are real numbers, is abcd=ad-bcabcd=ad-bc

To get the real number value of the determinate we subtract the products of the diagonals, as shown.

A 2 by 2 determinant is show, with its first row being a, b and second one being c, d. These values are written between two vertical lines instead of brackets as in the case of matrices. Two arrows are shown, one from a to d, the other from c to b. This determinant is equal to ad minus bc.

Example 1

Find the determinant of the 2x2 matrix 4-23-14-23-1

Practice Makes Perfect

Find the determinant of the 2x2 matrices.

1.

6-23-16-23-1

2.

-48-35-48-35

Objective 2: Evaluate the determinant of a 3×3 matrix (IA 4.6.2)

To evaluate the determinant of a 3×3 matrix, we must be able to evaluate the minor of an entry in the determinant.

The minor of an entry is the 2×2 determinant found by eliminating the row and column in the 3×3 determinant that contains the entry.

For example, to find the minor of entry a1, we eliminate the row and column which contain it. So, we eliminate the first row and first column. Then we write the 2×2 determinant that remains.

The first row of the 3 by 3 determinant is a1, b1, c1. Row 2 is a2, b2, c2. Row 3 is a3, b3, c3. a1 is highlighted. Lines strike out the first row and the first column. What remains is called minor of a1. It is shown as a separate determinant whose first row is b2, c2 and second row is b3, c3.

To find the minor of entry b2, we eliminate the row and column that contain it. So, we eliminate the second row and second column. Then we write the 2×2 determinant that remains.

The first row of the 3 by 3 determinant is a1, b1, c1. Row 2 is a2, b2, c2. Row 3 is a3, b3, c3. b2 is highlighted. Lines strike out the second row and second column. What remains is minor of b2. It is written as a separate determinant whose first row is a1, c1 and second row is a3, c3.

Example 2

For the determinant |4−2310−3−2−42|,|4−2310−3−2−42|, find and then evaluate the minor of a1a1 b3b3

Try It #1

For the following determinant, find and then evaluate the minor of c2

4-2310-3-2-424-2310-3-2-42

Eliminate the row and column that contains c2c2.
Write the 2×22×2 determinant that remains.
Evaluate and simplify. ________________________________________

Strategy for evaluating the determinant of a 3x3 matrix

To evaluate a 3×3 determinant we can expand by minors using any row or column. Choosing a row or column other than the first row sometimes makes the work easier.

When we expand by any row or column, we must be careful about the sign of the terms in the expansion. To determine the sign of the terms, we use the following sign pattern chart.

+-+-+-+-++-+-+-+-+

Expanding by minors along the first row to evaluate a 3x3 determinant.

To evaluate a 3×3 determinant by expanding by minors along the first row, we use the following pattern:

A 3 by 3 determinant has row 1: plus, minus, plus, row 2: minus, plus, minus and row 3: plus, minus, plus. The three signs in the first row each point to a minor determinant in the expansion of a 3 by 3 determinant. Plus points to minor of a1, minus to the minor of b1 and plus to the minor of c1.

NOTE: We can evaluate the determinant of a matrix by expanding minors along any row or column. When a row or a column has a zero entry, expanding by that row or column results in less calculations.

Example 3

Evaluate the determinant of the 3x3 matrix by expanding by minors along the first row

2-3-1320-1-1-22-3-1320-1-1-2

Practice Makes Perfect

3.

Evaluate the determinant of the 3x3 matrix by expanding by minors along the first row. -5-1-440-32-26-5-1-440-32-26

Soriya plans to invest $10,500 into two different bonds to spread out her risk. The first bond has an annual return of 10%, and the second bond has an annual return of 6%. In order to receive an 8.5% return from the two bonds, how much should Soriya invest in each bond? What is the best method to solve this problem?

There are several ways we can solve this problem. As we have seen in previous sections, systems of equations and matrices are useful in solving real-world problems involving finance. After studying this section, we will have the tools to solve the bond problem using the inverse of a matrix.

Finding the Inverse of a Matrix

We know that the multiplicative inverse of a real number a a is a −1 , a −1 , and a a −1 = a −1 a=( 1 a )a=1. a a −1 = a −1 a=( 1 a )a=1. For example, 2 −1 = 1 2 2 −1 = 1 2 and ( 1 2 )2=1. ( 1 2 )2=1. The multiplicative inverse of a matrix is similar in concept, except that the product of matrix A A and its inverse A −1 A −1 equals the identity matrix. The identity matrix is a square matrix containing ones down the main diagonal and zeros everywhere else. We identify identity matrices by I n I n where n n represents the dimension of the matrix. Observe the following equations.

I 2 =[ 1 0 0 1 ] I 2 =[ 1 0 0 1 ]
I 3 =[ 1 0 0 0 1 0 0 0 1 ] I 3 =[ 1 0 0 0 1 0 0 0 1 ]

The identity matrix acts as a 1 in matrix algebra. For example, AI=IA=A. AI=IA=A.

A matrix that has a multiplicative inverse has the properties

A A −1 =I A −1 A=I A A −1 =I A −1 A=I

A matrix that has a multiplicative inverse is called an invertible matrix. Only a square matrix may have a multiplicative inverse, as the reversibility, A A −1 = A −1 A=I, A A −1 = A −1 A=I, is a requirement. Not all square matrices have an inverse, but if A A is invertible, then A −1 A −1 is unique. We will look at two methods for finding the inverse of a 2×2 2×2 matrix and a third method that can be used on both 2×2 2×2 and 3×3 3×3 matrices.

The Identity Matrix and Multiplicative Inverse

The identity matrix, I n , I n , is a square matrix containing ones down the main diagonal and zeros everywhere else.

I 2 =[ 1 0 0 1 ] I 3 =[ 1 0 0 0 1 0 0 0 1 ]        2×2                3×3 I 2 =[ 1 0 0 1 ] I 3 =[ 1 0 0 0 1 0 0 0 1 ]        2×2                3×3

If A A is an n×n n×n matrix and B B is an n×n n×n matrix such that AB=BA= I n , AB=BA= I n , then B= A −1 , B= A −1 , the multiplicative inverse of a matrix A. A.

Example 1

Showing That the Identity Matrix Acts as a 1

Given matrix A, show that AI=IA=A. AI=IA=A.

A=[ 3 4 −2 5 ] A=[ 3 4 −2 5 ]

How To

Given two matrices, show that one is the multiplicative inverse of the other.

  1. Given matrix A A of order n×n n×n and matrix B B of order n×n n×n multiply AB. AB.
  2. If AB=I, AB=I, then find the product BA. BA. If BA=I, BA=I, then B= A −1 B= A −1 and A= B −1 . A= B −1 .

Example 2

Showing That Matrix A Is the Multiplicative Inverse of Matrix B

Show that the given matrices are multiplicative inverses of each other.

A=[ 1 5 −2 −9 ],B=[ −9 −5 2 1 ] A=[ 1 5 −2 −9 ],B=[ −9 −5 2 1 ]

Try It #2

Show that the following two matrices are inverses of each other.

A=[ 1 4 −1 −3 ],B=[ −3 −4 1 1 ] A=[ 1 4 −1 −3 ],B=[ −3 −4 1 1 ]

Finding the Multiplicative Inverse Using Matrix Multiplication

We can now determine whether two matrices are inverses, but how would we find the inverse of a given matrix? Since we know that the product of a matrix and its inverse is the identity matrix, we can find the inverse of a matrix by setting up an equation using matrix multiplication.

Example 3

Finding the Multiplicative Inverse Using Matrix Multiplication

Use matrix multiplication to find the inverse of the given matrix.

A=[ 1 −2 2 −3 ] A=[ 1 −2 2 −3 ]

Finding the Multiplicative Inverse by Augmenting with the Identity

Another way to find the multiplicative inverse is by augmenting with the identity. When matrix A A is transformed into I, I, the augmented matrix I I transforms into A −1 . A −1 .

For example, given

A=[ 2 1 5 3 ] A=[ 2 1 5 3 ]

augment A A with the identity

[ 2 1 5 3 | 1 0 0 1 ] [ 2 1 5 3 | 1 0 0 1 ]

Perform row operations with the goal of turning A A into the identity.

  1. Switch row 1 and row 2.
    [ 5 3 2 1 | 0 1 1 0 ] [ 5 3 2 1 | 0 1 1 0 ]
  2. Multiply row 2 by −2 −2 and add to row 1.
    [ 1 1 2 1 | −2 1 1 0 ] [ 1 1 2 1 | −2 1 1 0 ]
  3. Multiply row 1 by −2 −2 and add to row 2.
    [ 1 1 0 −1 | −2 1 5 −2 ] [ 1 1 0 −1 | −2 1 5 −2 ]
  4. Add row 2 to row 1.
    [ 1 0 0 −1 | 3 −1 5 −2 ] [ 1 0 0 −1 | 3 −1 5 −2 ]
  5. Multiply row 2 by −1. −1.
    [ 1 0 0 1 | 3 −1 −5 2 ] [ 1 0 0 1 | 3 −1 −5 2 ]

The matrix we have found is A −1 . A −1 .

A −1 =[ 3 −1 −5 2 ] A −1 =[ 3 −1 −5 2 ]

Finding the Multiplicative Inverse of 2×2 Matrices Using a Formula

When we need to find the multiplicative inverse of a 2×2 2×2 matrix, we can use a special formula instead of using matrix multiplication or augmenting with the identity.

If A A is a 2×2 2×2 matrix, such as

A=[ a b c d ] A=[ a b c d ]

the multiplicative inverse of A A is given by the formula

A −1 = 1 adbc [ d b c a ] A −1 = 1 adbc [ d b c a ]

where adbc0. adbc0. If adbc=0, adbc=0, then A A has no inverse.

Example 4

Using the Formula to Find the Multiplicative Inverse of Matrix A

Use the formula to find the multiplicative inverse of

A=[ 1 −2 2 −3 ] A=[ 1 −2 2 −3 ]

Analysis

We can check that our formula works by using one of the other methods to calculate the inverse. Let’s augment A A with the identity.

[ 1 −2 2 −3 | 1 0 0 1 ] [ 1 −2 2 −3 | 1 0 0 1 ]

Perform row operations with the goal of turning A A into the identity.

  1. Multiply row 1 by −2 −2 and add to row 2.
    [ 1 −2 0 1 | 1 0 −2 1 ] [ 1 −2 0 1 | 1 0 −2 1 ]
  2. Multiply row 2 by 2 and add to row 1.
    [ 1 0 0 1 | −3 2 −2 1 ] [ 1 0 0 1 | −3 2 −2 1 ]

So, we have verified our original solution.

A −1 =[ −3 2 −2 1 ] A −1 =[ −3 2 −2 1 ]

Try It #3

Use the formula to find the inverse of matrix A. A. Verify your answer by augmenting with the identity matrix.

A=[ 1 −1 2 3 ] A=[ 1 −1 2 3 ]

Example 5

Finding the Inverse of the Matrix, If It Exists

Find the inverse, if it exists, of the given matrix.

A=[ 3 6 1 2 ] A=[ 3 6 1 2 ]

Finding the Multiplicative Inverse of 3×3 Matrices

Unfortunately, we do not have a formula similar to the one for a 2×2 2×2 matrix to find the inverse of a 3×3 3×3 matrix. Instead, we will augment the original matrix with the identity matrix and use row operations to obtain the inverse.

Given a 3×3 3×3 matrix

A=[ 2 3 1 3 3 1 2 4 1 ] A=[ 2 3 1 3 3 1 2 4 1 ]

augment A A with the identity matrix

A|I=[ 2 3 1 3 3 1 2 4 1  |   1 0 0 0 1 0 0 0 1 ] A|I=[ 2 3 1 3 3 1 2 4 1  |   1 0 0 0 1 0 0 0 1 ]

To begin, we write the augmented matrix with the identity on the right and A A on the left. Performing elementary row operations so that the identity matrix appears on the left, we will obtain the inverse matrix on the right. We will find the inverse of this matrix in the next example.

How To

Given a 3×3 3×3 matrix, find the inverse

  1. Write the original matrix augmented with the identity matrix on the right.
  2. Use elementary row operations so that the identity appears on the left.
  3. What is obtained on the right is the inverse of the original matrix.
  4. Use matrix multiplication to show that A A −1 =I A A −1 =I and A −1 A=I. A −1 A=I.

Example 6

Finding the Inverse of a 3 × 3 Matrix

Given the 3×3 3×3 matrix A, A, find the inverse.

A=[ 2 3 1 3 3 1 2 4 1 ] A=[ 2 3 1 3 3 1 2 4 1 ]

Analysis

To prove that B= A −1 , B= A −1 , let’s multiply the two matrices together to see if the product equals the identity, if A A −1 =I A A −1 =I and A −1 A=I. A −1 A=I.

A A −1 =[ 2 3 1 3 3 1 2 4 1 ]  [ −1 1 0 −1 0 1 6 −2 −3 ] =[ 2(−1)+3(−1)+1(6) 2(1)+3(0)+1(−2) 2(0)+3(1)+1(−3) 3(−1)+3(−1)+1(6) 3(1)+3(0)+1(−2) 3(0)+3(1)+1(−3) 2(−1)+4(−1)+1(6) 2(1)+4(0)+1(−2) 2(0)+4(1)+1(−3) ] =[ 1 0 0 0 1 0 0 0 1 ] A A −1 =[ 2 3 1 3 3 1 2 4 1 ]  [ −1 1 0 −1 0 1 6 −2 −3 ] =[ 2(−1)+3(−1)+1(6) 2(1)+3(0)+1(−2) 2(0)+3(1)+1(−3) 3(−1)+3(−1)+1(6) 3(1)+3(0)+1(−2) 3(0)+3(1)+1(−3) 2(−1)+4(−1)+1(6) 2(1)+4(0)+1(−2) 2(0)+4(1)+1(−3) ] =[ 1 0 0 0 1 0 0 0 1 ]
A −1 A=[ −1 1 0 −1 0 1 6 −2 3 ]  [ 2 3 1 3 3 1 2 4 1 ] =[ −1(2)+1(3)+0(2) −1(3)+1(3)+0(4) −1(1)+1(1)+0(1) −1(2)+0(3)+1(2) −1(3)+0(3)+1(4) −1(1)+0(1)+1(1) 6(2)+−2(3)+−3(2) 6(3)+−2(3)+−3(4) 6(1)+−2(1)+−3(1) ] =[ 1 0 0 0 1 0 0 0 1 ] A −1 A=[ −1 1 0 −1 0 1 6 −2 3 ]  [ 2 3 1 3 3 1 2 4 1 ] =[ −1(2)+1(3)+0(2) −1(3)+1(3)+0(4) −1(1)+1(1)+0(1) −1(2)+0(3)+1(2) −1(3)+0(3)+1(4) −1(1)+0(1)+1(1) 6(2)+−2(3)+−3(2) 6(3)+−2(3)+−3(4) 6(1)+−2(1)+−3(1) ] =[ 1 0 0 0 1 0 0 0 1 ]

Try It #4

Find the inverse of the 3×3 3×3 matrix.

A=[ 2 −17 11 −1 11 −7 0 3 −2 ] A=[ 2 −17 11 −1 11 −7 0 3 −2 ]

Solving a System of Linear Equations Using the Inverse of a Matrix

Solving a system of linear equations using the inverse of a matrix requires the definition of two new matrices: X X is the matrix representing the variables of the system, and B B is the matrix representing the constants. Using matrix multiplication, we may define a system of equations with the same number of equations as variables as

AX=B AX=B

To solve a system of linear equations using an inverse matrix, let A A be the coefficient matrix, let X X be the variable matrix, and let B B be the constant matrix. Thus, we want to solve a system AX=B. AX=B. For example, look at the following system of equations.

a 1 x+ b 1 y= c 1 a 2 x+ b 2 y= c 2 a 1 x+ b 1 y= c 1 a 2 x+ b 2 y= c 2

From this system, the coefficient matrix is

A=[ a 1 b 1 a 2 b 2 ] A=[ a 1 b 1 a 2 b 2 ]

The variable matrix is

X=[ x y ] X=[ x y ]

And the constant matrix is

B=[ c 1 c 2 ] B=[ c 1 c 2 ]

Then AX=B AX=B looks like

[ a 1 b 1 a 2 b 2 ]  [ x y ]=[ c 1 c 2 ] [ a 1 b 1 a 2 b 2 ]  [ x y ]=[ c 1 c 2 ]

Recall the discussion earlier in this section regarding multiplying a real number by its inverse, ( 2 −1 )2=( 1 2 )2=1. ( 2 −1 )2=( 1 2 )2=1. To solve a single linear equation ax=b ax=b for x, x, we would simply multiply both sides of the equation by the multiplicative inverse (reciprocal) of a. a. Thus,

 ax=b  ( 1 a )ax=( 1 a )b ( a −1   )ax=( a −1 )b [( a −1 )a]x=( a −1 )b            1x=( a −1 )b              x=( a −1 )b  ax=b  ( 1 a )ax=( 1 a )b ( a −1   )ax=( a −1 )b [( a −1 )a]x=( a −1 )b            1x=( a −1 )b              x=( a −1 )b

The only difference between a solving a linear equation and a system of equations written in matrix form is that finding the inverse of a matrix is more complicated, and matrix multiplication is a longer process. However, the goal is the same—to isolate the variable.

We will investigate this idea in detail, but it is helpful to begin with a 2×2 2×2 system and then move on to a 3×3 3×3 system.

Solving a System of Equations Using the Inverse of a Matrix

Given a system of equations, write the coefficient matrix A, A, the variable matrix X, X, and the constant matrix B. B. Then

AX=B AX=B

Multiply both sides by the inverse of A A to obtain the solution.

( A −1 )AX=( A −1 )B [ ( A −1 )A ]X=( A −1 )B IX=( A −1 )B X=( A −1 )B ( A −1 )AX=( A −1 )B [ ( A −1 )A ]X=( A −1 )B IX=( A −1 )B X=( A −1 )B

Q&A

If the coefficient matrix does not have an inverse, does that mean the system has no solution?

No, if the coefficient matrix is not invertible, the system could be inconsistent and have no solution, or be dependent and have infinitely many solutions.

Example 7

Solving a 2 × 2 System Using the Inverse of a Matrix

Solve the given system of equations using the inverse of a matrix.

3x+8y=5 4x+11y=7 3x+8y=5 4x+11y=7

Q&A

Can we solve for X X by finding the product B A −1 ? B A −1 ?

No, recall that matrix multiplication is not commutative, so A −1 BB A −1 . A −1 BB A −1 . Consider our steps for solving the matrix equation.

( A −1 )AX=( A −1 )B [ ( A −1 )A ]X=( A −1 )B IX=( A −1 )B X=( A −1 )B ( A −1 )AX=( A −1 )B [ ( A −1 )A ]X=( A −1 )B IX=( A −1 )B X=( A −1 )B

Notice in the first step we multiplied both sides of the equation by A −1 , A −1 , but the A −1 A −1 was to the left of A A on the left side and to the left of B B on the right side. Because matrix multiplication is not commutative, order matters.

Example 8

Solving a 3 × 3 System Using the Inverse of a Matrix

Solve the following system using the inverse of a matrix.

5x+15y+56z=35 −4x−11y−41z=−26 x−3y−11z=−7 5x+15y+56z=35 −4x−11y−41z=−26 x−3y−11z=−7

Try It #5

Solve the system using the inverse of the coefficient matrix.

 2x17y+11z=0  x+11y7z=8               3y2z=−2  2x17y+11z=0  x+11y7z=8               3y2z=−2

How To

Given a system of equations, solve with matrix inverses using a calculator.

  1. Save the coefficient matrix and the constant matrix as matrix variables [ A ] [ A ] and [ B ]. [ B ].
  2. Enter the multiplication into the calculator, calling up each matrix variable as needed.
  3. If the coefficient matrix is invertible, the calculator will present the solution matrix; if the coefficient matrix is not invertible, the calculator will present an error message.

Example 9

Using a Calculator to Solve a System of Equations with Matrix Inverses

Solve the system of equations with matrix inverses using a calculator

2x+3y+z=32 3x+3y+z=−27 2x+4y+z=−2 2x+3y+z=32 3x+3y+z=−27 2x+4y+z=−2

Media

Access these online resources for additional instruction and practice with solving systems with inverses.

7.7 Section Exercises

Verbal

1.

In a previous section, we showed that matrix multiplication is not commutative, that is, ABBA ABBA in most cases. Can you explain why matrix multiplication is commutative for matrix inverses, that is, A −1 A=A A −1 ? A −1 A=A A −1 ?

2.

Does every 2×2 2×2 matrix have an inverse? Explain why or why not. Explain what condition is necessary for an inverse to exist.

3.

Can you explain whether a 2×2 2×2 matrix with an entire row of zeros can have an inverse?

4.

Can a matrix with an entire column of zeros have an inverse? Explain why or why not.

5.

Can a matrix with zeros on the diagonal have an inverse? If so, find an example. If not, prove why not. For simplicity, assume a 2×2 2×2 matrix.

Algebraic

In the following exercises, show that matrix A A is the inverse of matrix B. B.

6.

A=[ 1 0 −1 1 ],B=[ 1 0 1 1 ] A=[ 1 0 −1 1 ],B=[ 1 0 1 1 ]

7.

A=[ 1 2 3 4 ],B=[ −2 1 3 2 1 2 ] A=[ 1 2 3 4 ],B=[ −2 1 3 2 1 2 ]

8.

A=[ 4 5 7 0 ],B=[ 0 1 7 1 5 4 35 ] A=[ 4 5 7 0 ],B=[ 0 1 7 1 5 4 35 ]

9.

A=[ −2 1 2 3 −1 ],B=[ −2 −1 −6 −4 ] A=[ −2 1 2 3 −1 ],B=[ −2 −1 −6 −4 ]

10.

A=[ 1 0 1 0 1 −1 0 1 1 ],B= 1 2 [ 2 1 −1 0 1 1 0 −1 1 ] A=[ 1 0 1 0 1 −1 0 1 1 ],B= 1 2 [ 2 1 −1 0 1 1 0 −1 1 ]

11.

A=[ 1 2 3 4 0 2 1 6 9 ],B= 1 4 [ 6 0 −2 17 −3 −5 −12 2 4 ] A=[ 1 2 3 4 0 2 1 6 9 ],B= 1 4 [ 6 0 −2 17 −3 −5 −12 2 4 ]

12.

A=[ 3 8 2 1 1 1 5 6 12 ],B= 1 36 [ −6 84 −6 7 −26 1 −1 −22 5 ] A=[ 3 8 2 1 1 1 5 6 12 ],B= 1 36 [ −6 84 −6 7 −26 1 −1 −22 5 ]

For the following exercises, find the multiplicative inverse of each matrix, if it exists.

13.

[ 3 −2 1 9 ] [ 3 −2 1 9 ]

14.

[ −2 2 3 1 ] [ −2 2 3 1 ]

15.

[ −3 7 9 2 ] [ −3 7 9 2 ]

16.

[ −4 −3 −5 8 ] [ −4 −3 −5 8 ]

17.

[ 1 1 2 2 ] [ 1 1 2 2 ]

18.

[ 0 1 1 0 ] [ 0 1 1 0 ]

19.

[ 0.5 1.5 1 −0.5 ] [ 0.5 1.5 1 −0.5 ]

20.

[ 1 0 6 −2 1 7 3 0 2 ] [ 1 0 6 −2 1 7 3 0 2 ]

21.

[ 0 1 −3 4 1 0 1 0 5 ] [ 0 1 −3 4 1 0 1 0 5 ]

22.

[ 1 2 −1 −3 4 1 −2 −4 −5 ] [ 1 2 −1 −3 4 1 −2 −4 −5 ]

23.

[ 1 9 −3 2 5 6 4 −2 7 ] [ 1 9 −3 2 5 6 4 −2 7 ]

24.

[ 1 −2 3 −4 8 −12 1 4 2 ] [ 1 −2 3 −4 8 −12 1 4 2 ]

25.

[ 1 2 1 2 1 2 1 3 1 4 1 5 1 6 1 7 1 8 ] [ 1 2 1 2 1 2 1 3 1 4 1 5 1 6 1 7 1 8 ]

26.

[ 1 2 3 4 5 6 7 8 9 ] [ 1 2 3 4 5 6 7 8 9 ]

For the following exercises, solve the system using the inverse of a 2×2 2×2 matrix.

27.

5x6y=61 4x+3y=2 5x6y=61 4x+3y=2

28.

8x+4y=−100 3x−4y=1 8x+4y=−100 3x−4y=1

29.

3x−2y=6 x+5y=−2 3x−2y=6 x+5y=−2

30.

5x−4y=−5 4x+y=2.3 5x−4y=−5 4x+y=2.3

31.

−3x−4y=9 12x+4y=−6 −3x−4y=9 12x+4y=−6

32.

−2x+3y= 3 10 x+5y= 1 2 −2x+3y= 3 10 x+5y= 1 2

33.

8 5 x 4 5 y= 2 5 8 5 x+ 1 5 y= 7 10 8 5 x 4 5 y= 2 5 8 5 x+ 1 5 y= 7 10

34.

1 2 x+ 1 5 y= 1 4 1 2 x 3 5 y= 9 4 1 2 x+ 1 5 y= 1 4 1 2 x 3 5 y= 9 4

For the following exercises, solve a system using the inverse of a 3×3 3×3 matrix.

35.

3x−2y+5z=21 5x+4y=37 x−2y−5z=5 3x−2y+5z=21 5x+4y=37 x−2y−5z=5

36.

4x+4y+4z=40 2x3y+4z=−12 x+3y+4z=9 4x+4y+4z=40 2x3y+4z=−12 x+3y+4z=9

37.

6x5yz=31 x+2y+z=−6 3x+3y+2z=13 6x5yz=31 x+2y+z=−6 3x+3y+2z=13

38.

6x−5y+2z=−4 2x+5yz=12 2x+5y+z=12 6x−5y+2z=−4 2x+5yz=12 2x+5y+z=12

39.

4x−2y+3z=−12 2x+2y−9z=33 6y−4z=1 4x−2y+3z=−12 2x+2y−9z=33 6y−4z=1

40.

1 10 x 1 5 y+4z= −41 2 1 5 x−20y+ 2 5 z=−101 3 10 x+4y 3 10 z=23 1 10 x 1 5 y+4z= −41 2 1 5 x−20y+ 2 5 z=−101 3 10 x+4y 3 10 z=23

41.

1 2 x 1 5 y+ 1 5 z= 31 100 3 4 x 1 4 y+ 1 2 z= 7 40 4 5 x 1 2 y+ 3 2 z= 1 4 1 2 x 1 5 y+ 1 5 z= 31 100 3 4 x 1 4 y+ 1 2 z= 7 40 4 5 x 1 2 y+ 3 2 z= 1 4

42.

0.1x+0.2y+0.3z=−1.4 0.1x−0.2y+0.3z=0.6 0.4y+0.9z=−2 0.1x+0.2y+0.3z=−1.4 0.1x−0.2y+0.3z=0.6 0.4y+0.9z=−2

Technology

For the following exercises, use a calculator to solve the system of equations with matrix inverses.

43.

2xy=−3 x+2y=2.3 2xy=−3 x+2y=2.3

44.

1 2 x 3 2 y= 43 20 5 2 x+ 11 5 y= 31 4 1 2 x 3 2 y= 43 20 5 2 x+ 11 5 y= 31 4

45.

12.3x−2y−2.5z=2 36.9x+7y−7.5z=−7 8y−5z=−10 12.3x−2y−2.5z=2 36.9x+7y−7.5z=−7 8y−5z=−10

46.

0.5x−3y+6z=−0.8 0.7x−2y=−0.06 0.5x+4y+5z=0 0.5x−3y+6z=−0.8 0.7x−2y=−0.06 0.5x+4y+5z=0

Extensions

For the following exercises, find the inverse of the given matrix.

47.

[ 1 0 1 0 0 1 0 1 0 1 1 0 0 0 1 1 ] [ 1 0 1 0 0 1 0 1 0 1 1 0 0 0 1 1 ]

48.

[ 1 0 2 5 0 0 0 2 0 2 1 0 1 3 0 1 ] [ 1 0 2 5 0 0 0 2 0 2 1 0 1 3 0 1 ]

49.

[ 1 2 3 0 0 1 0 2 1 4 2 3 5 0 1 1 ] [ 1 2 3 0 0 1 0 2 1 4 2 3 5 0 1 1 ]

50.

[ 1 2 0 2 3 0 2 1 0 0 0 0 3 0 1 0 2 0 0 1 0 0 1 2 0 ] [ 1 2 0 2 3 0 2 1 0 0 0 0 3 0 1 0 2 0 0 1 0 0 1 2 0 ]

51.

[ 1 0 0 0 0 0 0 1 0 0 0 0 0 0 1 0 0 0 0 0 0 1 0 0 0 0 0 0 1 0 1 1 1 1 1 1 ] [ 1 0 0 0 0 0 0 1 0 0 0 0 0 0 1 0 0 0 0 0 0 1 0 0 0 0 0 0 1 0 1 1 1 1 1 1 ]

Real-World Applications

For the following exercises, write a system of equations that represents the situation. Then, solve the system using the inverse of a matrix.

52.

2,400 tickets were sold for a basketball game. If the prices for floor 1 and floor 2 were different, and the total amount of money brought in is $64,000, how much was the price of each ticket?

53.

In the previous exercise, if you were told there were 400 more tickets sold for floor 2 than floor 1, how much was the price of each ticket?

54.

A food drive collected two different types of canned goods, green beans and kidney beans. The total number of collected cans was 350 and the total weight of all donated food was 348 lb, 12 oz. If the green bean cans weigh 2 oz less than the kidney bean cans, how many of each can was donated?

55.

Students were asked to bring their favorite fruit to class. 95% of the fruits consisted of banana, apple, and oranges. If oranges were twice as popular as bananas, and apples were 5% less popular than bananas, what are the percentages of each individual fruit?

56.

The nursing club held a bake sale to raise money and sold brownies and chocolate chip cookies. They priced the brownies at $1 and the chocolate chip cookies at $0.75. They raised $700 and sold 850 items. How many brownies and how many cookies were sold?

57.

A clothing store needs to order new inventory. It has three different types of hats for sale: straw hats, beanies, and cowboy hats. The straw hat is priced at $13.99, the beanie at $7.99, and the cowboy hat at $14.49. If 100 hats were sold this past quarter, $1,119 was taken in by sales, and the amount of beanies sold was 10 more than cowboy hats, how many of each should the clothing store order to replace those already sold?

58.

Anna, Percy, and Morgan weigh a combined 370 lb. If Morgan weighs 20 lb more than Percy, and Anna weighs 1.5 times as much as Percy, how much does each person weigh?

59.

Three roommates shared a package of 12 ice cream bars, but no one remembers who ate how many. If Micah ate twice as many ice cream bars as Joe, and Albert ate three less than Micah, how many ice cream bars did each roommate eat?

60.

A farmer constructed a chicken coop out of chicken wire, wood, and plywood. The chicken wire cost $2 per square foot, the wood $10 per square foot, and the plywood $5 per square foot. The farmer spent a total of $51, and the total amount of materials used was 14 ft 2 . 14 ft 2 . He used 3 ft 2 3 ft 2 more chicken wire than plywood. How much of each material in did the farmer use?

61.

Jay has lemon, orange, and pomegranate trees in his backyard. An orange weighs 8 oz, a lemon 5 oz, and a pomegranate 11 oz. Jay picked 142 pieces of fruit weighing a total of 70 lb, 10 oz. He picked 15.5 times more oranges than pomegranates. How many of each fruit did Jay pick?

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