Linear Algebra with Applications (9th Edition) (Featured Titles for Linear Algebra (Introductory))
Linear Algebra with Applications (9th Edition) (Featured Titles for Linear Algebra (Introductory))
9th Edition
ISBN: 9780321962218
Author: Steven J. Leon
Publisher: PEARSON
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Textbook Question
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Chapter 4, Problem 1E

Use MATLAB to generate a matrix W and a vector x by setting
W = t r i u ( o n e s ( 5 ) )
and
x = [ 1 : 5 ] '
The columns of W can be used to form an ordered basis
F = { w 1 , w 2 , w 3 , w 4 , w 5 }
Let L : 5 5 be a linear operator such that
L ( w 1 ) = w 2 , L ( w 2 ) = w 3 , L ( w 3 ) = w 4
and
L ( w 4 ) = 4 w 1 + 3 w 2 + 2 w 3 + w 4
L ( w 5 ) = w 1 + w 2 + w 3 + 3 w 4 + w 5
(a) Determine the matrix A representing L with respect to F, and enter it in MATLAB.
(b) Use MATLAB to compute the coordinate vector y = W 1 x of x with respect to F.
(c) Use A to compute the coordinate vector z of L ( x ) with respect to F.
(d) W is the transition matrix from F to the standard basis for 5 . Use W to compute the coordinate vector of L ( x ) with respect to the standard basis.

a.

Expert Solution
Check Mark
To determine

Calculate the matrix A using given relation.

Answer to Problem 1E

The solution is

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

Explanation of Solution

Given:The information has been given

  W=triu(ones(4))x=[1:4]'F={ w 1 , w 2 , w 3 , w 4 }L(w1)=w2L(w2)=w3L(w3)=w4L(w4)=4w1+3w2+2w3+w4

Concept Used:

Given,

  W=triu(ones(4))x=[1:4]'F={ w 1 , w 2 , w 3 , w 4 }L(w1)=w2L(w2)=w3L(w3)=w4L(w4)=4w1+3w2+2w3+w4

Using the above relation, we will calculate the matrix A representing L with respect to F.

Program:

clc

clear

close all

W = triu(ones(4));

x = (1:4)';

A = [0 0 5 1;

1 0 4 2;

0 1 3 3;

0 0 2 4];

y = W^-1*x;

z = A*y;

Lx = W*z;

fprintf('The matrix A is: \n')

disp(A)

fprintf('The relation W^-1*x is: \n')

disp(y)

fprintf('The coordinate vector z is: \n')

disp(z)

fprintf('The coordinate vector of Lx is: \n')

disp(Lx)

Quarry:

  • First, we have defined the given matrix W.
  • Then define the matrix x.
  • Calculate the matrix A and write.
  • b.

    Expert Solution
    Check Mark
    To determine

    Calculate the given relation using relations.

    Answer to Problem 1E

    The solution is

      y=W1x=[-1-1-1 4]

    Explanation of Solution

    Given:The information has been given

      W=triu(ones(4))x=[1:4]'F={ w 1 , w 2 , w 3 , w 4 }L(w1)=w2L(w2)=w3L(w3)=w4L(w4)=4w1+3w2+2w3+w4

    Concept Used:

    Given,

      W=triu(ones(4))x=[1:4]'F={ w 1 , w 2 , w 3 , w 4 }L(w1)=w2L(w2)=w3L(w3)=w4L(w4)=4w1+3w2+2w3+w4

    Calculate y=W1x

    After calculating, we will get

      y=W1x=[-1-1-1 4]

    Program:

    clc
    clear
    close all
    W = triu(ones(4));
    x = (1:4)';
    A = [0 0 5 1;
         1 0 4 2;
         0 1 3 3;
         0 0 2 4]; 
    y = W^-1*x; 
    z = A*y; 
    Lx = W*z;
    fprintf('The matrix A is: \n')
    disp(A)
    fprintf('The relation W^-1*x is: \n')
    disp(y)
    fprintf('The coordinate vector z is: \n')
    disp(z)
    fprintf('The coordinate vector of Lx is: \n')
    disp(Lx)
    

    Quarry:

    • First, we have defined the given matrix W.
    • Then define the matrix x.
    • Calculate the relation y=W1x .

    c.

    Expert Solution
    Check Mark
    To determine

    Using the matrix A calculate the coordinate vector.

    Answer to Problem 1E

    The solution is

      z=[-1 3 814]

    Explanation of Solution

    Given:The information has been given

      W=triu(ones(4))x=[1:4]'F={ w 1 , w 2 , w 3 , w 4 }L(w1)=w2L(w2)=w3L(w3)=w4L(w4)=4w1+3w2+2w3+w4

    Concept Used:

    Given,

      W=triu(ones(4))x=[1:4]'F={ w 1 , w 2 , w 3 , w 4 }L(w1)=w2L(w2)=w3L(w3)=w4L(w4)=4w1+3w2+2w3+w4

    Calculate coordinate vector z=AW1X=Ay .

    After calculating, we will get

      z=[-1 3 814]

    Program:

    clc
    clear
    close all
    W = triu(ones(4));
    x = (1:4)';
    A = [0 0 5 1;
         1 0 4 2;
         0 1 3 3;
         0 0 2 4]; 
    y = W^-1*x; 
    z = A*y; 
    Lx = W*z;
    fprintf('The matrix A is: \n')
    disp(A)
    fprintf('The relation W^-1*x is: \n')
    disp(y)
    fprintf('The coordinate vector z is: \n')
    disp(z)
    fprintf('The coordinate vector of Lx is: \n')
    disp(Lx)
    

    Quarry:

    • First, we have defined the given matrix W.
    • Then define the matrix x.
    • Calculate coordinate vector z.

    d.

    Expert Solution
    Check Mark
    To determine

    Calculate the coordinate vector of Lx with respect to standard basis.

    Answer to Problem 1E

    The solution is

      Lx=[24252214]

    Explanation of Solution

    Given:The information has been given

      W=triu(ones(4))x=[1:4]'F={ w 1 , w 2 , w 3 , w 4 }L(w1)=w2L(w2)=w3L(w3)=w4L(w4)=4w1+3w2+2w3+w4

    Concept Used:

    Given,

      W=triu(ones(4))x=[1:4]'F={ w 1 , w 2 , w 3 , w 4 }L(w1)=w2L(w2)=w3L(w3)=w4L(w4)=4w1+3w2+2w3+w4

    Calculate coordinate vector of Lx=Wz .

    After calculating, we will get

      Lx=[24252214]

    Program:

    clc
    clear
    close all
    W = triu(ones(4));
    x = (1:4)';
    A = [0 0 5 1;
         1 0 4 2;
         0 1 3 3;
         0 0 2 4]; 
    y = W^-1*x; 
    z = A*y; 
    Lx = W*z;
    fprintf('The matrix A is: \n')
    disp(A)
    fprintf('The relation W^-1*x is: \n')
    disp(y)
    fprintf('The coordinate vector z is: \n')
    disp(z)
    fprintf('The coordinate vector of Lx is: \n')
    disp(Lx)
    

    Quarry:

    • First, we have defined the given matrix W.
    • Then define the matrix x.
    • Calculate coordinate vector of Lx.

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    Chapter 4 Solutions

    Linear Algebra with Applications (9th Edition) (Featured Titles for Linear Algebra (Introductory))

    Ch. 4.1 - Determine whether the following are linear...Ch. 4.1 - Use mathematical induction to prove that if L is a...Ch. 4.1 - Let {v1,...,vn} be a basis for a vector space V,...Ch. 4.1 - Let L be a linear operator on 1 and let a=L(1) ....Ch. 4.1 - Let L be a linear operator on a vector space V....Ch. 4.1 - Let L1:UV and L2:VW be a linear transformations,...Ch. 4.1 - Determine the kernel and range of each of the...Ch. 4.1 - Let S be the subspace of 3 spanned by e1 and e2 ....Ch. 4.1 - Find the kernel and range of each of the following...Ch. 4.1 - Let L:VW be a linear transformation, and let T be...Ch. 4.1 - A linear transformation L:VW is said to be...Ch. 4.1 - A linear transformation L:VW is said to be map V...Ch. 4.1 - Which of the operators defined in Exercise 17 are...Ch. 4.1 - Let A be a 22 matrix, and let LA be the linear...Ch. 4.1 - Let D be the differentiation operator on P3 , and...Ch. 4.2 - Refer to Exercise 1 of Section 4.1. For each...Ch. 4.2 - For each of the following linear transformations L...Ch. 4.2 - For each of the following linear operators L on 3...Ch. 4.2 - Let L be the linear operators on 3 defined by...Ch. 4.2 - Find the standard matrix representation for each...Ch. 4.2 - Let b1=[110],b2=[101],b3=[011] and let L be the...Ch. 4.2 - Let y1=[111],y2=[110],y3=[100] and let I be the...Ch. 4.2 - Let y1,y2, and y3 be defined as in Exercise 7, and...Ch. 4.2 - Let R=[001100110011111] The column vectors of R...Ch. 4.2 - For each of the following linear operators on 2 ,...Ch. 4.2 - Determine the matrix representation of each of the...Ch. 4.2 - Let Y, P, and R be the yaw, pitch, and roll...Ch. 4.2 - Let L be the linear transformatino mapping P2 into...Ch. 4.2 - The linear transformation L defined by...Ch. 4.2 - Let S be the subspace of C[a,b] spanned by ex,xex...Ch. 4.2 - Let L be the linear operator on n . Suppose that...Ch. 4.2 - Let L be a linear operator on a vector space V....Ch. 4.2 - Let E=u1,u2,u3 and F=b1,b2 , where...Ch. 4.2 - Suppose that L1:VW and L2:WZ are linear...Ch. 4.2 - Let V and W be vector spaces with ordered bases E...Ch. 4.3 - For each of the following linear operators L on 2...Ch. 4.3 - Let u1,u2 and v1,v2 be ordered bases for 2 , where...Ch. 4.3 - Let L be the linear transformation on 3 defined by...Ch. 4.3 - Let L be the linear operator mapping 3 into 3...Ch. 4.3 - Let L be the operator on P3 defined by...Ch. 4.3 - Let V be the subspace of C[a,b] spanned by 1,ex,ex...Ch. 4.3 - Prove that if A is similar to B and B is similar...Ch. 4.3 - Suppose that A=SS1 , where is a diagonal matrix...Ch. 4.3 - Suppose that A=ST , where S is nonsingular. Let...Ch. 4.3 - Let A and B be nn matrices. Show that is A is...Ch. 4.3 - Show that if A and B are similar matrices, then...Ch. 4.3 - Let A and B t similar matrices. Show that (a) AT...Ch. 4.3 - Show that if A is similar to B and A is...Ch. 4.3 - Let A and B be similar matrices and let be any...Ch. 4.3 - The trace of an nn matrix A, denoted tr(A) , is...Ch. 4 - Use MATLAB to generate a matrix W and a vector x...Ch. 4 - Set A=triu(ones(5))*tril(ones(5)) . If L denotes...Ch. 4 - Prob. 3ECh. 4 - For each statement that follows, answer true if...Ch. 4 - Prob. 2CTACh. 4 - Prob. 3CTACh. 4 - For each statement that follows, answer true if...Ch. 4 - Prob. 5CTACh. 4 - Prob. 6CTACh. 4 - Prob. 7CTACh. 4 - Prob. 8CTACh. 4 - Prob. 9CTACh. 4 - Prob. 10CTACh. 4 - Determine whether the following are linear...Ch. 4 - Prob. 2CTBCh. 4 - Prob. 3CTBCh. 4 - Prob. 4CTBCh. 4 - Prob. 5CTBCh. 4 - Prob. 6CTBCh. 4 - Let L be the translation operator on 2 defined by...Ch. 4 - Let u1=[ 3 1 ],u2=[ 5 2 ] and let L be the linear...Ch. 4 - Let and and let L be the linear operator onwhose...Ch. 4 - Prob. 10CTB
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