Answer to Question #235886 in Discrete Mathematics for lavanya

Question #235886

Determine all eigenvalues and the corresponding eigenspaces for the matrix 𝐴 = [ −9 4 4 −8 3 4 −16 8 7 ]


1
Expert's answer
2021-09-12T23:52:10-0400
"A-\\lambda I=\\begin{pmatrix}\n -9-\\lambda & 4 & 4 \\\\\n -8& 3-\\lambda & 4 \\\\\n -16 & 8 & 7-\\lambda \\\\\n\\end{pmatrix}"

"\\det(A-\\lambda I)=\\begin{vmatrix}\n -9-\\lambda & 4 & 4 \\\\\n -8& 3-\\lambda & 4 \\\\\n -16 & 8 & 7-\\lambda \\\\\n\\end{vmatrix}"


"=(-9-\\lambda)\\begin{vmatrix}\n 3-\\lambda & 4 \\\\\n 8 & 7-\\lambda\n\\end{vmatrix}-4\\begin{vmatrix}\n -8 & 4 \\\\\n -16 & 7-\\lambda\n\\end{vmatrix}"

"+4\\begin{vmatrix}\n -8 & 3-\\lambda \\\\\n -16 & 8\n\\end{vmatrix}=(-9-\\lambda)(21-10\\lambda+\\lambda^2-32)"

"-4(-56+8\\lambda+64)+4(-64+48-16\\lambda)"

"=99+11\\lambda+90\\lambda+10\\lambda^2-9\\lambda^2-\\lambda^3"

"-32-32\\lambda-64-64\\lambda"

"=-\\lambda^3+\\lambda^2+5\\lambda+3=0"

"-\\lambda^2(\\lambda+1)+2\\lambda(\\lambda+1)+3(\\lambda+1)=0"

"-(\\lambda+1)(\\lambda^2-2\\lambda-3)=0"

"-(\\lambda+1)^2(\\lambda-3)=0"



"\\lambda_1=-1, \\lambda_2=-1, \\lambda_3=3"


These are the eigenvalues: "-1, -1, 3."


"\\lambda=-1"


"A-\\lambda I=\\begin{pmatrix}\n -9+1 & 4 & 4 \\\\\n -8& 3+1 & 4 \\\\\n -16 & 8 & 7+1 \\\\\n\\end{pmatrix}"

"=\\begin{pmatrix}\n -8 & 4 & 4 \\\\\n -8 & 4 & 4 \\\\\n -16 & 8 & 8 \\\\\n\\end{pmatrix}"

"R_2=R_2-R_1"


"\\begin{pmatrix}\n -8 & 4 & 4 \\\\\n 0 & 0 & 0 \\\\\n -16 & 8 & 8 \\\\\n\\end{pmatrix}"

"R_3=R_3-2R_1"


"\\begin{pmatrix}\n -8 & 4 & 4 \\\\\n 0 & 0 & 0 \\\\\n 0 & 0 &0 \\\\\n\\end{pmatrix}"

"R_1=R_1\/(-8)"


"\\begin{pmatrix}\n 1 & -1\/2 & -1\/2 \\\\\n 0 & 0 & 0 \\\\\n 0 & 0 &0 \\\\\n\\end{pmatrix}"

"\\begin{pmatrix}\n 1 & -1\/2 & -1\/2 \\\\\n 0 & 0 & 0 \\\\\n 0 & 0 &0 \\\\\n\\end{pmatrix}\\begin{pmatrix}\n x_1 \\\\\nx_2 \\\\\nx_3 \\\\\n\\end{pmatrix}=\\begin{pmatrix}\n0 \\\\\n0 \\\\\n0 \\\\\n\\end{pmatrix}"

If we take "x_2=t, x_3=s," then "x_1=\\dfrac{1}{2}t+\\dfrac{1}{2}s"

Thus


"\\vec x=\\begin{pmatrix}\ns\/2+t\/2 \\\\\n1 \\\\\n1 \\\\\n\\end{pmatrix}s=\\begin{pmatrix}\n1\/2 \\\\\n1 \\\\\n0 \\\\\n\\end{pmatrix}t+\\begin{pmatrix}\n1\/2 \\\\\n0 \\\\\n1 \\\\\n\\end{pmatrix}s"

The eigenvectors are


"\\begin{pmatrix}\n1\/2 \\\\\n1 \\\\\n0 \\\\\n\\end{pmatrix},\\begin{pmatrix}\n1\/2 \\\\\n0 \\\\\n1 \\\\\n\\end{pmatrix}"

"\\lambda=3"

"A-\\lambda I=\\begin{pmatrix}\n -9-3 & 4 & 4 \\\\\n -8& 3-3 & 4 \\\\\n -16 & 8 & 7-3 \\\\\n\\end{pmatrix}"

"=\\begin{pmatrix}\n -12 & 4 & 4 \\\\\n -8 & 0 & 4 \\\\\n -16 & 8 & 4 \\\\\n\\end{pmatrix}"

"R_2=R_2-2R_1\/3"

"\\begin{pmatrix}\n -12 & 4 & 4 \\\\\n 0 & -8\/3 & 4\/3 \\\\\n -16 & 8 & 4 \\\\\n\\end{pmatrix}"

"R_3=R_3-4R_1\/3"

"\\begin{pmatrix}\n -12 & 4 & 4 \\\\\n 0 & -8\/3 & 4\/3 \\\\\n 0 & 8\/3 & -4\/3 \\\\\n\\end{pmatrix}"

"R_3=R_3+R_2"

"\\begin{pmatrix}\n -12 & 4 & 4 \\\\\n 0 & -8\/3 & 4\/3 \\\\\n 0 & 0 & 0 \\\\\n\\end{pmatrix}"

"R_2=-3R_2\/8"


"\\begin{pmatrix}\n -12 & 4 & 4 \\\\\n 0 & 1 & -1\/2 \\\\\n 0 & 0 & 0 \\\\\n\\end{pmatrix}"

"R_1=-R_1\/12"


"\\begin{pmatrix}\n 1 &-1\/3 & -1\/3 \\\\\n 0 & 1 & -1\/2 \\\\\n 0 & 0 & 0 \\\\\n\\end{pmatrix}"

"R_1=R_1+R_2\/3"


"\\begin{pmatrix}\n 1 &0 & -1\/2 \\\\\n 0 & 1 & -1\/2 \\\\\n 0 & 0 & 0 \\\\\n\\end{pmatrix}"


"\\begin{pmatrix}\n 1 &0 & -1\/2 \\\\\n 0 & 1 & -1\/2 \\\\\n 0 & 0 & 0 \\\\\n\\end{pmatrix}\\begin{pmatrix}\n x_1 \\\\\nx_2 \\\\\nx_3 \\\\\n\\end{pmatrix}=\\begin{pmatrix}\n0 \\\\\n0 \\\\\n0 \\\\\n\\end{pmatrix}"

If we take "x_3=t," then "x_1=\\dfrac{1}{2}t, x_2=\\dfrac{1}{2}t"

Thus


"\\vec x=\\begin{pmatrix}\nt\/2 \\\\\nt\/2 \\\\\nt \\\\\n\\end{pmatrix}=\\begin{pmatrix}\n1\/2 \\\\\n1\/2 \\\\\n1 \\\\\n\\end{pmatrix}t"


The eigenvector is


"\\begin{pmatrix}\n1\/2 \\\\\n1\/2 \\\\\n1 \\\\\n\\end{pmatrix}"



Eigenvalue: −1, multiplicity: 2, eigenvectors: "\\begin{pmatrix}\n1\/2 \\\\\n1 \\\\\n0 \\\\\n\\end{pmatrix},\\begin{pmatrix}\n1\/2 \\\\\n0 \\\\\n1 \\\\\n\\end{pmatrix}"


Eigenvalue: 3, multiplicity: 1, eigenvector: "\\begin{pmatrix}\n1\/2 \\\\\n1\/2 \\\\\n1 \\\\\n\\end{pmatrix}"



Need a fast expert's response?

Submit order

and get a quick answer at the best price

for any assignment or question with DETAILED EXPLANATIONS!

Comments

No comments. Be the first!

Leave a comment

LATEST TUTORIALS
APPROVED BY CLIENTS