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| − | Question from James Down Under ([[User:Jayling|Jayling]]): | + | Question from James Down Under ([[User:Jayling|Jayling]]): |
| − | For Page 329 Question 11. | + | For Page 329 Question 11. Am I meant to calculate all eigenvalues and eigenvectors or just calculate the eigenvector corresponding to the given eigenvalue of 3? |
| − | Answer from [[User:Bell|Steve Bell]] : | + | Answer from [[User:Bell|Steve Bell]] : |
| − | Yes, you are only supposed to find the eigenvector for lambda=3. | + | Yes, you are only supposed to find the eigenvector for lambda=3. (The idea here is to spare you from finding the roots of a rather nasty 3rd degree polynomial.) |
| − | (The idea here is to spare you from finding the roots of a rather | + | |
| − | nasty 3rd degree polynomial.) | + | |
| − | [[User:Jayling|Jayling]]: | + | [[User:Jayling|Jayling]]: thanks Steve, I did try the hard way first but then started to drown in the algebra. |
| − | Question from a student: | + | Question from a student: |
| − | Let 3x+4y+2z = 0; 2x+5z= 0 be the system for which I have to find the basis. | + | Let 3x+4y+2z = 0; 2x+5z= 0 be the system for which I have to find the basis. |
| − | When Row Reduced the above system gives [ 1 0 2.5 0 ; 0 1 -1.375 0]. | + | When Row Reduced the above system gives [ 1 0 2.5 0 ; 0 1 -1.375 0]. |
| − | Rank = no of non zero rows = 2 = | + | Rank = no of non zero rows = 2 => Dim(rowspace) = 2 ; Nullity = # free variables = 1 |
| − | Q1: Aren't [ 1 0 2.5] and [0 1 -1.375] called the basis of the system? | + | Q1: Aren't [ 1 0 2.5] and [0 1 -1.375] called the basis of the system? |
| − | A1 from [[User:Bell|Steve Bell]]: | + | A1 from [[User:Bell|Steve Bell]]: |
| − | Those two vectors form a basis for the ROW SPACE. | + | Those two vectors form a basis for the ROW SPACE. |
| − | The solution space is only 1 dimensional (since the | + | The solution space is only 1 dimensional (since the number of free variables is only 1). |
| − | number of free variables is only 1). | + | |
| − | Q2: Why is that we get a basis by considering the free variable as some "parameter" and reducing further(and get 1 vector in this case). Isn't | + | Q2: Why is that we get a basis by considering the free variable as some "parameter" and reducing further(and get 1 vector in this case). Isn't that the solution of the system? |
| − | that the solution of the system? | + | |
| − | A2 from [[User:Bell|Steve Bell]] : | + | A2 from [[User:Bell|Steve Bell]] : |
| − | If the system row reduces to | + | If the system row reduces to |
| − | + | <pre>[ 1 0 2.5 0 ] | |
| − | < | + | |
| − | [ 1 0 2.5 0 ] | + | |
[ 0 1 -1.375 0 ] | [ 0 1 -1.375 0 ] | ||
| − | </ | + | </pre> |
| + | then z is the free variable. Let it be t. The top equation gives | ||
| − | + | x = -2.5 t | |
| − | + | ||
| − | + | and the second equation gives | |
| − | + | y = 1.375 t | |
| − | + | and of course, | |
| − | + | z = t. | |
| − | + | So the general solution is | |
| − | + | <pre>[ x ] [ -2.5 ] | |
| − | So the general solution is | + | |
| − | + | ||
| − | < | + | |
| − | [ x ] [ -2.5 ] | + | |
[ y ] = [ 1.375 ] t | [ y ] = [ 1.375 ] t | ||
[ z ] [ 1 ] | [ z ] [ 1 ] | ||
| − | </ | + | </pre> |
| + | Thus, you can find the solution from the row echelon matrix, but I wouldn't say that you can read it off from there -- not without practice, at least. | ||
| − | + | Question from the Linear Algebra Noobee ([[User:Jayling|Jayling]]) regarding the Lesson 7 material | |
| − | + | An observation from me with eigenvalues and eigenvectors on the 2x2 matrices examples that you presented is that the column space of A-λI when you solve for the first eigenvalue corresponds to the column vector of the second eigenvalue? For the example on page 2 when you REF the A-λI the pivot yields the column space vector in the original matrix of [-2 1]T which exactly matches the eigenvector for when λ=-4, and similarly vice versa when λ=-1 and you REF the A-λI matrix it yields a column space vector of [1 1] T. Is this true for all matrix eigenvalue problems in general, I noticed that it is also true for the complex example that follows? Is this an obvious fact or just a coincidence? Your insight on this would be appreciated. | |
| − | + | ||
| − | An observation from me with eigenvalues and eigenvectors on the 2x2 matrices examples that you presented is that the column space of A-λI when you solve for the first eigenvalue corresponds to the column vector of the second eigenvalue? | + | |
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| + | On problem 11, I swapped rows 1 and 2 during row reduction and my final solution has x1 and x2 swapped. Do I need to swap back any row swaps or did I make a mistake along the way? [[User:Tlouvar|Tlouvar]] | ||
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| + | [[2013 Fall MA 527 Bell|Back to MA527, Fall 2013]] | ||
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[[2013 Fall MA 527 Bell|Back to MA527, Fall 2013]] | [[2013 Fall MA 527 Bell|Back to MA527, Fall 2013]] | ||
Revision as of 17:18, 5 September 2013
Homework 3 collaboration area
Question from James Down Under (Jayling):
For Page 329 Question 11. Am I meant to calculate all eigenvalues and eigenvectors or just calculate the eigenvector corresponding to the given eigenvalue of 3?
Answer from Steve Bell :
Yes, you are only supposed to find the eigenvector for lambda=3. (The idea here is to spare you from finding the roots of a rather nasty 3rd degree polynomial.)
Jayling: thanks Steve, I did try the hard way first but then started to drown in the algebra.
Question from a student:
Let 3x+4y+2z = 0; 2x+5z= 0 be the system for which I have to find the basis.
When Row Reduced the above system gives [ 1 0 2.5 0 ; 0 1 -1.375 0].
Rank = no of non zero rows = 2 => Dim(rowspace) = 2 ; Nullity = # free variables = 1
Q1: Aren't [ 1 0 2.5] and [0 1 -1.375] called the basis of the system?
A1 from Steve Bell:
Those two vectors form a basis for the ROW SPACE.
The solution space is only 1 dimensional (since the number of free variables is only 1).
Q2: Why is that we get a basis by considering the free variable as some "parameter" and reducing further(and get 1 vector in this case). Isn't that the solution of the system?
A2 from Steve Bell :
If the system row reduces to
[ 1 0 2.5 0 ] [ 0 1 -1.375 0 ]
then z is the free variable. Let it be t. The top equation gives
x = -2.5 t
and the second equation gives
y = 1.375 t
and of course,
z = t.
So the general solution is
[ x ] [ -2.5 ] [ y ] = [ 1.375 ] t [ z ] [ 1 ]
Thus, you can find the solution from the row echelon matrix, but I wouldn't say that you can read it off from there -- not without practice, at least.
Question from the Linear Algebra Noobee (Jayling) regarding the Lesson 7 material
An observation from me with eigenvalues and eigenvectors on the 2x2 matrices examples that you presented is that the column space of A-λI when you solve for the first eigenvalue corresponds to the column vector of the second eigenvalue? For the example on page 2 when you REF the A-λI the pivot yields the column space vector in the original matrix of [-2 1]T which exactly matches the eigenvector for when λ=-4, and similarly vice versa when λ=-1 and you REF the A-λI matrix it yields a column space vector of [1 1] T. Is this true for all matrix eigenvalue problems in general, I noticed that it is also true for the complex example that follows? Is this an obvious fact or just a coincidence? Your insight on this would be appreciated.
On problem 11, I swapped rows 1 and 2 during row reduction and my final solution has x1 and x2 swapped. Do I need to swap back any row swaps or did I make a mistake along the way? Tlouvar
