|
|
| Line 14: |
Line 14: |
|
|
|
|
|
|
|
|
|
:::::::<math>det(A) + det(B) = det\begin{pmatrix}...\\A_i\\A_{i + 1}\\...\end{pmatrix} + det\begin{pmatrix}...\\A_{i + 1}\\A_i\\...\end{pmatrix} = </math> |
|
:::::::<math>det(A) + det(B) = det\begin{pmatrix}...\\A_i\\A_{i + 1}\\...\end{pmatrix} + det\begin{pmatrix}...\\A_{i + 1}\\A_i\\...\end{pmatrix} =</math> |
|
|
|
|
|
:::::::<math>det\begin{pmatrix}...\\A_i\\A_i\\...\end{pmatrix} + det\begin{pmatrix}...\\A_i\\A_{i + 1}\\...\end{pmatrix} + det\begin{pmatrix}...\\A_{i + 1}\\A_{i + 1}\\...\end{pmatrix} + det\begin{pmatrix}...\\A_{i + 1}\\A_i\\...\end{pmatrix}</math>. |
|
:::::::<math>det\begin{pmatrix}...\\A_i\\A_i\\...\end{pmatrix} + det\begin{pmatrix}...\\A_i\\A_{i + 1}\\...\end{pmatrix} + det\begin{pmatrix}...\\A_{i + 1}\\A_{i + 1}\\...\end{pmatrix} + det\begin{pmatrix}...\\A_{i + 1}\\A_i\\...\end{pmatrix}</math>. |
| Line 22: |
Line 22: |
|
|
|
|
|
|
|
|
|
<math>det(A) + det(B) = det\begin{pmatrix}...\\A_i\\A_i\\...\end{pmatrix} + det\begin{pmatrix}...\\A_i\\A_{i + 1}\\...\end{pmatrix} + det\begin{pmatrix}...\\A_{i + 1}\\A_{i + 1}\\...\end{pmatrix} + det\begin{pmatrix}...\\A_{i + 1}\\A_i\\...\end{pmatrix} = det\begin{pmatrix}...\\A_i\\A_i + A_{i + 1}\\...\end{pmatrix} + det\begin{pmatrix}...\\A_{i + 1}\\A_i + A_{i + 1}\\...\end{pmatrix} = det\begin{pmatrix}...\\A_i + A_{i + 1}\\A_i + A_{i + 1}\\...\end{pmatrix} = 0</math>. |
|
<math>det(A) + det(B) = det\begin{pmatrix}...\\A_i\\A_i\\...\end{pmatrix} + det\begin{pmatrix}...\\A_i\\A_{i + 1}\\...\end{pmatrix} + det\begin{pmatrix}...\\A_{i + 1}\\A_{i + 1}\\...\end{pmatrix} + det\begin{pmatrix}...\\A_{i + 1}\\A_i\\...\end{pmatrix} = </math> |
|
|
|
|
|
<math>det\begin{pmatrix}...\\A_i\\A_i + A_{i + 1}\\...\end{pmatrix} + det\begin{pmatrix}...\\A_{i + 1}\\A_i + A_{i + 1}\\...\end{pmatrix} = det\begin{pmatrix}...\\A_i + A_{i + 1}\\A_i + A_{i + 1}\\...\end{pmatrix} = 0</math>. |
|
|
|
|
|
==Nikita== |
|
==Nikita== |
Revision as of 16:11, 7 December 2014
Welcome to Math 240!
(additions to this web site no longer count towards good deed points)
|
| #
|
Week of...
|
Notes and Links
|
| 1
|
Sep 8
|
About This Class, What is this class about? (PDF, HTML), Monday, Wednesday
|
| 2
|
Sep 15
|
HW1, Monday, Wednesday, TheComplexField.pdf,HW1_solutions.pdf
|
| 3
|
Sep 22
|
HW2, Class Photo, Monday, Wednesday, HW2_solutions.pdf
|
| 4
|
Sep 29
|
HW3, Wednesday, Tutorial, HW3_solutions.pdf
|
| 5
|
Oct 6
|
HW4, Monday, Wednesday, Tutorial, HW4_solutions.pdf
|
| 6
|
Oct 13
|
No Monday class (Thanksgiving), Wednesday, Tutorial
|
| 7
|
Oct 20
|
HW5, Term Test at tutorials on Tuesday, Wednesday
|
| 8
|
Oct 27
|
HW6, Monday, Why LinAlg?, Wednesday, Tutorial
|
| 9
|
Nov 3
|
Monday is the last day to drop this class, HW7, Monday, Wednesday, Tutorial
|
| 10
|
Nov 10
|
HW8, Monday, Tutorial
|
| 11
|
Nov 17
|
Monday-Tuesday is UofT November break
|
| 12
|
Nov 24
|
HW9
|
| 13
|
Dec 1
|
Wednesday is a "makeup Monday"! End-of-Course Schedule, Tutorial
|
| F
|
Dec 8
|
The Final Exam
|
| Register of Good Deeds
|
Add your name / see who's in!
|
|
|
Boris
Theorem
Let 
be a 
matrix and 
be the matrix with two rows interchanged. Then 
. Boris decided to prove the following lemma first:
Lemma 1
Let be a matrix and be the matrix with two adjacent rows interchanged. Then .
All we need to show is that 
. Assume that is the matrix with row 
of interchanged with row 
of . Since the determinant of a matrix with two identical rows is 
, then:
.
Since the determinant is linear in each row, then:
.
Nikita
