(2 intermediate revisions by the same user not shown)
Line 1: Line 1:
== Lecture 4 (01/21/10) ==
+
== Lecture 4 (01/21/10) ==
  
== Row Echelon Form (ref) ==
+
== Row Echelon Form (ref) ==
[[Definition:]]Let A be a matrix, A will be a row echelon form(ref) if:
+
  
1. If any, a row full of zeros has to be at the bottom.
+
[[Definition:]]Let A be a matrix, A will be a row echelon form(ref) if:
  
2. The leftmost nonzero in any row is "1", also known as 'leading 1's'
+
1. If any, a row full of zeros has to be at the bottom.
  
3. If row i and j are nonzero and i<j, the the 'leading 1' in row i is to the left of'leading 1'in row j
+
2. The leftmost nonzero in any row is "1", also known as 'leading 1's'
  
[[Note:]]Numbers following the 'leading 1's' can be any numbers
+
3. If row i and j are nonzero and i&lt;j, the the 'leading 1' in row i is to the left of'leading 1'in row j
  
== Reduced Row Echelon Form (rref) ==
+
[[Note:]]Numbers following the 'leading 1's' can be any numbers
[[Definition:]]Matrix A is in reduced row echelon form(rref) if:
+
  
1. A is in row echelon form(ref)
+
== Reduced Row Echelon Form (rref) ==
  
2. Any number above 'leading's 1' can only be zeros
+
[[Definition:]]Matrix A is in reduced row echelon form(rref) if:
 +
 
 +
1. A is in row echelon form(ref)
 +
 
 +
2. Any number above 'leading's 1' can only be zeros  
  
 
[[Note:]]Every number in the column above the 'leading 1' need to be zeros  
 
[[Note:]]Every number in the column above the 'leading 1' need to be zeros  
  
== Elementary Transformation Steps for rref Conversion ==
+
== Elementary Transformation Steps for rref Conversion ==
 +
 
 +
1. Switching rows
 +
 
 +
2. Scale rows with any number
 +
 
 +
3.Take any row and add a scale version of any other row to it.
 +
 
 +
[[Note:]]It is always a good idea to try to rearrange rows to make the matrix easier to convert first and tries to avoid creating any fractions, especially in the early stages.
 +
 
 +
<br>
 +
 
 +
<br> Properties of a Determinant
 +
 
 +
1. det(A) = det(transpose of A)
 +
 
 +
2. det(A with rows i and j interchanged) = -det(A)
 +
 
 +
3. det(A with row j replaced by row j +c*rowi) = det(A)
 +
 
 +
4. det(matrix with a row of zeros) = 0
 +
 
 +
5. det(matrix with 2 equal rows) = 0
 +
 
 +
- All of these properties stay true if you replace row with column
 +
 
 +
6. det(AB) = det(A)*det(B)
  
1. Switching rows
+
7. if det(A) = 0 then it has no inverse
  
2. Scale rows with any number
+
8. det(BA(inverseB)) = det(A)
  
3.Take any row and add a scale version of any other row to it.
+
<br>
  
[[Note:]]It is always a good idea to try to rearrange rows to make the matrix easier to convert first and tries to avoid creating any fractions, especially in the early stages.
+
<br>
  
Category:MA265Spring2010Walther
+
<br> Category:MA265Spring2010Walther

Latest revision as of 15:14, 18 February 2010

Lecture 4 (01/21/10)

Row Echelon Form (ref)

Definition:Let A be a matrix, A will be a row echelon form(ref) if:

1. If any, a row full of zeros has to be at the bottom.

2. The leftmost nonzero in any row is "1", also known as 'leading 1's'

3. If row i and j are nonzero and i<j, the the 'leading 1' in row i is to the left of'leading 1'in row j

Note:Numbers following the 'leading 1's' can be any numbers

Reduced Row Echelon Form (rref)

Definition:Matrix A is in reduced row echelon form(rref) if:

1. A is in row echelon form(ref)

2. Any number above 'leading's 1' can only be zeros

Note:Every number in the column above the 'leading 1' need to be zeros

Elementary Transformation Steps for rref Conversion

1. Switching rows

2. Scale rows with any number

3.Take any row and add a scale version of any other row to it.

Note:It is always a good idea to try to rearrange rows to make the matrix easier to convert first and tries to avoid creating any fractions, especially in the early stages.



Properties of a Determinant

1. det(A) = det(transpose of A)

2. det(A with rows i and j interchanged) = -det(A)

3. det(A with row j replaced by row j +c*rowi) = det(A)

4. det(matrix with a row of zeros) = 0

5. det(matrix with 2 equal rows) = 0

- All of these properties stay true if you replace row with column

6. det(AB) = det(A)*det(B)

7. if det(A) = 0 then it has no inverse

8. det(BA(inverseB)) = det(A)




Category:MA265Spring2010Walther

Alumni Liaison

Questions/answers with a recent ECE grad

Ryne Rayburn