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==Lecture Notes==
Fix a linear transformation T:V->W

'''Definition:'''

N(T)= ker T = {v ∈ V: Tv=O} ⊂ V
"null space" "kernal"

R(T)= img T = {Tv: v ∈ V} ⊂ W
"range" "image"

'''Proposition/Definition'''

1. N(T) is a subspace of V nullity(T)= dim N(T)
2. R(T) is a subspace of W rank (T) = dim R(T)

'''Example 1'''

T= 0 of linear transformation Tv=0

ker T = N(T)= V nullity(T) = dim V

img T = R(T)={0} rank (T)= dim{0}=0

'''Example 2'''

V=W; T=I Tv=V

ker T = N(T)= {0} nullity(T) = 0

img T = R(T)= V rank (T)= dim V

'''Example 3'''

V=Pn('''R''')= W; T=d/dx T(x^3)=3(x^2)

ker T = N(T)= {c(x^0): c∈'''R'''} nullity(T) = 1

img T = R(T)= Pn-1('''R''') rank (T) = n

sum=n+1=dim V

'''Theorem: Dimension Theorem/Rank-Nullity Theorem'''

Given T:V->W, (V is finite dimensional)

dim V = rank(T) + nullity (T)


'''Corollary of Theorem'''

If dim V = dim W then TFAE (the following are equivalent)

1. T is 1-1

2. T is onto

3. rank (T) = dimV (maximal)

4. T is invertible


T is 1-1 <=> nullity (T) = 0 as n+r = dim V

<=> rank(T) = dim V

<=> T is onto

1<=> 3



invertible => 1-1 and onto

1-1 => onto => invertible

onto => 1-1 => invertible



== Lecture notes scanned by [[User:KJMorenz|KJMorenz]] ==
== Lecture notes scanned by [[User:KJMorenz|KJMorenz]] ==
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Image:12-240-Oct30.jpg|Oct 30 Page 1
Image:12-240-Oct30.jpg|Oct 30 Page 1
Image:12-240-Oct30-2.jpg|Oct 30 Page 2
Image:12-240-Oct30-2.jpg|Oct 30 Page 2
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== Lecture notes uploaded by [[User:Grace.zhu|gracez]] ==
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Image:12-240-O30.jpg|Page 1
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Latest revision as of 14:22, 8 November 2012

Lecture Notes

Fix a linear transformation T:V->W

Definition:

N(T)= ker T = {v ∈ V: Tv=O} ⊂ V "null space" "kernal"

R(T)= img T = {Tv: v ∈ V} ⊂ W "range" "image"

Proposition/Definition

1. N(T) is a subspace of V nullity(T)= dim N(T) 2. R(T) is a subspace of W rank (T) = dim R(T)

Example 1

T= 0 of linear transformation Tv=0

ker T = N(T)= V nullity(T) = dim V

img T = R(T)={0} rank (T)= dim{0}=0

Example 2

V=W; T=I Tv=V

ker T = N(T)= {0} nullity(T) = 0

img T = R(T)= V rank (T)= dim V

Example 3

V=Pn(R)= W; T=d/dx T(x^3)=3(x^2)

ker T = N(T)= {c(x^0): c∈R} nullity(T) = 1

img T = R(T)= Pn-1(R) rank (T) = n

sum=n+1=dim V

Theorem: Dimension Theorem/Rank-Nullity Theorem

Given T:V->W, (V is finite dimensional)

dim V = rank(T) + nullity (T)


Corollary of Theorem

If dim V = dim W then TFAE (the following are equivalent)

1. T is 1-1

2. T is onto

3. rank (T) = dimV (maximal)

4. T is invertible


T is 1-1 <=> nullity (T) = 0 as n+r = dim V

<=> rank(T) = dim V

<=> T is onto

1<=> 3


invertible => 1-1 and onto

1-1 => onto => invertible

onto => 1-1 => invertible


Lecture notes scanned by KJMorenz

Lecture notes uploaded by gracez