12-240/Classnotes for Thursday October 18: Difference between revisions

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===Linear transformation===
== Theorems ==
1. If G generates, |G| <math>\ge \!\,</math> n and G contains a basis, |G|=n then G is a basis


'''Definition:'''
2. If L is linearly independent, |L| <math>\le \!\,</math> n and L can be extended to be a basis. |L|=n => L is a basis.


A function L: V-> W is called a linear transformation if it preserve following structures:
3.W <math>\subset \!\,</math> V a subspace then W is finite dimensioned and dim W <math>\le \!\,</math> dim V


If dim W = dim V, then V = W
1) L(x + y)= L(x) + L(y)
If dim W < dim V, then any basis of W can be extended to be a basis of V


2) L(cx)= c.L(x)
Proof of W is finite dimensioned:


3) L(0 of V) = 0 of W
Let L be a linearly independent subset of W which is of maximal size.


Fact about '''N'''
'''Proposition:'''
: Every subset A of '''N''', which is:


1) property 2 => property 3
1. Non empty


2. Bounded : <math>\exist \!\,</math> N <math>\in \!\,</math> '''N''', <math>\forall \!\,</math> a <math>\in \!\,</math> A, a <math>\le \!\,</math> N
2) L: V -> W is a linear transformation iff <math>\forall\,\!</math> c <math>\in\,\!</math> F, <math>\forall\,\!</math> x, y <math>\in\,\!</math> V: L(cx + y)= cL(x) + L(y)


'''Proof:'''
has a maximal element: an element m <math>\in \!\,</math> A, <math>\forall\!\,</math> a <math>\in \!\,</math> A, a <math>\le \!\,</math> m ( m + 1 <math>\notin \!\,</math> A )


1) take c= 0 in F and x=0 in V. Then L(cx)=cL(x) -> L(0 of F * 0 of V)=(0 of F)*L(0 of V)=0 of W
== class note ==


2)(=>)Assume L is linear transformation


L(cx + y)= L(cx) + L(y)= c*L(x) + L(y)
<gallery>
Image:12-240-Oct-15-Page-1.jpg |page1
Image:12-240-Oct-15-Page-2.jpg |page2
Image:12-240-Oct-15-Page-3.jpg |page3
</gallery>


(<=) 1. Follows from L(c*x+y) = c*L(x)+L(y) by taking c=1

2. Follows by taking y=0

'''Examples'''

1. L: '''R'''^2 -> '''R'''^2 by

2. P,Q: P(F)


== lecture note on oct 18, uploaded by [[User:starash|starash]]==
== lecture note on oct 18, uploaded by [[User:starash|starash]]==
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</gallery>
</gallery>


== HW5 link dead from this page, by [[User:Failure|Failure]]==
== Lecture notes uploaded by [[User:Grace.zhu|gracez]] ==
<gallery>
Image:12-240-O18-1.jpg|Page 1
Image:12-240-O18-2.jpg|Page 2
</gallery>

Latest revision as of 20:40, 12 December 2012

Riddle Along

The game of 15 is played as follows. Two players alternate choosing cards numbered between 1 and 9, with repetitions forbidden, so that the game ends at most after 9 moves (or four and a half rounds). The first player to have within her/his cards a set of precisely 3 cards that add up to 15 wins.

Does this game have a winning strategy? What is it? Who wins, the first to move or the second? Why am I asking this question at this particular time?

12-240-DeckOfCards.png

See also a video and the transcript of that video.

Dror's notes above / Students' notes below

Linear transformation

Definition:

A function L: V-> W is called a linear transformation if it preserve following structures:

1) L(x + y)= L(x) + L(y)

2) L(cx)= c.L(x)

3) L(0 of V) = 0 of W

Proposition:

1) property 2 => property 3

2) L: V -> W is a linear transformation iff c F, x, y V: L(cx + y)= cL(x) + L(y)

Proof:

1) take c= 0 in F and x=0 in V. Then L(cx)=cL(x) -> L(0 of F * 0 of V)=(0 of F)*L(0 of V)=0 of W

2)(=>)Assume L is linear transformation

L(cx + y)= L(cx) + L(y)= c*L(x) + L(y)

(<=) 1. Follows from L(c*x+y) = c*L(x)+L(y) by taking c=1

2. Follows by taking y=0

Examples

1. L: R^2 -> R^2 by


2. P,Q: P(F)

lecture note on oct 18, uploaded by starash

Lecture notes uploaded by gracez