09-240/Classnotes for Tuesday October 13: Difference between revisions

09-240/Navigation Panel   Additions to the MAT 240 web site no longer count towards good deed points # Week of... Notes and Links 1 Sep 7 Tue, About, Thu 2 Sep 14 Tue, HW1, HW1 Solution, Thu 3 Sep 21 Tue, HW2, HW2 Solution, Thu, Photo 4 Sep 28 Tue, HW3, HW3 Solution, Thu 5 Oct 5 Tue, HW4, HW4 Solution, Thu, 6 Oct 12 Tue, Thu 7 Oct 19 Tue, HW5, HW5 Solution, Term Test on Thu 8 Oct 26 Tue, Why LinAlg?, HW6, HW6 Solution, Thu 9 Nov 2 Tue, MIT LinAlg, Thu 10 Nov 9 Tue, HW7, HW7 Solution Thu 11 Nov 16 Tue, HW8, HW8 Solution, Thu 12 Nov 23 Tue, HW9, HW9 Solution, Thu 13 Nov 30 Tue, On the final, Thu S Dec 7 Office Hours F Dec 14 Final on Dec 16 To Do List The Algebra Song! Register of Good Deeds Misplaced Material Add your name / see who's in!

• 

  Bright - 1

• 

  2

• 

  3

• 

  4

Replacement Theorem

...

3. dim(V) = n
   1. If G generates V then ${\displaystyle |G|\geq n}$. If also ${\displaystyle \,\!|G|=n}$ then G is a basis.
   2. If L is linearly dependent then ${\displaystyle |L|\leq n}$. If also ${\displaystyle \,\!|L|=n}$ then L is a basis. If also ${\displaystyle \,\!|L|<n}$ then L can be extended to a basis. Proofs a1. If G has a subset which is a basis then that subset has n elements, so ${\displaystyle |G|\geq n}$.
      a2. Let ${\displaystyle \beta }$ be a basis of V, then ${\displaystyle \,\!|B|=n}$. Now use replacement with G & L = ${\displaystyle \beta }$. Hence, ${\displaystyle |G|\geq |L|=|B|=n}$.
      a. From a1 and a2, we know ${\displaystyle |G|\geq n}$. If ${\displaystyle \,\!|G|=n}$ then G contains a basis ${\displaystyle \beta }$. But ${\displaystyle \,\!|B|=n}$, so ${\displaystyle \,\!|G|=\beta }$, and hence G is a basis.
      
      b. Use replacement with G' being some basis of V. |G| = n.
      
      If ${\displaystyle |L|=|G|}$ then ${\displaystyle |R|=n=|G|}$, so ${\displaystyle R=G}$, so ${\displaystyle (G\backslash R)\cup L}$ generates, so L generates, so L is a basis since it is linearly independent.
      
      We have that L is basis. If ${\displaystyle |L|<|G|}$ the nagain find ${\displaystyle R\subset G}$ such that ${\displaystyle |R|=|L|}$ and ${\displaystyle (G\backslash R)\cup L}$ generates.
      
      1. ${\displaystyle \beta }$ generates V.
      2. ${\displaystyle |B|\leq |G|-|R|+|L|=n}$. So by part a, ${\displaystyle \beta }$ is a basis.
      3.
4. If V is finite-dimensional (f.d.) and ${\displaystyle \mathbf {W} \subset \mathbf {V} }$ is a subspace of V, then W is also finite, and ${\displaystyle \operatorname {dim} (\mathbf {W} )\leq \operatorname {dim} (\mathbf {V} )}$. If also dim(W) = dim(V) then W = V and if dim(W) < dim(V) then any basis of W can be extended to a basis of V.
   
   Proof: Assuming W is finite-dimensional, pick a basis ${\displaystyle \beta }$ of W; ${\displaystyle \beta }$ is linearly independent in V so by Corollary 3 of part b, ${\displaystyle |B|\leq \operatorname {dim} (\mathbf {V} )\Rightarrow \operatorname {dim} (\mathbf {W} )=|B|\leq \operatorname {dim} (\mathbf {V} )}$. So span(${\displaystyle \beta }$) = V = W so V = W. ...
   
   Assume W is not finite-dimensional. ${\displaystyle \mathbf {W} \neq \{0\}}$ so pick a ${\displaystyle x_{1}\in W}$ such that ${\displaystyle x_{1}\neq 0}$. So ${\displaystyle \{x_{1}\}}$ is linearly independent in W, and ${\displaystyle \operatorname {span} (\{x_{1}\})\subsetneq \mathbf {W} }$. Pick ${\displaystyle x_{2}\in W\backslash \operatorname {span} (\{x_{1}\})}$. So ${\displaystyle \{x_{1},x_{2}\}}$ is linearly dependent and ${\displaystyle \operatorname {span} (\{x_{1},x_{2}\})\subsetneq \mathbf {W} }$. Pick ${\displaystyle x_{3}\in W\backslash \operatorname {span} (\{x_{1},x_{2}\})}$ ... continue in this way to get a sequence ${\displaystyle x_{1},x_{2},\ldots ,x_{n+1}}$ where n = dim(V) and ${\displaystyle \{x_{1},\ldots ,x_{n+1}\}}$ is linearly independent. There is a contradiction by Corollary 3.b.

The Lagrange Interpolation Formula

[Aside: ${\displaystyle (a-x)(b-x)\ldots (z-x)=0}$ because ${\displaystyle x-x=0}$]

Where ${\displaystyle 1\leq i<n,}$

Let ${\displaystyle x_{i}}$ be distinct points in ${\displaystyle \Re }$.

Let ${\displaystyle y_{i}}$ be any points in ${\displaystyle \Re }$.

Can you find a polynomial ${\displaystyle P\in \mathbb {P} _{n}(\Re )}$ such that ${\displaystyle P(x_{i})=y_{i}}$? Is it unique?

Example:

${\displaystyle x_{i}=0,1,3}$

${\displaystyle y_{i}=5,2,2}$

Can we find a ${\displaystyle P\in \mathbb {P} _{2}}$ such that

${\displaystyle P(0)=5}$

${\displaystyle P(1)=2}$

${\displaystyle P(2)=2}$?

Solution: Let ${\displaystyle {\tilde {P}}_{i}(x)=\prod _{j=1,j\neq 1}^{n+1}(x-x_{j})\in \mathbb {P} _{n}(\Re )}$. (Remember capital pi notation.)

Then ${\displaystyle {\tilde {P}}_{i}(x_{k})={\begin{cases}0&i\neq k\\\prod _{i\neq j}(x_{i}-x_{j})&i=k\\\end{cases}}}$

${\displaystyle {\tilde {P}}_{1}=(x-x_{2})(x-x_{3})=(x-1)(x-3)=x^{2}-4x+3}$

${\displaystyle {\tilde {P}}_{2}=(x-0)(x-3)=x^{2}-3x}$

${\displaystyle {\tilde {P}}_{3}=(x-0)(x-1)=x^{2}-x}$

${\displaystyle {\begin{matrix}{\tilde {P}}_{1}(0)=3&{\tilde {P}}_{1}(1)=0&{\tilde {P}}_{1}(3)=0\\{\tilde {P}}_{2}(0)=0&{\tilde {P}}_{2}(1)=-2&{\tilde {P}}_{2}(3)=0\\{\tilde {P}}_{3}(0)=0&{\tilde {P}}_{3}(1)=0&{\tilde {P}}_{3}(3)=6\\\end{matrix}}}$

Set ${\displaystyle P_{i}(x)={\frac {1}{{\tilde {P}}_{i}(x)}}\cdot {\tilde {P}}_{i}=\prod _{j\neq i}{\frac {(x-x_{j})}{(x_{i}-x_{j})}}}$

Then ${\displaystyle P_{i}(x_{k})={\begin{cases}0&i\neq k\\1&i=k\\\end{cases}}}$

${\displaystyle P_{1}(x)={\frac {1}{3}}x^{2}-{\frac {4}{3}}x+1}$

${\displaystyle P_{2}(x)=-{\frac {1}{2}}x^{2}+{\frac {3}{2}}x}$

${\displaystyle P_{3}(x)={\frac {1}{6}}x^{2}-{\frac {1}{6}}x}$

Let ${\displaystyle P=\sum _{i=1}^{n+1}y_{i}P_{i}(x)\in \mathbb {P} _{n}(\Re )}$

${\displaystyle P=5\cdot \left({\frac {1}{3}}x^{2}-{\frac {4}{3}}x+1\right)+2\cdot \left(-{\frac {1}{2}}x^{2}+{\frac {3}{2}}x\right)+2\cdot \left({\frac {1}{6}}x^{2}-{\frac {1}{6}}x\right)}$

${\displaystyle \,\!=x^{2}-4x+5}$