06-240/Classnotes For Thursday, September 21: Difference between revisions

Revision as of 06:31, 27 September 2006

A force has a direction & a magnitude.

Force Vectors

${\mbox{There is a special force vector called 0.}}$
${\mbox{They can be added.}}$
${\mbox{They can be multiplied by any scalar.}}$

Properties

${\mbox{(convention: }}x,y,z{\mbox{ are vectors; }}a,b,c{\mbox{ are scalars)}}$

$x+y=y+x\$
$x+(y+z)=(x+y)+z\$
$x+0=x\$
$\forall x\;\exists \ y\ {\mbox{ s.t. }}x+y=0$
$1\cdot x=x\$
$a(bx)=(ab)x\$
$a(x+y)=ax+ay\$
$(a+b)x=ax+bx\$

Definition

Let F be a field "of scalars". A vector space over F is a set V, of "vectors", along with two operations

+:V\times V\to V

\cdot :F\times V\to V{\mbox{, so that:}}

$\forall x,y\in V\ x+y=y+x$
$\forall x,y\in V\ x+(y+z)=(x+y)+z$
$\exists \ 0\in Vs.t.\;\forall x\in V\ x+0=x$
$\forall x\in V\;\exists \ y\in V\ s.t.\ x+y=0$
$1\cdot x=x\$
$a(bx)=(ab)x\$
$a(x+y)=ax+ay\$
$\forall x\in V\ ,\forall a,b\in F\ (a+b)x=ax+bx$

9. $x\mapsto \vert x\vert \in \mathbb {R} \ \vert x+y\vert \leq \vert x\vert +\vert y\vert$

Examples

Ex.1. $F^{n}=\lbrace (a_{1},a_{2},a_{3},\ldots ,a_{n-1},a_{n}):\forall i\ a_{i}\in F\rbrace$
$n\in \mathbb {Z} \ ,n\geq 0$
$x=(a_{1},\ldots ,a_{2})\ y=(b_{1},\ldots ,b_{2})\$
$x+y:=(a_{1}+b_{1},a_{2}+b_{2},\ldots ,a_{n}+b_{n})\$
$0_{F^{n}}=(0,\ldots ,0)$
$a\in F\ ax=(aa_{1},aa_{2},\ldots ,aa_{n})$
${\mbox{In }}\mathbb {Q} ^{3}\ \left({\frac {3}{2}},-2,7\right)+\left({\frac {-3}{2}},{\frac {1}{3}},240\right)=\left(0,{\frac {-5}{3}},247\right)$
$7\left({\frac {1}{5}},{\frac {1}{7}},{\frac {1}{9}}\right)=\left({\frac {7}{5}},1,{\frac {7}{9}}\right)$
Ex.2. $V=M_{m\times n}(F)=\left\lbrace {\begin{pmatrix}a_{11}&\cdots &a_{1n}\\\vdots &&\vdots \\a_{m1}&\cdots &a_{mn}\end{pmatrix}}:a_{ij}\in F\right\rbrace$
$M_{3\times 2}(\mathbb {R} )\ni {\begin{pmatrix}7&-7\\\pi &{\mathit {e}}\\-5&2\end{pmatrix}}$
${\mbox{Addition by adding entry by entry:}}$

$M_{2\times 2}\ {\begin{pmatrix}a_{11}&a_{12}\\a_{21}&a_{22}\end{pmatrix}}+{\begin{pmatrix}b_{11}&b_{12}\\b_{21}&b_{22}\end{pmatrix}}={\begin{pmatrix}{a_{11}+b_{11}}&{a_{12}+b_{12}}\\{a_{21}+b_{21}}&{a_{22}+b_{22}}\end{pmatrix}}$

${\mbox{Multiplication by multiplying scalar c to all entries by M.}}$

$c\cdot M_{2\times 2}\ {\begin{pmatrix}a_{11}&a_{12}\\a_{21}&a_{22}\end{pmatrix}}={\begin{pmatrix}c\cdot a_{11}&c\cdot a_{12}\\c\cdot a_{21}&c\cdot a_{22}\end{pmatrix}}$

${\mbox{Zero matrix has all entries = 0:}}$

$0_{M_{m\times n}}={\begin{pmatrix}0&\cdots &0\\\vdots &&\vdots \\0&\cdots &0\end{pmatrix}}$
Ex.3. $\mathbb {C}$ form a vector space over $\mathbb {R}$ .
Ex.4. ${\mbox{F is a vector space over itself.}}$
Ex.5. $\mathbb {R}$ is a vector space over $\mathbb {Q}$ .
Ex.6. ${\mbox{Let S be a set. Let}}$
${\mathcal {F}}(S,\mathbb {R} )={\big \{}f:S\to \mathbb {R} {\big \}}$
$f,g\in {\mathcal {F}}(S,\mathbb {R} )$
$(f+g)(t)=f(t)+g(t)\ for\ any\ t\in S$
$(af)(t)=a\cdot f(t)\$

@@ Line 2: / Line 2: @@
 ==<center><u>'''Force Vectors'''</u></center>==
-#There is a special force vector called 0.
+#<math>\mbox{There is a special force vector called 0.}</math>
-#They can be added.
+#<math>\mbox{They can be added.}</math>
-#They can be multiplied by any scalar.
+#<math>\mbox{They can be multiplied by any scalar.}</math>
-====''Properties''==== (convention: x,y,z-vectors; a,b,c-scalars)
+====''Properties''====
-# <math> x+y=y+x \ </math>
+<math>\mbox{(convention: }x,y,z \mbox{ are vectors; }a,b,c \mbox{ are scalars)}</math>
+#<math> x+y=y+x \ </math>
 #<math> x+(y+z)=(x+y)+z \ </math>
 #<math> x+0=x \ </math>
-#<math> \forall x\; \exists\ y \ s.t.\ x+y=0 \ </math>
+#<math> \forall x\; \exists\ y \ \mbox{ s.t. }x+y=0</math>
 #<math> 1\cdot x=x \ </math>
 #<math> a(bx)=(ab)x \ </math>
@@ Line 16: / Line 18: @@
 #<math> (a+b)x=ax+bx \ </math>
+=====Definition=====
-=====Definition===== Let F be a field "of scalars". A vector space over F is a set V (of "vectors") along with two operations:
+Let F be a field "of scalars". A vector space over F is a set V, of "vectors", along with two operations
 : <math> +: V \times V \to V </math>
-: <math>  \cdot: F \times V \to V </math>, so that
+: <math>  \cdot: F \times V \to V \mbox{, so that:}</math>
 #<math> \forall x,y \in V\ x+y=y+x  </math>
 #<math> \forall x,y \in V\ x+(y+z)=(x+y)+z </math>
@@ Line 37: / Line 42: @@
 <math> 0_{F^n}=(0,\ldots,0) </math> <br/>
 <math> a\in F\ ax=(aa_1,aa_2,\ldots,aa_n) </math> <br/>
-<math> In \  \mathbb{Q}^3  \ \left( \frac{3}{2},-2,7\right)+\left( \frac{-3}{2}, \frac{1}{3},240\right)=\left(0, \frac{-5}{3},247\right) </math> <br/>
+<math> \mbox{In } \mathbb{Q}^3  \ \left( \frac{3}{2},-2,7\right)+\left( \frac{-3}{2}, \frac{1}{3},240\right)=\left(0, \frac{-5}{3},247\right) </math> <br/>
 <math> 7\left( \frac{1}{5},\frac{1}{7},\frac{1}{9}\right)=\left( \frac{7}{5},1,\frac{7}{9}\right) </math> <br/>
 '''Ex.2.'''
@@ Line 43: / Line 48: @@
  & \vdots \\ a_{m1} & \cdots & a_{mn}\end{pmatrix}: a_{ij} \in F \right\rbrace </math> <br/>
 <math> M_{3\times 2}( \mathbb{R})\ni \begin{pmatrix} 7 & -7 \\ \pi & \mathit{e} \\ -5 & 2 \end{pmatrix} </math> <br/>
-Addition by adding entry by entry:
+<math>\mbox{Addition by adding entry by entry:}</math>
 <math> M_{2\times 2}\ \begin{pmatrix} a_{11} & a_{12} \\ a_{21} & a_{22} \end{pmatrix}+\begin{pmatrix} b_{11} & b_{12} \\ b_{21} & b_{22} \end{pmatrix}=\begin{pmatrix} {a_{11}+b_{11}} & {a_{12}+b_{12}} \\ {a_{21}+b_{21}} & {a_{22}+b_{22}} \end{pmatrix}</math> <br/>
-Multiplication by multiplying scalar c to all entries by M.
+<math>\mbox{Multiplication by multiplying scalar c to all entries by M.}</math>
 <math> c\cdot M_{2\times 2}\ \begin{pmatrix} a_{11} & a_{12} \\ a_{21} & a_{22} \end{pmatrix}=\begin{pmatrix} c\cdot a_{11} & c\cdot a_{12} \\ c\cdot a_{21} & c\cdot a_{22} \end{pmatrix}</math> <br/> <br/>
-Zero matrix has all entries = 0:
+<math>\mbox{Zero matrix has all entries = 0:}</math>
 <math> 0_{M_{m\times n}}=\begin{pmatrix} 0 & \cdots & 0 \\ \vdots &
@@ Line 58: / Line 63: @@
 <math> \mathbb{C}</math> form a vector space over <math> \mathbb{R}</math>. <br/>
 '''Ex.4.'''
-F is a vector space over itself. <br/>
+<math>\mbox{F is a vector space over itself.}</math> <br/>
 '''Ex.5.'''
 <math> \mathbb{R}</math> is a vector space over <math> \mathbb{Q}</math>. <br/>
 '''Ex.6.'''
-Let S be a set. Let <br/>
+<math>\mbox{Let S be a set. Let}</math> <br/>
 <math> \mathcal{F}(S,\mathbb{R})=\big\{f:S\to \mathbb{R} \big\} </math> <br/>
 <math> f,g \in \mathcal{F}(S,\mathbb{R}) </math> <br/>

06-240/Classnotes For Thursday, September 21: Difference between revisions

Revision as of 06:31, 27 September 2006

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