Revision as of 12:30, 7 January 2010

Definitions

Electric	Magnetic	Notes
$V=\int {\overrightarrow {E}}{\overrightarrow {dl}}$	${\overrightarrow {F}}=\int {\overrightarrow {H}}{\overrightarrow {dl}}$
$\sum _{n}V_{n}=0=\oint {\overrightarrow {E}}{\overrightarrow {dl}}$	$\oint {\overrightarrow {H}}{\overrightarrow {dl}}=Ni=\sum _{n}Hl+Ni=0$	Kirchoff's voltage law
$\sum _{n}I_{n}=0=\oint _{S}{\overrightarrow {J}}{\overrightarrow {dS}}$	$\oint {\overrightarrow {B}}{\overrightarrow {dS}}=0$	Kirchoff's current law, The B-field has to go around in a loop
$\oint {\overrightarrow {J}}{\overrightarrow {dS}}=I$	$\int {\overrightarrow {B}}{\overrightarrow {dS}}=\Phi$	Magnetic flux, Phi
$R={\frac {V}{I}}$	${\mathfrak {R}}={\frac {F}{\Phi }}={\frac {Ni}{\Phi }}$	Reluctance
$I={\frac {V}{R}}=GV$ or ${\overrightarrow {J}}=\sigma {\overrightarrow {E}}$	${\overrightarrow {B}}=\mu H$	Assumes linearity - exceptions: Hysterisis loop, etc

@@ Line 32: / Line 32: @@
 |-
 | <math>\oint \overrightarrow{J} \overrightarrow{dS} = I</math>
-| <math>\int \overrightarrow{B} \overrightarrow{dS} = \overbrace{\Phi}^{phi} </math>
+| <math>\int \overrightarrow{B} \overrightarrow{dS} = \Phi </math>
-|Magnetic flux
+|Magnetic flux, Phi
 |-
 | <math> R = \frac{V}{I}</math>
-| <math> \overbrace{R}^{reluctance} = \frac{F}{\Phi} = \frac{N i}{\Phi}</math>
+| <math> \mathfrak{R} = \frac{F}{\Phi} = \frac{N i}{\Phi}</math>
+|Reluctance
 |-
 | <math> I = \frac{V}{R} = G V </math> or <math>\overrightarrow{J} = \sigma \overrightarrow{E}</math>