(New page: ==Diagrammatical Explanations== ==Mathematical Explanations== As some people find the mathematical explanations simpler to understand and/or work with, they will be presented here: ===Co...) |
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==Diagrammatical Explanations== | ==Diagrammatical Explanations== | ||
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==Mathematical Explanations== | ==Mathematical Explanations== | ||
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===Concepts=== | ===Concepts=== | ||
− | '''Linearity:''' The function ("The system") f is '''linear''' iff <math>\forall x_1(t), x_2(t) \text{ and } \forall a,b \in \mathbb{C}, f(ax_1 + bx_2) = af(x_1) + bf(x_2)</math> | + | *'''Linearity:''' The function ("The system") f is '''linear''' iff <math>\forall x_1(t), x_2(t) \text{ and } \forall a,b \in \mathbb{C}, f(ax_1 + bx_2) = af(x_1) + bf(x_2)</math> |
− | '''Time Invariant:''' Define <math>S_{t_0}</math> as the shifting operator <math>S_{t_0}(x(t))=x(t-t_0).</math> (In other words, <math>S_{t_0}</math> introduces a time delay of <math>t_0</math> onto the function/signal x(t).) A function ("system") f is considered time-invariant iff <math>f(S_{t_0}(x))=S_{t_0}(f(x))\ \forall x(t), t_0.</math> | + | *'''Time Invariant:''' Define <math>S_{t_0}</math> as the shifting operator <math>S_{t_0}(x(t))=x(t-t_0).</math> (In other words, <math>S_{t_0}</math> introduces a time delay of <math>t_0</math> onto the function/signal x(t).) A function ("system") f is considered '''time-invariant''' iff <math>f(S_{t_0}(x))=S_{t_0}(f(x))\ \forall x(t), t_0.</math> |
− | ===Translations=== | + | |
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+ | ===Translations between Diagrammatical and Mathematical Explanations=== | ||
* 'The system' <==> 'The function f' | * 'The system' <==> 'The function f' | ||
− | * | + | * <math>x \rightarrow \text{system} \rightarrow y \Leftrightarrow y = f(x) \left ( x \rightarrow \text{f} \rightarrow f(x) \right )</math> |
==References== | ==References== | ||
ECE301 lectures by Mimi Boutin, Purdue University, Fall 2008 | ECE301 lectures by Mimi Boutin, Purdue University, Fall 2008 | ||
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http://en.wikipedia.org/wiki/Linearity | http://en.wikipedia.org/wiki/Linearity | ||
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http://en.wikipedia.org/wiki/Time_invariant | http://en.wikipedia.org/wiki/Time_invariant |
Latest revision as of 15:09, 3 December 2008
Contents
Diagrammatical Explanations
Mathematical Explanations
As some people find the mathematical explanations simpler to understand and/or work with, they will be presented here:
Concepts
- Linearity: The function ("The system") f is linear iff $ \forall x_1(t), x_2(t) \text{ and } \forall a,b \in \mathbb{C}, f(ax_1 + bx_2) = af(x_1) + bf(x_2) $
- Time Invariant: Define $ S_{t_0} $ as the shifting operator $ S_{t_0}(x(t))=x(t-t_0). $ (In other words, $ S_{t_0} $ introduces a time delay of $ t_0 $ onto the function/signal x(t).) A function ("system") f is considered time-invariant iff $ f(S_{t_0}(x))=S_{t_0}(f(x))\ \forall x(t), t_0. $
Translations between Diagrammatical and Mathematical Explanations
- 'The system' <==> 'The function f'
- $ x \rightarrow \text{system} \rightarrow y \Leftrightarrow y = f(x) \left ( x \rightarrow \text{f} \rightarrow f(x) \right ) $
References
ECE301 lectures by Mimi Boutin, Purdue University, Fall 2008