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== TIME INVARIANCE == | == TIME INVARIANCE == | ||
Time invariance, in my definition, is such a system that does not stretch or shrink the input function and does not change time shift of input is called "time invariance." | Time invariance, in my definition, is such a system that does not stretch or shrink the input function and does not change time shift of input is called "time invariance." | ||
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'''Proof:''' | '''Proof:''' | ||
| − | <math>x(t) \to System \to y(t)=e^{x(t)}</math> | + | <math>x(t) \to System \to y(t)=e^{x(t)} \to Time Shift(t0) \to z(t)=y(t-t0)</math> |
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| + | <math>\, =e^{x(t-t0)}\,</math> | ||
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| + | <math>x(t) \to Time Shift(t0) \to y(t)=x(t-t0) \to System \to z(t)=e^{y(t)}</math> | ||
| + | |||
| + | <math>\, =e^{x(t-t0)}\,</math> | ||
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| + | Both cascades yielded the same outputs, thus <math>\,y(t)=e^{x(t)}\,</math> is time invariant. | ||
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| + | == Example of Time variant system and its proof == | ||
| + | <math>\,y(t)=x(2t)\,</math> | ||
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| + | '''Proof:''' | ||
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| + | <math>x(t) \to System \to y(t)=x(2t) \to Time Shift(t0) \to z(t)=y(t-t0)</math> | ||
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| + | <math>\, =x(2t-2t0)\,</math> | ||
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| + | |||
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| + | <math>x(t) \to Time Shift(t0) \to y(t)=x(t-t0) \to System \to z(t)=y(2t)</math> | ||
| + | |||
| + | <math>\, =x(2t-t0)\,</math> | ||
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| + | They yielded different outputs, thus <math>\,y(t)=x(2t)\,</math> is time-variant. | ||
Latest revision as of 17:22, 12 September 2008
TIME INVARIANCE
Time invariance, in my definition, is such a system that does not stretch or shrink the input function and does not change time shift of input is called "time invariance."
Example of Time invariant system and its proof
$ \,y(t)=e^{x(t)}\, $
Proof:
$ x(t) \to System \to y(t)=e^{x(t)} \to Time Shift(t0) \to z(t)=y(t-t0) $
$ \, =e^{x(t-t0)}\, $
$ x(t) \to Time Shift(t0) \to y(t)=x(t-t0) \to System \to z(t)=e^{y(t)} $
$ \, =e^{x(t-t0)}\, $
Both cascades yielded the same outputs, thus $ \,y(t)=e^{x(t)}\, $ is time invariant.
Example of Time variant system and its proof
$ \,y(t)=x(2t)\, $
Proof:
$ x(t) \to System \to y(t)=x(2t) \to Time Shift(t0) \to z(t)=y(t-t0) $
$ \, =x(2t-2t0)\, $
$ x(t) \to Time Shift(t0) \to y(t)=x(t-t0) \to System \to z(t)=y(2t) $
$ \, =x(2t-t0)\, $
They yielded different outputs, thus $ \,y(t)=x(2t)\, $ is time-variant.
