(Again, not with words but with diagrams)
(Again, not words but DIAGRAMS)
 
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===Again, not words but DIAGRAMS===
 
===Again, not words but DIAGRAMS===
 +
[[image:timeinvariant301.jpg]] if z(t)=y(t) then it is said to be Time Invariant (T.I)
 +
===Not time Invariant System===
 +
<math>\,\ x(t) = t^2 </math> and the system multiplies it by t.
 +
 +
<math>\,\ y(t) = (t-to)^3</math>
 +
 +
<math>\,\ z(t) = t(t-to)^2</math>
 +
 +
and thus it is not T.I. because y(t) does not equal z(t)
 +
===Time Invariant System===
 +
<math>\,\ x(t) = t^2 </math> and the system multiplies it by 3.
 +
 +
<math>\,\ y(t) = 3(t-to)^2</math>
 +
 +
<math>\,\ z(t) = 3(t-to)^2</math>
 +
 +
and '''BAMO''' y(t) does indeed equal z(t) so it is T.I.

Latest revision as of 18:43, 11 September 2008

Again, not words but DIAGRAMS

File:Timeinvariant301.jpg if z(t)=y(t) then it is said to be Time Invariant (T.I)

Not time Invariant System

$ \,\ x(t) = t^2 $ and the system multiplies it by t.

$ \,\ y(t) = (t-to)^3 $

$ \,\ z(t) = t(t-to)^2 $

and thus it is not T.I. because y(t) does not equal z(t)

Time Invariant System

$ \,\ x(t) = t^2 $ and the system multiplies it by 3.

$ \,\ y(t) = 3(t-to)^2 $

$ \,\ z(t) = 3(t-to)^2 $

and BAMO y(t) does indeed equal z(t) so it is T.I.

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