(New page: == part a == it can't be a time invariant because output is not same. <math>X_k[n] = \delta[n-k]</math> <math>\delta[n-k]\rightarrow time delay\rightarrow\delta[n-k-n_0]\rightarrow sys...)
 
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<math>\delta[n-k]\rightarrow time delay\rightarrow\delta[n-k-n_0]\rightarrow system \rightarrow (k+n_0+1)^2\delta[n-(k+n_0+1)]</math>
 
<math>\delta[n-k]\rightarrow time delay\rightarrow\delta[n-k-n_0]\rightarrow system \rightarrow (k+n_0+1)^2\delta[n-(k+n_0+1)]</math>
  
<math>\delta[n-k]\rightarrow system \rightarrow Y_k[n] \rightarrow</math>
+
<math>\delta[n-k]\rightarrow system \rightarrow Y_k[n] \rightarrow time delay \rightarrow (k+1)^2\delta[n-(k+n_0+1)] </math>
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== part b ==

Revision as of 18:32, 11 September 2008

part a

it can't be a time invariant because output is not same.

$ X_k[n] = \delta[n-k] $

$ \delta[n-k]\rightarrow time delay\rightarrow\delta[n-k-n_0]\rightarrow system \rightarrow (k+n_0+1)^2\delta[n-(k+n_0+1)] $

$ \delta[n-k]\rightarrow system \rightarrow Y_k[n] \rightarrow time delay \rightarrow (k+1)^2\delta[n-(k+n_0+1)] $


part b

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Basic linear algebra uncovers and clarifies very important geometry and algebra.

Dr. Paul Garrett