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'''For the system to be time invariant both the outputs should be same but they are not. so the system is not time variant it is rather a time variant system as the output varies with time.''' | '''For the system to be time invariant both the outputs should be same but they are not. so the system is not time variant it is rather a time variant system as the output varies with time.''' | ||
| − | ''' | + | '''6.b)''' |
| − | 6.b)''' | + | |
Revision as of 13:12, 12 September 2008
Linearity and Time Invariance
6.a)
the system is defined as
$ X_k[n] = \delta[n - k] \to sys \to Y_k[n] = (k + 1)^2 \delta[n - (k + 1)] $
let us check for time invariance
System followed by time delay
now,let us apply a time-delay of $ t_0 $ to the system.
$ \delta[n - k] \to sys \to (k + 1)^2 \delta[n - (k + 1)] \to timedelay \to (k + 1)^2 \delta[n - t_0 -(k + 1)] = (k + 1)^2 \delta[n -(k + 1 +t_0)] $
Time-delay followed by system:
$ \delta[n - k] \to timedelay \to \delta[n-(k + t_0)] \to sys \to (k + t_0 + 1)^2 \delta[n - (k + t_0 + 1)] $
For the system to be time invariant both the outputs should be same but they are not. so the system is not time variant it is rather a time variant system as the output varies with time.
6.b)
