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== E-a == | == E-a == | ||
| − | + | No,the system can not be time-invariant. | |
| − | the | + | Based on the data, if X has been delayed by 1, Y is not only delayed by 1,but also scale in the magnitude. |
| − | + | ||
| − | + | Since if we operate delay, the outputs won't match, the system is not time-invariant. | |
| − | + | ||
| − | + | ||
| − | + | ||
| − | Since the outputs match, the system is time-invariant. | + | |
== E-b == | == E-b == | ||
Since the system is linear, the input should be X[n] = u[n] in order to get Y[n]=u[n-1], | Since the system is linear, the input should be X[n] = u[n] in order to get Y[n]=u[n-1], | ||
where k=0 | where k=0 | ||
Latest revision as of 18:35, 12 September 2008
E-a
No,the system can not be time-invariant.
Based on the data, if X has been delayed by 1, Y is not only delayed by 1,but also scale in the magnitude.
Since if we operate delay, the outputs won't match, the system is not time-invariant.
E-b
Since the system is linear, the input should be X[n] = u[n] in order to get Y[n]=u[n-1], where k=0
