(→Input X[n]) |
|||
| Line 22: | Line 22: | ||
<math> d[n-k] --> [timedelay -1] --> d[n-k-1)] --> [system] --> k^2*d[n-k] \,</math> | <math> d[n-k] --> [timedelay -1] --> d[n-k-1)] --> [system] --> k^2*d[n-k] \,</math> | ||
| + | |||
| + | |||
| + | Remember: Time delay only occurs on function, not variable on equations. | ||
| + | |||
| + | Concluded, it is time invariant if we say n represents time, and it is time variant if we say k represents time. | ||
| Line 31: | Line 36: | ||
with an input <math>X[n] = u[n] + u[1] \,</math> | with an input <math>X[n] = u[n] + u[1] \,</math> | ||
| − | |||
| − | |||
| − | |||
| − | |||
| − | |||
Revision as of 18:55, 10 September 2008
Contents
Time Invariance? or Time Variance?
System: $ Y_k[n] = (k+1)^2 d[n - (k+1)] \, $
Input: $ X_k[n] = d[n-k] \, $
Prob: Which variable represent time ?
1st Assumption: n represents time
$ d[n-k] --> [system] --> (k+1)^2*d[n-(k+1)] --> [timedelay -1] --> (k+1)^2*d[(n-1)-(k+1)] \, $
yields the same result as:
$ d[n-k] --> [timedelay -1] --> d[(n-1)-k] --> [system] --> (k+1)^2*d[(n-1)-(k+1)] \, $
2st Assumption: k represents time
$ d[n-k] --> [system] --> (k+1)^2*d[n-k+1)] --> [timedelay -1] --> (k+1)^2*d[n-k] \, $
yields not the same result as:
$ d[n-k] --> [timedelay -1] --> d[n-k-1)] --> [system] --> k^2*d[n-k] \, $
Remember: Time delay only occurs on function, not variable on equations.
Concluded, it is time invariant if we say n represents time, and it is time variant if we say k represents time.
Input X[n]
Since it is linear, we can say that
$ Y[n] = u[n-1] \, $
with an input $ X[n] = u[n] + u[1] \, $
