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| − | As you can see in graph the signal is being repeated and a value T can be used to get the same value during other times of the signal. | + | As you can see in graph the signal is being repeated and a value T can be used to |
| + | get the same value during other times of the signal. | ||
* Non-Periodic Discrete-Time Signal | * Non-Periodic Discrete-Time Signal | ||
<math>x[n] = \cos(\frac{\pi}{8}n^2)</math> | <math>x[n] = \cos(\frac{\pi}{8}n^2)</math> | ||
| − | + | ||
| − | + | [[Image:JAL_Nonperiodic_ECE301Fall2008mboutin.JPG]] | |
| + | |||
| + | As you can see the graph is non-periodic due to the fact that here is no value of | ||
| + | N that could be added so that <math>x[n] = x[n+N</math> | ||
* Bonus Question | * Bonus Question | ||
Revision as of 08:48, 5 September 2008
Periodic Signal Definition
- For a Continuous-time signal
There exists a positive value of T for which
$ x(t) = x(t - T) $
for all values of t.
- For a Discrete-time signal
There exists a positive integer N for which
$ x[n] = x[n + N] $
for all values of n.
Note: N is the period of the signal.
Problems
- Periodic Continuous-Time Signal
$ x(t) = 3\cos(4t + \frac{\pi}{3}) $
As you can see in graph the signal is being repeated and a value T can be used to
get the same value during other times of the signal.
- Non-Periodic Discrete-Time Signal
$ x[n] = \cos(\frac{\pi}{8}n^2) $As you can see the graph is non-periodic due to the fact that here is no value of N that could be added so that $ x[n] = x[n+N $
- Bonus Question
$ x(t) = e^{j(\pi t-1)} $
Is periodic, when graphed it produces a straigh line.
Since it is a line, at any time the value of the signal will be equal to any other time.
Credit: Problems were taken from Signals & Systems 2nd ed. (Oppenheim) Page 61
