(Periodic Functions)
(Periodic Functions)
 
(7 intermediate revisions by the same user not shown)
Line 1: Line 1:
 
== Periodic Functions ==
 
== Periodic Functions ==
  
A Continuous Time signal is said to be periodic if there exists <math>T > 0</math> such that <math>x(t+T)=x(t)</math>
+
A Continuous Time signal is said to be periodic if there exists <math>\ T > 0</math> such that <math>\ x(t+T)=x(t)</math>
  
A Discrete Time signal is said to be periodic if there exists <math>N > 0</math> (where N is an integer) such that <math>x[n+N]=x[n]</math>
+
A Discrete Time signal is said to be periodic if there exists <math>\ N > 0</math> (where N is an integer) such that <math>\ x[n+N]=x[n]</math>
  
An example of a DT periodic signal is <math>x[n] = j^{n}</math> because
+
An example of a CT periodic signal is <math>x(t) = sawtooth(t,.5)</math> (which is actually a tri wave):
  
<math>x[1] = j</math>         
+
[[Image:tri_ECE301Fall2008mboutin.jpg]]
  
<math>x[2] = -1</math>     
+
As you can see the function has a fundamental period of two Pi. Therefore any multiple of two Pi is a period.
  
<math>x[3] = -j</math>
+
== Non-periodic Functions ==
  
<math>x[4] = 1</math>    
+
A Continuous Time signal is said to be non-periodic if there is no value of <math>\ T > 0</math> that satisfies <math>\ x(t+T)=x(t)</math>
  
<math>x[5] = j</math>  
+
A Discrete Time signal is said to be non-periodic if there is no value of <math>\ N > 0</math> (where N is an integer) that satisfies<math>\ x[n+N]=x[n]</math>
  
<math>x[6] = -1</math>  
+
An example of a non-periodic continuous time signal would be <math>\ x(t) = e^{(-1 + j)t}</math>. This goes to show that not all complex exponential functions are periodic.
  
<math>x[7] = -j</math>
+
Here is what the function looks like when graphed:
 
+
<math>x[8] = 1</math>
+
 
+
As you can see the function has a fundamental period of 4. Therefore any multiple of 4 is a period.
+
 
+
== Non-periodic Functions ==
+
  
A Continuous Time signal is said to be non-periodic if there is no value of <math>T > 0</math> that satisfies <math>x(t+T)=x(t)</math>
+
[[Image:np_exp_ECE301Fall2008mboutin.jpg]]
  
A Discrete Time signal is said to be non-periodic if there is no value of <math>N > 0</math> (where N is an integer) that satisfies<math>x[n+N]=x[n]</math>
+
As you can see from the graph the function is non-periodic.

Latest revision as of 11:21, 5 September 2008

Periodic Functions

A Continuous Time signal is said to be periodic if there exists $ \ T > 0 $ such that $ \ x(t+T)=x(t) $

A Discrete Time signal is said to be periodic if there exists $ \ N > 0 $ (where N is an integer) such that $ \ x[n+N]=x[n] $

An example of a CT periodic signal is $ x(t) = sawtooth(t,.5) $ (which is actually a tri wave):

Tri ECE301Fall2008mboutin.jpg

As you can see the function has a fundamental period of two Pi. Therefore any multiple of two Pi is a period.

Non-periodic Functions

A Continuous Time signal is said to be non-periodic if there is no value of $ \ T > 0 $ that satisfies $ \ x(t+T)=x(t) $

A Discrete Time signal is said to be non-periodic if there is no value of $ \ N > 0 $ (where N is an integer) that satisfies$ \ x[n+N]=x[n] $

An example of a non-periodic continuous time signal would be $ \ x(t) = e^{(-1 + j)t} $. This goes to show that not all complex exponential functions are periodic.

Here is what the function looks like when graphed:

Np exp ECE301Fall2008mboutin.jpg

As you can see from the graph the function is non-periodic.

Alumni Liaison

Correspondence Chess Grandmaster and Purdue Alumni

Prof. Dan Fleetwood