(New page: == Time Invariant Systems == === Worded Definitions === ==== Time Invariant ==== A system is said to be time invariant if a time shift does not affect the output of the system. If x(t)...)
 
Line 1: Line 1:
 
 
== Time Invariant Systems ==
 
== Time Invariant Systems ==
  
Line 18: Line 17:
 
Step 1: The System
 
Step 1: The System
  
<math>\,\!y(t)=2x(t)cos(t)</math>
+
<math>\,\!y(t)=x(t)sin(t)</math>
  
 
Step 2: Time delay
 
Step 2: Time delay
  
<math>\,\!z(t)=y(t-k)=2x(t-k)cos(t-k)</math>
+
<math>\,\!z(t)=y(t-k)=x(t-k)sin(t-k)</math>
 +
 
 +
Step 1: Time delay
 +
 
 +
<math>\,\!y(t)=x(t-k)</math>
 +
 
 +
Step 2: The System
 +
 
 +
<math>\,\!z(t)=y(t)sin(t)=x(t-k)sin(t-k)</math>
 +
 
 +
The functions z(t) are equal, so the system is time invariant.
 +
 
 +
=== Example of a Time Variant System ===
 +
 
 +
<math>\,\!y(t)=tx(t)</math>
 +
 
 +
Step 1: The System
 +
 
 +
<math>\,\!y(t)=tx(t)</math>
 +
 
 +
Step 2: Time delay
 +
 
 +
<math>\,\!z(t)=y(t-k)=(t-k)x(t-k)</math>
 +
 
 +
Step 1: Time delay
  
Next, we do the time shift first, then the system:
+
<math>\,\!y(t)=x(t-k)</math>
  
<math>\,\!y(t)=x(t-k)</math> , now the system
+
Step 2: The System
  
<math>\,\!z(t)=2y(t)cos(t)=2x(t-k)cos(t-k)</math>
+
<math>\,\!z(t)=ty(t)=tx(t-k)
  
These results are equal, so it is time invariant
+
The results for z(t) are not equal so this system is time variant.

Revision as of 13:39, 18 September 2008

Time Invariant Systems

Worded Definitions

Time Invariant

A system is said to be time invariant if a time shift does not affect the output of the system. If x(t) is put through the system, then time shifted, the results should be identical to x(t) being time shifted, then put through the system.

Time Variant

A system is time variant if a time shift does affect the output of the system. In the same way as before, if x(t) is put through the system then time shifted, the results will be different than if x(t) is time shifted, then put through the system.

Example of a Time Invariant System

$ \,\!y(t)=x(t)sin(t) $

Step 1: The System

$ \,\!y(t)=x(t)sin(t) $

Step 2: Time delay

$ \,\!z(t)=y(t-k)=x(t-k)sin(t-k) $

Step 1: Time delay

$ \,\!y(t)=x(t-k) $

Step 2: The System

$ \,\!z(t)=y(t)sin(t)=x(t-k)sin(t-k) $

The functions z(t) are equal, so the system is time invariant.

Example of a Time Variant System

$ \,\!y(t)=tx(t) $

Step 1: The System

$ \,\!y(t)=tx(t) $

Step 2: Time delay

$ \,\!z(t)=y(t-k)=(t-k)x(t-k) $

Step 1: Time delay

$ \,\!y(t)=x(t-k) $

Step 2: The System

$ \,\!z(t)=ty(t)=tx(t-k) The results for z(t) are not equal so this system is time variant. $

Alumni Liaison

Correspondence Chess Grandmaster and Purdue Alumni

Prof. Dan Fleetwood