(New page: The problem on the test I most screwed up was this one: Is the system <math>y(t)=x(1-t)</math> Time Invaiant? The best way to solve this is to just go slow and if nessecary change a vari...)
 
 
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The best way to solve this is to just go slow and if nessecary change a variable to make sure you get the expression correct
 
The best way to solve this is to just go slow and if nessecary change a variable to make sure you get the expression correct
  
x(t) -->|system|-->y(t)=x(1-t)-->|delay|-->y(t-t0)=x(1-t-t0)
+
x(t) -->|system|-->y(t)=x(1-t)-->|delay|-->y(t-t0)=x(1-(t-t0))=x(1-t+t0)
  
x(t) -->|delay|-->x(t-t0)-->|system|-->y(t-t0)=x(1-(t-t0))=x(1-t+t0)
+
x(t) -->|delay|-->x(t-t0)-->|system|-->y(t-t0)=x(1-t-t0)
  
  
 
So since the outputs are not the same, the system is not Time Invariant.
 
So since the outputs are not the same, the system is not Time Invariant.

Latest revision as of 16:51, 15 October 2008

The problem on the test I most screwed up was this one:

Is the system $ y(t)=x(1-t) $ Time Invaiant?

The best way to solve this is to just go slow and if nessecary change a variable to make sure you get the expression correct

x(t) -->|system|-->y(t)=x(1-t)-->|delay|-->y(t-t0)=x(1-(t-t0))=x(1-t+t0)

x(t) -->|delay|-->x(t-t0)-->|system|-->y(t-t0)=x(1-t-t0)


So since the outputs are not the same, the system is not Time Invariant.

Alumni Liaison

Correspondence Chess Grandmaster and Purdue Alumni

Prof. Dan Fleetwood