Line 22: Line 22:
 
  '''y[n]=cos[nQ]*x[n]'''
 
  '''y[n]=cos[nQ]*x[n]'''
  
*y[x[n-n0]]=cos[nQ]*x[n-n0]
+
*<math>y[x[n-n0]]=cos[nQ]*x[n-n0]</math>
 
Also,
 
Also,
*y[n-n0]= cos[n-n0]* x[n-n0]
+
*<math>y[n-n0]= cos[n-n0]Q* x[n-n0]</math>
  
 
Thus from above we can say that the system is '''time variant'''
 
Thus from above we can say that the system is '''time variant'''

Latest revision as of 10:11, 12 September 2008

Time invariance

A system is called time invariant if the cascade

  • x[n]----->Time delay ----> System -----> z[n]

yields the same output as

  • x[n]----->system----->Time Delay-----> y[n]


Time Invariance check

Let us check for y[n] = x[n]^2
  • $ y[x[n-n0]] = x{[n-n0]^2} $

Also,

  • $ y[n-n0] = x{[n-n0]^2} $

Thus the above system is time invariant


Time Variance check

Let us test for

y[n]=cos[nQ]*x[n]
  • $ y[x[n-n0]]=cos[nQ]*x[n-n0] $

Also,

  • $ y[n-n0]= cos[n-n0]Q* x[n-n0] $

Thus from above we can say that the system is time variant

Alumni Liaison

Abstract algebra continues the conceptual developments of linear algebra, on an even grander scale.

Dr. Paul Garrett