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CDA6530: Performance Models of Computers and Networks Review of Transform Theory

CDA6530: Performance Models of Computers and Networks Review of Transform Theory. TexPoint fonts used in EMF. Read the TexPoint manual before you delete this box.: A A A A A A A A A. Why using transform? Make analysis easier Two transforms for probability Non-negative integer r.v.

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CDA6530: Performance Models of Computers and Networks Review of Transform Theory

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  1. CDA6530: Performance Models of Computers and NetworksReview of Transform Theory TexPoint fonts used in EMF. Read the TexPoint manual before you delete this box.: AAAAAAAAA

  2. Why using transform? • Make analysis easier • Two transforms for probability • Non-negative integer r.v. • Z-transform (or called probability generating function (pgf)) • Non-negative, real valued r.v. • Laplace transform (LT)

  3. Z-transform • Definition: • GX(Z) is Z-transform for r.v. X • Example: • X is geometric r.v., pk = (1-p)pk For pz<1

  4. Poisson distr., pk = ¸ke-¸/k!

  5. Benefit • Thus • Convolution: X, Y independent with Z-transforms GX(z) and GY(z), Let U=X+Y

  6. Solution of M/M/1 Using Transform • Multiplying by zi, using ½ =¸/¹, and summing over i )

  7. Laplace Transform • R.v. X has pdf fX(x) • X is non-negative, real value • The LT of X is:

  8. Example • X: exp. Distr. fX(x)=¸ e-¸ x • Moments:

  9. Convolution • X1, X2, , Xn are independent rvs with • If Y=X1+X2++Xn • If Y is n-th Erlang,

  10. Z-transform and LT • X1, X2, , XN are i.i.d. r.v with LT • N is r.v. with pgf GN(z) • Y= X1+X2 ++XN • If Xi is discrete r.v. with GX(Z), then

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