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| + | [[ECE_PhD_Qualifying_Exams|ECE Ph.D. Qualifying Exam]] | ||
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| + | Communication, Networking, Signal and Image Processing (CS) | ||
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| + | Question 1: Probability and Random Processes | ||
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| + | January 2001 | ||
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| + | ---- | ||
| + | ---- | ||
| + | =Part 5= | ||
Let a linear discrete parameter shift-invariant system have the following difference equation: <math class="inline">y\left(n\right)=0.7y\left(n-1\right)+x\left(n\right)</math> where <math class="inline">x\left(n\right)</math> in the input and <math class="inline">y\left(n\right)</math> is the output. Now suppose this system has as its input the discrete parameter random process <math class="inline">\mathbf{X}_{n}</math> . You may assume that the input process is zero-mean i.i.d. | Let a linear discrete parameter shift-invariant system have the following difference equation: <math class="inline">y\left(n\right)=0.7y\left(n-1\right)+x\left(n\right)</math> where <math class="inline">x\left(n\right)</math> in the input and <math class="inline">y\left(n\right)</math> is the output. Now suppose this system has as its input the discrete parameter random process <math class="inline">\mathbf{X}_{n}</math> . You may assume that the input process is zero-mean i.i.d. | ||
Latest revision as of 10:37, 13 September 2013
Communication, Networking, Signal and Image Processing (CS)
Question 1: Probability and Random Processes
January 2001
Contents
Part 5
Let a linear discrete parameter shift-invariant system have the following difference equation: $ y\left(n\right)=0.7y\left(n-1\right)+x\left(n\right) $ where $ x\left(n\right) $ in the input and $ y\left(n\right) $ is the output. Now suppose this system has as its input the discrete parameter random process $ \mathbf{X}_{n} $ . You may assume that the input process is zero-mean i.i.d.
(a) (5 pts) Is the input wide-sense stationary (show your work)?
(b) (5 pts) Is the output process wide-sense stationary (show your work)?
(c) (5 pts) Find the autocorrelation function of the input process.
(d) (5 pts) Find the autocorrelation function, in closed form, for the output process.
Solution 1 (retrived from here)
(a)
$ E\left[\mathbf{X}_{n}\right]=0. $
$ R_{\mathbf{XX}}\left(n+m,\; n\right) $
$ \therefore\;\mathbf{X}_{n}\text{ is wide-sense stationary.} $
(b)
$ E\left[\mathbf{Y}_{n}\right]=0.7E\left[\mathbf{Y}_{n-1}\right]+E\left[\mathbf{X}_{n}\right]=0.7E\left[\mathbf{Y}_{n-1}\right]=0.7^{2}E\left[\mathbf{Y}_{n-2}\right]=0.7^{n}E\left[\mathbf{Y}_{0}\right]=0. $
$ E\left[\mathbf{Y}_{0}\right]=E\left[\sum_{n=-\infty}^{\infty}h\left(0-n\right)\mathbf{X}\left(n\right)\right]=\sum_{n=-\infty}^{\infty}h\left(-n\right)E\left[\mathbf{X}\left(n\right)\right]=0. $
$ R_{\mathbf{YY}}\left(n+m,\; n\right) $
$ R_{\mathbf{YY}}\left(n+m,\; n\right) $ depends on the time difference $ m $ . Thus, $ \mathbf{Y}_{n} $ is wide-sense stationary.
(c)
$ R_{\mathbf{XX}}\left(n,n+m\right)=R_{\mathbf{X}}\left(m\right)=\sigma_{\mathbf{X}}^{2}\delta\left(m\right). $
(d)
$ R_{\mathbf{Y}}\left(m\right) $
$ \because\; E\left[\mathbf{X}\left(n\right)\mathbf{Y}\left(m\right)\right]=E\left[\sum_{k=-\infty}^{\infty}h\left(m-k\right)\mathbf{X}\left(n\right)\mathbf{X}\left(k\right)\right]=\sum_{k=-\infty}^{\infty}h\left(m-k\right)\left(\sigma_{\mathbf{X}}^{2}\delta\left(n-k\right)\right). $
Solution 2
Write it here.
