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- 11:32, 16 November 2008 (diff | hist) . . (+27) . . Problem 7 (ECE301Summer2008asan) (→Problem 7)
- 11:30, 16 November 2008 (diff | hist) . . (+984) . . N Problem 7 (ECE301Summer2008asan) (New page: ==Problem 7== Determine the Fourier Series co-efficient for the following continuous time periodic signals.Show the details of your calculations and simplify your answers. [[Image:Figure....)
- 11:30, 16 November 2008 (diff | hist) . . (+84) . . Problem 6 (ECE301Summer2008asan)
- 11:29, 16 November 2008 (diff | hist) . . (-3) . . Problem 6 (ECE301Summer2008asan)
- 11:26, 16 November 2008 (diff | hist) . . (+4,001) . . N Problem 6 (ECE301Summer2008asan) (New page: ==Problem 6== Read the discussion on discussion page using the discussion page tab. (Aung 11:13pm on 07/18/2008) ---------------------------------------------------------------------------...)
- 11:25, 16 November 2008 (diff | hist) . . (+30) . . Problem 5 - Graphical Solution (ECE301Summer2008asan)
- 11:25, 16 November 2008 (diff | hist) . . (0) . . N File:ECE301Summer2008 San Exam1 P5 Graphical Solution.pdf (current)
- 11:24, 16 November 2008 (diff | hist) . . (+67) . . N Problem 5 - Graphical Solution (ECE301Summer2008asan) (New page: ==Problem 5 - Graphical Solution== Image:Graphical_Solution.pdf)
- 11:24, 16 November 2008 (diff | hist) . . (+989) . . N Problem 5 - Alternate Solution (ECE301Summer2008asan) (New page: ==Problem 5 - Alternate Solution== We are given the input to an LTI system along with the system's impulse response and told to find the output y(t). Since the input and impulse response ...)
- 11:23, 16 November 2008 (diff | hist) . . (+952) . . N Problem 5 (ECE301Summer2008asan) (New page: ==Problem 5== We are given the input to an LTI system along with the system's impulse response and told to find the output y(t). Since the input and impulse response are given, we simply ...)
- 11:22, 16 November 2008 (diff | hist) . . (+780) . . N Problem 4 - Mistake in solution posted (ECE301Summer2008asan) (New page: ==Problem 4 - Mistake in solution posted== I thought that the solution posted in the Bonus 3 for problem 4 is slightly wrong in explaining why System II is Stable. Its given that <math> x...)
- 11:21, 16 November 2008 (diff | hist) . . (+4,267) . . N Problem 4 (ECE301Summer2008asan) (New page: ==Problem 4== SYSTEM 1 - <math>h[n] = \delta[n+1] + \delta[n-1]</math> A - <math>y[n] = \sum_{k= \neg \infty}^\infty x[k]h[n-k]</math> <math>y[n] = \sum_{k= \neg \infty}^\infty h[k]x[...)
- 11:20, 16 November 2008 (diff | hist) . . (-5) . . Problem 3 (ECE301Summer2008asan)
- 11:18, 16 November 2008 (diff | hist) . . (+1,583) . . N Problem 3 (ECE301Summer2008asan) (New page: ==Problem 3== (a) Derive the condition for which the discrete time complex exponetial signal x[n] is periodic. <math>x[n] = e^{jw_{o}n}</math> <math>x[n] = x[n+N] = e^{jw_{o}...)
- 11:17, 16 November 2008 (diff | hist) . . (+1,305) . . N Problem 2 (2) (ECE301Summer2008asan) (New page: ==Problem 2 (2)== (A) We first change the form of y[n] that we are given by separating the exponentials and converting the complex exponential using Euler's method. <math> \begin{align...)
- 11:17, 16 November 2008 (diff | hist) . . (+436) . . N Problem 2 (ECE301Summer2008asan) (New page: ==Problem 2== (a) Compute the energy E infinity y[n]=e^2+j4.71235n <n><math>lim</math> from T to -T as T goes to infinity |y[n]|^2 |y[n]|^2= (e^2.e^jw)^2 = e^4.1 = e^4 us...)
- 11:16, 16 November 2008 (diff | hist) . . (0) . . N File:Xofttrans.doc (current)
- 11:16, 16 November 2008 (diff | hist) . . (0) . . N File:X2ofn.doc (current)
- 11:16, 16 November 2008 (diff | hist) . . (0) . . N File:X1ofn.doc (current)
- 11:11, 16 November 2008 (diff | hist) . . (+772) . . N Problem 1 (ECE301Summer2008asan) (New page: ==Problem 1== a) This problem is transformation of the independent variable. The transformation consists of a shift and time scaling. The resulting signal is shifted to the left by 5 and ...)
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