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- [[Category:signal processing]] ''' [[ECE438| ECE438: Digital Signal Processing with Applications]]'''2 KB (189 words) - 08:26, 11 November 2013
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34 B (7 words) - 07:18, 13 December 2013
- [[Category:signal processing]] ''' [[ECE438| ECE438: Digital Signal Processing with Applications]]'''1 KB (134 words) - 09:12, 19 August 2019
- [[Category:signal processing]] ''' [[ECE438| ECE438: Digital Signal Processing with Applications]]'''6 KB (759 words) - 08:10, 11 November 2013
- [[Category:signal processing]] ''' [[ECE438| ECE438: Digital Signal Processing with Applications]]'''1,002 B (119 words) - 05:58, 28 October 2013
- [[Category:signal processing]] ''' [[ECE438| ECE438: Digital Signal Processing with Applications]]'''4 KB (471 words) - 19:34, 9 February 2015
- [[Category:signal processing]]706 B (95 words) - 11:20, 14 October 2014
- '''The [http://mireilleboutin.com Boutin] Lectures on Digital Signal Processing - Part 1''' ...cy domain view of the relationship between a signal and a sampling of that signal. ==3 KB (409 words) - 15:48, 24 March 2015
- [[Category:signal processing]] ''' [[ECE438| ECE438: Digital Signal Processing with Applications]]'''3 KB (389 words) - 19:26, 16 March 2015
- ...015_Fall_ECE_438_Boutin_Digital Signal Processing With Application|Digital Signal Processing With Application]] ...015_Fall_ECE_438_Boutin_Digital Signal Processing With Application|Digital Signal Processing With Application]]. Please leave me a comment below if you have914 B (125 words) - 03:39, 29 November 2015
- <center><font size= 4>Digital Signal Processing With Application</font size> ...value) of two different transmitted frequencies component in the received signal.3 KB (417 words) - 04:38, 29 November 2015
- [[Category:signal]] [[Category:continuous-time signal]]2 KB (373 words) - 10:09, 22 January 2018
- [[Category:signal]] [[Category:continuous-time signal]]2 KB (229 words) - 10:22, 22 January 2018
- Topic: Signal Energy and Power ...</math> and the power <math>P_\infty</math> of the following discrete-time signal2 KB (263 words) - 11:13, 22 January 2018
- ...nfty</math> and the power <math class="inline">P_\infty</math> of this DT signal: Norm of a signal:1 KB (196 words) - 19:39, 1 December 2018
- Compute the energy and the power of the CT sinusoidal signal below:1 KB (178 words) - 19:48, 1 December 2018
Page text matches
- ...Fourier transform of x[n], which is the sampled signal of continuous time signal x(t) <br>546 B (93 words) - 20:27, 18 February 2009
- [[Category:signal processing]]769 B (105 words) - 06:44, 16 September 2013
- ...ng: when you upsample after having downsampled, you introduce zeros in the signal that were not previously there. To undo a downsampling, you have to use an2 KB (383 words) - 21:03, 10 February 2009
- ...at starts at -1e-4 and goes to 1e-4. The ideal sampler creates a discrete signal with 5 points each 5e-5 apart.844 B (152 words) - 18:26, 11 February 2009
- ...e relationship between the FT of a signal and the FT of a sampling of that signal. Anybdy sees a mistake? Perhaps one can rewrite this so it becomes a bit cl2 KB (374 words) - 12:35, 17 February 2009
- *Basic properties of signal and systems <li>Don't forget the different signal's metrics! --[[User:Mboutin|Mboutin]] 16:15, 17 February 2009 (UTC)</li>710 B (115 words) - 14:35, 17 February 2009
- [[Category:signal processing]] <p>use DFT to approximate <math>X(a)</math> for a DT signal x(n)2 KB (376 words) - 06:44, 16 September 2013
- ...o union between the ROCs, then it's null such that there is no ROC for the signal --[[User:Mlo|Mlo]] 15:18, 24 February 2009 (UTC)549 B (90 words) - 08:37, 26 February 2009
- ...rect in time. In frequency, this is multiplication of the spectrum of the signal with the spectrum of the rect (which is a sinc). This is effectively a coa906 B (143 words) - 12:40, 4 March 2009
- [[Category:signal processing]]3 KB (522 words) - 06:45, 16 September 2013
- ** Signal Processing258 B (29 words) - 08:56, 27 March 2009
- [[Category:signal processing]]2 KB (324 words) - 06:45, 16 September 2013
- Note: PM refers to the official course book, Digital Signal Processing, 3rd edition, J.G. Proakis and D.G. Manolakis. ...due.edu/~bouman/ece438/lecture/module_1/1.1_signals/1.1.1_signal_types.pdf Signal Types]8 KB (1,226 words) - 11:40, 1 May 2009
- :[[ECE438|ECE438: "Digital Signal Processing with Applications"]] *[[ECE438|ECE 438]]: "Digital Signal Processing with Applications"4 KB (474 words) - 07:08, 4 November 2013
- =Rhea Section for [[ECE438|ECE 438: Digital Signal Processing with Applications]] Professor [[User:mboutin|Boutin]], Fall 20097 KB (1,067 words) - 12:05, 25 June 2010
- * [[HW1.5 Nicholas Browdues - Signal Power and Energy_ECE301Fall2008mboutin]] * [[HW1.5 Ben Laskowski - Signal Power and Energy_ECE301Fall2008mboutin]]24 KB (3,272 words) - 06:58, 1 September 2010
- == Continuous Signal == Continuous signal is a signal that varies with time, and can be represented as a function of time, x(t).2 KB (311 words) - 16:27, 3 December 2008
- %as we replace t with 2t,so double the time in signal function %which also means double the frequency of each signal2 KB (347 words) - 17:52, 3 September 2008
- jpbak=flipud(jp); %reverse the signal544 B (83 words) - 18:34, 1 September 2008
- [[Category:signal]] Compute the power and energy of the signal1,007 B (151 words) - 13:45, 24 February 2015
- == Periodic Signal == Notice, the signal is the same throughout each cycle.481 B (60 words) - 07:15, 14 April 2010
- == Signal ==917 B (143 words) - 09:29, 4 September 2008
- == Signal ==1 KB (193 words) - 13:29, 2 September 2008
- - Signal Processing952 B (163 words) - 13:23, 4 September 2008
- == Signal ==945 B (160 words) - 16:01, 3 September 2008
- Example of Periodic Function since it is a repeated signal every cycle --> Triangle Wave1 KB (171 words) - 06:06, 29 August 2011
- == Signal Energy == == Signal Power ==650 B (86 words) - 06:49, 3 September 2008
- The signal is: x(t) = 2cos(2t)644 B (94 words) - 06:39, 3 September 2008
- The function that we are using in this example to compute the signal power and energy is:1 KB (170 words) - 18:37, 3 September 2008
- ...e Signal <math>x(t)=3sin(2*pi*3t)</math>, Find the energy and power of the signal from 0 to 5 seconds.1 KB (206 words) - 08:36, 4 September 2008
- This page calculates the energy and power of the <math>2\sin(t)\cos(t)</math> signal.1 KB (240 words) - 08:03, 4 September 2008
- A discrete time signal is periodic if there exists T > 0 such that x(t + T) = x(t) A continuous time signal is periodic if there exists some integer N > 0 such that x[n + N] = x[n]1 KB (205 words) - 07:20, 14 April 2010
- This page calculates the Energy and Power of the signal <math>2\sin(t)\cos(t)</math>1 KB (221 words) - 08:17, 4 September 2008
- A continuous time signal is periodic if there exists a value <math> T </math> such that <math> x(t + A discrete time signal is periodic if there exists a value <math> N </math> such that <math> X[n +1 KB (169 words) - 07:22, 14 April 2010
- Let us find the energy and average power of a signal <math>x(t) = 5e^{5t}</math> for the time interval [0,5]739 B (117 words) - 10:12, 4 September 2008
- The following is the energy expended by the signal <math> sin(2t) </math> from <math> t = 0 </math> to <math> t = 4\pi </math> The following is the average power expended by the signal <math> sin(2t) </math> from <math> t = 0 </math> to <math> t = 4\pi </math>897 B (142 words) - 10:00, 4 September 2008
- signal = sin(2*pi * t * NV(i)); sound(signal, 1/delta);1 KB (160 words) - 15:33, 4 September 2008
- == Signal ==888 B (154 words) - 10:47, 4 September 2008
- == Signal ==888 B (154 words) - 10:48, 4 September 2008
- ==Periodic Signal== In discrete time, a signal x[n] is considered a '''periodic signal''' if there exists a natural number N such that for all integers n, x[n+N]2 KB (279 words) - 07:18, 14 April 2010
- %c) Play signal corresponding to the tune of a) and rescale2 KB (329 words) - 14:14, 4 September 2008
- %Take the signal and transform it to y(t)=wave(2t)3 KB (496 words) - 12:53, 4 September 2008
- == Signal Energy == The signal energy expanded from <math>t_1\!</math> to <math>t_2\!</math> is defined as1 KB (172 words) - 13:29, 4 September 2008
- %Changin signal to x[-0.5n]:511 B (91 words) - 16:01, 5 September 2008
- == Signal Energy and Power Calculations == The energy of a signal within specific time limits is defined as:655 B (97 words) - 15:50, 4 September 2008
- == Signal == The signal used was <math>cos(3t)</math>.569 B (88 words) - 13:55, 4 September 2008
- <math>x[n]=</math><math>j^{n}</math> is a discrete time (DT) periodic signal. It's period is 4*k, where k is an integer. However, it's fundamental perio <math>x[n]=\cos{n}</math> is an example of a non-periodoc signal because there is not integer value for n such that <math>x[n+N]=x[n]</math>883 B (143 words) - 07:24, 14 April 2010
- Compute the Energy and Power of the signal <math>x(t)=\dfrac{2t}{t^2+5}</math> between 3 and 5 seconds.966 B (143 words) - 14:42, 4 September 2008
- Power of the equation <math>e^{-2t}u(t)</math> is 0 because the energy of the signal is < ∞329 B (60 words) - 14:39, 4 September 2008
- == Energy of a Signal== == Power of a Signal ==536 B (79 words) - 15:09, 4 September 2008