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- [[Category:signal]] Compute the power and energy of the signal1,007 B (151 words) - 13:45, 24 February 2015
- ==Power==1 KB (185 words) - 10:12, 2 September 2008
- == Signal == We will compute the Power and Energy of a 440HZ sin wave, also known as an "A".917 B (143 words) - 09:29, 4 September 2008
- == Signal Energy == == Signal Power ==650 B (86 words) - 06:49, 3 September 2008
- The function that we are using in this example to compute the signal power and energy is: == Power Calculation ==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. == Power ==1 KB (206 words) - 08:36, 4 September 2008
- This page calculates the Energy and Power of the signal <math>2\sin(t)\cos(t)</math> ==Power==1 KB (221 words) - 08:17, 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
- == 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
- == Power == 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
- == Power ==668 B (104 words) - 15:05, 4 September 2008
- == Energy of a Signal== == Power of a Signal ==536 B (79 words) - 15:09, 4 September 2008
- [[Category:signal]] Given complex signal <math>f(t) = \cos(t) + j \sin(t)</math>, find <math>E_\infty</math> and <ma4 KB (734 words) - 15:54, 25 February 2015
- For a continuous-time signal <br> ...m_{T \to \infty} {\frac{E(\infty)}{2T}} = 0 ................ Finite-energy Signal</math><br>647 B (89 words) - 21:00, 4 September 2008
- Computation of Signal Energy and power. Source for definition Of Continuous Signal: Wikipedia.778 B (99 words) - 13:21, 5 September 2008
- == Signal == == Average Power ==1 KB (189 words) - 21:40, 4 September 2008
- Compute the energy and the power of the function A time shift should not effect the energy or power of periodic function over one period (0 to 2<math>\pi</math> in this case).1 KB (169 words) - 18:20, 5 November 2010
- The formula for the energy of this signal is given by: == Power ==267 B (48 words) - 07:53, 5 September 2008
- Consider the signal == Average Power ==747 B (114 words) - 14:19, 5 September 2008
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740 B (105 words) - 18:58, 5 September 2008
- The energy of a signal can by computed by the following Energy formula: on the other hand, power of a signal can be calculated by:574 B (92 words) - 18:37, 5 September 2008
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103 B (18 words) - 15:29, 15 October 2008
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101 B (18 words) - 15:32, 15 October 2008
- [[Category:signal]] =Continuous-Time (Average) Signal Power=1 KB (220 words) - 10:49, 21 April 2015
- [[Category:power]] [[Category:signal]]4 KB (595 words) - 11:01, 21 April 2015
- Topic: Signal Energy and Power ...</math> and the power <math>P_\infty</math> of the following discrete-time signal2 KB (317 words) - 16:18, 26 November 2013
- [[Category:power]] [[Category:signal]]2 KB (373 words) - 10:09, 22 January 2018
- [[Category:power]] [[Category: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
- ##[[Signal Energy and Power_(ECE301Summer2008asan)|Signal Energy and Power]] ...CT signal by its samples:_(ECE301Summer2008asan)| Representation of a CT signal by its samples]]7 KB (921 words) - 06:08, 21 October 2011
- :[[2015_Spring_ECE_438_Ersoy|ECE438: "Digital SIgnal Processing", Prof. Ersoy]] :[[2014_Fall_ECE_438_Boutin|ECE438: "Digital SIgnal Processing"]]13 KB (1,570 words) - 13:53, 7 August 2018
- *[[lecture1_ECE301Fall2008mboutin|Lecture 1]]: Intro; Example of DT signal (text) and system (enigma machine). *[[Lecture2_ECE301Fall2008mboutin|Lecture 2]]: Example of CT signal (sound); Creating sounds in Matlab; Example of linear system.5 KB (720 words) - 06:10, 16 September 2013
- *<math>\omega_m</math>: Maximum frequency in a band-limited signal (<math> = max(\{|w|\ :\ w \neq 0\})</math> ...hen the band-limited signal can be uniquely reconstructed from the sampled signal.2 KB (406 words) - 11:08, 12 November 2010
- [[Category:signal processing]] <li>Signal Characteristics</li>3 KB (508 words) - 06:43, 16 September 2013
- ...Power of a Signal over an infinite interval_ECE301Fall2008mboutin]] {{:CT Power of a Signal_ECE301Fall2008mboutin}}8 KB (989 words) - 07:20, 5 February 2009
- ...is is an advanced capture, process and display technology which enables RF signal analysis never before possible. Featured capabilities, discussed and demons *Display of RF signals normally invisible beneath higher power signals967 B (123 words) - 12:47, 5 February 2009
- ==Energy and Power == * [[HW1.5 Adrian Delancy - Energy and Power Calculations for Signals_ECE301Fall2008mboutin]]24 KB (3,272 words) - 06:58, 1 September 2010
- [[Category:signal]] Compute the power and energy of the signal1,007 B (151 words) - 13:45, 24 February 2015
- == Signal == We will compute the Power and Energy of a 440HZ sin wave, also known as an "A".917 B (143 words) - 09:29, 4 September 2008
- == Signal == == Average Power ==1 KB (193 words) - 13:29, 2 September 2008
- == Signal == ==Power==945 B (160 words) - 16:01, 3 September 2008
- == Signal Energy == == Signal Power ==650 B (86 words) - 06:49, 3 September 2008
- The signal is: x(t) = 2cos(2t) == Average Power ==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: == Power Calculation ==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. == Power ==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. == Power ==1 KB (240 words) - 08:03, 4 September 2008
- This page calculates the Energy and Power of the signal <math>2\sin(t)\cos(t)</math> ==Power==1 KB (221 words) - 08:17, 4 September 2008
- Let us find the energy and average power of a signal <math>x(t) = 5e^{5t}</math> for the time interval [0,5] ==Average Power==739 B (117 words) - 10:12, 4 September 2008
- == Energy and Power == The following is the energy 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 == == Power ==888 B (154 words) - 10:47, 4 September 2008
- == Signal == == Power ==888 B (154 words) - 10:48, 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
- == 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
- Compute the Energy and Power of the signal <math>x(t)=\dfrac{2t}{t^2+5}</math> between 3 and 5 seconds. ==Power==966 B (143 words) - 14:42, 4 September 2008
- == Power == 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
- ==Signal Energy and Power== Define a signal (either CT or DT) and compute its energy and its power. Post your answer on Rhea. Give your page a descriptive title.2 KB (248 words) - 13:04, 5 September 2008
- Energy of a Signal: <math>E = {1\over(t2-t1)}\int_{t_1}^{t_2} \! |f(t)|^2 dt</math> Power of a Signal: <math>P = \int_{t_1}^{t_2} \! |f(t)|^2\ dt</math>896 B (142 words) - 16:54, 4 September 2008
- I will calculate the energy expended by the signal <math>sin(2t)</math> from <math> t = 0 </math> to <math> t = 8\pi </math> - ==Power==819 B (140 words) - 17:25, 4 September 2008
- Suppose a signal is defined by <math>cos(t)</math> Suppose we want to compute the energy of the signal <math>cos(t)</math> in the interval <math>0</math> to <math>2\pi</math>.1 KB (199 words) - 20:14, 4 September 2008
- '''''I chose to compute the energy and power for the signal f(t) = 3x.''''' ==Power==574 B (97 words) - 05:11, 5 September 2008
- == Signal energy == == Signal power ==726 B (122 words) - 20:45, 4 September 2008
- Computation of Signal Energy and power. Source for definition Of Continuous Signal: Wikipedia.778 B (99 words) - 13:21, 5 September 2008
- == Signal == == Average Power ==1 KB (189 words) - 21:40, 4 September 2008
- ==Signal== ==Power==1 KB (204 words) - 22:14, 4 September 2008
- == Signal Energy == Signal Energy expended from <math>t_1\!</math> to <math>t_2\!</math> for CT functi2 KB (295 words) - 06:34, 5 September 2008
- == For a Continuous Time Signal== Average power in time interval from [<math>t_{1},t_{2} </math>]:788 B (127 words) - 12:34, 5 September 2008
- Compute the Energy and Power of the signal <math>x(t)=\dfrac{2t}{t^2+5}</math> between 0 and 2 seconds. ==Power==811 B (121 words) - 07:08, 5 September 2008
- ==Energy of a CT signal== ==Power of a CT signal==324 B (62 words) - 07:39, 5 September 2008
- The formula for the energy of this signal is given by: == Power ==267 B (48 words) - 07:53, 5 September 2008
- == The following signals are shown to be either an energy signal or a power signal == therefore x(t) is an energy function because the energy is finite, and not a power function.536 B (94 words) - 08:24, 5 September 2008
- == Signal Energy == find the signal energy of <math>x(t)=e^{4t}\!</math> on <math>[0,1]\!</math>700 B (110 words) - 08:53, 5 September 2008
- Given the Signal x(t) = 4sin(2 * pi * 6t), Find the energy and power of the signal from 2 to 6 seconds. == Power ==1 KB (193 words) - 09:32, 5 September 2008
- =Signal Power= The average power over an interval of time <math>[t_1,t_2]\!</math> is <math>P_{avg}=\frac{1}722 B (108 words) - 10:47, 5 September 2008
- == Energy and Power == The energy and power of a signal can be found through the use of basic calculus.552 B (84 words) - 12:42, 5 September 2008
- Consider the signal == Average Power ==747 B (114 words) - 14:19, 5 September 2008
- The signal is f(t) = sin(t) and t1=0 and t2=2pi Therefore for our signal:1,005 B (178 words) - 14:45, 5 September 2008
- == Signal == == Power ==603 B (94 words) - 14:51, 5 September 2008
- ==Energy of a signal== Consider the signal <math>\ y = \sin(t)</math>841 B (130 words) - 15:58, 5 September 2008
- The energy expanded from a time t1 to a time t2 in a CT signal is calculated by The power over a time period t1 to t2 is calculated by1,016 B (167 words) - 15:48, 5 September 2008
- ==Signal Energy and Power==339 B (38 words) - 18:19, 5 September 2008
- == Signal Energy == ==Signal Energy Example==601 B (94 words) - 18:35, 5 September 2008
- The energy of a signal can by computed by the following Energy formula: on the other hand, power of a signal can be calculated by:574 B (92 words) - 18:32, 5 September 2008
- The energy of a signal can by computed by the following Energy formula: on the other hand, power of a signal can be calculated by:574 B (92 words) - 18:37, 5 September 2008
- Compute the energy and power of a CT signal <math>y=2e^t</math> from (0,10) ===Power===596 B (90 words) - 18:57, 5 September 2008
- =Parte Dos - Make a Periodic Signal from Non-periodic Source= y1 = power(t1, 3);1 KB (217 words) - 08:58, 12 September 2008
- ===Signal power and energy === ...008mboutin| Example of how to take the Fourier transform of a non-periodic signal]]2 KB (243 words) - 08:04, 21 November 2008
- Suppose a DT signal x[n] satisfies 4. x[n] has minimum power among all signals that satisfy 1,2,3.672 B (117 words) - 13:08, 25 September 2008
- == Guess the signal == 4. <math>x[n]\,</math> has a minimum power among all signals that satisfy rules 1-31 KB (203 words) - 16:00, 25 September 2008
- ==Guess Signal== The signal is DT periodic with period of 4938 B (182 words) - 07:09, 26 September 2008
- Suppose a DT signal satisfies the following properties: 4)x[n] has minimum power among all signals that satisfy the above properties.2 KB (426 words) - 15:21, 26 September 2008
- We have a DT signal x[n] such that: 4. x[n] has minimum power among all signals that satisfy 1,2,3.719 B (121 words) - 16:44, 26 September 2008
- Suppose we are given the following information about a signal x(t): Two signals that would satisfy these coniditions is the input signal992 B (159 words) - 18:33, 26 September 2008
- Guessing the periodic signal: 4.x[n] has minimum power among all the signals that satisfy 1,2,3.994 B (178 words) - 18:44, 26 September 2008
- ===Guessing The Periodic Signal=== 4. x[n] has minimum power among all the signals that satisfy 1,2,31 KB (186 words) - 20:38, 26 September 2008
- ...r can always operate at peak power and any disruptions to or fading of the signal can be corrected at the receiver. However, frequency modulation will in mos Begin with a signal:1 KB (195 words) - 18:21, 17 November 2008
- |ee??? || CS-2 || (CS-1) || (Digital) Signal Processing | ? || ES-3 || ? || Power Electronics and Electric Drives2 KB (279 words) - 23:00, 9 March 2008
- [[Category:signal]] Compute the energy and the average power of the following signal:6 KB (975 words) - 15:35, 25 February 2015
- =Example of computation of Signal energy and Signal Power =2 KB (276 words) - 10:09, 16 September 2013
- [[Category:signal]] ...ath>E_\infty</math> and the average power <math>P_\infty</math> for the CT signal2 KB (408 words) - 17:20, 25 February 2015
- [[Category:signal]] ...ath>E_\infty</math> and the average power <math>P_\infty</math> for the CT signal1 KB (241 words) - 17:06, 25 February 2015
- [[Category:signal]] ...ath>E_\infty</math> and the average power <math>P_\infty</math> for the CT signal2 KB (415 words) - 17:05, 25 February 2015
- [[Category:signal]] ...ath>E_\infty</math> and the average power <math>P_\infty</math> for the CT signal3 KB (432 words) - 17:55, 25 February 2015
- * Signal properties (even/odd, periodicity, power, energy, etc.)5 KB (643 words) - 11:55, 6 August 2009
- *[[SignalMetricsFormula|Signal Metrics Definitions and Formulas]] (used in [[ECE301]], [[ECE438]]) *[[PowerSeriesFormulas|Power Series]] (used in [[ECE301]], [[ECE438]])3 KB (294 words) - 15:44, 12 March 2015
- keywords: energy, power, signal '''Signal Metrics Definitions and Formulas'''2 KB (307 words) - 14:54, 25 February 2015
- ...ignals_ECE301S11|Compute the norm of a continuous-time complex exponential signal (practice problem)]] from [[ECE301]] ..._signals_ECE301S11|Compute the norm of a discrete-time complex exponential signal (practice problem)]] from [[ECE301]]2 KB (293 words) - 05:21, 3 November 2011
- ...ler's formula to compute the norm of a continuous-time complex exponential signal (practice problem)]] from [[ECE301]] ...Euler's formula to compute the norm of a discrete-time complex exponential signal (practice problem)]] from [[ECE301]]2 KB (249 words) - 18:27, 23 February 2015
- ...we approximate as an analog signal. It is our goal to change this analog signal into a digital so that we can perform various forms of processing on it. * Since phonemes are the smallest block of a speech signal, it is no surprise that they form the basis for speech analysis.5 KB (841 words) - 15:26, 10 April 2013
- [[Category:Digital Signal Processing]] 1) avg power2 KB (390 words) - 07:46, 14 November 2011
- [[Category:Digital Signal Processing]] 1) avg power2 KB (387 words) - 07:47, 14 November 2011
- ...r factor correction, and maximum power transfer. Instantaneous and average power. <br/><br/> ...ty to define and explain the meaning/function of charge, current, voltage, power, energy, R, L, C, the op amp, and the fundamental principles of Ohm's law,6 KB (873 words) - 17:02, 15 April 2013
- ...computation|A collective page to practice computing Fourier series of a CT signal]] ...putation_DT|A collective page to practice computing Fourier series of a DT signal]]2 KB (211 words) - 05:39, 26 September 2011
- ...d a straightforward procedure for computing it using [[PowerSeriesFormulas|power series]]. If you do not feel completely comfortable with the geometric seri ...nesday. It basically consists in computing the inverse z-transforms of the signal you used in [[Hw2ECE38F10|HW2]] and in doing the peer review of [[Hw2ECE38F2 KB (249 words) - 12:30, 8 September 2010
- ...tal_signal_processing_practice_problems_list|Practice Question on "Digital Signal Processing"]]''' (On Computing the DFT of a discrete-time periodic signal.)5 KB (766 words) - 14:22, 21 April 2013
- ...tal_signal_processing_practice_problems_list|Practice Question on "Digital Signal Processing"]]''' ...using either the Taylor series formula or a [[PowerSeriesFormulas|table of power series formulas]].2 KB (273 words) - 12:49, 26 November 2013
- [[Category:signal]] keywords:signal energy, exercises1 KB (207 words) - 16:04, 25 February 2015
- [[Category:signal]] =Continuous-Time (Average) Signal Power=1 KB (220 words) - 10:49, 21 April 2015
- ...[Complex Exponential and Sinusoidal Amplitude Modulation|videos explaining signal modulation]]! ...problems to practice CT convlution, and two problems for practicing basic signal's properties. -pm18 KB (2,485 words) - 10:36, 11 November 2011
- ...for a DT signal) and discussed the kind of questions related to energy and power one could expect on the test. We continued with a description of the three * Solve the following practice problems on signal power and energy. (This should be very quick!)2 KB (254 words) - 13:24, 31 January 2011
- [[Category:power]] [[Category:signal]]4 KB (595 words) - 11:01, 21 April 2015
- Topic: Signal Energy and Power ...</math> and the power <math>P_\infty</math> of the following discrete-time signal2 KB (317 words) - 16:18, 26 November 2013
- Compute the energy <math class="inline">E_\infty</math> and the power <math class="inline">P_\infty</math> of the following signals. Prove that, for any DT signal x[n], we have3 KB (478 words) - 05:17, 25 January 2011
- ...signal has '''finite energy''', then we expect that it has '''zero average power'''.<br><br> b) ...he signal has '''infinite energy''', then we expect that it has '''average power that is greater than zero'''.<br><br> c)9 KB (1,579 words) - 16:57, 15 February 2011
- *[[PowerSeriesFormulas|Power Series]] *[[SignalMetricsFormula|Signal Metrics Definitions and Formulas]]890 B (101 words) - 17:30, 21 April 2013
- *Signal [[Signal_power_CT|Power]] and [[Signal_energy_CT|Energy]] in CT **[[Signal power energy exercise CT ECE301S18 exponential|Compute the power and energy of a (CT) exponential]]12 KB (1,768 words) - 10:25, 22 January 2018
- ...e picture, drawn by Scott, there is a bit to signal a right turn, a bit to signal a left turn, and two bits to designate the turn speed. The other four bits ...as causing even just the monitor display to take 20% of the CPU processing power. I tried to play some test *.mpg videos in VLC which didn't even play. Some33 KB (5,764 words) - 11:55, 10 December 2011
- ...e concluded that using the formula essentially boils down to comparing the power series of the z-transform with the formula for the z-transform (the trick w [[Category:signal processing]]1 KB (192 words) - 06:20, 11 September 2013