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- ...e and unit step functions_(ECE301Summer2008asan)|The unit impulse and unit step functions]] ##[[Unit step response of an LTI system_(ECE301Summer2008asan)|Unit step response of an LTI system]]7 KB (921 words) - 06:08, 21 October 2011
- [[Category: Unit Step Response]] ...nswers. One in paticular, c=0, appears to give better results for the step response...please see attached for explanation of what I am talking about...2 KB (379 words) - 08:35, 9 March 2011
- Fourier Transforms and the frequency response of a system. The frequency response has a fundamental relationship to the unit step response through Fourier Transforms as follows3 KB (449 words) - 17:07, 8 October 2008
- An LTI system has unit impulse response <math> h[n] = u[-n] </math> Compute the system's response to the input <math> x[n] = 2^{n}u[-n] </math>907 B (154 words) - 10:57, 12 October 2008
- ...Compute (a) the system's function <math>H(z)</math> and (b) the system's response to the input <math>x[n]=\cos(\pi n)</math>. <math>H(z)=1+\frac{1}{z}</math> due to the two step functions.680 B (127 words) - 03:59, 15 October 2008
- ...rier transform. The explanation is crystal clear and logical. No important step is missing. This deserves a perfect score! --[[User:Mboutin|Mboutin]] 09:14 ...thcal{F}((a)^n u[n]) = \frac{1}{1-a}, a<0 \,</math>, thus the unit impulse response for <math>\mathcal{X}(\omega)\,</math> is11 KB (1,951 words) - 03:48, 25 March 2011
- :(b) an ability to determine the impulse response of a differential or difference equation. [1,2;a] :(c) an ability to determine the response of linear systems to any input signal convolution in the time domain. [1,2,7 KB (1,017 words) - 10:05, 11 December 2008
- ##[[The unit impulse and unit step functions_Old Kiwi]] ##[[Unit step response of an LTI system_Old Kiwi]]4 KB (531 words) - 11:32, 25 July 2008
- ...urce transformation; Thevenin's and Norton's theorems; superposition. Step response of 1st order (RC, RL) and 2nd order (RLC) circuits. Phasor analysis, impeda iv. an ability to qualitatively predict and compute the step responses of first order (RL and RC) and second order (RLC) circuits.<br/>6 KB (873 words) - 17:02, 15 April 2013
- ...t),</math> where <math class="inline">u\left(t\right)</math> is the unit step function and <math class="inline">T>0</math> .14 KB (2,358 words) - 08:31, 27 June 2012
- ...le definitions, such as sine or complex exponential. However, for the unit step and impulse functions, the author goes into a lot of detail. A lot more of The chapter begins with a discussion of the unit impulse response, along with some quite good examples, then quickly moves on to the convolut5 KB (854 words) - 10:53, 6 May 2012
- ...t),</math> where <math class="inline">u\left(t\right)</math> is the unit step function and <math class="inline">T>0</math> .5 KB (735 words) - 01:17, 10 March 2015
- ...t),</math> where <math class="inline">u\left(t\right)</math> is the unit step function and <math class="inline">T>0</math> .6 KB (1,002 words) - 01:38, 10 March 2015
