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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. | 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. | ||
− | Computed- Energy and Power of the signal <math>2\sin(t)\cos(t)</math> | + | Computed- Energy and Power of the signal <font size="4"><math>2\sin(t)\cos(t)</math> |
==Energy== | ==Energy== | ||
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<math>E = {1\over(t2-t1)}\int_{t_1}^{t_2} \! |f(t)|^2 dt</math> | <math>E = {1\over(t2-t1)}\int_{t_1}^{t_2} \! |f(t)|^2 dt</math> | ||
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==Power== | ==Power== | ||
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<math>P = \int_{t_1}^{t_2} \! |f(t)|^2\ dt</math> | <math>P = \int_{t_1}^{t_2} \! |f(t)|^2\ dt</math> | ||
Latest revision as of 13:04, 5 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.
Computed- Energy and Power of the signal $ 2\sin(t)\cos(t) $
Energy
$ E = {1\over(t2-t1)}\int_{t_1}^{t_2} \! |f(t)|^2 dt $
$ E = {1\over(2\pi-0)}\int_{0}^{2\pi} \! |2\sin(t)cos(t)|^2 dt $
$ E = {1\over(2\pi)}\int_{0}^{2\pi} \! |\sin(2t)|^2 dt $
$ E = {1\over(2\pi)}\int_{0}^{2\pi} \! |{(1-\cos(4t))\over 2}| dt $
$ E = {1\over{2\pi}}*{1\over 2}\int_0^{2\pi} \! |1-\cos(4t)| dt $
$ E = {1\over{4\pi}} * [ t - {1\over4}\sin(4t) ]_0^{2\pi} $
$ E = {1\over{4\pi}} * [ 2\pi - {1\over4}\sin(8\pi) - ( 0 - {1\over4}\sin(4\pi*0) ) ] $
$ E = {1\over{4\pi}} * [ 2\pi - {1\over4}\sin(8\pi) ] $
$ E = {1\over{4\pi}} * 2\pi $
$ E = {1\over2} $
Power
$ P = \int_{t_1}^{t_2} \! |f(t)|^2\ dt $
$ P = \int_0^{2\pi} \! |2\sin(t)\cos(t)|^2\ dt $
$ P = \int_0^{2\pi} \! |\sin(2t)|^2\ dt $
$ P = \int_0^{2\pi} \! |{(1-\cos(4t))\over 2}| dt $
$ P = {1\over 2}\int_0^{2\pi} \! |1-\cos(4t)| dt $
$ P = {1\over 2} ( t - {1\over 4}\sin(4t) )\mid_0^{2\pi} $
$ P = {1\over 2}t - {1\over 8}\sin(4t) )\mid_0^{2\pi} $
$ P = {1\over 2}(2\pi) - {1\over 8}\sin(4*2\pi) - [{1\over 2}(0) - {1\over 8}\sin(4*0)] $
$ P = \pi - {1\over8}\sin(8\pi) $
$ P = \pi $