Martinez's Fourier Assignment: Difference between revisions
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Prove that a<sub>3</sub> = 0 for the waveform below: |
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[[Image:Circuit8.png|thumb|400px|center]] |
[[Image:Circuit8.png|thumb|400px|center]] |
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<math>\begin{align} |
<math>\begin{align} |
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a_n &= \frac{2}{T}\int_0^T f(t)\cos(n\omega_0t)\, dt\\ |
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\frac{2\pi}{\omega_0}\ &= 6\\ |
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\therefore \!\,\omega_o &= \frac{pi}{3}\\ |
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a_3 &= \frac{2}{6}\int_0^6 f(t)\cos(3\omega_0t)\, dt\\ |
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a_3 &= \frac{1}{3}[\int_2^3 \cos(\pi*t)\, dt + \int_3^4 \cos(3\omega_ot)\, dt\\ |
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\because \!\, \omega_o &= \frac{pi}{3}\\ |
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a_3 &= \frac{1}{3}[\frac{10}{pi}(sin(3\pi)-sin(2\pi)+\frac{5}{pi}(sin(4\pi)-sin(3\pi)]\\ |
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a_3 &= \frac{1}{3}[\frac{10}{pi}(0)+\frac{5}{pi}(0)]\\ |
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a_3 &= 0\\ |
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\end{align} |
\end{align} |
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Latest revision as of 02:03, 13 December 2010
Prove that a3 = 0 for the waveform below:
<math>\begin{align} T &= 6 seconds\\ a_n &= \frac{2}{T}\int_0^T f(t)\cos(n\omega_0t)\, dt\\ b_n &= \frac{2}{T}\int_0^T f(t)\sin(n\omega_0t)\, dt\\ \frac{2\pi}{\omega_0}\ &= 6\\ \because \!\, T &= 6\\ \therefore \!\,\omega_o &= \frac{pi}{3}\\ a_3 &= \frac{2}{6}\int_0^6 f(t)\cos(3\omega_0t)\, dt\\ a_3 &= \frac{1}{3}[\int_2^3 \cos(\pi*t)\, dt + \int_3^4 \cos(3\omega_ot)\, dt\\ \because \!\, \omega_o &= \frac{pi}{3}\\ a_3 &= \frac{1}{3}[\frac{10}{pi}(sin(3\pi)-sin(2\pi)+\frac{5}{pi}(sin(4\pi)-sin(3\pi)]\\ a_3 &= \frac{1}{3}[\frac{10}{pi}(0)+\frac{5}{pi}(0)]\\ a_3 &= 0\\ \end{align}