Timeline for Difference between 2$\pi f$ and $\omega$ in Fourier transform
Current License: CC BY-SA 4.0
7 events
| when toggle format | what | by | license | comment | |
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| Oct 19, 2019 at 6:09 | history | edited | Laurent Duval | CC BY-SA 4.0 |
added details
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| Nov 11, 2016 at 0:02 | comment | added | robert bristow-johnson | "in my book" is meant as a figure of speech. | |
| Nov 10, 2016 at 23:57 | comment | added | robert bristow-johnson | i would say, in the "analog case" (more formally, the "continuous-time case") it's $$ \Omega = 2\pi f$$ and in the "digital case" (more formally the "discrete-time case") it's $$ \omega = 2\pi \frac{f}{f_\text{s}} $$ in my book it's $$ s=j \Omega $$ and $$ z = e^{j \omega} $$ | |
| Nov 10, 2016 at 23:56 | history | edited | robert bristow-johnson | CC BY-SA 3.0 |
i don't see why the restriction. and if there was, it's $f \in [0,1)$ and $\omega \in [0,2\pi)$
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| Nov 10, 2016 at 18:25 | history | edited | Peter K.♦ | CC BY-SA 3.0 |
added 5 characters in body
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| Nov 10, 2016 at 17:08 | vote | accept | user137927 | ||
| Nov 10, 2016 at 17:03 | history | answered | Laurent Duval | CC BY-SA 3.0 |