Fourier Transform, Fourier Series, and frequency spectrum

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Guys the whole video is art for anyone who likes to understand math. The music, narration, and animation are all perfect. Plus the channel has many other videos about physics that are worth seeing.

πŸ‘οΈŽ︎ 46 πŸ‘€οΈŽ︎ u/[deleted] πŸ“…οΈŽ︎ Mar 09 2016 πŸ—«︎ replies

My favorite part was at about 14 minutes with shirtless gym shorts guy playing with waves in a sci-fi Roman temple.

πŸ‘οΈŽ︎ 21 πŸ‘€οΈŽ︎ u/NoodlesLongacre πŸ“…οΈŽ︎ Mar 09 2016 πŸ—«︎ replies

...and then it does downhill?

πŸ‘οΈŽ︎ 12 πŸ‘€οΈŽ︎ u/MaxChaplin πŸ“…οΈŽ︎ Mar 09 2016 πŸ—«︎ replies

The whole video is awesome!

If you understand, you can see what constitutes you.

πŸ‘οΈŽ︎ 11 πŸ‘€οΈŽ︎ u/[deleted] πŸ“…οΈŽ︎ Mar 09 2016 πŸ—«︎ replies

Wow that last point was magnificent.

πŸ‘οΈŽ︎ 8 πŸ‘€οΈŽ︎ u/HamletTheHamster πŸ“…οΈŽ︎ Mar 09 2016 πŸ—«︎ replies

Fantastic video. Thanks for sharing

πŸ‘οΈŽ︎ 6 πŸ‘€οΈŽ︎ u/123x2tothe6 πŸ“…οΈŽ︎ Mar 09 2016 πŸ—«︎ replies

I thought the whole video was very well done

Thanks for sharing!

πŸ‘οΈŽ︎ 6 πŸ‘€οΈŽ︎ u/[deleted] πŸ“…οΈŽ︎ Mar 09 2016 πŸ—«︎ replies

This is obviously also very relevant to anyone interested in or working with sound, audio, acoustics or synthesis. Very illuminating, thanks for sharing!

πŸ‘οΈŽ︎ 5 πŸ‘€οΈŽ︎ u/kitsua πŸ“…οΈŽ︎ Mar 09 2016 πŸ—«︎ replies

I feel like this overcomplicates the simple parts of complex analysis and skims over the important, useful parts.

Just eye candy imho

πŸ‘οΈŽ︎ 4 πŸ‘€οΈŽ︎ u/big_al337 πŸ“…οΈŽ︎ Mar 09 2016 πŸ—«︎ replies
Captions
We have an X axis and a Y axis. Let us also create an axis that represents the angle theta. The green line rotates by the angle theta. For each value of theta, the X coordinate represents the cosine of theta, and the Y coordinate represents the sine of theta. The angle theta can range anywhere between negative infinity and positive infinity. This two dimensional pattern is what we refer to as a sine wave. We can change the sine wave’s amplitude, phase, and frequency. Suppose we have two sine waves that are identical except for the fact that they have different amplitudes. If we add these two sine waves together, the result can be represented graphically as shown. Now, suppose that the two sine waves also have different phases. The sum of these two wave forms can be represented graphically like this. So long as the two sine waves have the same frequency, their sum will always be another sine wave of the exact same frequency, but with a different amplitude and phase. Now, suppose that the two sine waves also have a different frequency. If we add together sine waves of different frequencies, then the resultant waveform is no longer a sine wave. We can add together three sine waves. We can add together four sine waves. We can add together five sine waves. In fact, we can add together an infinite number of sine waves. Here, by adding together an infinite number of sine waves, we have produced a pattern that looks like this. Now, let’s add together a different set of sine waves. By adding an infinite number of sine waves, we have produced this other pattern that looks like this. As it turns out, every possible waveform and function in existence can be generated by just adding together different sets of sine waves. In the two examples shown here, the sum of all the sine waves happened to be repeating waveforms. In these cases, only certain frequencies of sine waves were needed, and each of these sine waves had a measurable amplitude. Non-repeating waveforms can also be generated by adding sine waves together, but in these cases, sine waves of every possible frequency may be needed, and each of these sine waves have an amplitude that is infinitely small. When an infinite number of sine waves with infinitely small amplitudes are added together, the result can be a waveform that we can see and measure. This is the same way in which if we add together an infinite number of infinitely thin sheets of paper, although each sheet of paper by itself has zero volume, their combination can be an object with an actual volume that we can see and measure. Some sheets of paper can be larger than others. Although the volume of each sheet of paper by itself is zero, when we have an infinite number of sheets of paper added together, we will be able to measure the object’s density, and the density in some parts of the object will be higher than the density in other parts of the object. Similarly, when we add together an infinite number of sine waves of infinitely small amplitudes, we will be able to measure the density of frequencies, and this density of frequencies will be higher around some frequencies than others. This is what we refer to as the frequency spectrum of a waveform. All signals and waveforms have a frequency spectrum. When signals and waveforms interact with physical objects, their frequency spectrum is altered. By understanding how their frequency spectrums are altered, we can understand how the signals and waveforms are altered. The signals and waveforms that we see in real life have a beginning and an end. However, each of these signals and waveforms can be thought of as the combination of an infinite number of sine waves, and each sine wave has no beginning or ending. It is just that all these sine waves exactly cancel each other out at all times except during the time that the signal is present. Therefore, all signals that we see in real life can be thought of as the combination of an infinite number of sine waves that have always been present since the beginning of time, and which will continue to exist through all eternity. More information about mathematics is available in the other videos on this channel, and please subscribe for notification when new videos are ready.
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Channel: Physics Videos by Eugene Khutoryansky
Views: 2,458,179
Rating: 4.9026794 out of 5
Keywords: Fourier Transform, Fourier Series (Award Discipline), Frequency (Dimension), Spectral Density, Spectrum
Id: r18Gi8lSkfM
Channel Id: undefined
Length: 15min 45sec (945 seconds)
Published: Sun Sep 06 2015
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