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  • - [Instructor] For many hundreds of years,

  • mathematicians have been fascinated

  • by the infinite sum, which we would call a series,

  • of one plus 1/2 plus 1/3 plus 1/4,

  • and you just keep adding on and on and on forever.

  • And this is interesting on many layers.

  • One, it just feels like something

  • that would be interesting to explore.

  • It's one over one plus one over two plus one over three,

  • that each of these terms are getting smaller and smaller.

  • They're approaching zero,

  • but when you add them all together,

  • these infinite number of terms,

  • do you get a finite number

  • or does it diverge, do not get a finite number?

  • This also shows up in music

  • and this actually might have been one

  • of the early motivations for studying this series.

  • Where if you have a fundamental note,

  • a fundamental frequency in music,

  • and the point of this video isn't to teach you too much

  • about music, but if you have a fundamental note,

  • that might be a pure A or something like that.

  • I'm just showing you one of its wavelengths.

  • Obviously, you would keep going like that

  • and hit is a hand-drawn version, so it's not perfect.

  • The harmonics are the frequencies, the overtones,

  • that at least to our ear, reinforce that A,

  • and what's true about the harmonics are

  • that they will be 1/2 of the wavelength of A.

  • In which case, it might look something like this.

  • So this would be a harmonic of A.

  • It has half of the wavelength of A and notice,

  • it gets, when it finishes its second full wave form,

  • it ends again right at the same time

  • that the wavelength of A ends.

  • And then it would be another harmonic

  • where it'd be something that has 1/3 the wavelength of an A

  • and a 1/4 of a wavelength of A,

  • and if you look at a lot of musical instruments

  • or what sounds good to our ears,

  • they're playing not just a fundamental tone,

  • but a lot of the harmonics.

  • But anyway, that was a long-winded way

  • of justifying why this is called the harmonic series.

  • Harmonic, harmonic series.

  • And in a future video,

  • we will prove that, and I don't want to ruin the punchline,

  • but this actually diverges,

  • and I will come up with general rules

  • for when things that look like this

  • might converge or diverge,

  • but the harmonic series in particular diverges.

  • So if we were to write it,

  • so in sigma form,

  • we would write it like this.

  • We're going from n equals one to infinity of one over n.

  • Now another interesting thing

  • is well, what if we were to throw in some exponents here?

  • So we already said, and I'll just rewrite it.

  • Doesn't hurt to rewrite it and get more familiar with it.

  • This right over here is the harmonic series.

  • One over one, which is just one

  • plus one over two plus one over three,

  • so on and so forth,

  • but what if we were to raise each of these denominators

  • to say, the second power?

  • So you might have something that looks like this,

  • where you have from n equals one to infinity

  • of one over n to the second power.

  • Well, then it would look like this.

  • It'd be one over one squared, which is one,

  • and we can just write that first term as one,

  • plus one over two squared, which would be 1/4,

  • plus one over three squared, which is 1/9,

  • and then you could go on and on forever.

  • Forever,

  • and then you could generalize it.

  • You could say hey, all right,

  • what if we wanted to have a general class of series

  • that we were to describe like this?

  • Going from n equals one to infinity

  • of one over n to the p,

  • where p could be any exponent.

  • So for example,

  • well the way this would play out

  • is this would be one plus one over two to the p

  • plus one over three to the p

  • plus one over four to the p,

  • and it doesn't just have to be an integer value.

  • It could be, some, p could be 1/2,

  • in which case, you would have one

  • plus one over the square root of two

  • plus one of the square root of three.

  • This entire class of series

  • and of course, harmonic series is a special case

  • where p is equal to one,

  • this is known as p series.

  • So these are known as p series

  • and I try to remember it

  • 'cause it's p for the power

  • that you are raising this denominator to.

  • You could also view it

  • as you're raising the whole expression to it

  • because one to any exponent is still going to be one.

  • But I hinted a little bit

  • that maybe some of these converge and some of these diverge,

  • and we're going to prove it in future videos,

  • but the general principle is

  • if p is greater than one,

  • then we are going to converge.

  • And that makes sense intuitively

  • because that means that the terms are getting smaller

  • and smaller fast enough

  • because the larger the exponent for that denominator,

  • that means that the denominator's going to get bigger faster

  • which means that the fraction is going to get smaller faster

  • and if p is less than or equal to one,

  • and of course, when p is equal to one,

  • we're dealing with the famous harmonic series,

  • that's a situation in which we diverge

  • and we will prove these things in future videos.

- [Instructor] For many hundreds of years,

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B2 中高級

諧波級數和?-級數 | 金剛砂微積分 BC | 可汗學院 (Harmonic series and ?-series | AP®︎ Calculus BC | Khan Academy)

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    林宜悉 發佈於 2021 年 01 月 14 日
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