For a physics degree? What a fascinating topic. Glad it was helpful!

You need to study Just Intonation and compare it to Pythagorean tuning.

@@TravisTellsTruths there's a lot to study.. like scientific pitch tuning system on a 12 TET temperament too..

Hopefully you spelled it correctly on your paper

So true! I hadn't realised what felt so uncommonly pleasant about this video till I read your comment.

Thanks for watching, Barry!

@@discovermaths My pleasure. Yes you teach well so we can understand. Excellent

(Altho it's a shame that the chart that follows it is upside down)

Thank you!

Thanks, Jane. I'm planning to upload the video on the Pythagorean comma tomorrow.

That's good to know - thanks for watching.

Same here. Finally some clarity!

Many thanks, QF. Yes, these are topics I'd been planning to cover.

Thank you!

Are you THE Andrew Barker, author of "The Science of Harmonics in Classical Greece?" If so I'm a big fan!

@@Hazuls Sorry. It's not me.

I'm very happy it was useful, Liliana - thank you!

Thanks, Mike. I'm glad it was helpful.

Just checked comments to see if somebody already pointed to this. Thak you.

Perfect pitch is out of tune!

*I think you might need to add a video explaining how the frequency manipulation of going up/down intervals in the second half of the video is related inversely to the string lengths of the notes in the first part of the video.* All sound waves you produce with an instrument travel at the same speed: the speed of sound, which is approximately 343 m·Hz. Since the speed is a non-changing quantity, a constant, there must be some mathematical relationship describing why, and there is. The mathematical relationship is v = λ·f. v is the speed of the sound waves. f is the frequency of the sound waves, and λ is the length of the string producing the sound waves. Since v is a constant, λ and f are inversely proportional. *Also, need to explain why constructing this scale using fifths produces notes that sound "consonant" together to create chords.* Modern chords in Pythagorean tuning are not consonant. The perfect unison, the perfect octave, the perfect fifth, the perfect fourth, the major second, and the minor seventh, are the only consonant intervals in Pythagorean tuning. Notably, the Pythagorean thirds and sixths are more dissonant than their juster, Ptolemic counterparts. The reason Pythagorean tuning sounded well to the Pythagoreans is because they used quartal harmony (if any), not tertial harmany as we did in medieval times and later. The reason the perfect fifth is such a perfect consonance is because 3/2 is the simplest ratio of frequencies after 2, and 4/3 is merely its octave complement.

Thank you!

Yes, I do plan to do one on just intonation in the near future to complement the ones on Pythagorean tuning and equal temperament,

256 is not a perfect number. By definition, a perfect number n is a natural number n such that n = σ(1, n) - n, where σ(1, n) the sum of the positive divisors of n. 256 = 2^8, and thus, does not satisfy this equation, since the set of positive divisors is {1, 2, 2^2, 2^3, 2^4, 2^5, 2^6, 2^7, 2^8}, so σ(1, 256) = 1 + 2 + 2^2 + 2^3 + 2^4 + 2^5 + 2^6 + 2^7 + 2^8 = (2^9 - 1)/(2 - 1) = 2^9 - 1, so σ(1, 256) - 256 = 2^9 - 1 - 2^8 = 2^8 - 1, which is not equal to 2^8, though it is as close as it possibly could be. So 256 is called a quasi-perfect number. That being said, this is all irrelevant. The numerical part of 256 Hz is 256 only when the unit of choice is Hz. However, if the unit of choice is 1/hr or anything else, the numerical part will change accordingly. There is nothing special about this frequency in the context of music theory. It is true however, that the ratio from A to C in Pythagorean tuning is 27/16, and 256 Hz·27/16 = 432 Hz. The problem is that it is very unlikely Pythagoras would have cared about the exact frequency of what we call A, and it is very unlikely he would have gone out of his way to choose its frequency to be 432 Hz. Finally, I end this by saying that I understand that there is a nonzero probability that this comment is a joke. Nonetheless, I know of way too many people that seriously believe in the nonsense that A = 432 Hz in Pythagorean tuning is some sort of objectively superior tuning to all others, and it is something that needs addressing.

The sacred number in music comes from the ratios, not the frequency.

I don't think Pythagoras would care about the actual pitches measured in hz.

Any well-temperament that is not an equal temperament does that.

i have the same question!!

Hi Ronda. That's on my "to do" list some time in the next few months. Thanks for watching and I'm glad they're proving useful.

I have the same question (I think!). Why break away from the formula followed thus far? Why go up a fourth from C rather than up a fifth (and back an octave if necessary) from the last note? I notice that you posted this comment a year ago. Have you found an explanation since then? If so, I'd be very grateful if you could share it with me! :)

i don't think its been created, even I was looking for it

Excellent idea, Dan. In fact, I've gone a step further and supplied links to all of my music theory videos in the comments below each music video. (I'll have to give your point about guitar tuning some thought - perhaps in another video!)

Guitars did not exist during the time of Pythagoreans. Also, the perfect fourth is the octave complement of the perfect fifth. You _cannot_ have perfect fourths without perfect fifths.

Pythagorean tuning, as explained in the video (which I assume you did not watch, based on your comment), is a tuning system where all musical intervals allowed are constructed from only perfect octaves (ratio 2) and perfect fifths (ratio 3/2). The ratio 10/9 cannot be constructed from only perfect octaves and perfect fifths, so its corresponding interval does not exist in Pythagorean tuning. It does exist, however, in Ptolemic tuning.

@@angelmendez-rivera351 I knew that 10/9 2nd does not occur in Pythagorean tuning but did not know there exist another tuning that has that. Thanks for the info I'll look it up. But if you can experiment a bit, I would suggest do try mixing 10/9 4/3 and 5/3, they go well with each other. 10/9 and 3/2 are dissonant.

@@siddheshdeshpande7183 The interval between a perfect fifth (3/2) and a major second (10/9) has a ratio (3/2)/(10/9) = 27/20, and so the interval is an acute fourth. You obtain the same interval if you add a syntonic comma (81/80), which I call an acute unison, to a perfect fourth (4/3), since 4/3·81/80 = 27/20. The acute fourth is a dissonant interval indeed.

@@angelmendez-rivera351 I am relieved that you agree that 10/9 and 3/2 are dissonant, I came to know this through my teacher and of course through the experience of listening. Don't really understand the terms guess I have to do a bit more research, appreciate the mathematical explanation though. Cheers!

@@siddheshdeshpande7183 Ptolemic tuning is a system of just intonation where you only use three intervals to construct all the other tuning intervals. The three intervals you use are the perfect octave (ratio 2), the perfect fifth (ratio 3/2), and the major third (ratio 5/4). This system has some peculiar things you have to be very careful about, though. The interval between the perfect fifth and the perfect fourth (ratio 4/3) is the interval with ratio 9/8. However, the interval between the perfect fourth and the minor third (ratio 6/5) is the interval with ratio 10/9. Both of these intervals are seconds, and furthermore, it appears both of these should be called the major second. Yet they are different intervals, the difference between them is the acute unison (ratio 81/80), which while very small, is still audible, and can make certain intervals sound out of tune. How do we know which one is truly the major second? We think of a major second as being half of a major third. For example, in 12-EDO, a major second is equal to 2 steps of 100 cents, and the major third is equal to 4 steps of 100 cents. So which of 9/8 and 10/9 is half of a major third? It turns out, both of them, because 9/8·10/9 = 5/4. In fact, if you want to tune the C major diatonic scale using just intonation, then you need both 9/8 and 10/9 to do so. Since the major sixth is tuned to the ratio 5/3 and the major seventh is tuned to the ratio 15/8, we obtain a scale with degrees tuned to 1, 10/9 or 9/8, 5/4, 4/3, 3/2, 5/3, 15/8, 2. The steps sizes, then, must be 10/9 or 9/8, 9/8 or 10/9 (respectively), 5/4, 16/15, 9/8, 10/9, 9/8, 16/15. There is no possible way to have an equivalent scale with only 2 step sizes. You can decompose every interval that is not a second into only seconds. For example, a major third is an interval of 9/8 plus an interval of 10/9, in any order. A perfect fourth is an interval 10/9 plus one of 16/15 plus one of 9/8, in some order. Why does this matter? Because it severely affects how you combine intervals together into chords, and how you stack them, and it also affects key changes. For example, a perfect fourth has 1 of 9/8, 1 of 10/9, and 1 of 16/15. If, instead, you play 2 of 9/8, and 1 of 16/15, you still have played two major seconds and one minor second, but instead, you now have an acute fourth of 27/20, rather than a perfect fourth of 4/3. It turns out that this also affects the chromatic scale. In the chromatic scale, the scale degrees are the perfect unison (1), the minor second (16/15 ?), the major second (10/9 or 9/8), the minor third (6/5), the major third (5/4), the perfect fourth (4/3), the tritone (25/18 or 45/32 or 64/45 or 36/25), the perfect fifth (3/2), the minor sixth (8/5), the major sixth (5/3), the minor seventh (16/9 or 9/5), the major seventh (15/8), the perfect octave (2). This results in chromatic steps 16/15, 25/24 or 135/108, 27/25 or 16/15 (respectively), 25/24, 16/15, 25/24 or 135/108 or 16/15 or 27/25, 27/25 or 16/15 or 135/108 or 25/24 (respectively), 16/15, 25/24, 16/15 or 27/25, 135/108 or 25/24 (respectively), 16/15. So there are 4 different chromatic steps sizes! The difference between the intervals of ratios 27/25 and 16/15 is 81/80, and the difference between the intervals of ratios 135/108 and 25/24 is also 81/80, the syntonic comma, or acute unison as I call it. Furthermore, the difference between the intervals of ratio 16/15 and 135/108 is this interval with ratio 2048/2025, called a diaschisma, which is approximately equal to a syntonic comma (the difference between the 2 is inaudible). So the smallest chromatic step is 25/24, the second smallest is that plus a syntonic comma, the second largest is the smallest plus approximately 2 syntonic commas, and the largest is the smallest plus approximately 3 syntonic commas. This is suspicious, is it not? The solution to this, quite frankly, is to not use the chromatic scale or diatonic scale we have been using. Instead, it appears as though the fundamental step size is, well, the syntonic comma itself, or at least some interval that is very close to it. There is a good reason to think this as well. We already have related the different chromatic steps to each other in terms of syntonic commas and diaschismas, and the diaschisma is indistinguishable, auditively speaking, from the syntonic comma. In fact, (16/15)/(25/24) = (16/5)/(25/8) = 128/125, and this is the ratio for the diminished second. The difference between a syntonic comma and a diminished second is a diaschisma, so the diminished second is indistinguishable from 2 syntonic comma steps. Furthermore, the difference between an augmented unison and 3 syntonic commas is equal to the intervallic ratio 1600000/1594323 = 2^9·5^5/3^13, whose interval is called an Amity comma, an interval much smaller than the syntinic comma that is barely inaudible. The syntonic comma and diaschisma differ by an inaudible interval called the schisma, with ratio (3^8·5)/2^15, and an Amity comma differs from 3 schismas by a ratio of 2^54·5^2/3^37, a ratio so tiny it is not worth talking about. As such, we have that the augmented unison is equal to 3 syntonic commas plus an Amity comma, which is approximately equal to 3 schismas. A Pythagorean comma (3^12/2^19) is equal to a syntonic comma plus a schisma. Thus, the augmented unison is almost exactly equal to the augmented unison, and the difference is the inaudible comma of ratio 2^54·5^2/3^37. The difference between the Pythagorean comma and the syntonic comma is inaudible, so we can actually almost treat them as the same interval, and treat them as the step size of the scale we must work with. I said "almost," because there is one detail that still needs to be taken care of. 12 perfect fifths approximate 7 octaves, with the difference being exactly one Pythagorean comma. This is actually the definition of the Pythagorean comma. On the other hand, 53 perfect fifths approximate 31 octaves even better, with the difference being exactly one Mercator comma (3^53/2^84), and 53 Pythagorean commas minus 12 Mercator commas are exactly equal to 1 octave. Therefore, 53 syntonic commas plus the error of 53 schismas minus 12 Mercator commas is exactly equal to 1 octave. The problem is that 53 schismas minus 12 Mercator commas is quite a large comma, and minus 12 Mercator commas by themselves are also a large negative comma. So we need to find the correct number of schismas from which to subtract 12 Mercator commas to minimize the error. That number is 22. This means the smallest error possible is with 22 schismas minus 12 Mercator commas, which means we have a 53-step scale, where 31 of the steps are Pythagorean commas, and 22 of the steps are syntonic commas. This gives a scale that is almost identical to 53-EDO. This is would be the correct scale for dealing with just intonation, and this is the scale where you can make most sense of chords and harmony with just intonation.

He didn't. The Pythagoreans would have just used relative pitch. That figure is based on our modern tuning system.

No. The way you described their tuning system is not how they actually did. Their tuning system was what they called the Greater Perfect System.

The music theory of the Pythagoreans was a philosophical exercise that had little to do with ancient Greek music in practice. I recommend reading John Chalmer's Divisions of the Tetrachord (should be available for free online)

In Pythagorean tuning, a major third is tuned to 81/64, not 5/4. The ratio 5/4 does not exist in Pythagorean tuning, because there is no combination of perfect octaves and perfect fifths that can produce an interval with this ratio. This is because there are no integer exponents m, n such that 2^m·(3/2)^n = 5/4.

So, no, it is not misleading.

I don't think I ever got around to making it. Thanks for reminding me - I'll add it to the list.

The 12 divisions of the octave came about through the diatonic scales. The diatonic scale has several octave species, involving the raising or lowering of certain scale degrees, and some of these are treated as enharmonic to one another due to only being different by small intervals called commas. When you account for this enharmonicity, you obtain 12 divisions.

Hi Thomas. I'm not quite sure what you're asking. The basic principle is to go up in fifths (i.e. increase the frequency by 3/2 each time) but halve the frequency if it takes you into the octave above.

@@discovermaths Hello! Thanks for the answer! What I'm confused about is, at 7:26, the image shows if you split the string at 2/3 of its length you get the fifth, so I'm imagining you would have to multiply 261.6 by 2/3 instead of 3/2 to find the fifth.

@@thomasvale5545 Ah, I see. The reason they're different is that one is a length division and the other a frequency multiplication.The fifth sounds if 2/3 the original length of the string is allowed to vibrate, producing a frequency of one over 2/3rds, or 3/2 the frequency of the open string. In the same way the octave sounds if the string is stopped at the halfway point, producing a frequency of one over a half, or twice, that of the open string.

@@discovermaths AAAAAH I get it now! Somehow I missed the youtube notification and tought I was left unanswered! Sorry for coming across as careless! Thank you for your patience. :)

We call this proportion a fifth because it is the fifth scale degree of our diatonic scale.

"Maths" is the abbreviation for "mathematics" in the UK and much of the English-speaking world outside the US. Similarly, we say "stats" instead of "stat" for statistics. The US edition of my recent book "Weird Maths" is titled "Weird Math" - so you can take your pick!

@@discovermaths To me its sounds like saying " musics" as in " Mozart's musics" or " the musics of the masters". Just sounds very odd to me. A grammatically misplaced plural.

@@johnvenable5638 It is not a misplaced plural. Mathematics are, quite literally, a plurality of discipline, just like quantum mechanics and physics, for example, are. You seem to not understand these subjects nearly as well as you think you do.

@@angelmendez-rivera351 would it be ok to use physic, mechanic, math, music or this would be considered odd? in other languages like danish, norwegian, swedish, german, french, finnish, italian, portugese and others all is singular.

@@rupertthurner8311 *would it be ok to use physic, mechanic, math, music or this would be considered odd?* Mechanic, math, and music are all regularly used words in the English language. The only odd one out is physic, which even then, is not incorrect if used in the appropriate context. *...in other languages like danish, norwegian, swedish, german, french, finnish, italian, portugese and others all is singular.* What?