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The Difference Between The Sharps And Flats


JLMoriart

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Here is a YouTube video I put up recently describing the difference between sharps and flats:

It requires a little prerequisite theory knowledge, though I hope it's accessible. Here is the video transcript:

"What is the difference between F sharp and G flat?" It's a question asked often enough, but what comes along less often is a satisfactory answer. It is my hope that by the end of this video you will have not only an understanding of WHY there's a difference, but an understanding of how to use that difference to make, play, and talk about music more effectively.

Let's start with a staple of music theory: the spiral of fifths. It shows that, starting from the naturals and using a chain of fifths, you can arrive at every note we could ever use in western music: The sharps, the flats, the double sharps, the double flats, and so on. Also, notice that we can derive any diatonic scale from a continuous, unbroken chain of seven fifths.

For one example, the G major diatonic scale can be generated from a chain of fifths from C to F#, which rearranges to G-A-B-C-D-E-F#.

Neither of those facts is coincidence. In fact it is by this chain of fifths that we DEFINE the notes that EXIST in western music, and it is by any 7 notes connected by an unbroken chain of fifths that we DEFINE our diatonic scales.

So most simply, the difference between F# and Gb is each's different location in the spiral of fifths, and therefor the scales to which they do and do not belong. If you're using the G major scale, the right note is F#, and if you're using the Db major scale, Gb is the correct note. But let's delve a little further and ask "So what?" If they're the same pitch, why define things that way?

First, know that intervals are measured in a unit called "cents" where there are 1200 in every octave, 100 cents per half step, and therefore 700 cents per fifth, at least in standard western tuning.

Let's prove that F# equals Gb specifically because the fifth is 700 cents.

From F# to Gb in fifths is F#-B-E-A-D-G-C-F-Bb-Eb-Ab-Db-Gb, or 12 fifths.

Starting with Gb at 0 cents, and adding

12 fifths * 700 cents/fifth gives you 8400 cents.

Dropping that note into the original octave by subtracting 6 octaves, 8400 cents - 1200 cents per octave times 6 octaves gives you 8400 cents minus 8400 cents, which comes out to 0 cents. Because 0 cents is a unison, F# is equal to Gb.

The G major scale and I IV V I progression using these pitches sound like this:

~~~~~~~~~~~~~~

And the same pattern but replacing Gb for F# sounds exactly the same.

The size of the fifth can change however, and when it is not exactly 700 cents then F# and Gb actually have DIFFERENT PITCHES. Motivations for adjusting the size of the fifth in the first place include better harmonic purity ("more in-tune") or melodic clarity (with a starker contrast between major and minor). Still, the over all musical structures stay pretty much the same.

If we flat the fifth a nearly imperceptible 5 cents to 695 cents:

From F# to Gb in fifths is still F#-B-E-A-D-G-C-F-Bb-Eb-Ab-Db-Gb, or 12 of these slightly flatter fifths.

12 fifths * 695 cents/fifth = 8340 cents

Dropping that note down 6 octaves gives 8340 cents - 8400 cents = -60 cents. That means that, with a fifth of 695 cents, F# differs from Gb by 60 cents!

The G major scale and I IV V I progression using these new pitches sound like this:

~~~~~~~~~~~~~~~

Different nuances from before, but recognizably the "same thing".

The same pattern but replacing Gb for F# sounds like this:

~~~~~~~~~~~~~~

It's completely different, and quite wrong for that "major scale" sound we all know and love.

Why would it turn out that F# sounds so much better in this context than Gb? Well, the decision to define our scales by unbroken chains of fifths is not arbitrary. Scales created by continuous unbroken chains of one given interval have perceptually relevant properties in music, where intervals sizes are regular (with only two sizes per interval class, aka major and minor), and where the different step sizes are distributed evenly throughout the scale. (For example, the diatonic scale has the minor seconds as far apart as possible between the major seconds.) Such scales are called "Moment of Symmetry" (or MOS) scales. Replacing a note like F# with another note like Gb, though they may be close in pitch, disrupts this regularity, and voids the definition of MOS.

You imply this difference between the sharps and flats even when using standard western tuning with a fifth of 700 cents, where F# and Gb are the same pitch. *This*, ladies and gentlemen, is the difference between the sharps and the flats. They differ in their location in the spiral of fifths, which describes their difference in function, which is audible in tunings where the fifth is not 700 cents.

Curious about playing and composing music in different tunings? Check out some of these links!

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rom F# to Gb in fifths is F#-B-E-A-D-G-C-F-Bb-Eb-Ab-Db-Gb, or 12 fifths.

Starting with Gb at 0 cents, and adding

12 fifths * 700 cents/fifth gives you 8400 cents.

Dropping that note into the original octave by subtracting 6 octaves, 8400 cents - 1200 cents per octave times 6 octaves gives you 8400 cents minus 8400 cents, which comes out to 0 cents. Because 0 cents is a unison, F# is equal to Gb

Ah, 1200 X 6 = 7200. Don't you mean 1200 X 7?

Also as commented, depends on the tuning you are using. In some tunings F# and G flat are not equivalent and therefore make keys based on these tones quite unusable.

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Ah, 1200 X 6 = 7200. Don't you mean 1200 X 7?

Quite right, I've corrected that in the video using annotations. Thanks!

Also as commented, depends on the tuning you are using. In some tunings F# and G flat are not equivalent and therefore make keys based on these tones quite unusable.

Keys based on those notes don't become unusable just because our enharmonics diverge. You just can't play a song that uses both on an interface like a piano that has only one key for the two of them.

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I think it's confusing that you never define which tuning you're using, which would be the well-tempered tuning. But then you talk about a 5th at 695 cents (which would mean 695 cents from our starting note I assume). But you don't mention which tuning this is. Is it just someone you made up for the purpose of the example? Also, why do you subtract your new number "8340" with the one you derived using the well-tempered fifth "8400" ? The circle of fifths is only consonant as long as you operate within the well-tempered tuning, so how do you justify still using it when you have left the well-tempered tuning.

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I think it's confusing that you never define which tuning you're using, which would be the well-tempered tuning.

The tunings in the video are not well tempered. Well tempered tunings use only 12 unequally spaced notes, where the pureness of some keys is maximized at the expense of others.

The tunings I use are "meantone tunings", where all the interval sizes are regular and are defined by an (infinitely long) chain of fifths. That is, all the major seconds are the same size, all the perfect fifths, all the minor sixths, etc. If you choose a twelve note subset of the infinite chain of fifths you do end up with "wolf fifths", but that's only because they are something like C# to Ab, or a doubly diminished sixth, NOT a fifth.

Because all the fifths are the same size, when you define its size the pitches of all other notes fall right into place (because their pitches are defined by their location in the circle of these regularly tempered fifths). So I *do* define which tuning I'm using, merely by the statement of the size of the fifth:

http://en.wikipedia.org/wiki/Meantone_temperament

Not sure if I follow the rest completely but I'll do my best to reply.

But then you talk about a 5th at 695 cents (which would mean 695 cents from our starting note I assume). But you don't mention which tuning this is. Is it just someone you made up for the purpose of the example?

The tuning with a fifth of 695 cents is about "1/3 comma meantone" to give it a name but, as I mentioned above, just by specifying the size of the fifth, the other notes are defined by their location in the circle of fifths. The reason you'd flat the fifth like that is then you end up with very pure thirds, and in fact a perfectly tuned minor third. Though the fifth is slightly flatter, over all the tuning is much "better" (or has less error).

Also, why do you subtract your new number "8340" with the one you derived using the well-tempered fifth "8400" ?

I subtracted the number 8400 because it is 7 octaves. What I mean is, I stacked up all those fifths, and then to compare it to the original note I started at I had to bring the new note down to the original octave. Originally it turned out that 12 fifths equalled 7 octaves (8400-8400=0), but the second time it turned out that 12 fifths did NOT equal 7 octaves (8340-8400=-60). So the 8400 came from octaves, not from the original fifth I used.

The circle of fifths is only consonant as long as you operate within the well-tempered tuning, so how do you justify still using it when you have left the well-tempered tuning.

This is very much so not true. Using the circle of fifths to define the rest of your notes provides you with good accuracy (consonance) over a wide range of values, as I showed in the video. Flatting the fifth to 695 cents gives you MUCH purer tuning than standard western tuning, and if you sharp it to 702 cents and then use C-Fb-G as your consonant triad it is *extremely* close to pure.

-J

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Besides harmony issues F# and Gb suppose to be two different sounds in frequency but there's not a single instrument (virtual or real) to support that old theory...

Actually there are, and were. New Instruments like generalized keyboards have different keys for the sharps and flats, and old organs had "split keys" where the enharmonics had different pitches.

-J

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OK... Ima try and understand this.. okay?... So WHY are there 1200 cents in an octave? why isn't it 8? I don't get it.

The decision to make the unit for intervals have 1200 of them in every octave is arbitrary. You could make it 8 cents/octave (where the tritone would be four cents, and the minor third would be 2 cents), or something silly 2125. 1200 is just convenient so that you get 100 cents per minor second in standard western tuning, which makes it easier to deal with the math and compare other tunings to the original 12.

-J

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But when do the fifths change?

You change the size of the fifth when you play in other tunings (temperaments). Historically during the use of "meantone" the fifth ranged anywhere from 694 cents to 700 cents, the tunings in between 19-tone equal temperament ("1/3 comma meantone") and 31-tone equal temperament ("1/4 comma meantone").

Also, should I understand that this only applies if I write in a tuning temperament different to equal temperament?

Yes, the enharmonics are only different pitches when you use a tuning different from standard western tuning (12-tone equal temperament). The video was supposed to show, however, that they way they sound different in other tunings is what you imply when using one vs the other in 12-tone tuning where they have the same pitch.

Also I would like to know the rules of when to put sharp and when to put flat. Thank you

If you take a look at the video I posted again you'll see that the scale you're using (aka what key you're in) decides whether to use a sharp or flat, via the circle of fifths. Let me know if something about it is not clear.

-J

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Actually on meantone instruments there are separate keys for D# and E flat. If two such enharmonic notes in more modern tunings can be separate in older tunings, then I stand by my assertion you got to state outright your tuning system.

Not sure what you mean by "you got to state outright your tuning system."

The tuning system *is* stated outright the moment you state the size of the fifth you use because it defines all notes of the tuning. The moment you say your fifth is 700 cents, for example, you know your tuning is 12-tone equal temperament because stacking that fifth up and down the chain of fifths *directly results* in 12-tone equal temperament.

-J

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Actually there are, and were. New Instruments like generalized keyboards have different keys for the sharps and flats, and old organs had "split keys" where the enharmonics had different pitches.

-J

:blink: what are those keyboards ?

Old organs have split stops but that means one stop is first two octaves and 2nd stop is the rest of the keys, but I have never know one has a different pipe for F# and other pipe for Gb in same stops

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:blink: what are those keyboards ?

This talks about old Halberstadt style keyboard instruments having different keys for the sharps and flats:

http://en.wikipedia....iki/Split_sharp

And the newer concept of a generalized keyboard also has different keys for sharps and flats, but laid out much more ergonomically:

http://en.wikipedia....den_note_layout

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Wow that 2nd one looks like a mess to play it, worse than Bandoneon or Concertina,

so we have to re-record all music ever recorded because we're not playing the Sharp/Flat correctly, who writes to the Deutch Gramophone director ?

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Wow that 2nd one looks like a mess to play it, worse than Bandoneon or Concertina,

Actually, though it may look daunting, it's quite easy to play. Much easier than a piano, IMO. Here's a video of Fur Elise played on one:

so we have to re-record all music ever recorded because we're not playing the Sharp/Flat correctly, who writes to the Deutch Gramophone director ?

Haha no, 12-tone equal temperament is no more or less valid than any other meantone tuning with any other size fifth, and other tunings even have different enharmonic equivalents. For example, 19-tone equal temperament has E#=Fb and B#=Cb.

12-TET It has it's benefits and its deficits, and tuning is just another dimension of expression that you can use to interpret a piece. Indeed, some pieces *require* our enharmonics to be equal through enharmonic modulation, while others may benefit for the more justly intoned triads of flatter fifths, while even still others may benefit melodically from sharping the fifth and achieving starker melodic contrasts.

-J

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I understand it as sharps are what you've got when you're going up (to the right) the spiral of fifths to generate pitches and flats are what you've got when you're going down (to the left).

That's quite right, but my hope with the video I posted was to place emphasis on the *implications* of that difference, namely in the possibility for our enharmonics having different pitches and, therefor, audibly different functions.

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  • 2 weeks later...

Wow... I need to get some more music theory books...

Actually, the stuff we're talking about here is not covered in most (any) theory books. Standard theory tells you that this ubiquitous, standard structure of music exists, and then gives this structure's components many names, but it doesn't deal at all with its derivation. It's these structures' derivations (and their implications and generalizations) that we're talking about. From my experience, theory books will deal more with *compositional tendencies* than anything more scientifically associated with the word "theory".

This stuff will one day, I hope, be in theory books, when the term "MOS Scale" is as ubiquitously known as "diatonic" is today, but for now it is the fringe of experimental music making. Very cool stuff, but no one much cares for it because it requires stepping outside of some boxes with walls so tall that most don't know stepping outside is an option.

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