## Noble frequency ratios as prime-count vectors in ℚ(√5) [superseded]

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Dave Keenan
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### Noble frequency ratios as prime-count vectors in ℚ(√5) [superseded]

[Note: This thread is of historical interest only. Please see the updated version (using a better choice for the fundamental primes) at viewtopic.php?f=21&t=557]

Why would anyone want to represent a noble frequency ratio as a prime-count vector? And what does that even mean?

“Mercy without justice is the mother of dissolution; justice without mercy is cruelty.”  — Thomas Aquinas

A musical interval or dyad, whose frequency ratio is a simple noble number, is maximally ambiguous and a source of tension, wanting to resolve to one of the justly-intoned intervals on either side of it. Near examples of these in 12edo are the tritone, the minor seventh and the minor tenth. In a play on the word "just", I like to call simple noble-number intervals "mercifully-intoned". They have also been called "anti-JI" or metastable intervals. It is rational to be just, and noble to be merciful.

The explosion of musical temperaments that occurred in the first decade of the 21st century, was largely the result of applying the tools of linear-algebra (matrix math) to justly-intoned interval ratios represented as prime-count vectors — a form of scale engineering that we now call Regular Temperament Theory (RTT).

My hope is that by expanding the repertoire of intervals that can be represented as prime-count vectors, we will be able to apply the methods of RTT to find and work with musical temperaments that target the simple noble frequency ratios of merciful intonation (MI), in addition to the simple rational frequency ratios of just intonation (JI).

There's no guarantee this will lead to anything useful, but I hope fellow students of tuning-math will at least find the following series of posts entertaining.

I dedicate this series to Margo Schulter @mschulter, whose explorations in neo-medieval harmony serve to ground this work. Please listen to her sampler of MI/JI cadences.

It's not clear whether this will ever have any relationship to the Sagittal microtonal notation, but the use of ℚ(√5) for prime factorisations of noble numbers, was suggested to me by @Ash9903b4 in the Magrathean diacritics thread on the Sagittal forum. And the Sagittal forum seems like a good place to record the results of my research.

Feudal Numbers

The blackboard bold "ℚ" (for "quotient") represents the set of rational numbers, i.e. the usual ratios or fractions of the form n/d where n and d are integers (and d is not zero). The set of integers is represented by the blackboard bold "ℤ".
ℚ(√5) is a quadratic field where the rationals are adjoined with the irrational number "root 5". Conveniently for our purposes, the numbers of ℚ(√5) can be written in the form (a+bϕ)/(x+yϕ) where ϕ is the golden ratio, (1+√5)/2 ≈ 1.618, and a, b, x, y are integers (and x, y are not both zero). "ϕ" is the Greek symbol phi, pronounced in English like the "fy" in "modify".
Both the rational numbers and the noble numbers are subsets of ℚ(√5). The rationals are numbers of the above form where b=0 and y=0. The nobles are those where, when we cross-multiply and subtract, we get ay-bx = ±1. I call the numbers in ℚ(√5) that are not noble "ignoble" (or low born) numbers. The rationals are included in the ignobles. And I call all of ℚ(√5) (noble and ignoble together), the "feudal" numbers, because, if we care about the difference between nobles and ignobles, we must be in a feudal system. And "feudal" sounds a bit like "phi-dal". And although this did not consciously occur to me when coining the term: It ties in nicely with the neo-medieval theme of Margo's work. And thanks to Ralph Hutchison for pointing out that another reason the name "feudal" is fitting, is that in chess, a knight's move is a distance of √5.

I note that some ignobles are irrational and some ignobles are rational, but all nobles are irrational, which is why they can't be represented as ordinary prime-count vectors in ℚ.

We can say that a feudal number is a quotient of two "feudal integers", a numerator and denominator, both having the form a+bϕ where I call a the "wooden part", and b the "golden part". a is called the "wooden part" because it remains an ordinary dull integer, while b is golden because it gets multiplied by the golden ratio. Notice that it's not bϕ that is the "golden part", but only b. This is analogous to the imaginary part of a complex number. e.g. the feudal integer 3+2ϕ has wooden part 3 and golden part 2. The set of feudal integers is represented as "ℤ[ϕ]".

Why ℤ[ϕ] and not ℤ[√5]? It turns out that because 5 modulo 4 = 1, ℤ[√5] is not the largest set of integer-like numbers (the largest ring) in ℚ(√5). It's only half of it. It turns out we still have a ring if we take all the numbers midway "horizontally" (integer part) between the numbers of ℤ(√5), provided we also offset them by 1/2 "vertically" (√5 part). And ϕ = 1/2 + √5/2. See Dirk Dekker's plot at the end of this post.

So a feudal integer is like a work of gold inlay, or a golden afternoon spent in a wooden boat, telling tales of feudal times.

I'll be talking a lot about feudal integers and feudal primes, so I'll just be calling them "integers" and "primes" in this context, and when I need to refer to the ordinary pre-feudal kind, I'll call them "ordinary integers" and "ordinary primes". Elsewhere you may see the ordinary kind called "rational integers" and "rational primes", but I find that terminology confusing.

In regular temperament theory (RTT), when we represent a rational number (a ratio of two ordinary integers) as a prime-count vector (a list of ordinary integers between square and angle brackets [...⟩ ), we first reduce the ratio to lowest terms, then we prime-factorise its numerator and denominator, and count the numbers of each prime (2, 3, 5, 7, 11 etc), and record these counts as entries in the vector, with a minus sign applied to the counts of primes in the denominator. For example $$\frac85$$ is represented as [3 0 -1, which is to say 2³×3⁰×5⁻¹ or $$\frac{2^3}{5^1}$$.

It turns out we can do exactly the same thing when we want to represent a noble number as a prime-count vector (PC-vector). It's just that our reduction-to-lowest-terms procedure is different, and our primes turn out to be feudal integers like 2+1ϕ, 3+1ϕ, 3+2ϕ, 4+1ϕ, 4+3ϕ, 5+2ϕ, 5+3ϕ. But the entries in the vector are still just ordinary integers.

If you're looking for a pattern in the list above, forget it. Feudal primes are just as random as ordinary primes, except that they come in complementary pairs, all but one of them. More on that later.

In addition to the primes, we also have "units", like 1+0ϕ, 0+1ϕ, 1+1ϕ. These are analogous to the numbers 1 and -1 in the rational numbers. We don't use negative rationals in RTT, so our vectors haven't needed a "unit count" entry. But we will need a unit-count entry for our noble-number vectors, even though we don't care about negative noble numbers either. All three of those (feudal) units shown above are positive. But we only need a single entry to cover all of them, because it turns out they correspond to powers of ϕ. The 3 above are ϕ⁰, ϕ¹, ϕ². All integer powers of ϕ are units in the feudal number system, but so far, I find we only need those three for the noble numbers.

It's interesting that so far, I've never had to prime-factorise the numerator or denominator of a noble number after it has been reduced to lowest-terms. After reducing to lowest terms, every noble so far, is simply a single prime or unit, divided by another single prime or unit. That's good in one way, because, as you can probably imagine, factorising feudal integers is not an easy thing to do by hand, or even with a spreadsheet. But it's bad in another way, because it means we'll need a lot of primes for a small number of nobles, and therefore we'll need a lot of entries in our PC-vectors.

So how does this reduction to lowest terms work? A common way to obtain a noble number is as a noble mediant (phi-weighted mediant) between two adjacent rationals on the Stern-Brocot tree. See Erv Wilson's Scale Tree. For an alternative treatment see Continued Fractions by Jordi Solà-Soler, 2014.

Consider the 422.5 ¢ supermajor third that is the noble mediant of 4/3 and 5/4 and is therefore the limit of these fibonacci-like sequences of numerators and denominators that zigzag down the Stern-Brocot tree:

Figure 1

---->
4  5  9 14
-- -- -- -- ...
3  4  7 11
---->


I say fibonacci-like because each new ordinary integer is the sum of the previous two in the same row.

This noble is commonly written as (4+5ϕ)/(3+4ϕ), but that is not in lowest terms.

To put it in lowest terms we run the fibonacci-like sequences backwards, starting with 5/4 and 4/3. So each new ordinary integer is the difference of the previous two, working from right to left, like this:

Figure 2

<----
-2  3  1  4  5
... -- -- -- -- --
-1  2  1  3  4
<----


I've actually gone one step too far, to show you what happens. If you get a negative ordinary integer, you've gone too far. Which is equivalent to saying: When you get an ordinary integer that's bigger than the one to its right, you can stop.

Figure 2a

<----
3  1  4  5
-- -- -- --
2  1  3  4
<----


Then we can write the noble number in lowest terms, as the noble mediant of the last two fractions, as:

Figure 3

3+1ϕ
----
2+1ϕ


And it turns out both of these (feudal) integers are prime.

How do I know? Professor Dirk Dekker wrote a wonderful paper in 2003 entitled Primes in quadratic fields. And it has a wonderful appendix 2 in which he has mapped the feudal primes (blue) and units (red), although of course he doesn't call them "feudal" but rather ℚ(√5).

It took me a while to figure out how to read it. I've enlarged the upper right quadrant and annotated it here (click to enlarge):

Figure 4

Attachments
Gold inlay wood box 400px.jpg

Dave Keenan
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### Re: Noble frequency ratios as prime-count vectors in ℚ(√5) [superseded]

[Note: This thread is of historical interest only. Please see the updated version (using a better choice for the fundamental primes) at viewtopic.php?p=4605#p4605]

Here is a table of the first 32 (superunison) noble numbers, working our way down the Stern-Brocot tree, shown as quotients of feudal primes (primes of ℚ(√5)). The alternating light grey and lighter grey backgrounds delineate the levels of the tree. The nobles whose cent values are shown in blue, can be heard in Margo Schulter's MI/JI cadence sampler. @mschulter

Table 1

Stern-	Mediends	Noble	Cents	Quotient of	Approximation	Alternative
Brocot	(weighted)	mediant		feudal primes	in 12edo	form
order	1	ϕ			or units			for units
-----------------------------------------------------------------------------------
1	1/1	2/1	1.6180	 833.1	(0+1ϕ)/(1+0ϕ)			ϕ
2	2/1	3/1	2.6180	1666.2	(1+1ϕ)/(1+0ϕ)			ϕ²
3	3/2	4/3	1.3820	 560.1	(2+1ϕ)/(1+1ϕ)
3	3/1	4/1	3.6180	2226.2	(2+1ϕ)/(1+0ϕ)
4	4/3	5/4	1.2764	 422.5	(3+1ϕ)/(2+1ϕ)
4	5/3	7/4	1.7236	 942.5	(3+2ϕ)/(2+1ϕ)
4	5/2	7/3	2.3820	1502.6	(3+2ϕ)/(1+1ϕ)	minor tenth
4	4/1	5/1	4.6180	2648.7	(3+1ϕ)/(1+0ϕ)
5	5/4	6/5	1.2165	 339.3	(4+1ϕ)/(3+1ϕ)
5	7/5	10/7	1.4198	 606.9	(4+3ϕ)/(3+2ϕ)	tritone
5	8/5	11/7	1.5802	 792.1	(5+3ϕ)/(3+2ϕ)
5	7/4	9/5	1.7835	1001.6	(5+2ϕ)/(3+1ϕ)	minor seventh
5	7/3	9/4	2.2764	1424.1	(5+2ϕ)/(2+1ϕ)
5	8/3	11/4	2.7236	1734.6	(5+3ϕ)/(2+1ϕ)
5	7/2	10/3	3.3820	2109.4	(4+3ϕ)/(1+1ϕ)
5	5/1	6/1	5.6180	2988.1	(4+1ϕ)/(1+0ϕ)
6	6/5	7/6	1.1780	 283.6	(5+1ϕ)/(4+1ϕ)
6	9/7	13/10	1.2957	 448.5	(5+4ϕ)/(4+3ϕ)
6	11/8	15/11	1.3672	 541.4	(7+4ϕ)/(5+3ϕ)
6	10/7	13/9	1.4393	 630.4	(7+3ϕ)/(5+2ϕ)
6	11/7	14/9	1.5607	 770.6	(8+3ϕ)/(5+2ϕ)
6	13/8	18/11	1.6328	 848.9	(8+5ϕ)/(5+3ϕ)
6	12/7	17/10	1.7043	 923.0	(7+5ϕ)/(4+3ϕ)
6	9/5	11/6	1.8220	1038.6	(7+2ϕ)/(4+1ϕ)
6	9/4	11/5	2.2165	1378.0	(7+2ϕ)/(3+1ϕ)
6	12/5	17/7	2.4198	1529.9	(7+5ϕ)/(3+2ϕ)
6	13/5	18/7	2.5802	1641.0	(8+5ϕ)/(3+2ϕ)
6	11/4	14/5	2.7835	1772.3	(8+3ϕ)/(3+1ϕ)
6	10/3	13/4	3.2764	2054.5	(7+3ϕ)/(2+1ϕ)
6	11/3	15/4	3.7236	2276.0	(7+4ϕ)/(2+1ϕ)
6	9/2	13/3	4.3820	2557.9	(5+4ϕ)/(1+1ϕ)
6	6/1	7/1	6.6180	3271.7	(5+1ϕ)/(1+0ϕ)


It is important to realise that there is no octave-equivalence among nobles. None of the above differ by 1200 cents. Nor is there tritave equivalence (1902c) or fifth-equivalence (702c). And perhaps more surprising, there is no phitave equivalence among nobles. Only one pair of nobles differ by 833c, namely ϕ and ϕ² (833c and 1666c).

When the unison is added to the above list, and all of the 528 pairwise cent differences are calculated, the most any difference-interval occurs is 3 times. Those difference-intervals are the simple nobles near: 339c, 560c, 607c, 792c, 849c, 923c, 943c. There are some other difference-intervals that approximately reoccur 3 or more times. Notably 138c, 242c, 501c. These point to small "feudal commas" that may be exploited in future.

One might say that nobility is fragile. It rarely survives multiplication. Very few pairs of nobles can breed successfully. And when nobles attempt to multiply with rationals, the result is usually an irrational ignoble.

Below is the complete set of 15 primes and 3 units that occur in the above table. Notice that they don't have wooden parts greater than 8 or golden parts greater than 5. And 6 does not occur as a wooden part, despite the existence of the primes (6+1ϕ) and (6+5ϕ) which do occur in higher-order nobles.

Units and primes of the first 32 nobles:

Table 2

1+0ϕ, 0+1ϕ, 1+1ϕ   [the units ϕ⁰, ϕ¹, ϕ²]
2+1ϕ
3+1ϕ
3+2ϕ
4+1ϕ
4+3ϕ
5+1ϕ
5+2ϕ
5+3ϕ
5+4ϕ
7+2ϕ
7+3ϕ
7+4ϕ
7+5ϕ
8+3ϕ
8+5ϕ


So we'd need PC-vectors with 16 entries, just to represent the first 32 nobles! Mind you, these are probably the only nobles of any interest musically. Their mediends (pronounced "mee-dee-ENDS", which are the two rationals you take the noble-mediant of, to obtain the noble) have an ordinary prime limit of 13.

If we limit ourselves to the first 16 nobles, we only need 8 entries. You might think we'd need another 6 entries to represent the 13-prime-limit rationals, but it turns out we only need another 4 entries, for a total of 12.

That's because we have a tiny win when we come to represent rational numbers in the feudal system, as some of the ordinary primes are feudal composites, and are composed of the same primes that make up the simplest nobles.

Of the ordinary primes, only 2, and those whose decimal representation ends in 3 or 7, are feudal primes. Which means that 5, and those ending in 1 or 9, are composite. More about that soon.

So the following ordinary primes are prime in ℚ(√5):

Table 3

2+0ϕ
3+0ϕ
7+0ϕ
13+0ϕ
17+0ϕ
23+0ϕ
37+0ϕ
43+0ϕ
47+0ϕ
53+0ϕ
67+0ϕ
73+0ϕ
...


They can be called "wooden primes", as they are feudal primes with a zero golden part. A wooden prime is a feudal prime that is also an ordinary prime. Notice that the feudal primes that occur as the numerator or denominator of a noble number above, are all "non-wooden primes", as they all have a non-zero golden part.

The following ordinary primes are composite in ℚ(√5), with the given prime factorisation and unit:

Table 4

5+0ϕ = (2+1ϕ)(2+1ϕ)(2-1ϕ) = (2+1ϕ)2(2-1ϕ)   [Note: (2-1ϕ) = ϕ⁻²]
11+0ϕ = (3+1ϕ)(3+2ϕ)(2-1ϕ)
19+0ϕ = (4+1ϕ)(4+3ϕ)(2-1ϕ)
29+0ϕ = (5+1ϕ)(5+4ϕ)(2-1ϕ)
31+0ϕ = (5+2ϕ)(5+3ϕ)(2-1ϕ)
41+0ϕ = (6+1ϕ)(6+5ϕ)(2-1ϕ)  [Note: (6+1ϕ) and (6+5ϕ) are not used in the first 32 nobles]
59+0ϕ = (7+2ϕ)(7+5ϕ)(2-1ϕ)
61+0ϕ = (7+3ϕ)(7+4ϕ)(2-1ϕ)
71+0ϕ = (8+1ϕ)(8+7ϕ)(2-1ϕ)  [Note: (8+1ϕ) and (8+7ϕ) are not used in the first 32 nobles]
79+0ϕ = (8+3ϕ)(8+5ϕ)(2-1ϕ)
...


If we want to avoid integers with negative parts (or powers of ϕ with negative exponents), we can write these as quotients:

Table 4a

5+0ϕ = (2+1ϕ)(2+1ϕ)/(1+1ϕ) = (2+1ϕ)2/(1+1ϕ)   [Note: (1+1ϕ) = ϕ²]
11+0ϕ = (3+1ϕ)(3+2ϕ)/(1+1ϕ)
...


It is known that ordinary primes that are composite in ℚ(√5) always factorise into exactly two unequal primes, except for 5 which is the square of a prime. These can be called "split primes". See what patterns you can spot in the above factorisations before reading on.

The wooden parts of the prime factors are always the same, and are the floor of the square root of the ordinary prime. The golden parts sum to give the wooden part. The product of the wooden parts plus the product of the golden parts is the ordinary prime.

And notice that the prime factors of these ordinary primes include all 15 prime factors of the first 32 nobles.

If you want to confirm any of these factorisations, you can do the multiplication. You will obtain some ϕ²'s, but these can be eliminated by using the identity ϕ² = 1+ϕ. Or you can just use the formula in the last line below.

(a+bϕ)×(x+yϕ)
= ax + (ay+bx)ϕ + byϕ²
= ax + (ay+bx)ϕ + by(1+ϕ)
= (ax+by) + (ay+bx+by)ϕ
= (ax+by) + (by+bx+ay)ϕ [reordered so the two uses of "by" are close together]

Here's feudal integer multiplication shown graphically:

Figure 5
___________
|   ______  |
a  | +|  b   | |  ϕ
:.|  |,':   | |
_:  .,'  :_  | |
| :  ,'.  : | | |
| :,'    .: | | |
| x    +   y | | |  ϕ
|  __________| | |
| |          | | |
v v          v v v
(ax+by)  +  (by+bx+ay)ϕ


Dave Keenan
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Joined: Tue Sep 01, 2015 2:59 pm
Location: Brisbane, Queensland, Australia
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### Re: Noble frequency ratios as prime-count vectors in ℚ(√5) [superseded]

[Note: This thread is of historical interest only. Please see the updated version (using a better choice for the fundamental primes) at viewtopic.php?p=4606#p4606]

I've been somewhat glossing over the idea of "units" — those integers of ℤ[ϕ] (and hence ℚ(√5)) that Dirk Dekker and I have been colouring red. Why are they called units? And if they are all powers of ϕ then why isn't ϕ considered to be just another prime in this system? After all, we need an entry for the ϕ-count in our prime-count vectors,

A hint comes above when I note that 2-1ϕ (the unit that appears in the factorisations of ordinary primes above) is ϕ-2. The standard definition of a negative power is as the reciprocal of the corresponding positive power, x-n = 1/xn. This means that ϕ2 x ϕ-2 = 1. I've also mentioned that 1+1ϕ is ϕ2. So we can check whether (1+1ϕ)(2-1ϕ) = 1 using the multiplication algorithm above.

Figure 6
___________
|   ______  |
1  | +|  1   | |  ϕ
:.|  |,':   | |
_:  .,'  :_  | |
| :  ,'.  : | | |
| :,'    .: | | |
| 2    +  -1 | | |  ϕ
|  __________| | |
| |          | | |
v v          v v v
( 2+-1)  +  (-1+ 2+-1)ϕ
= 1+0ϕ
= 1


So we see that (2-1ϕ) really is the reciprocal of (1+1ϕ).

It is a rare thing that an integer has a reciprocal that is also an integer. 1/2, 1/3, 1/4, ... are not integers. In fact, that is the definition of a "unit":

"A unit is an integer whose reciprocal is also an integer."

Among the ordinary integers, only 1 and -1 have that property. They happen to be their own reciprocals. e.g. 1/-1 = -1. As soon as you have a pair of integers that multiply to give 1, e.g -1 × -1 = 1, then you can break the naive definition of a prime number as "a number divisible only by 1 and itself". e.g. we can write 3 = 3 × -1 × -1 so that 3 appears to no longer be prime. And we can break the naive version of the fundamental theorem of arithmetic that says that "any integer can be represented as a product of primes in only one way", because we can write 6 as 2 × 3 or -2 × -3.

But we don't actually want to treat -2×-3 as a different factorisation from 2×3 because it's obvious that -2 and 2 are related, as are -3 and 3. We call them "associated primes" or simply "associates". The only difference between -2 and 2 is multiplication by a unit (an integer whose reciprocal is also an integer).

So we can amend the naive definition of a prime to become:

"A prime is an integer divisible only by units and its associates (which are copies of itself multiplied by different units)".

And within any set of associated primes, we can always designate one of them as the fundamental prime (or the normal form of the prime). Among the ordinary integers these are the positive primes. Among the feudal integers, for this thread I've chosen this definition: A fundamental prime has both parts positive, with the wooden part greater than the golden part. This ensures that the ordinary integers that are its parts, are as small as possible while never being negative.

Then we can amend the naive version of the fundamental theorem to become:

"Any nonzero integer can be represented as a product of zero-or-more fundamental primes, and one unit, in only one way (ignoring the order of the factors)."

A number system that obeys this form of the fundamental theorem is called a unique factorisation domain (UFD). Fortunately for us, the feudal integers form a unique factorisation domain, which means that every feudal number (not only the feudal integers) has a unique representation as a prime-count vector. However the vector must have an entry for the unit, in addition to entries for the primes, so strictly speaking, it is a unit-and-prime-count vector.

I mentioned that all integer powers of ϕ are feudal units. Their negations, -ϕⁿ are the only other feudal units, but we don't need negative feudals for tuning theory. Recognition of feudal units is aided by the fact that their wooden and golden parts are successive Fibonacci numbers, including "negative Fibonacci numbers" obtained by "running the rule backwards", as shown below.

Here's a list of some (positive) feudal units:

Table 5
...
ϕ-9	-55+34ϕ		Notice how the minus sign alternates
ϕ-8	 34-21ϕ		between wooden and golden parts
ϕ-7	-21+13ϕ		for powers of ϕ with negative exponents
ϕ-6	 13-8ϕ
ϕ-5	 -8+5ϕ
ϕ-4	  5-3ϕ
ϕ-3	 -3+2ϕ
ϕ-2	  2-1ϕ
ϕ-1	 -1+1ϕ
ϕ0 = 1	  1+0ϕ
ϕ1 = ϕ	  0+1ϕ
ϕ2	  1+1ϕ
ϕ3	  1+2ϕ
ϕ4	  2+3ϕ
ϕ5	  3+5ϕ
ϕ6	  5+8ϕ
ϕ7	  8+13ϕ
ϕ8	 13+21ϕ
ϕ9	 21+34ϕ
...


I note that the procedure given in the earlier post, for "reducing a noble number to lowest terms", only serves to factor out common units in the numerator and denominator, leaving any primes as fundamental primes. It does not cancel any common primes that may occur in the numerator and denominator. However the latter has not proven necessary, because every noble examined so far has been either a ratio of two primes, a single prime, or a unit. But we should no longer call it "reducing to lowest terms" but rather "normalising".

Each step of the reduction procedure is equivalent to dividing top and bottom by ϕ. To see this, notice that dividing by ϕ is equivalent to multiplying by ϕ-1 = -1+1ϕ, and (a+bϕ)(-1+1ϕ) = (-a+b)+(b+-b+a)ϕ = (a-b)+aϕ.

Dave Keenan
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Joined: Tue Sep 01, 2015 2:59 pm
Location: Brisbane, Queensland, Australia
Contact:

### Re: Noble frequency ratios as prime-count vectors in ℚ(√5) [superseded]

[Note: This thread is of historical interest only. Please see the updated version (using a better choice for the fundamental primes) at viewtopic.php?p=4607#p4607]

Here's a 2D table of the small feudal integers we've been discussing. Only the units and fundamental-primes are labelled. As usual, units are shown in red, and primes in black or green. Those in black are the primes that occur in the first 32 nobles. Primes labelled with a lowercase "f" followed by an ordinary prime number, are factors of that ordinary prime number, as well as being numerators or denominators of various nobles.

The two factors of a given prime are distinguished by appending a "prime" symbol ′ (U+2032) to its label. An apostrophe ' (U+0027) should only be used as a substitute in ASCII-only environments, where exponents are written as "^2", otherwise an apostrophe risks confusion with an exponent of 1. The prime symbol can be pronounced "complement" in a feudal context, to avoid confusion between the prime symbol and prime numbers. We will learn later why the name "complement" is appropriate.

For integers with wooden parts beyond 8, only wooden primes are labelled, as the others are unlikely to be of musical interest, being factors of ordinary primes greater than 79 and of complex nobles beyond level 6 of the Stern-Brocot tree.

Table 6

|    g o l d e n   p a r t
+ |	0ϕ	1ϕ	2ϕ	3ϕ	4ϕ	5ϕ	6ϕ	7ϕ	8ϕ
-----+-------------------------------------------------------------------------
w  0 |		ϕ
o  1 |	1	ϕ²	ϕ³
o  2 |	2	f5		ϕ⁴
d  3 |	3	f11	f11′			ϕ⁵
e  4 |		f19		f19′
n  5 |		f29	f31	f31′	f29′				ϕ⁶
6 |		f41				f41′
p  7 |	7		f59	f61	f61′	f59′
a  8 |		f71		f79		f79′		f71′
r  … |
t 13 |	13	…
… |
17 |	17	…
… |
23 |	23	…
… |



Dave Keenan
Posts: 2092
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### Re: Noble frequency ratios as prime-count vectors in ℚ(√5) [superseded]

[Note: This thread is of historical interest only. Please see the updated version (using a better choice for the fundamental primes) at viewtopic.php?p=4608#p4608]

In RTT it is convenient that we have an obvious ordering of primes, so that unless we are told otherwise, a vector like [-2 0 0 1 can be interpreted as 2⁻²×3⁰×5⁰×7¹ = 7/4. And it's convenient that this ordering agrees with the typical order of introduction of primes, as temperaments become more complex.

It's not so obvious what the standard ordering should be for the feudal primes, since they are arranged on a plane, not a line. And their order of introduction is very different depending on whether you're adding a prime in order to facilitate new nobles, or new rationals. Some rationals require wooden primes. Nobles never do.

A standard ordering also needs to be easy to remember.

One option is lexicographic order of the a+bϕ form, which corresponds to reading-order on the table above.

red for units, green for primes not used by the first 32 nobles.

Table 7

0+1ϕ =   ϕ
2+0ϕ =   2
2+1ϕ =  f5
3+0ϕ =   3
3+1ϕ = f11
3+2ϕ = f11′
4+1ϕ = f19
4+3ϕ = f19′
5+1ϕ = f29
5+2ϕ = f31
5+3ϕ = f31′
5+4ϕ = f29′
6+1ϕ = f41
6+5ϕ = f41′
7+0ϕ =   7
7+2ϕ = f59
7+3ϕ = f61
7+4ϕ = f61′
7+5ϕ = f59′
8+1ϕ = f71
8+3ϕ = f79
8+5ϕ = f79′
8+7ϕ = f71′
then a lot of fairly useless primes until we get to
13+0ϕ = 13
then even more completely useless primes until we get to
17+0ϕ = 17
then even more completely useless primes until we get to
23+0ϕ = 23


Another option is to place them in order of the ordinary prime that they are a factor of:

Table 8

0+1ϕ =   ϕ
2+0ϕ =   2
3+0ϕ =   3
2+1ϕ =  f5
7+0ϕ =   7
3+1ϕ = f11
3+2ϕ = f11′
13+0ϕ = 13
17+0ϕ = 17
4+1ϕ = f19
4+3ϕ = f19′
23+0ϕ = 23  [primes beyond here are likely only wanted for nobles, not rationals]
5+1ϕ = f29
5+4ϕ = f29′
5+2ϕ = f31
5+3ϕ = f31′
37+0ϕ = 37  [fairly useless]
6+1ϕ = f41
6+5ϕ = f41′
43+0ϕ = 43  [fairly useless]
43+0ϕ = 47  [fairly useless]
53+0ϕ = 53  [fairly useless]
7+2ϕ = f59
7+5ϕ = f59′
7+3ϕ = f61
7+4ϕ = f61′
67+0ϕ = 67  [fairly useless]
8+1ϕ = f71
8+7ϕ = f71′
76+0ϕ = 76  [fairly useless]
8+3ϕ = f79
8+5ϕ = f79′


My favourite option is to use a hybrid of the two orders above, to give the nearest thing to backwards-compatibility with the existing rational-only PC-vectors. First listing, in ordinary-prime-order, all the feudal primes that are used to encode rational numbers in a given temperament, followed by a semicolon, followed by the units and primes that are only used to encode nobles, in lexicographic order. The semicolon (followed by a space) separates the two sections, whether or not commas (or only spaces) are used to separate the other counts.

For a 13-prime-limit-plus-nobles temperament, the order would be:

Table 9

2+0ϕ =   2
3+0ϕ =   3
2+1ϕ =  f5  [This will be used for nobles as well as being doubled for the ordinary prime 5]
7+0ϕ =   7
3+1ϕ = f11  [This will be used for nobles as well as the ordinary prime 11]
3+2ϕ = f11′ [This will be used for nobles as well as the ordinary prime 11]
13+0ϕ = 13
; semicolon separator
0+1ϕ =   ϕ  [primes from here on will only be used for nobles, not rationals]
4+1ϕ = f19
4+3ϕ = f19′
5+1ϕ = f29
5+2ϕ = f31
5+3ϕ = f31′
5+4ϕ = f29′
6+1ϕ = f41
6+5ϕ = f41′
7+2ϕ = f59
7+3ϕ = f61
7+4ϕ = f61′
7+5ϕ = f59′
8+1ϕ = f71
8+3ϕ = f79
8+5ϕ = f79′
8+7ϕ = f71′


The last four green ones could be omitted from the nobles-only section, if we don't need to encode any nobles beyond the first 32 (the "6th-order-limit").

With this format, the conversion of an existing 13-limit rationals-only PC-vector into a feudal PC-vector would look like this:

Figure 7

[ a  b  c  d  e  f ⟩
|  |  |  |  |\  \
[ a  b 2c  d  e  e  f; -2(c+e) 0 0 ... ⟩


i.e. The 5-count must be doubled, the 11-count duplicated and the unit-count set to the negative of double the sum of the 5 and 11 counts.

When we are representing nobles independent of any rational prime limit, the PC-vectors will begin with a semicolon, and will list (non-wooden) primes in lexicographic order of their a+bϕ form. Assuming 6th-order-limit nobles, the vectors will be of the form:

[; α β γ δ ε ζ η θ ι κ λ μ ν ξ π ρ

Where α (alpha) is the count of units, β (beta) is the count of prime 2+1ϕ, γ (gamma) is the count of prime 3+1ϕ, etc, up to the 16th entry ρ (rho) as the count of prime 8+5ϕ.

Dave Keenan
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Location: Brisbane, Queensland, Australia
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### Re: Noble frequency ratios as prime-count vectors in ℚ(√5) [superseded]

[Note: This thread is of historical interest only. Please see the updated version (using a better choice for the fundamental primes) at viewtopic.php?p=4609#p4609]

I've had some fun naming the orders of nobles on the Stern-Brocot tree. To get enough names, I've rationalised multiple European nobility ranking systems, but I've used English words. The result is closest to the French system. I made up the adjectives for the middle three orders, as I couldn't find any existing. I note that "marquis" is pronounced "mar-KEE" in the original French, but has been anglicised as "MAR-kwis".

Table 10

1. prince, princes, princely
2. duke, dukes, ducal
3. marquis, marquises, marquial
4. count, counts, countial
5. viscount, viscounts, viscountial
6. baron, barons, baronial
7. knight, knights, knightly
8. lord, lords, lordly

If you wanted to use the corresponding female terms, they could be applied to the left half of the Stern-Brocot tree, which contains the reciprocals of the right half that we use here. These are not usually used as frequency ratios, but are used as fractions of an octave in generating noble MOS scales.

I designed the terminology used in this thread so as not to clash with the terminology used in Douglas Blumeyer's article Metallic MOS. I note that feudalism and aristocracy are distinct medieval sociopolitical systems.

Here are the first 32 nobles on the Stern-Brocot tree (the 6th-order-limit nobles), in cents, and as feudal numbers in normal form. Units are shown as 1, ϕ, ϕ², but I remind you they can also be written as 1+0ϕ, 0+1ϕ, 1+1ϕ.

Figure 8   Stern-Brocot tree

Order 6      5          4              3               2     1
barons viscounts  counts         marquises       duke prince
1:1 \
/ |
7:6 \                                                       | .
284c (5+1ϕ)/(4+1ϕ)                                      | .
6:5 \                                                | .
/     339c (4+1ϕ)/(3+1ϕ)                               |
11:9 /        \                                              |
\                                             |
5:4 \                                       |
/      \                                      |
14:11\        /        \                                     |
\      /         422c (3+1ϕ)/(2+1ϕ)                    |
9:7 /            \                                   |
448c (5+4ϕ)/(4+3ϕ)   \                                  |
13:10/                     \                                 |
\                                |
4:3 \                          |
/      \                         |
15:11\                     /        \                        |
541c (7+4ϕ)/(5+3ϕ)   /          \                       |
11:8 \            /            \                      |
/      \          /             560c (2+1ϕ)/ϕ²         |
18:13/        \        /                \                    |
\      /                  \                   |
7:5 /                    \                  |
/                           \                 |
17:12\        /                             \                |
\     607c (4+3ϕ)/(3+2ϕ)               \               |
10:7 /                                 \              |
630c (7+3ϕ)/(5+2ϕ)                        \             |
13:9 /                                          \            |
\           |
3:2 \     |
/     |     |
14:9 \                                          /      |     |
771c (8+3ϕ)/(5+2ϕ)                        /       |     |
11:7 \                                 /        |     |
/     792c (5+3ϕ)/(3+2ϕ)               /         |     |
19:12/        \                             /          |     |
\                           /           |     |
8:5 \                    /            |     |
/      \                  /             |     |
21:13\        /        \                /              |     |
\      /          \              /               |   833c ϕ/1
13:8 /            \            /                |     |
849c (8+5ϕ)/(5+3ϕ)   \          /                 |     |
18:11/                     \        /                  |     |
\      /                   |     |
5:3 /                    |     |
/                          |     |
17:10\                     /                           |     |
923c (7+5ϕ)/(4+3ϕ)   /                            |     |
12:7 \            /                             |     |
/      \         943c (3+2ϕ)/(2+1ϕ)              |     |
19:11/        \        /                               |     |
\      /                                |     |
7:4 /                                 |     |
/                                       |     |
16:9 \        /                                        |     |
\    1002c (5+2ϕ)/(3+1ϕ)                         |     |
9:5 /                                          |     |
1039c (7+2ϕ)/(4+1ϕ)                                |     |
11:6 /                                                 |     |
\     /
Order 6      5          4              3                 2:1
/
11:5 \                                                 |
1378c (7+2ϕ)/(3+1ϕ)                                |
9:4 \                                          |
/    1424c (5+2ϕ)/(2+1ϕ)                         |
16:7 /        \                                        |
\                                       |
7:3 \                                 |
/      \                                |
19:8 \        /        \                               |
\      /        1503c (3+2ϕ)/ϕ²                  |
12:5 /            \                             |
1530c (7+5ϕ)/(3+2ϕ)   \                            |
17:7 /                     \                           |
\                          |
5:2 \                    |
/      \                   |
18:7 \                     /        \                  |
1641c (8+5ϕ)/(3+2ϕ)   /          \                 |
13:5 \            /            \                |
/      \          /              \             1666c ϕ²/1
21:8 /        \        /                \              |
\      /                  \             |
8:3 /                    \            |
/                           \           |
19:7 \        /                             \          |
\    1735c (5+3ϕ)/(2+1ϕ)               \         |
11:4 /                                 \        |
1772c (8+3ϕ)/(3+1ϕ)                        \       |
14:5 /                                          \      |
\     |
3:1 /
/
13:4 \                                          /
2055c (7+3ϕ)/(2+1ϕ)                        /
10:3 \                                 /
/    2109c (4+3ϕ)/ϕ²                   /
17:5 /        \                             /
\                           /
7:2 \                    /
/      \                  /
18:5 \        /        \                /
\      /          \            2226c (2+1ϕ)/1
11:3 /            \            /
2276c (7+4ϕ)/(2+1ϕ)   \          /
15:4 /                     \        /
\      /
4:1 /
/
13:3 \                     /
2558c (5+4ϕ)/ϕ²       /
9:2 \            /
/      \        2649c (3+1ϕ)/1
14:3 /        \        /
\      /
5:1 /
/
11:2 \        /
\    2988c (4+1ϕ)/1                                      .
6:1 /                                                  .
3272c (5+1ϕ)/1                                             .
7:1 /                                                         |
\
1:0
barons viscounts  counts         marquises       duke prince
Order 6      5          4              3               2     1


Dave Keenan
Posts: 2092
Joined: Tue Sep 01, 2015 2:59 pm
Location: Brisbane, Queensland, Australia
Contact:

### Re: Noble frequency ratios as prime-count vectors in ℚ(√5) [superseded]

[Note: This thread is of historical interest only. Please see the updated version (using a better choice for the fundamental primes) at viewtopic.php?p=4610#p4610]

We like to visualise the common factors among a set of rational pitches by displaying them on a prime lattice. However a lattice may not be the best way to visualise the common factor relationships between nobles, because there are so many prime dimensions, and the count of each prime is so low, only -1, 0 or 1 (and only -2, -1, 0, 1, 2 for the unit ϕ).

Here's what might be called an "order-limit triangle" analogous to an "odd-limit diamond". This one is limited to nobles up to the 6th-order. And of course it needs to contain units as well as primes. The primes are listed in lexicographic order.

Table 11

numerator |	ϕ⁰	ϕ¹	ϕ²	f5	f11	f11′	f19	f19′	f29	f31	f31′	f29′	f59	f61	f61′	f59′	f79	f79′
|	1.000	1.618	2.618	3.618	4.618	6.236	5.618	8.854	6.618	8.236	9.854	11.472	10.236	11.854	13.472	15.090	12.854	16.090
denominator	      |	1+0ϕ	0+1ϕ	1+1ϕ	2+1ϕ	3+1ϕ	3+2ϕ	4+1ϕ	4+3ϕ	5+1ϕ	5+2ϕ	5+3ϕ	5+4ϕ	7+2ϕ	7+3ϕ	7+4ϕ	7+5ϕ	8+3ϕ	8+5ϕ
------------------+-----------------------------------------------------------------------------------------------------------------------------------------------
ϕ⁰	1.000	1+0ϕ  |		 833c	1666c	2226c	2649c		2988c		3272c
ϕ¹	1.618	0+1ϕ  |			 833c
ϕ²	2.618	1+1ϕ  |				 560c		1503c		2109c				2558c
3.618	2+1ϕ  |					 422c	 943c				1424c	1735c			2055c	2276c
4.618	3+1ϕ  |							 339c			1002c			1378c				1772c
6.236	3+2ϕ  |								 607c			 792c					1530c		1641c
5.618	4+1ϕ  |									 284c				1039c
8.854	4+3ϕ  |												 448c				 923c
6.618	5+1ϕ  |
8.236	5+2ϕ  |														 630c			 771c
9.854	5+3ϕ  |															 541c			 849c


Perhaps it's better transposed, so as not to require horizontal scrolling, even though this puts the denominators above the numerators:

Table 12

denominator  |	ϕ⁰	ϕ¹	ϕ²
|	1.000	1.618	2.618	3.618	4.618	6.236	5.618	8.854	6.618	8.236	9.854
numerator	      |	1+0ϕ	0+1ϕ	1+1ϕ	2+1ϕ	3+1ϕ	3+2ϕ	4+1ϕ	4+3ϕ	5+1ϕ	5+2ϕ	5+3ϕ
--------------------+--------------------------------------------------------------------------------------
ϕ⁰	1.000	1+0ϕ  |
ϕ¹	1.618	0+1ϕ  |	 833c
ϕ²	2.618	1+1ϕ  |	1666c	 833c
f5	3.618	2+1ϕ  |	2226c		 560c
f11	4.618	3+1ϕ  |	2649c			 422c
f11′	6.236	3+2ϕ  |			1503c	 943c
f19	5.618	4+1ϕ  |	2988c				 339c
f19′	8.854	4+3ϕ  |			2109c			 607c
f29	6.618	5+1ϕ  |	3272c						 284c
f31	8.236	5+2ϕ  |				1424c	1002c
f31′	9.854	5+3ϕ  |				1735c		 792c
f29′	11.472	5+4ϕ  |			2558c					 448c
f59	10.236	7+2ϕ  |					1378c		1039c
f61	11.854	7+3ϕ  |				2055c						 630c
f61′	13.472	7+4ϕ  |				2276c							 541c
f59′	15.090	7+5ϕ  |						1530c		 923c
f79	12.854	8+3ϕ  |					1772c					 771c
f79′	16.090	8+5ϕ  |						1641c					 849c


And here the units and primes are listed in order of their size as a real number:

Table 13
denominator  |	ϕ⁰	ϕ¹	ϕ²
|	1.000	1.618	2.618	3.618	4.618	5.618	6.236	6.618	8.236	8.854	9.854
numerator	      |	1+0ϕ	0+1ϕ	1+1ϕ	2+1ϕ	3+1ϕ	4+1ϕ	3+2ϕ	5+1ϕ	5+2ϕ	4+3ϕ	5+3ϕ
--------------------+--------------------------------------------------------------------------------------
ϕ⁰	1.000	1+0ϕ  |
ϕ¹	1.618	0+1ϕ  |	 833c
ϕ²	2.618	1+1ϕ  |	1666c	 833c
f5	3.618	2+1ϕ  |	2226c		 560c
f11	4.618	3+1ϕ  |	2649c			 422c
f19	5.618	4+1ϕ  |	2988c				 339c
f11′	6.236	3+2ϕ  |			1503c	 943c
f29	6.618	5+1ϕ  |	3272c					 284c
f31	8.236	5+2ϕ  |				1424c	1002c
f19′	8.854	4+3ϕ  |			2109c				 607c
f31′	9.854	5+3ϕ  |				1735c			 792c
f59	10.236	7+2ϕ  |					1378c	1039c
f29′	11.472	5+4ϕ  |			2558c							 448c
f61	11.854	7+3ϕ  |				2055c					 630c
f79	12.854	8+3ϕ  |					1772c				 771c
f61′	13.472	7+4ϕ  |				2276c							 541c
f59′	15.090	7+5ϕ  |							1530c			 923c
f79′	16.090	8+5ϕ  |							1641c				 849c


If we wanted to use this triangle of nobles as a target interval set, for the tuning of some noble temperament, we might decide to truncate it to remove intervals larger than say 13/4 (2041 cents) (shown violet above) on the basis that these are so wide as to occur rarely, and to not require accurate tuning when they do. This leaves 24 nobles. We could then call it the "truncated 6th-order-limit triangle" and abbreviate it to the "6-TOLT", moving the "T" for "truncated" after the 6 to obtain a pronounceable acronym. This is analogous to the truncated integer-limit triangle (TILT) for rational intervals. [In future, the TILT article may be accessible via this link: TILT]

More likely than a purely noble temperament, would be a noble/rational temperament, in which case the target interval set could be the union of a TOLT and a TILT.

It's unfortunate that "order-limit" and "odd-limit" have the same abbreviation, so we are relying here on the fact that the corresponding odd-limit set is a diamond (OLD) rather than a triangle (TOLT, TILT).

Dave Keenan
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### Re: Noble frequency ratios as prime-count vectors in ℚ(√5) [superseded]

[Note: This thread is of historical interest only. Please see the updated version (using a better choice for the fundamental primes) at viewtopic.php?p=4611#p4611]

Here at last are the 6th-order-limit nobles as PC-vectors, in Stern-Brocot-tree reading-order of their mediends:

Table 14

Stern-	  Mediends	Cents	Quotient of	Prime count vector
Brocot	  (weighted)		feudal primes	      2+1ϕ  3+2ϕ  4+3ϕ  5+2ϕ  5+4ϕ  7+3ϕ  7+5ϕ  8+5ϕ
order	  1	  ϕ		or units	    ϕ    3+1ϕ  4+1ϕ  5+1ϕ  5+3ϕ  7+2ϕ  7+4ϕ  8+3ϕ
----------------------------------------------------------------------------------------------------
1	 1/1	 2/1	 833c	(0+1ϕ)/(1+0ϕ)	[;  1  0  0  0  0  0  0  0  0  0  0  0  0  0  0  0 ⟩
2	 2/1	 3/1	1666c	(1+1ϕ)/(1+0ϕ)	[;  2  0  0  0  0  0  0  0  0  0  0  0  0  0  0  0 ⟩
3	 3/2	 4/3	 560c	(2+1ϕ)/(1+1ϕ)	[; -2  1  0  0  0  0  0  0  0  0  0  0  0  0  0  0 ⟩
3	 3/1	 4/1	2226c	(2+1ϕ)/(1+0ϕ)	[;  0  1  0  0  0  0  0  0  0  0  0  0  0  0  0  0 ⟩
4	 4/3	 5/4	 422c	(3+1ϕ)/(2+1ϕ)	[;  0 -1  1  0  0  0  0  0  0  0  0  0  0  0  0  0 ⟩
4	 5/3	 7/4	 943c	(3+2ϕ)/(2+1ϕ)	[;  0 -1  0  1  0  0  0  0  0  0  0  0  0  0  0  0 ⟩
4	 5/2	 7/3	1503c	(3+2ϕ)/(1+1ϕ)	[; -2  0  0  1  0  0  0  0  0  0  0  0  0  0  0  0 ⟩
4	 4/1	 5/1	2649c	(3+1ϕ)/(1+0ϕ)	[;  0  0  1  0  0  0  0  0  0  0  0  0  0  0  0  0 ⟩
5	 5/4	 6/5	 339c	(4+1ϕ)/(3+1ϕ)	[;  0  0 -1  0  1  0  0  0  0  0  0  0  0  0  0  0 ⟩
5	 7/5	10/7	 607c	(4+3ϕ)/(3+2ϕ)	[;  0  0  0 -1  0  1  0  0  0  0  0  0  0  0  0  0 ⟩
5	 8/5	11/7	 792c	(5+3ϕ)/(3+2ϕ)	[;  0  0  0 -1  0  0  0  0  1  0  0  0  0  0  0  0 ⟩
5	 7/4	 9/5	1002c	(5+2ϕ)/(3+1ϕ)	[;  0  0 -1  0  0  0  0  1  0  0  0  0  0  0  0  0 ⟩
5	 7/3	 9/4	1424c	(5+2ϕ)/(2+1ϕ)	[;  0 -1  0  0  0  0  0  1  0  0  0  0  0  0  0  0 ⟩
5	 8/3	11/4	1735c	(5+3ϕ)/(2+1ϕ)	[;  0 -1  0  0  0  0  0  0  1  0  0  0  0  0  0  0 ⟩
5	 7/2	10/3	2109c	(4+3ϕ)/(1+1ϕ)	[; -2  0  0  0  0  1  0  0  0  0  0  0  0  0  0  0 ⟩
5	 5/1	 6/1	2988c	(4+1ϕ)/(1+0ϕ)	[;  0  0  0  0  1  0  0  0  0  0  0  0  0  0  0  0 ⟩
6	 6/5	 7/6	 284c	(5+1ϕ)/(4+1ϕ)	[;  0  0  0  0 -1  0  1  0  0  0  0  0  0  0  0  0 ⟩
6	 9/7	13/10	 448c	(5+4ϕ)/(4+3ϕ)	[;  0  0  0  0  0 -1  0  0  0  1  0  0  0  0  0  0 ⟩
6	11/8	15/11	 541c	(7+4ϕ)/(5+3ϕ)	[;  0  0  0  0  0  0  0  0 -1  0  0  0  1  0  0  0 ⟩
6	10/7	13/9	 630c	(7+3ϕ)/(5+2ϕ)	[;  0  0  0  0  0  0  0 -1  0  0  0  1  0  0  0  0 ⟩
6	11/7	14/9	 771c	(8+3ϕ)/(5+2ϕ)	[;  0  0  0  0  0  0  0 -1  0  0  0  0  0  0  1  0 ⟩
6	13/8	18/11	 849c	(8+5ϕ)/(5+3ϕ)	[;  0  0  0  0  0  0  0  0 -1  0  0  0  0  0  0  1 ⟩
6	12/7	17/10	 923c	(7+5ϕ)/(4+3ϕ)	[;  0  0  0  0  0 -1  0  0  0  0  0  0  0  1  0  0 ⟩
6	 9/5	11/6	1039c	(7+2ϕ)/(4+1ϕ)	[;  0  0  0  0 -1  0  0  0  0  0  1  0  0  0  0  0 ⟩
6	 9/4	11/5	1378c	(7+2ϕ)/(3+1ϕ)	[;  0  0 -1  0  0  0  0  0  0  0  1  0  0  0  0  0 ⟩
6	12/5	17/7	1530c	(7+5ϕ)/(3+2ϕ)	[;  0  0  0 -1  0  0  0  0  0  0  0  0  0  1  0  0 ⟩
6	13/5	18/7	1641c	(8+5ϕ)/(3+2ϕ)	[;  0  0  0 -1  0  0  0  0  0  0  0  0  0  0  0  1 ⟩
6	11/4	14/5	1772c	(8+3ϕ)/(3+1ϕ)	[;  0  0 -1  0  0  0  0  0  0  0  0  0  0  0  1  0 ⟩
6	10/3	13/4	2055c	(7+3ϕ)/(2+1ϕ)	[;  0 -1  0  0  0  0  0  0  0  0  0  1  0  0  0  0 ⟩
6	11/3	15/4	2276c	(7+4ϕ)/(2+1ϕ)	[;  0 -1  0  0  0  0  0  0  0  0  0  0  1  0  0  0 ⟩
6	 9/2	13/3	2558c	(5+4ϕ)/(1+1ϕ)	[; -2  0  0  0  0  0  0  0  0  1  0  0  0  0  0  0 ⟩
6	 6/1	 7/1	3272c	(5+1ϕ)/(1+0ϕ)	[;  0  0  0  0  0  0  1  0  0  0  0  0  0  0  0  0 ⟩


And here we list them in order of their size in cents:

Table 15

Stern-	  Mediends	Cents	Quotient of	Prime count vector
Brocot	  (weighted)		feudal primes	      2+1ϕ  3+2ϕ  4+3ϕ  5+2ϕ  5+4ϕ  7+3ϕ  7+5ϕ  8+5ϕ
order	  1	  ϕ		or units	    ϕ    3+1ϕ  4+1ϕ  5+1ϕ  5+3ϕ  7+2ϕ  7+4ϕ  8+3ϕ
----------------------------------------------------------------------------------------------------
6	 6/5	 7/6	 284c	(5+1ϕ)/(4+1ϕ)	[;  0  0  0  0 -1  0  1  0  0  0  0  0  0  0  0  0 ⟩
5	 5/4	 6/5	 339c	(4+1ϕ)/(3+1ϕ)	[;  0  0 -1  0  1  0  0  0  0  0  0  0  0  0  0  0 ⟩
4	 4/3	 5/4	 422c	(3+1ϕ)/(2+1ϕ)	[;  0 -1  1  0  0  0  0  0  0  0  0  0  0  0  0  0 ⟩
6	 9/7	13/10	 448c	(5+4ϕ)/(4+3ϕ)	[;  0  0  0  0  0 -1  0  0  0  1  0  0  0  0  0  0 ⟩
6	11/8	15/11	 541c	(7+4ϕ)/(5+3ϕ)	[;  0  0  0  0  0  0  0  0 -1  0  0  0  1  0  0  0 ⟩
3	 3/2	 4/3	 560c	(2+1ϕ)/(1+1ϕ)	[; -2  1  0  0  0  0  0  0  0  0  0  0  0  0  0  0 ⟩
5	 7/5	10/7	 607c	(4+3ϕ)/(3+2ϕ)	[;  0  0  0 -1  0  1  0  0  0  0  0  0  0  0  0  0 ⟩
6	10/7	13/9	 630c	(7+3ϕ)/(5+2ϕ)	[;  0  0  0  0  0  0  0 -1  0  0  0  1  0  0  0  0 ⟩
6	11/7	14/9	 771c	(8+3ϕ)/(5+2ϕ)	[;  0  0  0  0  0  0  0 -1  0  0  0  0  0  0  1  0 ⟩
5	 8/5	11/7	 792c	(5+3ϕ)/(3+2ϕ)	[;  0  0  0 -1  0  0  0  0  1  0  0  0  0  0  0  0 ⟩
1	 1/1	 2/1	 833c	(0+1ϕ)/(1+0ϕ)	[;  1  0  0  0  0  0  0  0  0  0  0  0  0  0  0  0 ⟩
6	13/8	18/11	 849c	(8+5ϕ)/(5+3ϕ)	[;  0  0  0  0  0  0  0  0 -1  0  0  0  0  0  0  1 ⟩
6	12/7	17/10	 923c	(7+5ϕ)/(4+3ϕ)	[;  0  0  0  0  0 -1  0  0  0  0  0  0  0  1  0  0 ⟩
4	 5/3	 7/4	 943c	(3+2ϕ)/(2+1ϕ)	[;  0 -1  0  1  0  0  0  0  0  0  0  0  0  0  0  0 ⟩
5	 7/4	 9/5	1002c	(5+2ϕ)/(3+1ϕ)	[;  0  0 -1  0  0  0  0  1  0  0  0  0  0  0  0  0 ⟩
6	 9/5	11/6	1039c	(7+2ϕ)/(4+1ϕ)	[;  0  0  0  0 -1  0  0  0  0  0  1  0  0  0  0  0 ⟩
6	 9/4	11/5	1378c	(7+2ϕ)/(3+1ϕ)	[;  0  0 -1  0  0  0  0  0  0  0  1  0  0  0  0  0 ⟩
5	 7/3	 9/4	1424c	(5+2ϕ)/(2+1ϕ)	[;  0 -1  0  0  0  0  0  1  0  0  0  0  0  0  0  0 ⟩
4	 5/2	 7/3	1503c	(3+2ϕ)/(1+1ϕ)	[; -2  0  0  1  0  0  0  0  0  0  0  0  0  0  0  0 ⟩
6	12/5	17/7	1530c	(7+5ϕ)/(3+2ϕ)	[;  0  0  0 -1  0  0  0  0  0  0  0  0  0  1  0  0 ⟩
6	13/5	18/7	1641c	(8+5ϕ)/(3+2ϕ)	[;  0  0  0 -1  0  0  0  0  0  0  0  0  0  0  0  1 ⟩
2	 2/1	 3/1	1666c	(1+1ϕ)/(1+0ϕ)	[;  2  0  0  0  0  0  0  0  0  0  0  0  0  0  0  0 ⟩
5	 8/3	11/4	1735c	(5+3ϕ)/(2+1ϕ)	[;  0 -1  0  0  0  0  0  0  1  0  0  0  0  0  0  0 ⟩
6	11/4	14/5	1772c	(8+3ϕ)/(3+1ϕ)	[;  0  0 -1  0  0  0  0  0  0  0  0  0  0  0  1  0 ⟩
6	10/3	13/4	2055c	(7+3ϕ)/(2+1ϕ)	[;  0 -1  0  0  0  0  0  0  0  0  0  1  0  0  0  0 ⟩
5	 7/2	10/3	2109c	(4+3ϕ)/(1+1ϕ)	[; -2  0  0  0  0  1  0  0  0  0  0  0  0  0  0  0 ⟩
3	 3/1	 4/1	2226c	(2+1ϕ)/(1+0ϕ)	[;  0  1  0  0  0  0  0  0  0  0  0  0  0  0  0  0 ⟩
6	11/3	15/4	2276c	(7+4ϕ)/(2+1ϕ)	[;  0 -1  0  0  0  0  0  0  0  0  0  0  1  0  0  0 ⟩
6	 9/2	13/3	2558c	(5+4ϕ)/(1+1ϕ)	[; -2  0  0  0  0  0  0  0  0  1  0  0  0  0  0  0 ⟩
4	 4/1	 5/1	2649c	(3+1ϕ)/(1+0ϕ)	[;  0  0  1  0  0  0  0  0  0  0  0  0  0  0  0  0 ⟩
5	 5/1	 6/1	2988c	(4+1ϕ)/(1+0ϕ)	[;  0  0  0  0  1  0  0  0  0  0  0  0  0  0  0  0 ⟩
6	 6/1	 7/1	3272c	(5+1ϕ)/(1+0ϕ)	[;  0  0  0  0  0  0  1  0  0  0  0  0  0  0  0  0 ⟩


Dave Keenan
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Joined: Tue Sep 01, 2015 2:59 pm
Location: Brisbane, Queensland, Australia
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### Re: Noble frequency ratios as prime-count vectors in ℚ(√5) [superseded]

[Note: This thread is of historical interest only. Please see the updated version (using a better choice for the fundamental primes) at viewtopic.php?p=4612#p4612]

By searching on "2, 3, 7, 13, 17, 23, 37, 43, 47, 53, 67, 73" (wooden primes) in the OEIS, I found a reference to this book:
F. W. Dodd, Number Theory in the Quadratic Field with Golden Section Unit, Polygon Publishing House, Passaic, NJ 07055, 1983.
It is online here:
https://archive.org/details/numbertheor ... d/mode/2up
You just need to sign up for an account to "borrow" the book for an hour at a time, provided no one else is doing so.

There's some interesting stuff in there from a pure math perspective, beyond the things I've described above. Notably the concepts of conjugates and arithmetic norms (unfortunately very different from the vector norms used in advanced RTT). But I haven't yet found this additional material useful for our application. Although it did make me realise that when ordinary primes are composite in the feudal system, their two prime factors are complements, in the sense that if one is a+bϕ, the other is (a+bϕ)′ = a+(a-b)ϕ. e.g. the prime factors of 31 are 5+2ϕ and 5+(5-2)ϕ = 5+3ϕ.

Conjugates have a simple form when the feudal basis is (1, √5), but when using a basis of (1, ϕ) = (1, (1+√5)/2), as is most convenient for representing our nobles, conjugates are messy, having negative golden parts, unless you introduce a symbol such as ϕ̅ (phi bar) for the negative unit -1/ϕ = -ϕ⁻¹ = 1-1ϕ = (1-√5)/2 as Dodd does. But this leads to other problems such as the appearance that 5 has two different prime factors (2+1ϕ)(2+1ϕ̅), i.e. 2+1ϕ and its conjugate, when in fact (2+1ϕ̅) is an associate of (2+1ϕ) since (2+1ϕ̅) = (2+1ϕ)ϕ⁻². This is why I've defined the complement above. The complement is simply the conjugate multiplied by ϕ².

The arithmetic norm (pronounced AR-ith-MET-ik norm) has symbol "N" and is defined such that N(a+bϕ) = a²+ab-b². It has only rational values (which may be negative, unlike vector norms) and has the properties that
N(αβ) = N(α)N(β)
N(α/β) = N(α)/N(β) when β≠0.

What we need now, is for some clever volunteers to do computer searches for noble commas, and noble/rational commas, that can form null-space bases for temperaments. A first test might be to see if you can find a feudal-comma basis for Margo Schulter's Zest-24 tuning as used in her sampler of noble/rational cadences. [Not you, Douglas Blumeyer. We have other fish to fry. ]

Paul Erlich pointed out that 72-edo should be fertile ground to look for feudal commas.

As I said at the start of this series, there's no guarantee this will lead to anything useful. But I hope some fellow students of tuning-math find it interesting enough to investigate, if only as a form of recreational math.

Dave Keenan