Tuning map: Difference between revisions

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A '''tuning map''' represents the tuning of a [[regular temperament]]. It can take a vector representation of an interval ([[monzo]]) as input and outputs its ~~pitch, usually measured in cents or octaves~~.

A '''tuning map''' represents the tuning of a [[regular temperament]]. It specifies the tuning of a temperament in terms of logarithmic [[interval size unit]]s (such as [[cent]]s or [[octave]]s) rather than scale steps. It can take a vector representation of an interval ([[monzo]]) as input and outputs its tempered size.

A tuning map has one entry for each [[basis element]] of the temperament, giving its size in ~~[[cent]]s or [[octave]]s (~~or any other logarithmic ~~pitch~~ unit).

A tempered-prime tuning map has one entry for each [[basis element]] of the temperament's JI subgroup (e.g. 2, 9, 5 in a 2.9.5-subgroup temperament), giving its size in cents, octaves, or any other logarithmic interval size unit.

It may be helpful, then, to think of the units of each entry of a tuning map as <math>{\large\mathsf{¢}}\small /𝗽</math> (read "cents per prime"), <math>\small \mathsf{oct}/𝗽</math> (read "octaves per prime"), or any other logarithmic pitch unit per prime (for more information, see [[Dave Keenan & Douglas Blumeyer's guide to RTT~~: units~~ analysis]]).

It may be helpful, then, to think of the units of each entry of a tuning map as <math>{\large\mathsf{¢}}\small /𝗽</math> (read "cents per prime"), <math>\small \mathsf{oct}/𝗽</math> (read "octaves per prime"), or any other logarithmic pitch unit per prime (for more information, see [[Dave Keenan & Douglas Blumeyer's guide to RTT/Units analysis]]).

== Generator tuning map ==

A '''generator tuning map''' is similar to a (tempered-prime) tuning map, but it specifies a tuning for a temperament by giving the sizes of its generators. Each entry of the generator tuning map gives the size of a different [[generator]]. It takes a vector in tempered interval space (a "[[tmonzos and tvals|tmonzo]]").

A '''generator tuning map''' is ~~like~~ a (~~temperament~~) tuning map, but ~~each~~ entry gives the size ~~in cents or octaves~~ of a different [[generator]]~~, rather than of~~ a ~~formal prime~~.

It may be helpful, then, to think of the units of each entry of a generator tuning map as <math>{\large\mathsf{¢}}\small /𝗴</math> (read "cents per generator"), <math>\small \mathsf{oct}/𝗴</math> (read "octaves per generator"), or any other logarithmic pitch unit per generator.

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$$T = GM$$

To go the other ~~way — that~~ is, to find the generator tuning map from the ~~(primes)~~ tuning ~~map — we~~ can multiply the tuning map by any right-inverse of the mapping, such as the [[pseudoinverse]] ''M''+, as in

To go the other way – that is, to find the generator tuning map from the ordinary tuning map – we can multiply the tuning map by any right-inverse of the mapping, such as the [[pseudoinverse]] ''M''+, as in

$$G = TM^{+}$$

For a detailed explanation see [[Dave Keenan %26 Douglas Blumeyer%27s guide to RTT~~: tuning~~ in nonstandard domains #9. Find pseudoinverse]].

Note that this only works if the original tuning of the primes was valid for the temperament. For a detailed explanation see [[Dave Keenan %26 Douglas Blumeyer%27s guide to RTT/Tuning in nonstandard domains #9. Find pseudoinverse]].

== With respect to JIP ==

[[JI]] can be conceptualized as the temperament where no intervals are made to [[vanish]], and as such, the untempered primes can be thought of as its generators~~, or of course its basis elements~~. So, JI subgroups have ~~generator~~ tuning maps and tuning maps too; the ~~generator~~ tuning maps and tuning maps are always the same thing as each other, and they are all subsets of the entries of the [[JIP]].

[[JI]] can be conceptualized as the temperament where no intervals are made to [[vanish]], and as such, the untempered primes can be thought of as its generators. So, JI subgroups have tuning maps and generator tuning maps too; the tuning maps and generator tuning maps are always the same thing as each other, and they are all subsets of the entries of the [[JIP]].

== Error map ==

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Consider meantone temperament, with the mapping {{mapping| 1 1 0 | 0 1 4 }}. Temperaments, as represented by mappings, remain abstract; while this mapping does convey that the generators are ~2/1 and ~3/2, it does not specify exact tunings for those approximations. One example tuning would be quarter-comma meantone, where the octave is pure and the perfect fifth is 51/4; this gives a generator tuning map of {{map| 1200.000 696.578 }}.

The tuning map from ''G'' = {{map| 1200.000 696.578 }} and ''M'' = {{mapping| 1 1 0 | 0 1 4 }} is ''T'' = {{map| 1200.000 1896.578 2786.314 }}. For the error map we use ''J'' = {{val| 1200.000 1901.955 2786.314 }} and find ''Ɛ'' = {{val| 0.000 -5.377 0.000 }}, showing us prime 3 is tempered flat by 5.377 cents while primes 2 and 5 are pure.

The tuning map from {{nowrap|''G'' {{=}} {{map| 1200.000 696.578 }}}} and {{nowrap|''M'' {{=}} {{mapping| 1 1 0 | 0 1 4 }}}} is {{nowrap|''T'' {{=}} {{map| 1200.000 1896.578 2786.314 }}}}. For the error map we use {{nowrap|''J'' {{=}} {{val| 1200.000 1901.955 2786.314 }}}} and find {{nowrap|''Ɛ'' {{=}} {{val| 0.000 -5.377 0.000 }}}}, showing us prime 3 is tempered flat by 5.377 cents while primes 2 and 5 are pure.

So, to answer the question, "how many cents is the approximation of the interval 16/15 in quarter-comma meantone?" we use the dot product to map 16/15's [[prime-count vector]] {{vector| 4 -1 -1 }} via the tuning map given above, 4×1200.000 + (-1)~~×1896~~.578 + (-1)~~×2786~~.314 = 117.108 ~~cents~~. Similarly, to answer "how many cents is the approximation different from JI?" we go through the same process via the error map: ~~4×0~~.000 + (-1)×(-5.377) + (-1)×0.000 = +5.377 ~~cents~~.

So, to answer the question, "how many cents is the approximation of the interval 16/15 in quarter-comma meantone?" we use the dot product to map 16/15's [[prime-count vector]] {{vector| 4 -1 -1 }} via the tuning map given above, {{nowrap|4×1200.000 + (−1) × 1896.578 + (−1) × 2786.314 {{=}} 117.108{{cent}}}}. Similarly, to answer "how many cents is the approximation different from JI?" we go through the same process via the error map: {{nowrap| 4 × 0.000 + (−1) × (-5.377) + (−1) × 0.000 {{=}} +5.377{{c}} }}.

Another example tuning for meantone would be the [[TE tuning]], which is the default that [http://x31eq.com/temper|~~Graham~~ Breed's popular RTT web tool] provides. This gives us a tuning map of {{map| 1201.397 1898.446 2788.196 }} and error map of {{val| +1.397 -3.509 +1.882 }}. To answer the same questions about 16/15 in this tuning of meantone, we use the same prime count vector, but map it with these different tuning and error maps. So that gives us ~~4×1201~~.397 + (-1)~~×1898~~.446 + (-1)~~×2788~~.196 = 118.946 ~~cents~~ and ~~4×1~~.397 + (-1)×(-3.509) + (-1~~)×1~~.882 = +7.215 ~~cents~~, respectively. And that is our answer for TE meantone.

Another example tuning for meantone would be the [[TE tuning]], which is the default that [http://x31eq.com/temper|Breed's popular RTT web tool] provides. This gives us a tuning map of {{map| 1201.397 1898.446 2788.196 }} and error map of {{val| +1.397 -3.509 +1.882 }}. To answer the same questions about 16/15 in this tuning of meantone, we use the same prime count vector, but map it with these different tuning and error maps. So that gives us {{nowrap| 4 × 1201.397 + (−1) × 1898.446 + (−1) × 2788.196 {{=}} 118.946{{c}} }} and {{nowrap| 4 × 1.397 + (−1) × (−3.509) + (−1) × 1.882 {{=}} +7.215{{c}} }}, respectively. And that is our answer for TE meantone.

== Cents versus octaves ==

Sometimes you will see tuning maps given in octaves instead of cents. They work the same exact way. The only difference is that these octave-based tuning maps have each entry divided by 1200. For example, the quarter-comma meantone tuning map, in octaves, would be {{map|1200 1896.578 2786.314}}/1200 = {{map|1 1.580 2.322}}. If we dot product {{vector|4 -1 -1}} with that, we get ~~4×1~~ + (-1~~)×1~~.580 + (-1)×2.322 = 0.098, which tells us that 16/15 is a little less than 1/10 of an octave here.

Sometimes you will see tuning maps given in octaves instead of cents. They work the same exact way. The only difference is that these octave-based tuning maps have each entry divided by 1200. For example, the quarter-comma meantone tuning map, in octaves, would be {{map| 1200 1896.578 2786.314 }}/1200 = {{map| 1 1.580 2.322 }}. If we dot product {{vector| 4 -1 -1 }} with that, we get {{nowrap| 4 × 1 + (−1) × 1.580 + (−1) × 2.322 {{=}} 0.098 }}, which tells us that 16/15 is a little less than 1/10 of an octave here.

== With respect to linear algebra ==

A tuning map can be thought of ~~either~~ as a ~~one-row~~ matrix ~~or as~~ a ~~covector~~. The same is true of error maps and generator tuning maps.

A tuning map is a real-valued linear form (or covector). If we identify interval space with the integer lattice, it is a linear map <math>\varphi: \mathbb{Z}^n \to \mathbb{R}</math>, which projects abstract intervals onto the real line which measures pitch. It can also be thought of as a matrix with a single row. The same is true of error maps and generator tuning maps.

[[Category:Regular temperament tuning| ]]

[[Category:Regular temperament tuning| ]]

[[Category:Terms]]

[[Category:Math]]

[[Category:Val]]

@@ Line 1: / Line 1: @@
-A '''tuning map''' represents the tuning of a [[regular temperament]]. It can take a vector representation of an interval ([[monzo]]) as input and outputs its pitch, usually measured in cents or octaves.
+A '''tuning map''' represents the tuning of a [[regular temperament]]. It specifies the tuning of a temperament in terms of logarithmic [[interval size unit]]s (such as [[cent]]s or [[octave]]s) rather than scale steps. It can take a vector representation of an interval ([[monzo]]) as input and outputs its tempered size.
-A tuning map has one entry for each [[basis element]] of the temperament, giving its size in [[cent]]s or [[octave]]s (or any other logarithmic pitch unit).
+A tempered-prime tuning map has one entry for each [[basis element]] of the temperament's JI subgroup (e.g. 2, 9, 5 in a 2.9.5-subgroup temperament), giving its size in cents, octaves, or any other logarithmic interval size unit.
-It may be helpful, then, to think of the units of each entry of a tuning map as <math>{\large\mathsf{¢}}\small /𝗽</math> (read "cents per prime"), <math>\small \mathsf{oct}/𝗽</math> (read "octaves per prime"), or any other logarithmic pitch unit per prime (for more information, see [[Dave Keenan & Douglas Blumeyer's guide to RTT: units analysis]]).
+It may be helpful, then, to think of the units of each entry of a tuning map as <math>{\large\mathsf{¢}}\small /𝗽</math> (read "cents per prime"), <math>\small \mathsf{oct}/𝗽</math> (read "octaves per prime"), or any other logarithmic pitch unit per prime (for more information, see [[Dave Keenan & Douglas Blumeyer's guide to RTT/Units analysis]]).
 == Generator tuning map ==
+A '''generator tuning map''' is similar to a (tempered-prime) tuning map, but it specifies a tuning for a temperament by giving the sizes of its generators. Each entry of the generator tuning map gives the size of a different [[generator]]. It takes a vector in tempered interval space (a "[[tmonzos and tvals|tmonzo]]").
-A '''generator tuning map''' is like a (temperament) tuning map, but each entry gives the size in cents or octaves of a different [[generator]], rather than of a formal prime.
 It may be helpful, then, to think of the units of each entry of a generator tuning map as <math>{\large\mathsf{¢}}\small /𝗴</math> (read "cents per generator"), <math>\small \mathsf{oct}/𝗴</math> (read "octaves per generator"), or any other logarithmic pitch unit per generator.
@@ Line 15: / Line 14: @@
 $$T = GM$$
-To go the other way — that is, to find the generator tuning map from the (primes) tuning map — we can multiply the tuning map by any right-inverse of the mapping, such as the [[pseudoinverse]] ''M''<sup>+</sup>, as in
+To go the other way – that is, to find the generator tuning map from the ordinary tuning map – we can multiply the tuning map by any right-inverse of the mapping, such as the [[pseudoinverse]] ''M''<sup>+</sup>, as in
 $$G = TM^{+}$$
-For a detailed explanation see [[Dave Keenan %26 Douglas Blumeyer%27s guide to RTT: tuning in nonstandard domains #9. Find pseudoinverse]].
+Note that this only works if the original tuning of the primes was valid for the temperament. For a detailed explanation see [[Dave Keenan %26 Douglas Blumeyer%27s guide to RTT/Tuning in nonstandard domains #9. Find pseudoinverse]].
 == With respect to JIP ==
 {{Main| JIP }}
-[[JI]] can be conceptualized as the temperament where no intervals are made to [[vanish]], and as such, the untempered primes can be thought of as its generators, or of course its basis elements. So, JI subgroups have generator tuning maps and tuning maps too; the generator tuning maps and tuning maps are always the same thing as each other, and they are all subsets of the entries of the [[JIP]].
+[[JI]] can be conceptualized as the temperament where no intervals are made to [[vanish]], and as such, the untempered primes can be thought of as its generators. So, JI subgroups have tuning maps and generator tuning maps too; the tuning maps and generator tuning maps are always the same thing as each other, and they are all subsets of the entries of the [[JIP]].
 == Error map ==
@@ Line 34: / Line 33: @@
 Consider meantone temperament, with the mapping {{mapping| 1 1 0 | 0 1 4 }}. Temperaments, as represented by mappings, remain abstract; while this mapping does convey that the generators are ~2/1 and ~3/2, it does not specify exact tunings for those approximations. One example tuning would be quarter-comma meantone, where the octave is pure and the perfect fifth is 5<sup>1/4</sup>; this gives a generator tuning map of {{map| 1200.000 696.578 }}.
-The tuning map from ''G'' = {{map| 1200.000 696.578 }} and ''M'' = {{mapping| 1 1 0 | 0 1 4 }} is ''T'' = {{map| 1200.000 1896.578 2786.314 }}. For the error map we use ''J'' = {{val| 1200.000 1901.955 2786.314 }} and find ''Ɛ'' = {{val| 0.000 -5.377 0.000 }}, showing us prime 3 is tempered flat by 5.377 cents while primes 2 and 5 are pure.
+The tuning map from {{nowrap|''G'' {{=}} {{map| 1200.000 696.578 }}}} and {{nowrap|''M'' {{=}} {{mapping| 1 1 0 | 0 1 4 }}}} is {{nowrap|''T'' {{=}} {{map| 1200.000 1896.578 2786.314 }}}}. For the error map we use {{nowrap|''J'' {{=}} {{val| 1200.000 1901.955 2786.314 }}}} and find {{nowrap|''Ɛ'' {{=}} {{val| 0.000 -5.377 0.000 }}}}, showing us prime 3 is tempered flat by 5.377 cents while primes 2 and 5 are pure.
-So, to answer the question, "how many cents is the approximation of the interval 16/15 in quarter-comma meantone?" we use the dot product to map 16/15's [[prime-count vector]] {{vector| 4 -1 -1 }} via the tuning map given above, 4×1200.000 + (-1)×1896.578 + (-1)×2786.314 = 117.108 cents. Similarly, to answer "how many cents is the approximation different from JI?" we go through the same process via the error map: 4×0.000 + (-1)×(-5.377) + (-1)×0.000 = +5.377 cents.
+So, to answer the question, "how many cents is the approximation of the interval 16/15 in quarter-comma meantone?" we use the dot product to map 16/15's [[prime-count vector]] {{vector| 4 -1 -1 }} via the tuning map given above, {{nowrap|4×1200.000 + (−1) × 1896.578 + (−1) × 2786.314 {{=}} 117.108{{cent}}}}. Similarly, to answer "how many cents is the approximation different from JI?" we go through the same process via the error map: {{nowrap| 4 × 0.000 + (−1) × (-5.377) + (−1) × 0.000 {{=}} +5.377{{c}} }}.
-Another example tuning for meantone would be the [[TE tuning]], which is the default that [http://x31eq.com/temper|Graham Breed's popular RTT web tool] provides. This gives us a tuning map of {{map| 1201.397 1898.446 2788.196 }} and error map of {{val| +1.397 -3.509 +1.882 }}. To answer the same questions about 16/15 in this tuning of meantone, we use the same prime count vector, but map it with these different tuning and error maps. So that gives us 4×1201.397 + (-1)×1898.446 + (-1)×2788.196 = 118.946 cents and 4×1.397 + (-1)×(-3.509) + (-1)×1.882 = +7.215 cents, respectively. And that is our answer for TE meantone.
+Another example tuning for meantone would be the [[TE tuning]], which is the default that [http://x31eq.com/temper|Breed's popular RTT web tool] provides. This gives us a tuning map of {{map| 1201.397 1898.446 2788.196 }} and error map of {{val| +1.397 -3.509 +1.882 }}. To answer the same questions about 16/15 in this tuning of meantone, we use the same prime count vector, but map it with these different tuning and error maps. So that gives us {{nowrap| 4 × 1201.397 + (−1) × 1898.446 + (−1) × 2788.196 {{=}} 118.946{{c}} }} and {{nowrap| 4 × 1.397 + (−1) × (−3.509) + (−1) × 1.882 {{=}} +7.215{{c}} }}, respectively. And that is our answer for TE meantone.
 == Cents versus octaves ==
-Sometimes you will see tuning maps given in octaves instead of cents. They work the same exact way. The only difference is that these octave-based tuning maps have each entry divided by 1200. For example, the quarter-comma meantone tuning map, in octaves, would be {{map|1200 1896.578 2786.314}}/1200 = {{map|1 1.580 2.322}}. If we dot product {{vector|4 -1 -1}} with that, we get 4×1 + (-1)×1.580 + (-1)×2.322 = 0.098, which tells us that 16/15 is a little less than 1/10 of an octave here.
+Sometimes you will see tuning maps given in octaves instead of cents. They work the same exact way. The only difference is that these octave-based tuning maps have each entry divided by 1200. For example, the quarter-comma meantone tuning map, in octaves, would be {{map| 1200 1896.578 2786.314 }}/1200 = {{map| 1 1.580 2.322 }}. If we dot product {{vector| 4 -1 -1 }} with that, we get {{nowrap| 4 × 1 + (−1) × 1.580 + (−1) × 2.322 {{=}} 0.098 }}, which tells us that 16/15 is a little less than 1/10 of an octave here.
 == With respect to linear algebra ==
-A tuning map can be thought of either as a one-row matrix or as a covector. The same is true of error maps and generator tuning maps.
+A tuning map is a real-valued linear form (or covector). If we identify interval space with the integer lattice, it is a linear map <math>\varphi: \mathbb{Z}^n \to \mathbb{R}</math>, which projects abstract intervals onto the real line which measures pitch. It can also be thought of as a matrix with a single row. The same is true of error maps and generator tuning maps.
-[[Category:Regular temperament tuning| ]] <!-- main article -->
+[[Category:Regular temperament tuning| ]] <!-- Main article -->
 [[Category:Terms]]
 [[Category:Math]]
 [[Category:Val]]