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| <h2>IMPORTED REVISION FROM WIKISPACES</h2>
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| This is an imported revision from Wikispaces. The revision metadata is included below for reference:<br>
| | == Introduction == |
| : This revision was by author [[User:genewardsmith|genewardsmith]] and made on <tt>2011-03-14 11:57:53 UTC</tt>.<br>
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| : The original revision id was <tt>210294168</tt>.<br>
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| : The revision comment was: <tt></tt><br>
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| The revision contents are below, presented both in the original Wikispaces Wikitext format, and in HTML exactly as Wikispaces rendered it.<br>
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| <h4>Original Wikitext content:</h4>
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| <div style="width:100%; max-height:400pt; overflow:auto; background-color:#f8f9fa; border: 1px solid #eaecf0; padding:0em"><pre style="margin:0px;border:none;background:none;word-wrap:break-word;white-space: pre-wrap ! important" class="old-revision-html">=MODMOS scales=
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| A MOS scale is constructed by iterating a generator g inside of a period R. That is, for non-negative integers n, we take n*g and reduce it modulo the period R to the range 0 <= i < R. We stop only at points when there are exactly two sizes of intervals in the scale, the large interval L and the small interval s. If the period R is 1/P octave for some integer P, we obtain an octave-repeating [[periodic scale]] by conjoining P copies of the MOS scale inside R so produce a MOS scale for the whole octave.
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| If we continue by adding another interval, it will either fall short of R, or exceed it, but either way we will now have an interval c = L-s, which has been called the "chroma".
| | A scale is considered to be a [[MOS scale]] if every generic [[interval class]] comes in two specific [[interval]] sizes. For example, the familiar [[diatonic scale]] is an MOS. |
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| =Near-MOS (NMOS) Scales=
| | '''MODMOS scales''', also known as '''altered MOS scales''', generalize the class of scales which are not MOS, but which have been obtained by applying a finite number of "chromatic alterations" to an MOS. |
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| =**Basic Approach**=
| | The familiar melodic and harmonic minor scales are examples of MODMOS's: although these scales are not MOS, they can be obtained by applying one chromatic alteration each to one of the [[mode]]s of the diatonic MOS. |
| The modern jazz view of music theory is predominantly modal. Jazz musicians are often taught to think of a complex chord as implying one or more "background" modes that fill in the cracks between the notes in the chord. This is used as a tool to aid the musician in melodic improvisation, as well as in finding the most "similar" sounding harmonic extensions for a certain chord. When more than one mode fits a particular chord or melody, the choice is often left up to the improvisational caprice of the soloist. One good reference for more information on the specifics of modal harmony as used in jazz is Ron Miller's [[@http://www.amazon.com/Modal-Jazz-Composition-Harmony-1/dp/B000MMQ2HG|Modal Jazz Composition and Harmony.]] | |
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| Much of this paradigm was originally derived from the techniques used by composers during the impressionistic era, and most likely emerged from the attempts of jazz musicians such as Bill Evans to find "proper" scale closures for some of the novel harmonic concepts that were being employed by composers such as Debussy and Ravel.
| | A chromatic alteration means changing the size of an interval by increments of the MOS's [[chroma]], where the chroma is the difference between any pair of intervals sharing the same interval class. |
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| Many of the modes commonly used are modes of the melodic minor, harmonic minor, and harmonic major scales. These scales are all obtained by making a single chromatic alteration to the diatonic scale; they are **Near-MOS's** in which only some interval classes fall into two sizes. Furthermore, all of the scales most often used in this fashion are proper. Propriety is so commonly seen that if a chromatic alteration produces a near-MOS that is improper, but is a subset of some other proper scale, the encompassing proper scale will be used. For instance, if one starts with Lydian and flattens the 7 to Lydian b7, C D E F# G A Bb C is produced (commonly called "Lydian dominant"). If one desires to raise the 2 to a #2, the resultant improper scale is produced - C D# E F# G A Bb C, sometimes called the "Hungarian Major" scale. In this case, musicians will commonly reframe this scale as a 7-note subset of the octatonic scale, C Db Eb E F# G A Bb C, which is proper.
| | Alteration by increments of some other interval is possible, but they lack the useful properties of MODMOS scales, most importantly [[epimorphism]], so they are [[inflected MOS]] scales, rather than true MODMOS scales. |
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| A system of indexing exists for these near-MOS's - they have been given names which are often used in common parlance. The modes of melodic minor are generally indexed as Mixolydian #4, Lydian #5, Phrygian #6, Dorian #7, etc, or alternatively Lydian b7, Phrygian b1, Dorian b2, Ionian b3, which are equivalent. So in a sense, much of the modern jazz approach to modal harmony is already a theory of near-MOS; musicians are often taught this comprehensive system of indexing so as to learn how one scale can chromatically transform into another to aid in the fluid navigation of the 12-tet landscape in live improvisation.
| | In the exposition below, we give a formal treatment of MODMOS scales. |
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| We will see that it is possible to extend this paradigm to other MOS's than just 5L2s. Furthermore, we will see that a lot of the existing terminology, most notably the sharp (#) and flat (b) signs, can also fit into the extended structure in a mathematically rigorous way. Furthermore, the extensions to this paradigm have no need for recourse to ratios or Fokker Periodicity Blocks; the near-MOS's of an MOS can be viewed as inharmonic scale abstractions for purely melodic purposes.
| | == Definitions == |
| | An MOS scale is constructed by iterating a generator g inside of a period R. That is, for non-negative integers n, we take n*g and reduce it modulo the period R to the range 0 ≤ i < R. We stop only at points when there are exactly two sizes of intervals in the scale, the large interval L and the small interval s. If the period R is 1/P octave for some integer P, we obtain an octave-repeating [[Periodic_scale|periodic scale]] by conjoining P copies of the MOS scale inside R so as to produce a MOS scale for the whole octave. |
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| It may prove particularly useful in exploring the near-MOS's of temperaments where the basic MOS doesn't contain a lot of consonant chords; miracle[10] may be a good example of this.
| | If we continue by adding another interval, it will either fall short of R, or exceed it, but either way we will now have an interval c = L-s, which has been called the "chroma". A MODMOS, then, is a chromatically altered MOS; that is, a MOS altered by chromas. If we take a MOS scale, and adjust one or more its notes up or down by a chroma consistently, so that octave periodicity is respected, and do not obtain another MOS, then we obtain a MODMOS. |
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| =**Outline**= | | == Ways of Looking at MODMOS Scales == |
| # The chromatic vector for an MOS should assume that the MOS is the [[Chromatic Pairs|albitonic]] scale of a [[chromatic pairs|chromatic pair]].
| | Any number of alterations are permitted; it is up to the judgment of the composer which of the resulting scales are most musically useful. However, clearly, some MODMOS's will be more useful than others, and it is good to talk about some of the ways this can be the case. |
| # The chromatic vector doesn't have to be defined in terms of ratios, mappings, or [[Fokker Blocks|periodicity blocks]]. **In general, the chromatic vector c = L-s**, regardless of what mapping you use and regardless of whether or not the scale is proper or improper.
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| # To apply this systematically to an MOS, we need to define a which mode of the MOS we're making alterations on.
| | For starters, certain alterations will cause the notes of the scale to no longer be "'''monotonic'''" (in ascending order). Typically we are most interested in those MODMOS's which are. In fact, for any MOS, only finitely many MODMOS's will be monotonic in this way (up to transpositional equivalence). To see this, note that there is a smallest possible type of step any MODMOS of the original MOS can have, which has been chroma-flattened as much as possible; thus there is a '''flattest MODMOS''' which is made up of N-1 of these minimal seconds in a row, followed by one huge "maximal second" to make up the difference with the octave. Similarly, there will be a '''sharpest MODMOS''' which starts with one huge second, and then the N-1 minimal seconds. Every monotonic MODMOS will be intermediate to these two, formed from various intermediate seconds (of which there are only finitely many type). |
| # Sharpening one of the notes in an MOS by this vector can be denoted by an accidental. To keep with tradition, we will use the # sign and the scale degree of the base mode that is being altered, where the first note is scale degree 1. Flattening one of the notes can be denoted by another accidental, in this case the b sign.
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| # So, to demonstrate over the LLsLLLs mode of 5L2s (Ionian)
| | Another important note is that the more alterations are made, the less the resulting scale will resemble the original MOS. Thus, it can be very useful, when trying to "organize" the universe of MODMOS's generated by an MOS, to sort them by the total number of alterations that have been made. Thus one can look at '''single-alteration''' MODMOS's, '''double-alteration''' MODMOS's, and so on, each of which gets further from the character of the core MOS. Similarly, one can look at the maximum number of chroma-alterations that has been made to any particular note at a time: are all notes formed by one chroma alteration, or do we have any notes which have been doubly adjusted? Or triply adjusted? etc. |
| ## The melodic minor NMOS parent scale is reached by Ionian b3 or Ionian #4.
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| ## The harmonic minor NMOS parent scale is reached by Ionian #4 or Ionian b3, b6.
| | It is also important to look at, for some MODMOS, how many generators the entire thing will span, which is called the '''generator span''' or '''coverage''' of the MODMOS. For instance, the diatonic scale requires 7 contiguous generators, whereas the melodic minor requires 9, the harmonic minor and major scales require 10, and the double harmonic scale requires 11. It can be quite useful to look at the "coverage" of a MODMOS on the generator chain, particularly if one want the MODMOS to fit into a single larger "chromatic" or "enharmonic" sized MOS. |
| ## The harmonic major NMOS parent scale is reached by Ionian b6 or Ionian b3
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| ## The locrian major NMOS parent scale is reached by Ionian b2,b3 or Ionian #1,#2.
| | There are doubtless many other useful ways in which one can analyze the MODMOS universe associated to an MOS. As a baseline definition, however, all of these scales are still MODMOS scales. |
| ### Other NMOS's exist, but they may be wildly improper; above I stick only to the proper NMOS's that exist in 12-tet.
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| ### One can also arrive at these same NMOS's by making different alterations.
| | == Gene's Terminology == |
| ### There are also NMOS's that can be arrived at by three alterations; I chose to not explore that far.
| | The name comes from the fact that if the period is an octave and the number of notes in the MOS scale is N, then a chroma moves a note along the chain of generators by ±N, so that a MODMOS, reduced modulo N on the generator chain, becomes a MOS. In all cases the Graham complexity of the chroma c is N, since this is the number of generator steps needed to reach c times P, the number of periods to an octave. |
| ### Sometimes a chromatic alteration simply gives you another mode of the same scale.
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| # The same procedure can be applied to porcupine. In 22-tet, c = L-s = 3\22 - 2\22 = 1\22. So the chromatic vector here is about 55 cents.
| | If the steps of the MODMOS have a complexity no more than N, we may call it a chromatic MODMOS; these have all steps the same as Otherwise, the steps may be of complexity greater than N, for instance by having steps of size d = |s-c|; these we may call enharmonic MODMOS. If we were to limit ourselves to note adjustments of one chroma, then in no case can the complexity be more than 2N. |
| # Let's say we're performing manipulations on the Lssssss mode ("porcupine major"). In 22-tet, this is 4 3 3 3 3 3 3. Some interesting near-MOS's are
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| ## P-major b3 or P-major #7 - 4 2 4 3 3 3 3 - this is a P-major scale where the 5/4 has been replaced by 6/5; for a different mode replace the 11/6 with 15/8.
| | == Melisse Series == |
| ## P-major b4 - 4 3 2 4 3 3 3 - this is a P-major scale where the 11/8 has been replaced by 4/3; this gives it more of a "fractured" and less of a "wind chimes"y sound.
| | One particular way of generating MODMOS is via the Melisse series. For a MOS of size N with octave period, we may put the 1/1 at the base of the generator chain, so that it can be represented by 0, 1, 2 ... N-1. The Melisse series now consists of the N-1 MODMOS 0, 1, 2 ... N-1-k, 2N-k, 2N-k+1 ... 2N-1 for each k 0 < k < N. Since the 1/1 can be any note, we may then pick the desired note and subtract generators so as to make that note correspond to 0, giving the desired mode of the MODMOS. |
| ## P-major b5 - 4 3 3 2 4 3 3 - this is a P-major scale where the 3/2 has been replaced by an approximate 16/11; this ~650 cent interval can function in certain circumstances as a very flat "false fifth"
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| ## P-major b6 - 4 3 3 3 2 4 3 - this is a P-major scale where the 5/3 has been flattened to 8/5. Very gothic sound.
| | == Examples == |
| ## P-major b7 - 4 3 3 3 3 2 4 - this is a P-major scale where the 11/6 has been flattened to an approximate 7/4. Very "otonal" sounding, as an 8:9:10:11:12:14 hexad exists in this scale.
| | Consider the MOS series of 1/4-comma meantone, where the generator g is log2(5)/4 = 0.58048 octaves, or 696.578 cents. The seven note MOS is the diatonic scale tuned in 1/4 comma tuning, with large step L a whole tone of 193.157 cents and small step s a diatonic semitone of 117.108 cents. L-s is the chromatic semitone "c", equal to 193.157 - 117.108 = 78.049 cents. This interval is the chroma for meantone[7], and the adjustment of any note up or down by this interval is represented by the sharp # or flat b accidentals. |
| ## P-major #3 - 4 4 2 3 3 3 3 - this is a P-major scale where the 5/4 has been sharpened to a 9/7. Very "bright and brassy" sounding.
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| ## There are many more.
| | The diatonic scale has steps LLsLLLs, which in the key of C can be written C D E F G A B C'. From the definition of a MODMOS, if we add sharps and flats to this, and do not get another diatonic scale, then we have a MODMOS. For example, if we flatten the third, we obtain C D Eb F G A B C', the melodic minor scale, or LsLLLLs. Since this scale contains three types of fourths (C-F, "perfect", Eb-A, "augmented", B-Eb, "diminished"), it is no longer an MOS and is therefore a MODMOS. If we apply a further alteration and flatten the sixth as well, we obtain the harmonic minor scale of C D Eb F G Ab B C', which now has three sizes of second and fourth and is therefore also a MODMOS. However, if we apply one more alteration and flatten the seventh, we're left with the natural minor scale of C D Eb F G Ab Bb C' - this is a mode of the diatonic scale, and hence is a MOS rather than a MODMOS. |
| # If the chromatic interval is a generalized version of the "sharp" accidental, then generalized versions of the "half-sharp" accidental also exist.
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| ## If you go from the albitonic scale up to the chromatic scale, a chromatic vector c is implied. If you go up one more level to the hyperchromatic MOS, the large step in the chromatic MOS is split into two new intervals. If the albitonic scale was strictly proper, then its s > c, so s is what gets split. Otherwise, c is what gets split. If the scale is proper, no further shades of chromaticism exist.
| | If we take the 12 note MOS rather than the seven notes of the diatonic scale, then the chroma is a diesis, which in 1/4 comma meantone is exactly 128/125, or 41.059 cents. However, other meantone tunings will give it a different size, and in [[50edo|50et]], for example, it is exactly 48 cents in size. Subtracting this adjusts a note twelve fifths up on the chain of fifths, and adding it adjusts it twelve notes down. If we take a chain of eleven 50et fifths up from the unison to create a 12-note MOS, so that we have a generator chain from 0 to 11, we may adjust the 3 up to 15 and the 7 up to 19. This leads to the scale called "smithgw_modmos12a.scl" in the [http://www.huygens-fokker.org/docs/scales.zip Scala Scale Archive]. Another MODMOS of Meantone[12] in the archive is wreckpop, "smithgw_wreckpop.scl". This takes a gamut of Meantone[12] from -4 to 7, which we may call from Ab to F#, and adjusts the 5 (B) up a 48 cent diesis, and so down to -7 fifths, or Cb, and the -2 (Bb) down a diesis, and so up the chain of fifths to 10 (A#.) |
| ## Regardless of which gets split, the size of the new interval, which we will denote c2, is |c-s|.
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| ## Depending on the propriety of the scale you're working with, c2 may or may not be smaller than c, so the "half-sharp" moniker may not always be appropriate.
| | Of course, MODMOS are not confined to scales of meantone. If we take the [[hobbit scale]] [[prodigy11]] and tune it in a miracle tuning such as [[72edo|72et]], we obtain a MODMOS of Miracle[11]. In general, if we choose a rank three temperament with an optimal tuning very close to an optimal tuning for a rank two temperament and then tune a hobbit for it in that optimal rank two temperament tuning, we are very likely to construct an interesting MODMOS scale. It is particularly useful in connection with MODMOS of temperaments where the basic MOS doesn't contain a lot of consonant chords, such as Miracle[11]. |
| ## For meantone, in 31-tet, this interval is the diesis, which I will notate by "^" and "v" for upward and downward alteration, respectively. This leads to such near-near-MOS's as
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| ### C D Ev F G A B C - Ionian with a neutral third
| | Another quite interesting result of this is that if the rank-3 JI 5-limit major scale of (9/8, 5/4, 4/3, 3/2, 5/3, 15/8, 2/1) is tuned to any rank-2 5-limit temperament with a 7-note MOS, this scale will typically be a MODMOS of that MOS in that temperament. So for instance, this major scale will be a MODMOS of porcupine[7] (as Lssssss b4 #7), of tetracot[7] (as LLLLLLs #2 #3 b4 #7), etc. |
| ### C D Ebv F G A B C - In 31-tet, Ebv maps to 7/6, so this may well be thought of as a septimal Dorian scale
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| ### C D E F^ G A B C - Ionian with 4/3 replaced with 11/8
| | [[Category:MODMOS]] |
| ### C D E F^ G A Bbv C - This is Ionian with 4/3 replaced with 11/8 and 9/5 replaced with 7/4
| | [[Category:MOS scale]] |
| ### C D E F^ G Av Bbv C - This is Ionian with 4/3 replaced with 11/8, 9/5 replaced with 7/4, and 5/3 replaced with ~13/8.
| | [[Category:scales]] |
| ### As you can see, the more alterations we make, the less this scale starts to resemble the actual meantone MOS that it originated from.
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| # One can theoretically alter a scale as many times as one wants.
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| ## However, it is suggested by Rothenberg that the near-MOS's that will be most useful are those that are proper. The question of how to deal with near-MOS's that are derived from scales which are themselves improper, as in superpyth[7], is left up to future research.
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| ## It is also suggested, that, as a problem of managing the complexity of the sheer number of these resulting scales, that if more than two alterations are made, the resultant scale may best be viewed as a new scale in its own right and not a near-MOS of the original scale.
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| =Outline for General Algorithm=
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| # Start with the albitonic MOS that you want to modify.
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| # Compute the chromatic step = L-s.
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| # Find all of the resultant scales that lie at most N chromatic alteration away from the original MOS, where N is the near-MOS maximum alteration complexity that you want to search for.
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| # If any of these scales end up being permutations of one another, prune the duplicates.
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| # If so desired, prune the results to eliminate improper scales.</pre></div>
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| <h4>Original HTML content:</h4>
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| <div style="width:100%; max-height:400pt; overflow:auto; background-color:#f8f9fa; border: 1px solid #eaecf0; padding:0em"><pre style="margin:0px;border:none;background:none;word-wrap:break-word;width:200%;white-space: pre-wrap ! important" class="old-revision-html"><html><head><title>MODMOS Scales</title></head><body><!-- ws:start:WikiTextHeadingRule:0:&lt;h1&gt; --><h1 id="toc0"><a name="MODMOS scales"></a><!-- ws:end:WikiTextHeadingRule:0 -->MODMOS scales</h1>
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| A MOS scale is constructed by iterating a generator g inside of a period R. That is, for non-negative integers n, we take n*g and reduce it modulo the period R to the range 0 &lt;= i &lt; R. We stop only at points when there are exactly two sizes of intervals in the scale, the large interval L and the small interval s. If the period R is 1/P octave for some integer P, we obtain an octave-repeating <a class="wiki_link" href="/periodic%20scale">periodic scale</a> by conjoining P copies of the MOS scale inside R so produce a MOS scale for the whole octave.<br />
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| If we continue by adding another interval, it will either fall short of R, or exceed it, but either way we will now have an interval c = L-s, which has been called the &quot;chroma&quot;. <br />
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| <!-- ws:start:WikiTextHeadingRule:2:&lt;h1&gt; --><h1 id="toc1"><a name="Near-MOS (NMOS) Scales"></a><!-- ws:end:WikiTextHeadingRule:2 -->Near-MOS (NMOS) Scales</h1>
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| <!-- ws:start:WikiTextHeadingRule:4:&lt;h1&gt; --><h1 id="toc2"><a name="Basic Approach"></a><!-- ws:end:WikiTextHeadingRule:4 --><strong>Basic Approach</strong></h1>
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| The modern jazz view of music theory is predominantly modal. Jazz musicians are often taught to think of a complex chord as implying one or more &quot;background&quot; modes that fill in the cracks between the notes in the chord. This is used as a tool to aid the musician in melodic improvisation, as well as in finding the most &quot;similar&quot; sounding harmonic extensions for a certain chord. When more than one mode fits a particular chord or melody, the choice is often left up to the improvisational caprice of the soloist. One good reference for more information on the specifics of modal harmony as used in jazz is Ron Miller's <a class="wiki_link_ext" href="http://www.amazon.com/Modal-Jazz-Composition-Harmony-1/dp/B000MMQ2HG" rel="nofollow" target="_blank">Modal Jazz Composition and Harmony.</a><br />
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| <br />
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| Much of this paradigm was originally derived from the techniques used by composers during the impressionistic era, and most likely emerged from the attempts of jazz musicians such as Bill Evans to find &quot;proper&quot; scale closures for some of the novel harmonic concepts that were being employed by composers such as Debussy and Ravel.<br />
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| <br />
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| Many of the modes commonly used are modes of the melodic minor, harmonic minor, and harmonic major scales. These scales are all obtained by making a single chromatic alteration to the diatonic scale; they are <strong>Near-MOS's</strong> in which only some interval classes fall into two sizes. Furthermore, all of the scales most often used in this fashion are proper. Propriety is so commonly seen that if a chromatic alteration produces a near-MOS that is improper, but is a subset of some other proper scale, the encompassing proper scale will be used. For instance, if one starts with Lydian and flattens the 7 to Lydian b7, C D E F# G A Bb C is produced (commonly called &quot;Lydian dominant&quot;). If one desires to raise the 2 to a #2, the resultant improper scale is produced - C D# E F# G A Bb C, sometimes called the &quot;Hungarian Major&quot; scale. In this case, musicians will commonly reframe this scale as a 7-note subset of the octatonic scale, C Db Eb E F# G A Bb C, which is proper.<br />
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| A system of indexing exists for these near-MOS's - they have been given names which are often used in common parlance. The modes of melodic minor are generally indexed as Mixolydian #4, Lydian #5, Phrygian #6, Dorian #7, etc, or alternatively Lydian b7, Phrygian b1, Dorian b2, Ionian b3, which are equivalent. So in a sense, much of the modern jazz approach to modal harmony is already a theory of near-MOS; musicians are often taught this comprehensive system of indexing so as to learn how one scale can chromatically transform into another to aid in the fluid navigation of the 12-tet landscape in live improvisation.<br />
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| <br />
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| We will see that it is possible to extend this paradigm to other MOS's than just 5L2s. Furthermore, we will see that a lot of the existing terminology, most notably the sharp (#) and flat (b) signs, can also fit into the extended structure in a mathematically rigorous way. Furthermore, the extensions to this paradigm have no need for recourse to ratios or Fokker Periodicity Blocks; the near-MOS's of an MOS can be viewed as inharmonic scale abstractions for purely melodic purposes.<br />
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| <br />
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| It may prove particularly useful in exploring the near-MOS's of temperaments where the basic MOS doesn't contain a lot of consonant chords; miracle[10] may be a good example of this.<br />
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| <br />
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| <!-- ws:start:WikiTextHeadingRule:6:&lt;h1&gt; --><h1 id="toc3"><a name="Outline"></a><!-- ws:end:WikiTextHeadingRule:6 --><strong>Outline</strong></h1>
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| <ol><li>The chromatic vector for an MOS should assume that the MOS is the <a class="wiki_link" href="/Chromatic%20Pairs">albitonic</a> scale of a <a class="wiki_link" href="/chromatic%20pairs">chromatic pair</a>.</li><li>The chromatic vector doesn't have to be defined in terms of ratios, mappings, or <a class="wiki_link" href="/Fokker%20Blocks">periodicity blocks</a>. <strong>In general, the chromatic vector c = L-s</strong>, regardless of what mapping you use and regardless of whether or not the scale is proper or improper.</li><li>To apply this systematically to an MOS, we need to define a which mode of the MOS we're making alterations on.</li><li>Sharpening one of the notes in an MOS by this vector can be denoted by an accidental. To keep with tradition, we will use the # sign and the scale degree of the base mode that is being altered, where the first note is scale degree 1. Flattening one of the notes can be denoted by another accidental, in this case the b sign.</li><li>So, to demonstrate over the LLsLLLs mode of 5L2s (Ionian)<ol><li>The melodic minor NMOS parent scale is reached by Ionian b3 or Ionian #4.</li><li>The harmonic minor NMOS parent scale is reached by Ionian #4 or Ionian b3, b6.</li><li>The harmonic major NMOS parent scale is reached by Ionian b6 or Ionian b3</li><li>The locrian major NMOS parent scale is reached by Ionian b2,b3 or Ionian #1,#2.<ol><li>Other NMOS's exist, but they may be wildly improper; above I stick only to the proper NMOS's that exist in 12-tet.</li><li>One can also arrive at these same NMOS's by making different alterations.</li><li>There are also NMOS's that can be arrived at by three alterations; I chose to not explore that far.</li><li>Sometimes a chromatic alteration simply gives you another mode of the same scale.</li></ol></li></ol></li><li>The same procedure can be applied to porcupine. In 22-tet, c = L-s = 3\22 - 2\22 = 1\22. So the chromatic vector here is about 55 cents.</li><li>Let's say we're performing manipulations on the Lssssss mode (&quot;porcupine major&quot;). In 22-tet, this is 4 3 3 3 3 3 3. Some interesting near-MOS's are<ol><li>P-major b3 or P-major #7 - 4 2 4 3 3 3 3 - this is a P-major scale where the 5/4 has been replaced by 6/5; for a different mode replace the 11/6 with 15/8.</li><li>P-major b4 - 4 3 2 4 3 3 3 - this is a P-major scale where the 11/8 has been replaced by 4/3; this gives it more of a &quot;fractured&quot; and less of a &quot;wind chimes&quot;y sound.</li><li>P-major b5 - 4 3 3 2 4 3 3 - this is a P-major scale where the 3/2 has been replaced by an approximate 16/11; this ~650 cent interval can function in certain circumstances as a very flat &quot;false fifth&quot;</li><li>P-major b6 - 4 3 3 3 2 4 3 - this is a P-major scale where the 5/3 has been flattened to 8/5. Very gothic sound.</li><li>P-major b7 - 4 3 3 3 3 2 4 - this is a P-major scale where the 11/6 has been flattened to an approximate 7/4. Very &quot;otonal&quot; sounding, as an 8:9:10:11:12:14 hexad exists in this scale.</li><li>P-major #3 - 4 4 2 3 3 3 3 - this is a P-major scale where the 5/4 has been sharpened to a 9/7. Very &quot;bright and brassy&quot; sounding.</li><li>There are many more.</li></ol></li><li>If the chromatic interval is a generalized version of the &quot;sharp&quot; accidental, then generalized versions of the &quot;half-sharp&quot; accidental also exist.<ol><li>If you go from the albitonic scale up to the chromatic scale, a chromatic vector c is implied. If you go up one more level to the hyperchromatic MOS, the large step in the chromatic MOS is split into two new intervals. If the albitonic scale was strictly proper, then its s &gt; c, so s is what gets split. Otherwise, c is what gets split. If the scale is proper, no further shades of chromaticism exist.</li><li>Regardless of which gets split, the size of the new interval, which we will denote c2, is |c-s|.</li><li>Depending on the propriety of the scale you're working with, c2 may or may not be smaller than c, so the &quot;half-sharp&quot; moniker may not always be appropriate.</li><li>For meantone, in 31-tet, this interval is the diesis, which I will notate by &quot;^&quot; and &quot;v&quot; for upward and downward alteration, respectively. This leads to such near-near-MOS's as<ol><li>C D Ev F G A B C - Ionian with a neutral third</li><li>C D Ebv F G A B C - In 31-tet, Ebv maps to 7/6, so this may well be thought of as a septimal Dorian scale</li><li>C D E F^ G A B C - Ionian with 4/3 replaced with 11/8</li><li>C D E F^ G A Bbv C - This is Ionian with 4/3 replaced with 11/8 and 9/5 replaced with 7/4</li><li>C D E F^ G Av Bbv C - This is Ionian with 4/3 replaced with 11/8, 9/5 replaced with 7/4, and 5/3 replaced with ~13/8.</li><li>As you can see, the more alterations we make, the less this scale starts to resemble the actual meantone MOS that it originated from.</li></ol></li></ol></li><li>One can theoretically alter a scale as many times as one wants.<ol><li>However, it is suggested by Rothenberg that the near-MOS's that will be most useful are those that are proper. The question of how to deal with near-MOS's that are derived from scales which are themselves improper, as in superpyth[7], is left up to future research.</li><li>It is also suggested, that, as a problem of managing the complexity of the sheer number of these resulting scales, that if more than two alterations are made, the resultant scale may best be viewed as a new scale in its own right and not a near-MOS of the original scale.</li></ol></li></ol><!-- ws:start:WikiTextHeadingRule:8:&lt;h1&gt; --><h1 id="toc4"><a name="Outline for General Algorithm"></a><!-- ws:end:WikiTextHeadingRule:8 -->Outline for General Algorithm</h1>
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| <ol><li>Start with the albitonic MOS that you want to modify.</li><li>Compute the chromatic step = L-s.</li><li>Find all of the resultant scales that lie at most N chromatic alteration away from the original MOS, where N is the near-MOS maximum alteration complexity that you want to search for.</li><li>If any of these scales end up being permutations of one another, prune the duplicates.</li><li>If so desired, prune the results to eliminate improper scales.</li></ol></body></html></pre></div>
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