S-expression: Difference between revisions

An '''S-expression''' is any product, or ratio of products, of the '''square superparticulars''' '''S''k''''', which are defined as the fractions of the form {{sfrac|''k''²|''k''² − 1}}. Commas defined by S-expressions turn out to represent intuitive and wide-reaching families of tempered equivalences, and therefore present a very useful framework to learn for a good understanding of the [[comma]]s that appear frequently in [[JI]] and [[regular temperament|temperaments]].

As S-expressions are deployed widely on the wiki and in the broader xen community, below is a list of what the most common S-expression categories imply when they are [[tempering out|tempered out]]. The linked sections provide deeper information into each comma family.

* [[#Sk (square-particulars)|Square superparticulars]]: '''S''k''''', superparticular fractions of the form {{sfrac|''k''²|''k''² − 1}}. <br>Tempering out S''k'' equates {{sfrac|''k'' + 1|''k''}} with {{sfrac|''k''|''k'' − 1}} and splits {{sfrac|''k'' + 1|''k'' − 1}} in two.

* [[#Sk⋅S(k + 1) (triangle-particulars)|Triangle-particulars]]: {{nowrap|'''S''k''⋅S(''k'' + 1)'''}}, superparticular fractions of the form {{sfrac|''k''(''k'' + 1)/2|(''k'' − 1)(''k'' + 2)/2}}. <br>Tempering out {{nowrap|S''k''⋅S(''k'' + 1)}} equates {{sfrac|''k'' + 2|''k'' + 1}} with {{sfrac|''k''|''k'' − 1}}, and {{sfrac|''k'' + 2|''k''}} with {{sfrac|''k'' + 1|''k'' − 1}}.

* [[#Sk2⋅S(k + 1) and S(k − 1)⋅Sk2 (lopsided commas)|Lopsided commas]]: {{nowrap|'''(S''k'')²⋅S(''k'' + 1)'''}} and {{nowrap|'''(S''k'')²⋅S(''k'' − 1)'''}}. <br>Tempering out the former equates {{sfrac|''k'' + 2|''k''}} with {{pars|{{sfrac|''k''|''k'' − 1}}}}² and {{sfrac|''k'' + 2|''k'' − 1}} with {{pars|{{sfrac|''k''|''k'' − 1}}}}³, and tempering out the latter equates {{sfrac|''k''|''k'' − 2}} with  {{pars|{{sfrac|''k'' + 1|''k''}}}}² and {{sfrac|''k'' + 1|''k'' − 2}} with {{pars|{{sfrac|''k'' + 1|''k''}}}}³.

A square superparticular, or ''square-particular'' for short, is a [[superparticular]] [[interval]] whose numerator is a square number, which is to say, a superparticular of the form

$$ \frac {k^2}{k^2 - 1} = \frac {k/(k - 1)}{(k + 1)/k} $$

which is square-superparticular ''k'' for a given integer {{nowrap| ''k'' > 1 }}. A suggested shorthand for this interval is '''S''k''''' for the ''k''-th square superparticular, where the ''S'' stands for ''second-order/square superparticular''. This will be used later in this article as the notation will prove powerful in understanding the commas and implied tempered structures of [[regular temperament]]s. Note that {{nowrap| S2 {{=}} [[4/3]] }} is the first musically meaningful square-particular, as {{nowrap| S1 {{=}} 1/0 }}.

Also note that we use the notation S''k''^''p'' to mean (S''k'')^''p'' rather than S(''k''^''p'') for convenience in the practical analysis of regular temperaments using S-expressions.

=== Significance ===

Square-superparticulars are important structurally because they are the intervals between consecutive superparticular intervals while simultaneously being superparticular themselves, which means that whether and how they are tempered tells us information about how well a temperament can represent the [[harmonic series]] up to the ({{nowrap| ''k'' + 1 }})-th harmonic, as well as the potential representational sacrifices that must be made from that point onwards.

 

Specifically, tempering S''k'' out makes the harmonic segment centered around ''k'' have equal steps; e.g. tempering out {{nowrap| S9 {{=}} (9/8)/(10/9) {{=}} 81/80 }} equalizes 8:9:10, as in [[meantone]].

 

In other words, understanding the mappings of S''k'' in a given temperament (especially an [[equal temperament]]) is equivalent to understanding the spacing of consecutive superparticular intervals, and thereby to understanding the way it represents or tries to represent the harmonic series.

{| class="wikitable center-all left-4"

! Subgroup

| 2.3

| 2.3

| 2.3.5

| 2.3.5

| S6

| 2.3.5.7

| 2.3.7

| 2.3.7

| S9

| 2.3.5

| 2.3.5.11

| 2.3.5.11

| 2.3.11.13

| 2.3.7.13

| 2.3.5.7.13

| 2.3.5.7

| 2.3.5.17

| 2.3.17

| 2.3.17.19

| 2.3.5.19

| 2.3.5.7.19

| 2.3.5.7.11

| 2.3.7.11.23

| 2.3.11.23

| 2.3.5.23

| 2.3.5.13

| S26

| 2.3.5.13

| 2.3.7.13

| 2.3.7.29

| 2.3.5.7.29

| 2.3.5.29.31

| 2.3.5.31

| 2.3.11.31

| 2.3.11.17

| 2.3.5.7.11.17

| S35

| 2.3.5.7.17

| 2.3.5.13.19

| 2.3.5.11.23

| 2.3.5.7

| 2.3.5.7.17

| 2.3.5.13.17

| S55

| 2.3.5.7.11

| 2.3.5.7.11.19

| 2.3.7.19.29

| 2.3.7.31

| 2.3.5.7.13

| 2.3.5.11.13

| 2.3.5.7.17.23

| 2.3.5.7.11.19

| 2.3.7.11.13.19

| 2.3.5.7.13.23

| 2.3.7.13.23.31

| S99

| 2.3.5.7.11

| 2.3.5.19.23.29

| 2.3.5.13.23.29

| 2.3.5.7.11.17

| 2.3.5.7.31

| 2.3.5.11.13.29

| 2.3.7.11.17.19

| 2.3.5.7.11.17.31

| 2.3.5.7.11.13.31

| S161

| 2.3.5.7.23

| 2.3.5.7.13.17

| 2.3.5.13.17.19

| 2.3.5.7.11.29

| 2.3.11.13.19.23

| 2.3.5.7.11.13.19

| 2.3.5.7.11.23.29

| 2.3.5.17.29

| 2.3.7.13.19.23

| 2.3.5.13.17.19

| 2.3.5.11.17.19.31

| 2.3.7.11.19.31

| S351

| 2.3.5.7.11.13

| 2.3.5.7.13.17.23

| 2.3.5.7.11.13.17

| 2.3.5.11.13.17.19.29

| 2.3.5.11.13.19.31

| 2.3.11.17.23.31

| 2.3.5.11.19.23.29

| 2.3.5.7.11.13.17.23.31

| 2.3.7.17.23.29

| <small>([[1275/1274]])/([[1276/1275]])</small>

| <small>[[1625625/1625624]]</small>

| 2.3.5.7.11.13.17.29

| <small>([[1519/1518]])/([[1520/1519]])</small>

| <small>[[2307361/2307360]]</small>

| 2.3.5.7.11.19.23.31

| <small>([[1520/1519]])/([[1521/1520]])</small>

| <small>[[2310400/2310399]]</small>

| 2.3.5.7.13.19.31

| <small>([[2001/2000]])/([[2002/2001]])</small>

| <small>[[4004001/4004000]]</small>

| 2.3.5.7.11.13.23.29

| <small>([[2024/2023]])/([[2025/2024]])</small>

| <small>[[4096576/4096575]]</small>

| 2.3.5.7.11.17.23

| <small>([[2431/2430]])/([[2432/2431]])</small>

| <small>[[5909761/5909760]]</small>

| 2.3.5.11.13.17.19

| <small>([[3249/3248]])/([[3250/3249]])</small>

| <small>[[10556001/10556000]]</small>

| 2.3.5.7.13.19.29

| <small>([[9801/9800]])/([[9802/9801]])</small>

| <small>[[96059601/96059600]]</small>

| 2.3.5.7.11.13.29

| <small><small>([[13311/13310]])/([[13312/13311]])</small></small>

| <small><small>[[177182721/177182720]]</small></small>

| 2.3.5.11.13.17.29

| <small><small>([[13455/13454]])/([[13456/13455]])</small></small>

| <small><small>[[181037025/181037024]]</small></small>

| 2.3.5.7.13.23.29.31

=== Alternatives to tempering out square-particulars ===

It is common to temper out square superparticulars, equating two adjacent superparticulars at some point in the harmonic series, but for higher-accuracy or structural reasons it can be more beneficial to instead temper out differences between consecutive square superparticulars so that the corresponding consecutive superparticulars are tempered to have equal spacing between them. If we define a sequence of commas {{nowrap| U''k'' {{=}} {{sfrac|S''k''|S(''k'' + 1)}} }}, we get [[#Sk/S(k + 1) (ultraparticulars)|ultraparticulars]]<ref group="note">In analogy with the "super-", "ultra-" progression and because these would be differences between adjacent differences between adjacent superparticulars, which means a higher order of "particular", and as we will see, no longer superparticular, hence the need for a new name. Also note that the choice of indexing is rather arbitrary and up to debate, as U''k'' = S(''k'' - 1)/S''k'' and U''k'' = S(''k'' + 1)/S(''k'' + 2) also make sense. Therefore it is advised to use the S-expression to refer to an ultraparticular unambiguously, or the comma itself.</ref>. Ultraparticulars have a secondary and mathematically equivalent consequence: by tempering out {{sfrac|S''k''|S(''k'' + 1)}}, {{sfrac|''k'' + 2|''k'' + 1}} and {{sfrac|''k''|''k'' − 1}} are made equidistant from {{sfrac|''k'' + 1|''k''}}, which means that another expression for {{sfrac|S''k''|S(''k'' + 1)}} is the following:

$$ {\rm S}k / {\rm S} (k + 1) = \frac{(k + 2) / (k - 1)}{((k + 1)/k)^3} $$

This means you can read the ''k'' and {{nowrap| ''k'' + 1 }} from the S-expression of an ultraparticular as being the interval involved in the cubing equivalence (abbreviated to "cube relation" in [[#Sk/S(k + 1) (ultraparticulars)|the table of ultraparticulars]]).

Furthermore, defining another sequence of commas with formula {{sfrac|S''k''|S(''k'' + 2)}} leads to [[#Sk/S(k + 2) (semiparticulars)|semiparticulars]], which inform many natural ways in which one might want to halve intervals with other intervals, and with their own more structural consequences, talked about there. These also arise from tempering out consecutive ultraparticulars.

== {{nowrap|S''k''⋅S(''k'' + 1)}} (triangle-particulars) ==

# Every triangle-particular is superparticular, so these are efficient commas. (See also the [[#Short proof of the superparticularity of triangle-particulars]].)

# Often each individual triangle-particular, taken as a comma, implies other useful equivalences not necessarily corresponding to the general form. In particular, every triangle-particular is the difference between two nearly-adjacent superparticular intervals {{sfrac|''k'' + 2|''k'' + 1}} and {{sfrac| ''k''|''k'' − 1}}.

# Tempering out any two consecutive square-particulars S''k'' and {{nowrap|S(''k'' + 1)}} implies tempering out a triangle-particular, so these are common commas. (See also: [[lopsided comma]]s.)

# If we temper out {{nowrap|S''k''⋅S(''k'' + 1)}} but not S''k'' or {{nowrap|S(''k'' + 1)}}, then one or more intervals of {{sfrac|''k''|''k'' − 1}}, {{sfrac|''k'' + 1|''k''}}, and {{sfrac|''k'' + 2|''k'' + 1}} ''must'' be mapped inconsistently, because:

:: If {{sfrac|''k'' + 1|''k''}} is mapped above {{nowrap| {{sfrac|''k'' + 2|''k'' + 1}} ~ {{sfrac|''k''|''k'' − 1}} }} we have {{nowrap|{{sfrac|''k'' + 1|''k''}} > {{sfrac|''k''|''k'' − 1}}}} and if it is mapped below we have {{nowrap|{{sfrac|''k'' + 1|''k''}} < {{sfrac|''k'' + 2|''k'' + 1}}}}.

:: (Generalisations of this and their implications for [[consistency]] are discussed in the section covering [[#Sk⋅S(k + 1)⋅…⋅S(k + n − 1) (1/n-square-particulars)|1/''n''-square-particulars]].)

If we equate {{sfrac|''k'' + 2|''k'' + 1}} with {{sfrac|''k''|''k'' − 1}} by tempering out their difference, then multiply both sides by {{sfrac|''k'' + 1|''k''}}, we have:

$$ \left(\frac{k + 2}{k + 1}\right)\left(\frac{k + 1}{k}\right) = \left(\frac{k + 1}{k}\right)\left(\frac{k}{k - 1}\right) $$

$$ \frac{k + 2}{k} = \frac{k + 1}{k - 1} $$

 

$${\rm S}k \cdot {\rm S}(k+1) = \frac{k/(k-1)}{(k+1)/k} \cdot \frac{(k+1)/k}{(k+2)/(k+1)} = \frac{k/(k-1)}{(k+2)/(k+1)} $$

and this equivalence is achieved. Note that there is little to no reason to not also temper out S''k'' and {{nowrap|S(''k'' + 1)}} individually unless other considerations seem to force your hand.

$$ S(k) \cdot S(k + 1) = \frac{\frac{k}{k - 1}}{\frac{k + 2}{k + 1}} = \frac{k(k + 1)}{(k - 1)(k + 2)} = \frac{k^2 + k}{k^2 + k - 2} $$

Then notice that {{nowrap| ''k''² + ''k'' }} is always a multiple of 2; therefore the above always simplifies to a superparticular. Half of this superparticular is halfway between the corresponding square-particulars, and because of its composition it could be reasoned that it would likely be half as accurate as tempering out either of the square-particulars individually, so these are "1/2-square-particulars" in a sense, and half of a square is a triangle, which is not a coincidence here because the numerators of all of these superparticular intervals are [[triangular number]]s, hence the alternative name ''triangle-particular''.

For completeness, all the intervals of this form are included, because of their structural importance for JI, and for the possibility of inconsistency of mappings when tempered out for the above reason.

{| class="wikitable center-all left-4"

|+ style="font-size: 105%;" | 31-limit triangle-particulars<ref group="note">After 75, 76, 77, 78, streaks of four consecutive harmonics in the 23-limit become very sparse. The last few streaks are deeply related to the consistency and structure of [[311edo]], as 311edo can be described as the unique 23-limit temperament that tempers out all triangle-particulars from [[595/594]] up to [[21736/21735]]. It also tempers out all the square-particulars composing those triangle-particulars with the exception of S169 and S170, and maps the corresponding intervals of the 77-odd-limit consistently. 170/169 is the only place where the logic seems to "break" as it is mapped to 2 steps instead of 3, meaning the mapping of that superparticular is inconsistent.</ref>

! Subgroup

| S2⋅S3

| 2.3

| S3⋅S4

| 2.3.5

| S4⋅S5

| 2.3.5

| S5⋅S6

| 2.3.5.7

| S6⋅S7

| 2.3.5.7

| S7⋅S8

| 2.3.7

| S8⋅S9

| 2.3.5.7

| S9⋅S10

| 2.3.5.11

| S10⋅S11

| 2.3.5.11

| S11⋅S12

| 2.3.5.11.13

| S12⋅S13

| 2.3.7.11.13

| S13⋅S14

| 2.3.5.7.13

| S14⋅S15

| 2.3.5.7.13

| S15⋅S16

| 2.3.5.7.17

| S16⋅S17

| 2.3.5.17

| S17⋅S18

| 2.3.17.19

| S18⋅S19

| 2.3.5.17.19

| S19⋅S20

| 2.3.5.7.19

| S20⋅S21

| 2.3.5.7.11.19

| S21⋅S22

| 2.3.5.7.11.23

| S22⋅S23

| 2.3.5.7.11.23

| S23⋅S24

| 2.3.5.11.23

| S24⋅S25

| 2.3.5.13.23

| S25⋅S26

| 2.3.5.13

| S26⋅S27

| 2.3.5.7.13

| S27⋅S28

| 2.3.5.7.13.29

| S28⋅S29

| 2.3.5.7.29

| S29⋅S30

| 2.3.5.7.29.31

| S30⋅S31

| 2.3.5.29.31

| S31⋅S32

| 2.3.5.11.31

| S32⋅S33

| 2.3.11.17.31

| S33⋅S34

| 2.3.5.7.11.17

| S34⋅S35

| 2.3.5.7.11.17

| S49⋅S50

| 2.3.5.7.17

| S50⋅S51

| 2.3.5.7.13.17

| S55⋅S56

| 2.3.5.7.11.19

| S63⋅S64

| 2.3.5.7.13.31

| S64⋅S65

| 2.3.5.7.11.13

| S76⋅S77

| 2.3.5.7.11.13.19

| S91⋅S92

| 2.3.5.7.13.23.31

| <small>S115⋅S116</small>

| <small>([[115/114]])/([[117/116]])</small>

| 2.3.5.13.19.23.29

| <small>S153⋅S154</small>

| <small>([[153/152]])/([[155/154]])</small>

| <small>[[11781/11780]]</small>

| 2.3.5.7.11.17.19.31

| <small>S154⋅S155</small>

| <small>([[154/153]])/([[156/155]])</small>

| <small>[[11935/11934]]</small>

| 2.3.5.7.11.13.17.31

| <small>S169⋅S170</small>

| <small>([[169/168]])/([[171/170]])</small>

| <small>[[14365/14364]]</small>

| 2.3.5.7.13.17.19

| <small>S208⋅S209</small>

| <small>([[208/207]])/([[210/209]])</small>

| <small>[[21736/21735]]</small>

| 2.3.5.7.11.13.19

| <small>S323⋅S324</small>

| <small>([[323/322]])/([[325/324]])</small>

| <small>[[52326/52325]]</small>

| 2.3.5.7.13.17.19.23

| <small>S341⋅S342</small>

| <small>([[341/340]])/([[343/342]])</small>

| <small>[[58311/58310]]</small>

| 2.3.5.7.11.17.19.31

| <small>S494⋅S495</small>

| <small>([[494/493]])/([[496/495]])</small>

| <small>[[122265/122264]]</small>

| 2.3.5.7.11.13.19.29.31

| <small>S1519⋅S1520</small>

| <small>([[1519/1518]])/([[1521/1520]])</small>

| <small>[[1154440/1154439]]</small>

| 2.3.5.7.11.13.19.23.31

== S''k''⋅S(''k'' + 1)⋅…⋅S(''k'' + ''n'' − 1) (1/''n''-square-particulars) ==

=== Significance ===

1/''n''-square-particulars are a generalization of square- and 1/2-square-particulars to an interval whose S-expression can be written in the form of a product of ''n'' consecutive square-particulars (including S''k'' but not including {{nowrap|S(''k'' + ''n'')}}) and which can therefore be written as the ratio between the two superparticulars {{sfrac|''k''|''k'' − 1}} and {{sfrac|''k'' + ''n''|''k'' + ''n'' − 1}}.

In other words, each and every S-expression of a comma as a 1/''n''-square-particular corresponds exactly to expressing it as the ratio between two superparticular intervals, with ''n'' distance between them. For example, 10/9 and 11/10 are considered as having 1 distance between them, corresponding to ordinary square-particulars (in this case [[100/99|S10]]).

# As a generalization of important special cases {{nowrap| ''n'' {{=}} 0, 1, 2 }} (which are almost all superparticular; the only case where they are not is that {{nowrap|''n'' {{=}} 3}} (1/3-square-particulars) are throdd-particular one third of the time, so this suggests these are efficient commas. A cursory look will show that many 1/''n''-square-particulars for small ''n'' are superparticular, and many more are the next best things (odd-particular, throdd-particular, quodd-particular, etc.) so this confirms them being a family of efficient commas.

# Because of being the ratio of two superparticular intervals, in higher-complexity cases they often correspond to small commas between large commas which we do not want to temper out, for example {{nowrap| {{sfrac|[[81/80]]|[[91/90]]}} {{=}} S81⋅S82⋅…⋅S90}} {{nowrap|{{=}} [[729/728]]}} {{nowrap| {{=}} S27 }}. They also often simplify in cases like these; note that a suggested shorthand is S81..90 for {{nowrap|S81⋅S82⋅ …⋅S90}} and more generally S''a''..''b'' for {{nowrap|S''a''⋅S(''a'' + 1)⋅…⋅S''b''}}.

# They often correspond to "nontrivial" equivalences that need to be dug up, which are not obvious from their expression as a ratio of two superparticular intervals, for example, [[385/384|S33⋅S34⋅S35]], suggesting they are a goldmine for valuable tempering opportunities.  

# Their expressions naturally make them implied by tempering out consecutive square-particulars, so if they are present and that the individual square-particulars are not tempered out, if you want to extend the temperament and/or reduce its rank (tempering it down) and/or hope to make the temperament more efficient, you can try tempering out the observed square-particulars that a vanishing 1/''n''-square-particular is composed of – although this is not always possible. There is also good theoretical motivation for wanting to do this, as the next section will discuss.

# They are relevant to understanding how much damage is present in a temperament's harmonic series representation, because they show how many superparticular intervals are either not distinguished or worse mapped inconsistently. As such, they are relevant to understanding limitations of consistency (or more precisely, [[monotonicity]]) of any given temperament, as the next section will discuss.

1/''n''-square-particulars, which is to say, commas which can be written in the form of a product of ''n'' consecutive square-particulars (including S''k'' but not including {{nowrap|S(''k'' + ''n'')}}) and which can therefore be written as the ratio between the two superparticulars {{sfrac|''k''|''k'' − 1}} and {{sfrac|''k'' + ''n''|''k'' + ''n'' − 1}} have implications for the consistency of the ({{nowrap|''k'' + ''n''}})-[[odd-limit]] when tempered out. Specifically:

If a temperament tempers out a 1/''n''-square-particular of the form {{nowrap|S''k''⋅S(''k'' + 1)⋅…⋅S(''k'' + ''n'' − 1)}}, it must temper out all of the ''n'' square-particulars that compose it, which is to say it must also temper all of S''k'', {{nowrap|S(''k'' + 1)}}, …, {{nowrap|S(''k'' + ''n'' − 1)}} to make the ({{nowrap|''k'' + ''n''}})-odd-limit consistent. If it does not, it is ''necessarily'' inconsistent due to the lack of monotonicity in the segment.<ref group="note">Technically, the tuning of the higher-rank temperament corresponding to the lower-rank temperament that tempers out all of these commas is the exact set of tuning for which consistency is possible. </ref> A proof is as follows:

{{Proof|contents=

<math>\displaystyle \frac{k + n}{k + n - 1}, \frac{k + n - 1}{k + n - 2}, …, \frac{k + 1}{k}, \frac{k}{k - 1}</math>

Because of tempering out {{nowrap|S''k''⋅S(''k'' + 1)⋅…⋅S(''k'' + ''n'' − 1)}}, we require that {{nowrap|{{sfrac|''k'' + ''n''|''k'' + ''n'' − 1}} {{=}} {{sfrac|''k''|''k'' − 1}}}} consistently. Therefore, if any superparticular {{sfrac|''x''|''x'' − 1}} imbetween (meaning {{nowrap|''k'' + ''n'' > ''x'' > ''k''}}) is not tempered to the same tempered interval, it must be mapped to a different tempered interval. But this means that one of the following must be true:

=== S(''k'' − 1)⋅S''k''⋅S(''k'' + 1) (1/3-square-particulars) ===

This section concerns commas of the form {{nowrap| S(''k'' − 1)⋅S''k''⋅S(''k'' + 1) {{=}} {{sfrac|(''k'' − 1)/(''k'' − 2)|(''k'' + 2)/(''k'' + 1}}) }} which therefore do not directly involve the ''k''-th harmonic. These, along with square-particulars and {{frac|1|2}}-square-particulars (a.k.a. [[triangle-particular]]s), are a special case of 1/''n''-square-particulars.

# Two-thirds of all {{frac|1|3}}-square-particulars are superparticular and the other third are [[#Glossary|throdd-particular]], so these are efficient commas. (See also the [[#Proof of simplification of 1/3-square-particulars]].)

# Their omission of direct relation to the ''k''-th harmonic make them theoretically interesting and potentially useful. (The other type of comma on this page that does this is [[semiparticular]]s.)

{{Proof|title=Proof of simplification of 1/3-square-particulars|contents=

<math>\displaystyle

\begin{align}

S(k-1) \cdot S(k) \cdot S(k+1) &= \left(\frac{\frac{k-1}{k-2}}{\frac{k}{k-1}}\right)\left(\frac{\frac{k}{k-1}}{\frac{k+1}{k}}\right)\left(\frac{\frac{k+1}{k}}{\frac{k+2}{k+1}}\right) \\

\end{align}

</math>

<math>\displaystyle S(k-1) \cdot Sk \cdot S(k+1) = \frac{9n^2 + 6n}{9n^2 + 6n - 3} = \frac{3n^2 + 2n}{3n^2 + 2n - 1}</math>

If {{nowrap|''k'' {{=}} 3''n'' + 2}} then:

<math>\displaystyle S(k-1) \cdot Sk \cdot S(k+1) = \frac{9n^2 + 12n + 3}{9n^2 + 12n} = \frac{3n^2 + 4n + 1}{3n^2 + 4n}</math>

If {{nowrap|''k'' {{=}} 3''n''}} then:

<math>\displaystyle S(k-1) \cdot Sk \cdot S(k+1) = \frac{9n^2 - 1}{9n^2 - 4} </math>

In other words, what this shows is all {{frac|1|3}}-square-particulars of the form S(''k'' − 1)⋅S''k''⋅S(''k'' + 1) are superparticular iff ''k'' is throdd (not a multiple of 3), and all {{frac|1|3}}-square-particulars of the form {{nowrap|S(3''k'' − 1)⋅S(3''k'')⋅S(3''k'' + 1)}} are throdd-particular with the numerator and denominator always being one less than a multiple of 3 (which is to say, commas of this form are throdd-particular iff ''k'' is threven and superparticular iff ''k'' is throdd).

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