Numbers from extended array notation

Here are some typical numbers from extended array notation. They’re also examples to help you understand exAN.

Update note: those numbers are defined using an older version of exAN without the Rule 4.

Two row series

Those numbers are defined using expression s(a₁,a₂,…a_k-1,a_k{2}b₁,b₂,…b_k-1,b_k). The simplest ones are already defined in LAN numbers page, e.g.

In s(3,2{2}2), we start the process. We land at the 3rd entry – the 2 in s(3,2{2}2), and we meet case B2, so change s(3,2{2}2) into s(3,2{2}2{2}1). Then we focus on the first entry of the former {2}, and we meet case B3, so change s(3,2{2}2{2}1) into s(3,2{1}1{1}2{2}1). Since {1} is the comma, we get s(3,2{2}2) = s(3,2,1,2{2}1). That’s how exAN rules work. As a result,

s(3,2{2}2) = s(3,2,1,2{2}1) = s(3,2,1,2) = s(3,3,2,1) = s(3,3,2) = tribo
s(3,3{2}2) = s(3,3,1,1,2{2}1) = s(3,3,1,1,2) = s(3,3,3,3,1) = s(3,3,3,3) = tetentri
s(3,4{2}2) = s(3,4,1,1,1,2{2}1) = s(3,4,1,1,1,2) = s(3,3,3,3,4,1) = s(3,3,3,3,4) = truchaindupribolplex
s(4,2{2}2) = s(4,2,1,2{2}1) = s(4,2,1,2) = s(4,4,2,1) = s(4,4,2) = tetbo
s(4,4{2}2) = s(4,4,1,1,1,2{2}1) = s(4,4,1,1,1,2) = s(4,4,4,4,4,1) = s(4,4,4,4,4) = pententet
s(5,2{2}2) = s(5,2,1,2{2}1) = s(5,2,1,2) = s(5,5,2,1) = s(5,5,2) = pentbo
s(5,5{2}2) = s(5,5,1,1,1,1,2{2}1) = s(5,5,1,1,1,1,2) = s(5,5,5,5,5,5,1) = s(5,5,5,5,5,5) = hexenpent
s(6,2{2}2) = s(6,2,1,2{2}1) = s(6,2,1,2) = s(6,6,2,1) = s(6,6,2) = hexabo

Some larger numbers are listed below.

Linel group

This group includes linel, linelplex, lintrienel, lintetenel and linpentenel in order.

Linel = s(3,2,2{2}2) = s(3,s(3,1,2{2}2),1{2}2) = s(3,s(3,1,1{2}2),1{2}2) = s(3,s(3,1,1,2{2}1),1{2}2) = s(3,s(3,1,1,2),1{2}2) = s(3,s(3,3,1,1),1{2}2) = s(3,s(3,3),1{2}2) = s(3,27,1{2}2) = s(3,27,1,1,1,1,1,1,1,1,1,1,1,1,1,1,1,1,1,1,1,1,1,1,1,1,1,1,1,2{2}1) = s(3,27,1,1,1,1,1,1,1,1,1,1,1,1,1,1,1,1,1,1,1,1,1,1,1,1,1,1,1,2) = s(3,3,3,3,3,3,3,3,3,3,3,3,3,3,3,3,3,3,3,3,3,3,3,3,3,3,3,3,27,1) = s(3,3,3,3,3,3,3,3,3,3,3,3,3,3,3,3,3,3,3,3,3,3,3,3,3,3,3,3,27) (with 28 3′s).

Linelplex = s(3,3,2{2}2) = s(3,s(3,2,2{2}2),1{2}2) = s(3,s(3,2,2{2}2),1,1…,1,2{2}1) = s(3,s(3,2,2{2}2),1,1…,1,2) (with s(3,2,2{2}2) 1′s) = s(3,3,…3,3,s(3,2,2{2}2),1) = s(3,3,…3,3,s(3,2,2{2}2)) (with s(3,2,2{2}2) + 1 3′s). It’s so hard to express in LAN! Note: though s(3,2{2}2) = s(3,3,2), s(3,2{2}3) ≠ s(3,3,2{2}2). In fact, s(3,2{2}3) = s(3,2,1,2{2}2) = s(3,3,2,1{2}2) = s(3,3,…3,3,s(3,2,2{2}2)) (with s(3,2,2{2}2) + 2 3′s) – that’s because rule 3 only applies to “the 1 in the last entry”.

Lintrienel = s(3,3,3{2}2) = s(3,s(3,2,3{2}2),2{2}2) = s(3,s(3,s(3,1,3{2}2),2{2}2),2{2}2) = s(3,s(3,s(3,1,1{2}2),2{2}2),2{2}2) = s(3,s(3,27,2{2}2),2{2}2). The name “lintrienel” bases on “linel” and adds an “-trien-“, which means an “3,3,3” string in the “first row”.

Lintetenel = s(3,3,3,3{2}2) and linpentenel = s(3,3,3,3,3{2}2). And, for the same reason, s(3,3{2}3) ≠ s(3,3,3,3{2}2).

Dulinel group

This group includes dulinel, dulinelplex, dulintrienel and dulintetenel in order.

Dulinel = s(3,2,2{2}3) = s(3,s(3,1,2{2}3),1{2}3) = s(3,s(3,1,1{2}3),1{2}3) = s(3,s(3,1,1,2{2}2),1{2}3) = s(3,s(3,3,1,1{2}2),1{2}3) = s(3,s(3,3,1,1,1,1,2{2}1),1{2}3) = s(3,s(3,3,1,1,1,1,2),1{2}3) = s(3,hexentri,1{2}3) = s(3,hexentri,1,1…,1,2{2}2) (with hexentri 1′s) = s(3,3,…3,3,hexentri,1{2}2) (with hexentri + 1 3′s).

Dulinelplex = s(3,3,2{2}3) = s(3,s(3,2,2{2}3),1{2}3) = s(3,s(3,2,2{2}3),1{2}3) = s(3,dulinel,1{2}3) = s(3,dulinel,1,1…,1,2{2}2) (with dulinel 1′s) = s(3,3,…3,3,hexentri,1{2}2) (with dulinel + 1 3′s).

Dulintrienel = s(3,3,3{2}3) and dulintetenel = s(3,3,3,3{2}3).

Dienlinel group

This group includes dienlinel, dienlintrienel, trienlinel, tetenlinel and pentenlinel in order.

Dienlinel = s(3,2,2{2}3,3), dienlintrienel = s(3,3,3{2}3,3), trienlinel = s(3,2,2{2}3,3,3), tetenlinel = s(3,2,2{2}3,3,3,3) and pentenlinel = s(3,2,2{2}3,3,3,3,3). Here the “dien-“, “trien-“, “teten-” and “penten-” mean 2, 3, 4 or 5 entries of 3 respectively.

Dimensional series

Those numbers are defined using arrays with separator {n} only (where n is a positive integer). A special result is that s(a,1,1…,1{n}2 #) = s(a,1,1…,1{n-1}2 #), so s(a,1,1…,1{n}2 #) = s(a,1,1…,1,2 #).

Linbel group

This group includes linbel, lintrienbel, linblinel, linbdulinel, linbdienlinel, dulinbel, dienlinbel and trienlinbel in order.

Linbel = s(3,2,2{2}1{2}2) = s(3,s(3,1,2{2}1{2}2),1{2}1{2}2) = s(3,s(3,1,1{2}1{2}2),1{2}1{2}2) = s(3,s(3,1,1{2}1,2),1{2}1{2}2) = s(3,s(3,3,3{2}1,1),1{2}1{2}2) = s(3,trientri,1{2}1{2}2) = s(3,trientri,1{2}1,1,…1,1,2) with trientri 1′s. It marks the end of 2-row arrays (arrays with only one {2} and no separator higher than {2})!

Lintrienbel = s(3,3,3{2}1{2}2), linblinel = s(3,2,2{2}2{2}2), linbdulinel = s(3,2,2{2}3{2}2), linbdienlinel = s(3,2,2{2}3,3{2}2), dulinbel = s(3,2,2{2}1{2}3), dienlinbel = s(3,2,2{2}1{2}3,3) and trienlinbel = s(3,2,2{2}1{2}3,3,3).

Lintrel group

This group includes lintrel, lintetel, linpenel and linhexel in order.

Lintrel = s(3,2,2{2}1{2}1{2}2), lintetel = s(3,2,2{2}1{2}1{2}1{2}2), linpenel = s(3,2,2{2}1{2}1{2}1{2}1{2}2) and linhexel = s(3,2,2{2}1{2}1{2}1{2}1{2}1{2}2). They mark the end of 3-row, 4-row, 5-row and 6-row arrays respectively.

Planel group

This group includes planel, planelplex, plantrienel, planlinel and planlinbel in order.

Planel = s(3,2,2{3}2) = s(3,s(3,1,2{3}2),1{3}2) = s(3,s(3,1,1{3}2),1{3}2) = s(3,s(3,1,1{2}2),1{3}2) = s(3,s(3,1,1,2),1{3}2) = s(3,s(3,3,1,1),1{3}2) = s(3,27,1{3}2) = s(3,27,1{2}1{2}1{2}1{2}1{2}1{2}1{2}1{2}1{2}1{2}1{2}1{2}1{2}1{2}1{2}1{2}1{2}1{2}1{2}1{2}1{2}1{2}1{2}1{2}1{2}1{2}1{2}2). And planelplex = s(3,3,2{3}2) = s(3,planel,1{2}1{2}…1{2}1{2}2) with planel {2}′s – that marks the end of planar arrays (arrays with commas and {2}′s only)!

Plantrienel = s(3,3,3{3}2), planlinel = s(3,2,2{2}2{3}2) and planlinbel = s(3,2,2{2}1{2}2{3}2).

planbel group

This group includes duplanel, dienplanel, trienplanel, planbel and plantrel in order.

Duplanel = s(3,2,2{3}3), dienplanel = s(3,2,2{3}3,3), trienplanel = s(3,2,2{3}3,3,3), planbel = s(3,2,2{3}1{3}2) and plantrel = s(3,2,2{3}1{3}1{3}2).

Cubel group

This group includes cubel, tesseral and penteral in order.

Cubel = s(3,2,2{4}2) = s(3,s(3,1,2{4}2),1{4}2) = s(3,s(3,1,1{4}2),1{4}2) = s(3,s(3,1,1,2),1{4}2) = s(3,s(3,3,1,1),1{4}2) = s(3,27,1{4}2) = s(3,27,1{3}1{3}1{3}1{3}1{3}1{3}1{3}1{3}1{3}1{3}1{3}1{3}1{3}1{3}1{3}1{3}1{3}1{3}1{3}1{3}1{3}1{3}1{3}1{3}1{3}1{3}1{3}2).

Tesseral = s(3,2,2{5}2) = s(3,27,1{5}2) = s(3,27,1{4}1{4}1{4}1{4}1{4}1{4}1{4}1{4}1{4}1{4}1{4}1{4}1{4}1{4}1{4}1{4}1{4}1{4}1{4}1{4}1{4}1{4}1{4}1{4}1{4}1{4}1{4}2) – now you see how much tesseral is larger than cubel, but we only change the {4} into the {5}.

Finally penteral = s(3,2,2{6}2).

Post-dimensional series

In definition of those numbers, there’re at least layer-2 entries. Though rules for them are the same as before, the reducing process seems more complex. So let me explain more to you.

Dimentril group

This group includes dimensol, dimentriensol, dimenlinsol, dimenlinbsol, dimentril, diendimensol, lindimensol, and dimenbol in order.

Dimentril = s(3,3{1,2}3). To solve it, we start the process, and meet the 3 in s(3,3{1,2}3). It’s case B2, so change the “{1,2}3” into “{1,2}2{1,2}2“, and jump to the 1 in s(3,3{1,2}2{1,2}2). Then we meet the 2 in s(3,3{1,2}2{1,2}2). It’s case B1, so s(3,3{1,2}3) = s(3,3{3,1}2{1,2}2) = s(3,3{3}2{1,2}2). The next time we start the process, we first meet case B2 then case B3, and s(3,3{3}2{1,2}2) = s(3,3{2}1{2}1{2}2{1,2}2) = s(3,3{2}1{2}1,1,1,2{1,2}2) = s(3,3{2}3{2}3,3,3,1{1,2}2). Also s(3,1{1,2}1,1,2) = s(3,3{1,2}3,1,1) = dimentril, and s(3,3{1,2}1,2) = s(3,3{1,2}3,1) = dimentril. The name “dimentril” combines “dimension” and “-tril”, because it’s above dimensional arrays, and all entries at base layer are 3.

However, dimentril is too far above dimensional arrays, so let’s take some more steps to see its hugeness.

Dimensol = s(3,3{1,2}2) = s(3,3{3,1}2{1,2}1) = s(3,3{3}2) = s(3,3{2}1{2}1{2}2) = s(3,3{2}1{2}1,1,1,2) = s(3,3{2}3{2}3,3,3) – it’s not so large, even smaller than lintrel.

But dimentriensol is larger than all dimensional numbers. It’s s(3,3,3{1,2}2) = s(3,s(3,2,3{1,2}2),2{1,2}2) = s(3,s(3,s(3,1,3{1,2}2),2{1,2}2),2{1,2}2) = s(3,s(3,s(3,1,1{1,2}2),2{1,2}2),2{1,2}2) = s(3,s(3,s(3,3,3,2),2{1,2}2),2{1,2}2), where s(3,n,2{1,2}2) = s(3,s(3,n-1,2{1,2}2),1{1,2}2) = s(3,3,3{s(3,n-1,2{1,2}2)}2) – an s(3,n-1,2{1,2}2)-1 dimension array!

Dimenlinsol = s(3,3{2}2{1,2}2) = s(3,3,1,1,2{1,2}2) = s(3,3,3,3,1{1,2}2), and dimenlinbsol = s(3,3{2}1{2}2{1,2}2) = s(3,3{2}1,1,1,2{1,2}2) = s(3,3{2}3,3,3,1{1,2}2). And dimentril is the 3rd term beginning with dimenlinsol and dimenlinbsol.

Going beyond dimentril, diendimensol = s(3,3{1,2}3,3) = s(3,3{3}2{1,2}2,3), lindimensol = s(3,3{1,2}1{2}2) = s(3,3{1,2}1,1,1,2) = s(3,3{1,2}3,3,3), and dimenbol = s(3,3{1,2}1{1,2}2) = s(3,3{1,2}3{3,1}2{1,2}1) = s(3,3{1,2}3{3}2).

Dimensolplex group (New Naming System)

From now on, we start another naming system. In the system, we use 4 “namebases” to name numbers result from some typical expressions. They’re

• “ol” – to name expressions s(3,3A2)
• “trien” – to name expressions s(3,3,3A2)
• “tril” – to name expressions s(3,3A3)
• “bol” – to name expressions s(3,3A1A2)

where A is a separator. The first group beyond dimenbol is dimensolplex group. This group contains 19 numbers as follows. Though I use the same suffix “-plex” as before, they have fully different meaning.

• dimensolplex = s(3,3{2,2}2) = s(3,3{1,2}1{1,2}1{1,2}2) = s(3,3{1,2}3{1,2}3{3}2). It’s similar to dimenbol, but with 3 “dimension rows” instead of 2.
• dimentrienplex = s(3,3,3{2,2}2). Notice the change of the namebase from dimentril group. This time we have not just 3 dimension rows, because the {2,2} reduces only when you meet it in the process. Actually dimentrienplex = s(3,s(3,s(3,3,3{1,2}2),2{2,2}2),2{2,2}2), where s(3,n,2{2,2}2) reduces to an array with s(3,n-1,2{2,2}2) dimension rows!
• dimentrilplex = s(3,3{2,2}3) = s(3,3{1,2}1{1,2}1{1,2}2{2,2}2) = s(3,3{1,2}3{1,2}3{3}2{2,2}2).
• dimenbolplex = s(3,3{2,2}1{2,2}2) = s(3,3{2,2}1{1,2}1{1,2}1{1,2}2) = s(3,3{2,2}3{1,2}3{1,2}3{3}2).
• dimentrienbiplex = s(3,3,3{3,2}2)
• dimentrilbiplex = s(3,3{3,2}3)
• dimenbolbiplex = s(3,3{3,2}1{3,2}2)
• dimensoltriplex = s(3,3{4,2}2)
• dimentrientriplex = s(3,3,3{4,2}2)
• dimentriltriplex = s(3,3{4,2}3)
• dimenboltriplex = s(3,3{4,2}1{4,2}2)
• dimensolquadriplex = s(3,3{5,2}2)
• dimentrienquadriplex = s(3,3,3{5,2}2)
• dimentrilquadriplex = s(3,3{5,2}3)
• dimenbolquadriplex = s(3,3{5,2}1{5,2}2)
• dimensolquintiplex = s(3,3{6,2}2)
• dimentrienquintiplex = s(3,3,3{6,2}2)
• dimentrilquintiplex = s(3,3{6,2}3)
• dimenbolquintiplex = s(3,3{6,2}1{6,2}2)

So the suffix n-plex means that the separator A becomes {n+1,2}. However, there’s one missing number…

-dex group

Now we pick up the missing number – dimensoldex, but you may think that the missing number is dimensolbiplex. Actually they’re the same thing, because

Dimensoldex = s(3,3{1,3}2) = s(3,3{3,2}2) = dimensolbiplex. The reducing process is similar to dimensol or dimentril. First we start the process, and meet the “2” in s(3,3{1,3}2) – that’s case B2, so change the “{1,3}2” into “{1,3}2{1,3}1″, and jump to the “1“. Then we meet the “3” in s(3,3{1,3}2{1,3}1) – that’s case B3, so s(3,3{1,3}2) = s(3,3{3,2}2{1,3}1) = s(3,3{3,2}2).

The suffix “-dex” change the {1,2} into {1,3}, so we get dimentriendex = s(3,3,3{1,3}2), dimentrildex = s(3,3{1,3}3) and dimenboldex = s(3,3{1,3}1{1,3}2).

The {1,3} is not just {3,2} – it’s {b,2} where b is the iterator only when you meet it in the process. Dimensoldex = dimensolbiplex – that’s a bit weak. But could you imagine what’s the n such that dimentriendex ≈ dimentrien-n-plex? Try to reduce it, and you’ll get similar answer to what I said about dimentriensol and dimentrienplex.

Then we can add “n-plex” suffixes to those numbers, such as

• dimensoldexplex = s(3,3{2,3}2)
• dimentriendexplex = s(3,3,3{2,3}2)
• dimentrildexplex = s(3,3{2,3}3)
• dimenboldexplex = s(3,3{2,3}1{2,3}2)
• dimentriendexbiplex = s(3,3,3{3,3}2)
• dimentrildexbiplex = s(3,3{3,3}3)
• dimenboldexbiplex = s(3,3{3,3}1{3,3}2)

(still with one missing stuff…) So the suffix “n-plex” means the first entry of the separator A changed from 1 to n+1.

The next step is adding “-plex” prior to the “-dex”. And we get some larger numbers –

• dimensolplexdex = s(3,3{1,4}2) = s(3,3{3,3}2), a.k.a. the missing stuff – dimensoldexbiplex.
• dimentrienplexdex = s(3,3,3{1,4}2)
• dimentrilplexdex = s(3,3{1,4}3)
• dimenbolplexdex = s(3,3{1,4}1{1,4}2)
• dimensolplexdexplex = s(3,3{2,4}2)
• dimentrienplexdexplex = s(3,3,3{2,4}2)
• dimentrilplexdexplex = s(3,3{2,4}3)
• dimenbolplexdexplex = s(3,3{2,4}1{2,4}2)

And with “-biplex” prior to the “-dex”:

• dimensolbiplexdex = s(3,3{1,5}2) = s(3,3{3,4}2)
• dimentrienbiplexdex = s(3,3,3{1,5}2)
• dimentrilbiplexdex = s(3,3{1,5}3)
• dimenbolbiplexdex = s(3,3{1,5}1{1,5}2)
• dimensolbiplexdexplex = s(3,3{2,5}2)
• dimentrienbiplexdexplex = s(3,3,3{2,5}2)
• dimentrilbiplexdexplex = s(3,3{2,5}3)
• dimenbolbiplexdexplex = s(3,3{2,5}1{2,5}2)

With “-triplex” prior to the “-dex”:

• dimensoltriplexdex = s(3,3{1,6}2) = s(3,3{3,5}2)
• dimentrientriplexdex = s(3,3,3{1,6}2)
• dimentriltriplexdex = s(3,3{1,6}3)
• dimenboltriplexdex = s(3,3{1,6}1{1,6}2)

And so on. The “n-plex” prior to the “-dex” means adding n to the 2nd entry of the separator A.

-bidex group

Here’s how the suffix “-bidex” works.

Dimensolbidex = s(3,3{1,1,2}2). To solve it, first we start the process, and meet the “2” in s(3,3{1,1,2}2) – that’s case B2, so change the “{1,1,2}2” into “{1,1,2}2{1,1,2}1″, and jump to the “1“. Then we meet the “2” in s(3,3{1,1,2}2{1,1,2}1) – that’s case B3, so s(3,3{1,1,2}2) = s(3,3{1,3,1}2{1,1,2}1) = s(3,3{1,3}2) – it’s still dimensoldex (or dimensolbiplex).

• dimentrienbidex = s(3,3,3{1,1,2}2) – that’s much larger.
• dimentrilbidex = s(3,3{1,1,2}3)
• dimenbolbidex = s(3,3{1,1,2}1{1,1,2}2)

And adding “-plex” after “-biplex”:

• dimensolbidexplex = s(3,3{2,1,2}2)
• dimentrienbidexplex = s(3,3,3{2,1,2}2)
• dimentrilbidexplex = s(3,3{2,1,2}3)
• dimenbolbidexplex = s(3,3{2,1,2}1{2,1,2}2)

We can also add “-plex” prior to the “-biplex”, but this step is too big. The “-bidex” means two “-dex”es, so we can insert “-plex” between them, such as

• dimensoldexplexdex = s(3,3{1,2,2}2) = s(3,3{3,1,2}2)
• dimentriendexplexdex = s(3,3,3{1,2,2}2)
• dimentrildexplexdex = s(3,3{1,2,2}3)
• dimenboldexplexdex = s(3,3{1,2,2}1{1,2,2}2)
• dimensoldexplexdexplex = s(3,3{2,2,2}2)
• dimentriendexplexdexplex = s(3,3,3{2,2,2}2)
• dimentrildexplexdexplex = s(3,3{2,2,2}3)
• dimenboldexplexdexplex = s(3,3{2,2,2}1{2,2,2}2)
• dimentriendexbiplexdex = s(3,3,3{1,3,2}2)
• dimentrildexbiplexdex = s(3,3{1,3,2}3)
• dimenboldexbiplexdex = s(3,3{1,3,2}1{1,3,2}2)

Then we reach “-plex” prior to “-bidex”.

• dimensolthrex = s(3,3{1{2}2}2) = s(3,3{1,1,1,2}2) = s(3,3{1,1,3}2) = s(3,3{1,3,2}2) = s(3,3{3,2,2}2), a.k.a. dimensoltridex, dimensolplexbidex, dimensoldexbiplexdex and dimensoldexplexdexbiplex.
• dimentrienplexbidex = s(3,3,3{1,1,3}2)
• dimentrilplexbidex = s(3,3{1,1,3}3)
• dimenbolplexbidex = s(3,3{1,1,3}1{1,1,3}2)
• dimensolplexbidexplex = s(3,3{2,1,3}2)
• dimentrienplexbidexplex = s(3,3,3{2,1,3}2)
• dimentrilplexbidexplex = s(3,3{2,1,3}3)
• dimenbolplexbidexplex = s(3,3{2,1,3}1{2,1,3}2)
• dimensolplexdexplexdex = s(3,3{1,2,3}2) = s(3,3{3,1,3}2)
• dimentrienplexdexplexdex = s(3,3,3{1,2,3}2)
• dimentrilplexdexplexdex = s(3,3{1,2,3}3)
• dimenbolplexdexplexdex = s(3,3{1,2,3}1{1,2,3}2)
• dimentrienplexdexbiplexdex = s(3,3,3{1,3,3}2)
• dimentrilplexdexbiplexdex = s(3,3{1,3,3}3)
• dimenbolplexdexbiplexdex = s(3,3{1,3,3}1{1,3,3}2)

And with “-biplex”:

• dimensolbiplexbidex = s(3,3{1,1,4}2) = s(3,3{1,3,3}2) = s(3,3{3,2,3}2), a.k.a. dimensolplexdexbiplexdex.
• dimentrienbiplexbidex = s(3,3,3{1,1,4}2)
• dimentrilbiplexbidex = s(3,3{1,1,4}3)
• dimenbolbiplexbidex = s(3,3{1,1,4}1{1,1,4}2)

And so on. The “n-plex” prior to the “-bidex” means adding n to the 3rd entry of the separator A.

Multi-dex group

The suffix “-tridex” means 3 “-dex”es, so we can insert “-plex”es before them, after one, after two, or after them, such as

• dimentrientridex = s(3,3,3{1,1,1,2}2)
• dimentriltridex = s(3,3{1,1,1,2}3)
• dimenboltridex = s(3,3{1,1,1,2}1{1,1,1,2}2)
• dimensoltridexplex = s(3,3{2,1,1,2}2)
• dimensolbidexplexdex = s(3,3{1,2,1,2}2) = s(3,3{3,1,1,2}2)
• dimensolbidexplexdexplex = s(3,3{2,2,1,2}2)
• dimensoldexplexbidex = s(3,3{1,1,2,2}2) = s(3,3{1,3,1,2}2) = s(3,3{3,2,1,2}2)
• dimensoldexplexbidexplex = s(3,3{2,1,2,2}2)
• dimensoldexplexdexplexdex = s(3,3{1,2,2,2}2) = s(3,3{3,1,2,2}2)
• dimensoldexplexdexplexdexplex = s(3,3{2,2,2,2}2)
• dimensolquadridex = s(3,3{1,1,1,1,2}2) = s(3,3{1,1,1,3}2) = s(3,3{1,1,3,2}2) = s(3,3{1,3,2,2}2) = s(3,3{3,2,2,2}2), a.k.a. dimensolplextridex.
• dimensolbiplextridex = s(3,3{1,1,1,4}2) = s(3,3{1,1,3,3}2) = s(3,3{1,3,2,3}2) = s(3,3{3,2,2,3}2)

The suffix “-quadridex” means 4 “-dex”es, so we can also insert “-plex”es.

• dimentrienquadridex = s(3,3,3{1,1,1,1,2}2)
• dimentrilquadridex = s(3,3{1,1,1,1,2}3)
• dimenbolquadridex = s(3,3{1,1,1,1,2}1{1,1,1,1,2}2)
• dimensolquadridexplex = s(3,3{2,1,1,1,2}2)
• dimensoltridexplexdex = s(3,3{1,2,1,1,2}2) = s(3,3{3,1,1,1,2}2)
• dimensoltridexplexdexplex = s(3,3{2,2,1,1,2}2)
• dimensolbidexplexbidex = s(3,3{1,1,2,1,2}2) = s(3,3{1,3,1,1,2}2) = s(3,3{3,2,1,1,2}2)
• dimensolbidexplexbidexplex = s(3,3{2,1,2,1,2}2)
• dimensolbidexplexdexplexdex = s(3,3{1,2,2,1,2}2) = s(3,3{3,1,2,1,2}2)
• dimensolbidexplexdexplexdexplex = s(3,3{2,2,2,1,2}2)
• dimensoldexplextridex = s(3,3{1,1,1,2,2}2) = s(3,3{1,1,3,1,2}2) = s(3,3{1,3,2,1,2}2) = s(3,3{3,2,2,1,2}2)
• dimensoldexplextridexplex = s(3,3{2,1,1,2,2}2)
• dimensoldexplexbidexplexdex = s(3,3{1,2,1,2,2}2) = s(3,3{3,1,1,2,2}2)
• dimensoldexplexbidexplexdexplex = s(3,3{2,2,1,2,2}2)
• dimensoldexplexdexplexbidex = s(3,3{1,1,2,2,2}2) = s(3,3{1,3,1,2,2}2) = s(3,3{3,2,1,2,2}2)
• dimensoldexplexdexplexbidexplex = s(3,3{2,1,2,2,2}2)
• dimensoldexplexdexplexdexplexdex = s(3,3{1,2,2,2,2}2) = s(3,3{3,1,2,2,2}2)
• dimensoldexplexdexplexdexplexdexplex = s(3,3{2,2,2,2,2}2)
• dimensolquintidex = s(3,3{1,1,1,1,1,2}2) = s(3,3{1,1,1,1,3}2) = s(3,3{1,1,1,3,2}2) = s(3,3{1,1,3,2,2}2) = s(3,3{1,3,2,2,2}2) = s(3,3{3,2,2,2,2}2), a.k.a. dimensolplexquadridex.
• dimensolbiplexquadridex = s(3,3{1,1,1,1,4}2) = s(3,3{1,1,1,3,3}2) = s(3,3{1,1,3,2,3}2) = s(3,3{1,3,2,2,3}2) = s(3,3{3,2,2,2,3}2)

And the suffix “-quintidex” means 5 “-dex”es.

• dimentrienquintidex = s(3,3,3{1,1,1,1,1,2}2)
• dimentrilquintidex = s(3,3{1,1,1,1,1,2}3)
• dimenbolquintidex = s(3,3{1,1,1,1,1,2}1{1,1,1,1,1,2}2)
• dimensolquintidexplex = s(3,3{2,1,1,1,1,2}2)
• dimensolquadridexplexdex = s(3,3{1,2,1,1,1,2}2) = s(3,3{3,1,1,1,1,2}2)
• dimensoltridexplexbidex = s(3,3{1,1,2,1,1,2}2) = s(3,3{1,3,1,1,1,2}2) = s(3,3{3,2,1,1,1,2}2)
• dimensolbidexplextridex = s(3,3{1,1,1,2,1,2}2) = s(3,3{1,1,3,1,1,2}2) = s(3,3{1,3,2,1,1,2}2) = s(3,3{3,2,2,1,1,2}2)
• dimensoldexplexquadridex = s(3,3{1,1,1,1,2,2}2) = s(3,3{1,1,1,3,1,2}2) = s(3,3{1,1,3,2,1,2}2) = s(3,3{1,3,2,2,1,2}2) = s(3,3{3,2,2,2,1,2}2)
• dimensolplexquintidex = s(3,3{1,1,1,1,1,3}2) = s(3,3{1,1,1,1,3,2}2) = s(3,3{1,1,1,3,2,2}2) = s(3,3{1,1,3,2,2,2}2) = s(3,3{1,3,2,2,2,2}2) = s(3,3{3,2,2,2,2,2}2). Also s(3,3{1,1,1,1,1,1,2}2) = s(3,3{1,1,1,1,1,3}2) = dimensolplexquintidex.

And so on. Now have a look at effects of suffix “-dex” and “-plex”. First, both modify the “separator A” in the definition of namebases. The “n-dex” increase the (n+1)-th entry of A from 1 to 2, then the “n-plex” prior to m “-dex”es increase the (m+1)-th entry of A by n. However, since we start on A = {1,2}, names below dimensolbidex have an offset on the 2nd entry of A.

Naming space

Now I introduce an idea about naming numbers – the naming space. The size of naming space of a naming system shows how many regular names the system can produce.

Here’s how “-plex” and “-dex” works in my naming system. We can have arbitrary many “-plex”es, and shorten as “n-plex”, so this forms a naming space of . Notice that I don’t write because the levels of “-plex”, “-biplex”, “-triplex”, etc. are ordered. We want “-biplex” to be a higher-leveled modifier than “-plex”, and “-triplex” is even higher-leveled, and so on.

Next, a “-dex” is a stronger modifier than all the “n-plex”es, and “-dex” followed by “n-plex” form another naming space of , and of in total. Then “-plexdex” followed by “n-plex” form another , and so on. So “n-plexdex-m-plex” form a naming space of . We still want them to be ordered, e.g. “-plexdex” is higher-leveled than all the “-dex-n-plex”es.

Next, 2 “-dex”es separate “-plex”es into 3 groups, so they form a naming space of ; 3 “-dex”es separate “-plex”es into 4 groups, so they form a naming space of , and so on. Multi-dex and “-plex”es then form a naming space of .

What about the notation system? With “-plex”es and “-dex”es I named numbers up to separator {1{2}2}, which has recursion level  – that’s equal to the size of the naming space, so we can have a name for numbers at every separator recursion level. However, function f(n) = s(n,n{1{2}2}2) has growth rate , so the naming space is not enough if I must name for every growth rate (in FGH scale). I indeed named numbers up to separator {1{2}2}, but you can see what’s wrong with the naming system. The problem is that there’re many naming holes. e.g. between two adjacent terms in the naming system, dimentrienquintidex (where s(n,n,3{1,1,1,1,1,2}2) has growth rate ) and dimentrilquintidex (where s(n,n{1,1,1,1,1,2}3) has growth rate ), there’re many “unnamed growth rate” (i.e. without any named numbers), so they form a naming hole.

So how to deal with naming holes? One way is to leave it empty, but we can’t feel the hugeness of the step from before the hole to after the hole – it’s not good. A second way is to change the order of the modifiers we use, to form a larger naming space, then it fit our need. But, the new order may be more chaotic, and the result names may be longer and unclear. That’s a “notational way”, with more and more rules, not suit for naming. Another way is to add new modifiers to the naming system, which can fill the naming holes. Then the types of modifiers will be greater as we go on. That’s a “naming way”, with more and more new modifiers, and we get more and more colorful names – that’s good. So I choose the last one for the next steps.

-threx group

Now I introduce a new modifier – the suffix “-threx”. It means the 3rd single modifier after “-plex” and “-dex”. Here’s the basic framework of the naming system. First, we have “n-threx”, meaning n “-threx”es, and this form a naming space of . Second, we insert “-dex”es between “-threx”es, and this step multiply the naming space by . Finally, we insert “-plex”es between suffixes already existing, and this step multiply the naming space by  again. So the size of the naming space is . However, I still want the system can go up to separator recursion level ! So I must need more modifiers…

Let’s begin with a single “-threx”.

• dimentrienthrex = s(3,3,3{1{2}2}2)
• dimentrilthrex = s(3,3{1{2}2}3)
• dimenbolthrex = s(3,3{1{2}2}1{1{2}2}2)

Then add “-plex”es after the “-threx”.

• dimensolthrexplex = s(3,3{2{2}2}2)
• dimentrienthrexplex = s(3,3,3{2{2}2}2)
• dimentrilthrexplex = s(3,3{2{2}2}3)
• dimenbolthrexplex = s(3,3{2{2}2}1{2{2}2}2)
• dimensolthrexbiplex = s(3,3{3{2}2}2)
• dimentrienthrexbiplex = s(3,3,3{3{2}2}2)
• dimentrilthrexbiplex = s(3,3{3{2}2}3)
• dimenbolthrexbiplex = s(3,3{3{2}2}1{3{2}2}2)

Then we can add “-plex”es prior to the “-threx”, such as

• dimentrienplexthrex = s(3,3,3{1{2}3}2)
• dimentrilplexthrex = s(3,3{1{2}3}3)
• dimenbolplexthrex = s(3,3{1{2}3}1{1{2}3}2)

But wait! There’s a naming hole between {1,2{2}2} and {1{2}3}. To fill the naming hole, I use a new modifier.

• dimensolthrexdexiplex = s(3,3{1,2{2}2}2) = s(3,3{3,1{2}2}2), which is slightly larger than dimensolthrexbiplex.
• dimentrienthrexdexiplex = s(3,3,3{1,2{2}2}2)
• dimentrilthrexdexiplex = s(3,3{1,2{2}2}3)
• dimenbolthrexdexiplex = s(3,3{1,2{2}2}1{1,2{2}2}2)
• dimensolthrexdexibiplex = s(3,3{2,2{2}2}2)
• dimensolthrexbidexiplex = s(3,3{1,1,2{2}2}2) = s(3,3{1,3,1{2}2}2)
• dimensolthrexbidexibiplex = s(3,3{2,1,2{2}2}2)
• dimensolthrexdexiplexdexiplex = s(3,3{1,2,2{2}2}2) = s(3,3{3,1,2{2}2}2), a.k.a. dimensolthrexbidexitriplex.
• dimensolthrexdexiplexdexibiplex = s(3,3{2,2,2{2}2}2)
• dimensolthrexdex = s(3,3{1{2}1,2}2) = s(3,3{1{2}3}2) = s(3,3{1,1,1,2{2}2}2), a.k.a. dimensolplexthrex and dimensolthrextridexiplex.

Notice that I use “-dexi” instead of “-dex”, and I always leave one more “-plex” at the end of the name. That’s my way to fill the naming hole. Now continue upward…

• dimensolplexthrexplex = s(3,3{2{2}3}2)
• dimensolbiplexthrex = s(3,3{1{2}4}2) = s(3,3{1,1,1,2{2}3}2) = s(3,3{1,1,3,1{2}3}2) – and we have the same way to fill the naming hole between the first two numbers.
• dimensolthrexdexplex = s(3,3{2{2}1,2}2)
• dimensolthrexdexdexiplex = s(3,3{1,2{2}1,2}2)
• dimensolthrexplexdex = s(3,3{1{2}2,2}2)
• dimensolthrexplexdexplex = s(3,3{2{2}2,2}2)
• dimensolplexthrexdex = s(3,3{1{2}1,3}2). Also dimensolthrexbidex = s(3,3{1{2}1,1,2}2) = s(3,3{1{2}1,3}2) = dimensolplexthrexdex.
• dimensolplexthrexdexplex = s(3,3{2{2}1,3}2)
• dimensolplexthrexplexdex = s(3,3{1{2}2,3}2)
• dimensolplexthrexplexdexplex = s(3,3{2{2}2,3}2)

A “-threx” and a “-dex” can form 3 places where “n-plex” can insert. The last place corresponds to increasing the 1st entry of {1{2}1,2}, the 2nd place for the 2nd entry of {1{2}1,2}, and the 1st place for the last entry. For more “-threx”es and “-dex”es, this still holds.

• dimensolthrexbidexplex = s(3,3{2{2}1,1,2}2)
• dimensolthrexdexplexdex = s(3,3{1{2}2,1,2}2)
• dimensolthrexplexbidex = s(3,3{1{2}1,2,2}2)
• dimensoldexthrex = s(3,3{1{2}1{2}2}2) = s(3,3{1{2}1,1,1,2}2) = s(3,3{1{2}1,1,3}2), a.k.a. dimensolthrextridex and dimensolplexthrexbidex.
• dimensoldexthrexplex = s(3,3{2{2}1{2}2}2)
• dimensoldexplexthrex = s(3,3{1{2}2{2}2}2)
• dimensoldexthrexdex = s(3,3{1{2}1{2}1,2}2) = s(3,3{1{2}1{2}3}2), a.k.a. dimensolplexdexthrex .
• dimensoldexthrexdexplex = s(3,3{2{2}1{2}1,2}2)
• dimensoldexthrexplexdex = s(3,3{1{2}2{2}1,2}2)
• dimensoldexplexthrexdex = s(3,3{1{2}1{2}2,2}2)
• dimensoldexthrexbidex = s(3,3{1{2}1{2}1,1,2}2) = s(3,3{1{2}1{2}1,3}2), a.k.a. dimensolplexdexthrexdex.
• dimensoldexthrexbidexplex = s(3,3{2{2}1{2}1,1,2}2)
• dimensoldexthrexdexplexdex = s(3,3{1{2}2{2}1,1,2}2)
• dimensoldexthrexplexbidex = s(3,3{1{2}1{2}2,1,2}2)
• dimensoldexplexthrexbidex = s(3,3{1{2}1{2}1,2,2}2)
• extendol = s(3,3{1`2}2) = s(3,3{1{1,2}2}2) = s(3,3{1{3}2}2) = s(3,3{1{2}1{2}1{2}2}2) = s(3,3{1{2}1{2}1,1,1,2}2) = s(3,3{1{2}1{2}1,1,3}2), a.k.a. dimensoltetrex, dimensolbithrex, dimensolbidexthrex, dimensoldexthrextridex and dimensolplexdexthrexbidex. For more information about this number, see a later page “numbers from expanding array notation”.

Generally, a “-dex” add an entry at the end of the layer-1 separator (i.e. the “separator A”). If you want some expressions with extra entry not at the end of the separator A, then you go into a naming hole, and you need “-dexi”es. e.g. dimensoldexthrexdexiplexdex = s(3,3{1{2}1,2{2}1,2}2) = s(3,3{1{2}3,1{2}1,2}2).

• dimensolbithrexplex = s(3,3{2{3}2}2)
• dimensolthrexplexthrex = s(3,3{1{2}2{3}2}2). Hey! There’s an extra entry! This entry corresponds to {1{2}2}, or the strength of a “-threx”.
• dimensolthrexdexiplexthrex = s(3,3{1{2}1,2{3}2}2) – for other extra entries we need “-dexi”es.
• dimensolthrexthrexiplexthrex = s(3,3{1{2}1{2}2{3}2}2) – now “-threxi” appears.
• dimensolthrexthrexidexiiplexthrex = s(3,3{1{2}1,2{2}2{3}2}2) – now “-dexii” appears. That’s a way to fill an “2nd-order” naming hole, where even with “-dexi” and “-threxi” we still can’t cover. If there’re still naming holes, we’ll use more Roman numerals such as “-dexiii”, “-dexiv”, “-dexv”, “-dexvi”, etc.
• dimensolbithrexdex = s(3,3{1{3}1,2}2) = s(3,3{1{3}3}2), a.k.a. dimensolplexbithrex.
• dimensolbithrexdexplex = s(3,3{2{3}1,2}2)
• dimensolbithrexplexdex = s(3,3{1{2}2{3}1,2}2)
• dimensolthrexplexthrexdex = s(3,3{1{3}2,2}2)
• dimensolbithrexbidex = s(3,3{1{3}1,1,2}2) = s(3,3{1{3}1,3}2), a.k.a. dimensolplexbithrexdex.
• dimensolthrexdexthrex = s(3,3{1{3}1{2}2}2) = s(3,3{1{3}1,1,1,2}2) = s(3,3{1{3}1,1,3}2), a.k.a. dimensolbithrextridex and dimensolplexbithrexbidex.
• dimensolthrexdexthrexdex = s(3,3{1{3}1{2}1,2}2)
• dimensolthrexbidexthrex = s(3,3{1{3}1{2}1{2}2}2)
• dimensoldexbithrex = s(3,3{1{3}1{3}2}2) = s(3,3{1{3}1{2}1{2}1{2}2}2), a.k.a. dimensolthrextridexthrex.
• dimensoltrithrex = s(3,3{1{4}2}2) = s(3,3{1{3}1{3}1{3}2}2), a.k.a. dimensolbidexbithrex.
• dimensoltrithrexplex = s(3,3{2{4}2}2)
• dimensolbithrexplexthrex = s(3,3{1{2}2{4}2}2)
• dimensolthrexplexbithrex = s(3,3{1{3}2{4}2}2)
• dimensoltrithrexdex = s(3,3{1{4}1,2}2) = s(3,3{1{4}3}2), a.k.a. dimensolplextrithrex.
• dimensolbithrexdexthrex = s(3,3{1{4}1{2}2}2)
• dimensolthrexdexbithrex = s(3,3{1{4}1{3}2}2)
• dimensoldextrithrex = s(3,3{1{4}1{4}2}2)
• dimensolquadrithrex = s(3,3{1{5}2}2) = s(3,3{1{4}1{4}1{4}2}2), a.k.a. dimensolbidextrithrex.
• dimensolquintithrex = s(3,3{1{6}2}2)

Now I show you how the main naming system (excluding the filling naming hole part) works for the “-threx” level.

1. At the beginning, 4 namebases are mapped into expressions. Separator A is initialized as {1,2}.
2. Append “-threx”es to the name. The entry inside the separator inside A increases 1 every appending.
3. Insert “-dex”es to the name. For every insertion, look at the position from the end of the name. If it’s the k-th position, the A will add an entry at the end, where the separator corresponds to the result of “appending k ‘-threx’es at step 2”.
4. Insert “-plex”es to the name. For every insertion, look at the position from the end of the name. If it’s the k-th position, the k-th entry of A will increases 1.
5. Replace multiple same suffixes with “bi-“, “tri-“, “quadri-” etc. ones.

Using ordinals, the naming process can be more clear. A “-threx” means , a “-dex” means , and a “-plex” means  in separator recursion level, where the β is defined by the result of adding k suffixes in previous steps, where k is the position of the suffix we focus from the end of the name. What’s more important, this way works even beyond the “-threx” group!

-tetrex and beyond

Using suffix “-tetrex”, we have a naming space of .

• dimentrientetrex = s(3,3,3{1{1,2}2}2)
• dimentriltetrex = s(3,3{1{1,2}2}3)
• dimenboltetrex = s(3,3{1{1,2}2}1{1{1,2}2}2)
• dimensoltetrexplex = s(3,3{2{1,2}2}2)
• dimensoltetrexdexiplex = s(3,3{1,2{1,2}2}2) = s(3,3{3,1{1,2}2}2)
• dimensoltetrexplexdexiplex = s(3,3{1,3{1,2}2}2)
• dimensoltetrexbidexiplex = s(3,3{1,1,2{1,2}2}2) = s(3,3{1,3,1{1,2}2}2)
• dimensoltetrexthrexiplex = s(3,3{1{2}2{1,2}2}2) = s(3,3{1,1,1,2{2}1{1,2}2}2)
• dimensoltetrexthrexidexiiplex = s(3,3{1,2{2}2{1,2}2}2) = s(3,3{3,1{2}2{1,2}2}2)
• dimensoltetrexthrexidexiplex = s(3,3{1{2}1,2{1,2}2}2) = s(3,3{1{2}3,1{1,2}2}2)
• dimensoltetrexdexithrexiplex = s(3,3{1{2}1{2}2{1,2}2}2) = s(3,3{1{2}1,1,1,2{2}1{1,2}2}2)
• dimensoltetrexdex = s(3,3{1{1,2}1,2}2) = s(3,3{1{1,2}3}2) = s(3,3{1{3}2{1,2}2}2), a.k.a. dimensolplextetrex and dimensoltetrexbithrexiplex.
• dimensoltetrexdexplex = s(3,3{2{1,2}1,2}2)
• dimensoltetrexplexdex = s(3,3{1{1,2}2,2}2)
• dimensoltetrexbidex = s(3,3{1{1,2}1,1,2}2) = s(3,3{1{1,2}1,3}2), a.k.a. dimensolplextetrexdex.
• dimensoltetrexthrexidex = s(3,3{1{1,2}1{2}2}2) – Now a “-threxi” appears prior to a “-dex”.
• dimensoldextetrex = s(3,3{1{1,2}1{1,2}2}2) = s(3,3{1{1,2}1{3}2}2), a.k.a. dimensoltetrexbithrexidex.
• dimensoldextetrexplex = s(3,3{2{1,2}1{1,2}2}2)
• dimensoldexplextetrex = s(3,3{1{1,2}2{1,2}2}2)
• dimensoldextetrexdex = s(3,3{1{1,2}1{1,2}1,2}2) = s(3,3{1{1,2}1{1,2}3}2), a.k.a. dimensolplexdextetrex.
• dimensoltetrexthrex = s(3,3{1{2,2}2}2) = s(3,3{1{1,2}1{1,2}1{1,2}2}2), a.k.a. dimensolbidextetrex.
• dimensoltetrexthrexplex = s(3,3{2{2,2}2}2)
• dimensoltetrexplexthrex = s(3,3{1{1,2}2{2,2}2}2)
• dimensoltetrexthrexdex = s(3,3{1{2,2}1,2}2) = s(3,3{1{2,2}3}2), a.k.a. dimensolplextetrexthrex.
• dimensoltetrexthrexdexplex = s(3,3{2{2,2}1,2}2)
• dimensoltetrexthrexplexdex = s(3,3{1{1,2}2{2,2}1,2}2)
• dimensoltetrexplexthrexdex = s(3,3{1{2,2}2,2}2)
• dimensoltetrexthrexbidex = s(3,3{1{2,2}1,1,2}2) = s(3,3{1{2,2}1,3}2), a.k.a. dimensolplextetrexthrexdex.
• dimensoltetrexdexthrex = s(3,3{1{2,2}1{1,2}2}2)
• dimensoltetrexdexthrexplex = s(3,3{2{2,2}1{1,2}2}2)
• dimensoltetrexdexplexthrex = s(3,3{1{1,2}2{2,2}1{1,2}2}2)
• dimensoltetrexplexdexthrex = s(3,3{1{2,2}2{1,2}2}2)
• dimensoltetrexdexthrexdex = s(3,3{1{2,2}1{1,2}1,2}2) = s(3,3{1{2,2}1{1,2}3}2), a.k.a. dimensolplextetrexdexthrex.
• dimensoltetrexdexthrexbidex = s(3,3{1{2,2}1{1,2}1,1,2}2)
• dimensoltetrexbidexthrex = s(3,3{1{2,2}1{1,2}1{1,2}2}2)
• dimensoldextetrexthrex = s(3,3{1{2,2}1{2,2}2}2)
• dimensoldextetrexthrexdex = s(3,3{1{2,2}1{2,2}1,2}2)
• dimensoldextetrexthrexbidex = s(3,3{1{2,2}1{2,2}1,1,2}2)
• dimensoldextetrexdexthrex = s(3,3{1{2,2}1{2,2}1{1,2}2}2)
• dimensoldextetrexdexthrexdex = s(3,3{1{2,2}1{2,2}1{1,2}1,2}2)
• dimensoldextetrexdexthrexbidex = s(3,3{1{2,2}1{2,2}1{1,2}1,1,2}2)
• dimensoldextetrexbidexthrex = s(3,3{1{2,2}1{2,2}1{1,2}1{1,2}2}2)
• dimensolbitetrex = s(3,3{1{1,1,2}2}2) = s(3,3{1{1,3}2}2) = s(3,3{1{3,2}2}2) = s(3,3{1{2,2}1{2,2}1{2,2}2}2), a.k.a. dimensolthrextetrex, dimensoltetrexbithrex and dimensolbidextetrexthrex.
• dimensolbitetrexplex = s(3,3{2{1,1,2}2}2)
• dimensoltetrexplextetrex = s(3,3{1{1,2}2{1,1,2}2}2)
• dimensolbitetrexdex = s(3,3{1{1,1,2}1,2}2) = s(3,3{1{1,1,2}3}2), a.k.a. dimensolplexbitetrex.
• dimensolbitetrexdexplex = s(3,3{2{1,1,2}1,2}2)
• dimensolbitetrexplexdex = s(3,3{1{1,2}2{1,1,2}1,2}2)
• dimensoltetrexplextetrexdex = s(3,3{1{1,1,2}2,2}2)
• dimensolbitetrexbidex = s(3,3{1{1,1,2}1,1,2}2) = s(3,3{1{1,1,2}1,3}2), a.k.a. dimensolplexbitetrexdex.
• dimensoltetrexdextetrex = s(3,3{1{1,1,2}1{1,2}2}2)
• dimensoltetrexdextetrexplex = s(3,3{2{1,1,2}1{1,2}2}2)
• dimensoltetrexdexplextetrex = s(3,3{1{1,2}2{1,1,2}1{1,2}2}2)
• dimensoltetrexplexdextetrex = s(3,3{1{1,1,2}2{1,2}2}2)
• dimensoltetrexdextetrexdex = s(3,3{1{1,1,2}1{1,2}1,2}2) = s(3,3{1{1,1,2}1{1,2}3}2), a.k.a. dimensolplextetrexdextetrex.
• dimensoltetrexdextetrexbidex = s(3,3{1{1,1,2}1{1,2}1,1,2}2)
• dimensoltetrexbidextetrex = s(3,3{1{1,1,2}1{1,2}1{1,2}2}2)
• dimensoltetrexbidextetrexdex = s(3,3{1{1,1,2}1{1,2}1{1,2}1,2}2)
• dimensoltetrexbidextetrexbidex = s(3,3{1{1,1,2}1{1,2}1{1,2}1,1,2}2)
• dimensoldexbitetrex = s(3,3{1{1,1,2}1{1,1,2}2}2)
• dimensoldexbitetrexplex = s(3,3{2{1,1,2}1{1,1,2}2}2)
• dimensoldextetrexplextetrex = s(3,3{1{1,2}2{1,1,2}1{1,1,2}2}2)
• dimensoldexplexbitetrex = s(3,3{1{1,1,2}2{1,1,2}2}2)
• dimensoldexbitetrexdex = s(3,3{1{1,1,2}1{1,1,2}1,2}2) = s(3,3{1{1,1,2}1{1,1,2}3}2), a.k.a. dimensolplexdexbitetrex.
• dimensoldexbitetrexbidex = s(3,3{1{1,1,2}1{1,1,2}1,1,2}2)
• dimensoldextetrexdextetrex = s(3,3{1{1,1,2}1{1,1,2}1{1,2}2}2)
• dimensoldextetrexbidextetrex = s(3,3{1{1,1,2}1{1,1,2}1{1,2}1{1,2}2}2)
• dimensolbitetrexthrex = s(3,3{1{2,1,2}2}2) = s(3,3{1{1,1,2}1{1,1,2}1{1,1,2}2}2), a.k.a. dimensolbidexbitetrex.
• dimensolbitetrexthrexplex = s(3,3{2{2,1,2}2}2)
• dimensolbitetrexplexthrex = s(3,3{1{1,2}2{2,1,2}2}2)
• dimensoltetrexplextetrexthrex = s(3,3{1{1,1,2}2{2,1,2}2}2)
• dimensolbitetrexthrexdex = s(3,3{1{2,1,2}1,2}2) = s(3,3{1{2,1,2}3}2), a.k.a. dimensolplexbitetrexthrex.
• dimensolbitetrexthrexbidex = s(3,3{1{2,1,2}1,1,2}2)
• dimensolbitetrexdexthrex = s(3,3{1{2,1,2}1{1,2}2}2)
• dimensolbitetrexdexthrexdex = s(3,3{1{2,1,2}1{1,2}1,2}2)
• dimensolbitetrexdexthrexbidex = s(3,3{1{2,1,2}1{1,2}1,1,2}2)
• dimensolbitetrexbidexthrex = s(3,3{1{2,1,2}1{1,2}1{1,2}2}2)
• dimensoltetrexdextetrexthrex = s(3,3{1{2,1,2}1{1,1,2}2}2)
• dimensoltetrexdextetrexdexthrex = s(3,3{1{2,1,2}1{1,1,2}1{1,2}2}2)
• dimensoltetrexdextetrexbidexthrex = s(3,3{1{2,1,2}1{1,1,2}1{1,2}1{1,2}2}2)
• dimensoltetrexbidextetrexthrex = s(3,3{1{2,1,2}1{1,1,2}1{1,1,2}2}2)
• dimensoldexbitetrexthrex = s(3,3{1{2,1,2}1{2,1,2}2}2)
• dimensoldexbitetrexthrexdex = s(3,3{1{2,1,2}1{2,1,2}1,2}2)
• dimensoldexbitetrexdexthrex = s(3,3{1{2,1,2}1{2,1,2}1{1,2}2}2)
• dimensoldextetrexdextetrexthrex = s(3,3{1{2,1,2}1{2,1,2}1{1,1,2}2}2)
• dimensoltetrexthrextetrex = s(3,3{1{1,2,2}2}2) = s(3,3{1{3,1,2}2}2) = s(3,3{1{2,1,2}1{2,1,2}1{2,1,2}2}2), a.k.a. dimensolbitetrexbithrex and dimensolbidexbitetrexthrex.
• dimensoltetrexthrextetrexdex = s(3,3{1{1,2,2}1,2}2)
• dimensoltetrexthrexdextetrex = s(3,3{1{1,2,2}1{1,2}2}2)
• dimensoltetrexdexthrextetrex = s(3,3{1{1,2,2}1{1,1,2}2}2)
• dimensoldextetrexthrextetrex = s(3,3{1{1,2,2}1{1,2,2}2}2)
• dimensoltetrexthrextetrexthrex = s(3,3{1{2,2,2}2}2)
• dimensolpentex = s(3,3{1{1{2}2}2}2) = s(3,3{1{1,1,1,2}2}2) = s(3,3{1{1,1,3}2}2) = s(3,3{1{1,3,2}2}2) = s(3,3{1{3,2,2}2}2), a.k.a. dimensoltritetrex, dimensolthrexbitetrex, dimensoltetrexbithrextetrex and dimensoltetrexthrextetrexbithrex.
• dimensoltritetrexplex = s(3,3{2{1,1,1,2}2}2)
• dimensolbitetrexplextetrex = s(3,3{1{1,2}2{1,1,1,2}2}2)
• dimensoltetrexplexbitetrex = s(3,3{1{1,1,2}2{1,1,1,2}2}2)
• dimensoltritetrexdex = s(3,3{1{1,1,1,2}1,2}2) = s(3,3{1{1,1,1,2}3}2), a.k.a. dimensolplextritetrex.
• dimensolbitetrexdextetrex = s(3,3{1{1,1,1,2}1{1,2}2}2)
• dimensoltetrexdexbitetrex = s(3,3{1{1,1,1,2}1{1,1,2}2}2)
• dimensoldextritetrex = s(3,3{1{1,1,1,2}1{1,1,1,2}2}2)
• dimensoltritetrexthrex = s(3,3{1{2,1,1,2}2}2)
• dimensolbitetrexthrextetrex = s(3,3{1{1,2,1,2}2}2)
• dimensoltetrexthrexbitetrex = s(3,3{1{1,1,2,2}2}2)
• dimensolquadritetrex = s(3,3{1{1,1,1,1,2}2}2) = s(3,3{1{1,1,1,3}2}2), a.k.a. dimensolthrextritetrex.
• dimensolquadritetrexplex = s(3,3{2{1,1,1,1,2}2}2)
• dimensolquadritetrexdex = s(3,3{1{1,1,1,1,2}1,2}2) = s(3,3{1{1,1,1,1,2}3}2), a.k.a. dimensolplexquadritetrex.
• dimensoldexquadritetrex = s(3,3{1{1,1,1,1,2}1{1,1,1,1,2}2}2)
• dimensolquadritetrexthrex = s(3,3{1{2,1,1,1,2}2}2)
• dimensolquintitetrex = s(3,3{1{1,1,1,1,1,2}2}2) = s(3,3{1{1,1,1,1,3}2}2), a.k.a. dimensolthrexquadritetrex.

Using suffix “-pentex”, we have a naming space of .

• dimentrienpentex = s(3,3,3{1{1{2}2}2}2)
• dimentrilpentex = s(3,3{1{1{2}2}2}3)
• dimenbolpentex = s(3,3{1{1{2}2}2}1{1{1{2}2}2}2)
• dimensolpentexplex = s(3,3{2{1{2}2}2}2)
• dimensolpentexdex = s(3,3{1{1{2}2}1,2}2) = s(3,3{1{1{2}2}3}2), a.k.a. dimensolplexpentex.
• dimensoldexpentex = s(3,3{1{1{2}2}1{1{2}2}2}2)
• dimensolpentexthrex = s(3,3{1{2{2}2}2}2)
• dimensolpentextetrex = s(3,3{1{1{2}1,2}2}2) = s(3,3{1{1{2}3}2}2), a.k.a. dimensolthrexpentex.
• dimensoltetrexpentex = s(3,3{1{1{2}1{2}2}2}2)
• dimensolhex = s(3,3{1{1{1,2}2}2}2) = s(3,3{1{1{3}2}2}2), a.k.a. dimensolbipentex.
• dimensolbipentexplex = s(3,3{2{1{3}2}2}2)
• dimensolbipentexdex = s(3,3{1{1{3}2}1,2}2) = s(3,3{1{1{3}2}3}2), a.k.a. dimensolplexbipentex.
• dimensoldexbipentex = s(3,3{1{1{3}2}1{1{3}2}2}2)
• dimensolbipentexthrex = s(3,3{1{2{3}2}2}2)
• dimensolbipentextetrex = s(3,3{1{1{3}1,2}2}2) = s(3,3{1{1{3}3}2}2), a.k.a. dimensolthrexbipentex.
• dimensoltetrexbipentex = s(3,3{1{1{3}1{3}2}2}2)
• dimensoltripentex = s(3,3{1{1{4}2}2}2)
• dimensolquadripentex = s(3,3{1{1{5}2}2}2)
• dimensolquintipentex = s(3,3{1{1{6}2}2}2)

Using suffix “-hex”, we have a naming space of .

• dimentrienhex = s(3,3,3{1{1{1,2}2}2}2)
• dimentrilhex = s(3,3{1{1{1,2}2}2}3)
• dimenbolhex = s(3,3{1{1{1,2}2}2}1{1{1{1,2}2}2}2)
• dimensolhexplex = s(3,3{2{1{1,2}2}2}2)
• dimensolhexdex = s(3,3{1{1{1,2}2}1,2}2) = s(3,3{1{1{1,2}2}3}2), a.k.a. dimensolplexhex.
• dimensoldexhex = s(3,3{1{1{1,2}2}1{1{1,2}2}2}2)
• dimensolhexthrex = s(3,3{1{2{1,2}2}2}2)
• dimensolhextetrex = s(3,3{1{1{1,2}1,2}2}2) = s(3,3{1{1{1,2}3}2}2), a.k.a. dimensolthrexhex.
• dimensoltetrexhex = s(3,3{1{1{1,2}1{1,2}2}2}2)
• dimensolhexpentex = s(3,3{1{1{2,2}2}2}2)
• dimensolbihex = s(3,3{1{1{1,1,2}2}2}2) = s(3,3{1{1{1,3}2}2}2), a.k.a. dimensolpentexhex.
• dimensolheptex = s(3,3{1{1{1{2}2}2}2}2) = s(3,3{1{1{1,1,1,2}2}2}2), a.k.a. dimensoltrihex.
• dimensolquadrihex = s(3,3{1{1{1,1,1,1,2}2}2}2)
• dimensolquintihex = s(3,3{1{1{1,1,1,1,1,2}2}2}2)

And further…

• dimentrienheptex = s(3,3,3{1{1{1{2}2}2}2}2)
• dimentrilheptex = s(3,3{1{1{1{2}2}2}2}3)
• dimenbolheptex = s(3,3{1{1{1{2}2}2}2}1{1{1{1{2}2}2}2}2)
• dimensoloctex = s(3,3{1{1{1{1,2}2}2}2}2) = s(3,3{1{1{1{3}2}2}2}2), a.k.a. dimensolbiheptex.
• dimensolbioctex = s(3,3{1{1{1{1,1,2}2}2}2}2)
• dimensolennex = s(3,3{1{1{1{1{2}2}2}2}2}2) = s(3,3{1{1{1{1,1,1,2}2}2}2}2), a.k.a. dimensoltrioctex.
• dimensoldecex = s(3,3{1{1{1{1{1,2}2}2}2}2}2) = s(3,3{1{1{1{1{3}2}2}2}2}2), a.k.a. dimensolbiennex.

So an “n-ex” means  (where the α is at the n-th level of the power tower), where β is defined by the result of adding k suffixes in previous steps, where k is the position of the suffix we focus from the end of the name. Extending the suffixes to “n-ex” for any n, we have a naming space of , which is certainly not enough for every separator recursion level in exAN. But we can add modifiers “n-ex-r” (where r is in Roman numerals), then we have a naming space of  – that’s enough for every separator recursion level in exAN.

What’s more, ε₀ is the first ordinal that separator recursion level catches up with growth rate (in FGH scale). If we build a “junior” naming system, where the only difference from the normal one is that the “n-ex” rule is for growth rate instead of separator recursion level, then the “n-ex” is analogous to the “(n+2)-ex” in the “junior” naming system. e.g.

dimensolennex jr. = s(3,3{1{1{1{2}2}2}2}2) = dimensolheptex

So we can name every growth rate if we use the “junior” naming system. But here I don’t use that because I don’t want to left “-plex” and “-dex” below separators (which happens in the “junior” naming system), and separators are important in parts beyond exAN.