The Overlord of the Über-Feral says: Welcome to my bijou bloguette. You can scroll down to sample more or simply:
• Read a Writerization at Random: RaWaR
• ¿And What Doth It Mean To Be Flesh?
Gweel & Other Alterities – Incunabula’s new edition
Tales of Silence & Sortilege – Incunabula’s new edition
If you’d like to donate to O.o.t.Ü.-F., please click here.
I identify as √-37 (the square root of -37) in bases 5 (on Mondays and Wednesdays), 17 (Tuesdays, Thursdays and alternate Saturdays) and 89 (Fridays, Sundays and alternate Saturdays).
My preferred pronouns are 6.08276i, 雲 and მსოფლიოს მეფე.
Satanas
To Jorge Santayana
ECCE! Princeps infernorum,
Rex veneficus amorum
Vilium et mortiferorum,
Ecce! regnat Lucifer:
Animis qui dominatur,
Quibus coelum spoliatur;
Qui malignus bona fatur,
Cor corrumpens suaviter.
Fructus profert; inest cinis:
Profert flores plenos spinis:
Vitae eius mors est finis:
Crux est eius requies.
Qualis illic apparebit
Cruciatus, et manebit!
Quantas ista quot habebit
Mors amaritudines!
Iuventutis quam formosa
Floret inter rosas rosa!
Venit autem vitiosa
Species infamiae:
Veniunt crudeles visus,
Voces simulati risus;
Et inutilis fit nisus
Flebilis laetitae.
Quanto vitium splendescit,
Tanto anima nigrescit;
Tanto tandem cor marcescit,
Per peccata dulcia.
Gaudens mundi Princeps mali
Utitur veneno tali,
Voluptate Avernali;
0 mellita vitia!
Gaudet Princeps huius mundi
Videns animam confundi;
Cordis amat moribundi
Aspectare proelium.
Vana tentat, vana quaerens,
Cor anhelum, frustra moerens;
Angit animae inhaerens
Flamma cor miserrimum.
Gaudet Rector tenebrarum
Immolare cor amarum;
Satiare furiarum
Rex sorores avidas.
Vae! non stabit in aeternum
Regnum, ait Rex, infernum:
Sed, dum veniat Supernum,
Dabo vobis victimas.
• Lionel Johnson (1867-1902), text courtesy Laudator Temporis Acti
Today’s a Phiday Friday or Φiday Friday or Φriday, so let’s have some more Fibonacci Fun. Here is the famous Fibonacci sequence, where each number (after seeding with “0, 1”) is formed by adding the previous two numbers:
0, 1, 1, 2, 3, 5, 8, 13, 21, 34, 55, 89, 144, 233, 377, 610, 987, 1597, 2584, 4181, 6765, 10946, 17711, 28657, 46368, 75025, 121393, 196418, 317811, 514229, 832040, 1346269, 2178309, 3524578, 5702887, 9227465, 14930352, 24157817, 39088169, 63245986, 102334155, … — A000045 at the Online Encyclopedia of Integer Sequences (OEIS)
It’s obvious that the numbers get bigger for ever and that no number repeats except 1. But what happens to the final digit of the Fibonacci numbers, as underlined here?:
0, 1, 1, 2, 3, 5, 8, 13, 21, 34, 55, 89, 144, 233, 377, 610, 987, 1597, 2584, 4181, 6765, 10946, 17711, 28657, 46368, 75025, 121393, 196418, 317811, 514229, 832040, …
If you think about it, you’ll realize that the final digit has to repeat. Look for the “0, 1, 1” re-appearing:
0, 1, 1, 2, 3, 5, 8, 3, 1, 4, 5, 9, 4, 3, 7, 0, 7, 7, 4, 1, 5, 6, 1, 7, 8, 5, 3, 8, 1, 9, 0, 9, 9, 8, 7, 5, 2, 7, 9, 6, 5, 1, 6, 7, 3, 0, 3, 3, 6, 9, 5, 4, 9, 3, 2, 5, 7, 2, 9, 1, 0, 1, 1, 2, 3, 5, 8, 3, 1, 4, 5, 9, 4, 3, 7, 0, 7, 7, 4, 1, 5, 6, 1, 7, 8, 5, 3, 8, 1, 9, 0, 9, 9, 8, 7, 5, 2, 7, 9, 6, 5, … — A003893 at the OEIS, “a(n) = Fibonacci(n) mod 10”
As you’ll see, all the numbers 0 to 9 appear in that sequence. But what about the final two digits of the Fibonacci sequence? Do all the numbers 0 to 99 appear before the sequence repeats?
0, 1, 1, 2, 3, 5, 8, 13, 21, 34, 55, 89, 44, 33, 77, 10, 87, 97, 84, 81, 65, 46, 11, 57, 68, 25, 93, 18, 11, 29, 40, 69, 9, 78, 87, 65, 52, 17, 69, 86, 55, 41, 96, 37, 33, 70, 3, 73, 76, 49, 25, 74, 99, 73, 72, 45, 17, 62, 79, 41, 20, 61, 81, 42, 23, 65, 88, 53, 41, 94, 35, 29, 64, … — A105471 at the OEIS, “a(n) = Fibonacci(n) mod 100”
And what about the the final three digits and the numbers 0 to 999?
0, 1, 1, 2, 3, 5, 8, 13, 21, 34, 55, 89, 144, 233, 377, 610, 987, 597, 584, 181, 765, 946, 711, 657, 368, 25, 393, 418, 811, 229, 40, 269, 309, 578, 887, 465, 352, 817, 169, 986, 155, 141, 296, 437, 733, 170, 903, 73, 976, 49, 25, 74, 99, 173, 272 … — A248740 at the OEIS, “a(n) = Fibonacci(n) mod 1000”
In fact, some numbers do go missing as the final block of digits gets longer. But all that is based on the representation of the Fibonacci numbers in base 10. What about other bases? I had a look at that question and came up with some interesting patterns when I represented the final-block numbers on an Ulam-like spiral, where numbers are represented as squares on a spiral rotating counter-clockwise. This is the spiral for powers of 2 (the red square marks the center of the spiral and the number 1):
Spiral of final Fib-digits modulo 2^p
Fib-spiral mod 2^p (smaller scale)
Fib-spiral mod 2^p (smaller scale still)
What fraction of numbers are missing from the spiral? Watch this space. In the meantime, here’s the Fib-spiral for powers of 3:
Fib-spiral mod 3^p
It’s completely filled, because no numbers are missing (the red square marks “1” at the center of the spiral). What about powers of 4? Well, we’ve already seen that Fib-spiral, because all powers of 4 are also powers of 2:
Fib-spiral mod 4^p
The Fib-spiral for powers of 5 is the same as the Fib-spiral for powers of 3: it’s completely filled again. But the Fib-spiral for powers of 6 is interesting:
Fib-spiral mod 6^p
Fib-spiral mod 6^p (smaller scale)
Fib-spiral mod 6^p (smaller scale still)
And here are more Fib-spirals and more interesting patterns:
Fib-spiral mod 7^p
Fib-spiral mod 10^p — identical to the Fib-spiral for 2^p
Fib-spiral mod 11^p
Fib-spiral mod 11^p (smaller scale)
Fib-spiral mod 13^p
Fib-spiral mod 13^p (smaller scale)
Fib-spiral mod 17^p
Fib-spiral mod 17^p (smaller scale)
Fib-spiral mod 19^p
Fib-spiral mod 19^p (smaller scale)
Fib-spiral mod 41^p
Fib-spiral mod 41^p (smaller scale)
Fib-spiral mod 47^p
Elsewhere Other-Accessible…
• Friday is Φday — a first look at Phiday on Friday
A fractal dodecahedron by Jos Leys, a Belgian mathemartist (source here)
I was looking at numbers where the digit-runs of n in one base, b1, represented the digits of n in another base, b2. To understand digit-runs, take the number 775555111 (in whatever base). The function digitrun(775555111) = 2,4,3, because reading 775555111 left-to-right you see two 7s, four 5s, three 1s. Here’s one pattern I found:
10000011111 in base 2 = 1055 in base 10. The digit runs of 10000011111 are 1,5,5 and 15530 = 105510 = 100000111112.
10000022222 in base 3 = 59291 in base 10. The digit runs of 10000022222 are again 1,5,5 and 155241 = 5929110 = 100000222223.
1000009999910 → 1,5,5 and 15599998 = 1000009999910
The pattern isn’t difficult to understand — what are 30+2 and 99998+2? — and it’s easy to prove that it applies to all standard bases. But I wondered how AI would go about the proof. Here’s the result:
For base b ≥ 2, let the largest digit be d = b − 1. Then
100000dddddb
has digit runs
1, 5, 5
so the run-length encoding is always
155.
The value of 155 is interpreted in base
b5 − 2,
because
155b5−2 = (b5−2)2 + 5(b5−2) + 5.
Thus
100000dddddb = 155b5−2.
| Base b | n = 100000(b−1)(b−1)(b−1)(b−1)(b−1)b | Run Lengths | Compressed Form | Base-10 Value of n |
|---|---|---|---|---|
| 2 | 100000111112 | 1,5,5 | 15530 | 1,055 |
| 3 | 100000222223 | 1,5,5 | 155241 | 59,291 |
| 4 | 100000333334 | 1,5,5 | 1551022 | 1,049,599 |
| 5 | 100000444445 | 1,5,5 | 1553123 | 9,765,624 |
| 6 | 100000555556 | 1,5,5 | 1557774 | 60,466,175 |
| 7 | 100000666667 | 1,5,5 | 15516805 | 282,475,248 |
| 8 | 100000777778 | 1,5,5 | 15532766 | 1,074,266,111 |
| 9 | 100000888889 | 1,5,5 | 15559047 | 3,486,270,320 |
| 10 | 1000009999910 | 1,5,5 | 15599998 | 10,000,099,999 |
| 11 | 100000AAAAA11 | 1,5,5 | 155161049 | 26,094,908,050 |
| 12 | 100000BBBBB12 | 1,5,5 | 155248830 | 62,191,972,031 |
| 13 | 100000CCCCC13 | 1,5,5 | 155371291 | 136,858,491,292 |
| 14 | 100000DDDDD14 | 1,5,5 | 155537822 | 281,793,968,543 |
| 15 | 100000EEEEE15 | 1,5,5 | 155759373 | 547,918,611,874 |
| 16 | 100000FFFFF16 | 1,5,5 | 1551048574 | 1,099,512,627,199 |
| 17 | 100000GGGGG17 | 1,5,5 | 1551419855 | 2,141,423,647,200 |
| 18 | 100000HHHHH18 | 1,5,5 | 1551889566 | 4,058,363,974,751 |
| 19 | 100000IIIII19 | 1,5,5 | 1552476097 | 7,502,570,010,432 |
| 20 | 100000JJJJJ20 | 1,5,5 | 1553199998 | 13,120,000,000,000 |
(Here A = 10, B = 11, …, J = 19.)
Proof for All b ≥ 2
The number
100000(b−1)(b−1)(b−1)(b−1)(b−1)b
has value
b10 + (b−1)(b4 + b3 + b2 + b + 1).
Since
b4 + b3 + b2 + b + 1 = (b5 − 1)/(b − 1),
this becomes
b10 + (b5 − 1) = b10 + b5 − 1.
Now let
B = b5 − 2.
Then
155B = B2 + 5B + 5.
Substituting B = b5 − 2:
(B2 + 5B + 5) = (b5−2)2 + 5(b5−2) + 5
= b10−4b5+4+5b5−10+5
= b10 + b5−1.
Hence
b10 + b5 − 1 = (b5 − 2)2+5(b5 − 2)+5
for every b ≥ 2.
Therefore,
100000(b−1)5b = 155b5−2.
This is exactly the pattern observed in bases 2 to 20, and it holds for all bases.
The hover-hum
Of woodland flies,
Then buttercups
That gild the eyes.
A storied tree
Engorging light
And pimpernels
That blood the sight.
Light-winging nymphs
On nectar’d flower:
Magistra ’tis
In Maythic power.
Simple but seductive. That’s how I’d describe partitions. Except that they’re not so simple. There are hidden depths in the task of finding how many ways an integer can be expressed as the sum of smaller integers (and as the sum of itself). Here are the partitions of 4, for example:
4 = 1+3 = 2+2 = 1+1+2 = 1+1+1+1
4 (1) = 1+3 (2) = 2+2 (3) = 1+1+2 (4) = 1+1+1+1 (5), ∴ partcount(4) = 5
There are five partitions of 4, because an integer is counted as its own partition. Accordingly, partcount(4) = 5. But partcount(n) doesn’t return values in a predictable way:
partcount(1) = 1 ← 1
partcount(2) = 2 ← 2 = 1+1
partcount(3) = 3 ← 3 = 1+2 = 1+1+1
partcount(4) = 5 ← 4 = 1+3 = 2+2 = 1+1+2 = 1+1+1+1
partcount(5) = 7 ← 5 = 1+4 = 2+3 = 1+1+3 = 1+2+2 = 1+1+1+2 = 1+1+1+1+1
partcount(6) = 11 ← 6 = 1+5 = 2+4 = 3+3 = 1+1+4 = 1+2+3 = 2+2+2 = 1+1+1+3 = 1+1+2+2 = 1+1+1+1+2 = 1+1+1+1+1+1
partcount(7) = 15 ← 7 = 1+6 = 2+5 = 3+4 = 1+1+5 = 1+2+4 = 1+3+3 = 2+2+3 = 1+1+1+4 = 1+1+2+3 = 1+2+2+2 = 1+1+1+1+3 = 1+1+1+2+2 = 1+1+1+1+1+2 = 1+1+1+1+1+1+1
partcount(8) = 22 ← 8 = 1+7 = 2+6 = 3+5 = 4+4 = 1+1+6 = 1+2+5 = 1+3+4 = 2+2+4 = 2+3+3 = 1+1+1+5 = 1+1+2+4 = 1+1+3+3 = 1+2+2+3 = 2+2+2+2 = 1+1+1+1+4 = 1+1+1+2+3 = 1+1+2+2+2 = 1+1+1+1+1+3 = 1+1+1+1+2+2 = 1+1+1+1+1+1+2 = 1+1+1+1+1+1+1+1
1, 2, 3, 5, 7, 11, 15, 22, 30, 42, 56, 77, 101, 135, 176, 231, 297, 385, 490, 627, 792, 1002, 1255, 1575, 1958, 2436, 3010, 3718, 4565, 5604, 6842, 8349, 10143, 12310, 14883, 17977, 21637, 26015, 31185, 37338, 44583, 53174, 63261, 75175, 89134, 105558, 124754, 147273, 173525 — the number of partitions of n, A000041 at the Online Encyclopedia of Integer Sequences
And there are fractals — self-similarities at smaller and smaller scales — hidden in that simple arithmetic. Take the partitions of 8:
8 = 1+7 = 2+6 = 3+5 = 4+4 = 1+1+6 = 1+2+5 = 1+3+4 = 2+2+4 = 2+3+3 = 1+1+1+5 = 1+1+2+4 = 1+1+3+3 = 1+2+2+3 = 2+2+2+2 = 1+1+1+1+4 = 1+1+1+2+3 = 1+1+2+2+2 = 1+1+1+1+1+3 = 1+1+1+1+2+2 = 1+1+1+1+1+1+2 = 1+1+1+1+1+1+1+1 (c=22)
By definition, the sum of each partition of 8 is the same: 8. But the products — the result of multiplying the numbers of a partition — rise and fall wildly, hitting a maximum of 18 and a minimum of 1:
1.7 = 7
2.6 = 12
3.5 = 15
4.4 = 16
1.1.6 = 6
1.2.5 = 10
1.3.4 = 12
2.2.4 = 16
2.3.3 = 18
1.1.1.5 = 5
1.1.2.4 = 8
1.1.3.3 = 9
1.2.2.3 = 12
2.2.2.2 = 16
1.1.1.1.4 = 4
1.1.1.2.3 = 6
1.1.2.2.2 = 8
1.1.1.1.1.3 = 3
1.1.1.1.2.2 = 4
1.1.1.1.1.1.2 = 2
1.1.1.1.1.1.1.1 = 1
It’s interesting to ask when partitions(n) yield the biggest product (the answer is here). It’s also interesting to create graphs of prod(part(n)), the products of the partitions of n. You’ll see something I call partition fission. The graphs start to fissure into what look like fins or sails, and then each fin or sail starts to fissure too:
Graph for multiples of partitions(8) (partcount(8) = 22)
Graph for prod(part(9)) (partcount = 30)
prod(part(10)) (partcount = 42)
prod(part(11)) (partcount = 56)
prod(part(12)) (partcount = 77)
prod(part(13)) (partcount = 101)
prod(part(14)) (partcount = 135)
prod(part(15)) (partcount = 176)
prod(part(16)) (partcount = 231)
Those graphs are all on the same scale. The two graphs below have been adjusted to capture many more partitions and show the fractality coming into full flower:
prod(part(20)) (partcount = 627)
prod(part(28)) (partcount = 3718)
Finally, here’s an animated gif of the graphs for the partition-products of 8 to 16:
Animated gif for prod(part(8..16)) (animation at EZgif) (click for larger image)
• ὁ Ἡράκλειτός φησι τοῖς ἐγρηγορόσιν ἕνα καὶ κοινὸν κόσμον εἶναι τῶν δὲ κοιμωμένων ἕκαστον εἰς ἴδιον ἀποστρέφεσθαι. — Σέξτος Ἐμπειρικός, Πρὸς μαθηματικούς
• • Heraclitus said that for the waking is one common world, but the sleeping turn aside each into a world of his own. — Sextus Empiricus, fl. 150 A.D., Adversus Mathematicos / Against the Mathematicians (or: Against the Professors), VII. 129
Post-Performative Post-Scriptum
Κοινόκοσμος, Koinokosmos, “common-world”, “shared cosmos” ← κοινός, koinós, “common”, “shared” + κόσμος, kosmos, “world”, “order”, “universe”; καὶ, kai, “and”; Κωματόκοσμοι, Kōmatokosmoi, “sleep-worlds” ← Greek κῶμα, kôma, “deep sleep” + κόσμος, kosmos
M.C. Escher, Another World / Andere Wereld (1947)
This is almost my favorite image by Escher. But I’d like a frEscher perspective in it: I think the bird should be looking in the other direction, out into the impossibly overlapping universes, not into the cupola and at the viewer.
• Μεστὰ δὲ πάντα σημείων καὶ σοφός τις ὁ μαθὼν ἐξ ἄλλου ἄλλο. — Πλωτῖνος, Ἐννεάδες Βʹ.γʹ.ζʹ
• • “All teems with symbol; the wise man is he who in any one thing can learn of another.” — Plotinus, Ennead II. 3. 7
Orange-tip butterfly ♂, Anthocharis cardamines
lepidoptera, n. a large order of insects comprising the butterflies and moths. ← Greek λεπιδο-, “scale” + πτερόν, “wing” — Oxford English Dictionary
Overlord In Terms of Core Issues Around Maximal Engagement with Key Notions of the Über-Feral 