142857

From HandWiki
Short description: Sequence of six digits
Short description: Natural number
← 142856 142857 142858 →
Cardinalone hundred forty-two thousand eight hundred fifty-seven
Ordinal142857th
(one hundred forty-two thousand eight hundred fifty-seventh)
Factorization33 × 11 × 13 × 37
Divisors1, 3, 9, 11, 13, 27, 33, 37, 39, 99, 111, 117, 143, 297, 333, 351, 407, 429, 481, 999, 1221, 1287, 1443, 3663, 3861, 4329, 5291, 10989, 12987, 15873, 47619, 142857
Greek numeral[math]\displaystyle{ \stackrel{\iota\delta}{\Mu} }[/math]͵βωνζ´
Roman numeralCXLMMDCCCLVII
Binary1000101110000010012
Ternary210202220003
Quaternary2023200214
Quinary140324125
Senary30212136
Octal4270118
Duodecimal6A80912
Hexadecimal22E0916
VigesimalHH2H20
Base 36328936

The number 142,857 is a Kaprekar number.[1]

142857, the six repeating digits of 1/7 (0.142857), is the best-known cyclic number in base 10.[2][3][4][5] If it is multiplied by 2, 3, 4, 5, or 6, the answer will be a cyclic permutation of itself, and will correspond to the repeating digits of 2/7, 3/7, 4/7, 5/7, or 6/7 respectively.

Calculation

1 × 142,857 = 142,857
2 × 142,857 = 285,714
3 × 142,857 = 428,571
4 × 142,857 = 571,428
5 × 142,857 = 714,285
6 × 142,857 = 857,142
7 × 142,857 = 999,999

If multiplying by an integer greater than 7, there is a simple process to get to a cyclic permutation of 142857. By adding the rightmost six digits (ones through hundred thousands) to the remaining digits and repeating this process until only six digits are left, it will result in a cyclic permutation of 142857:[citation needed]

142857 × 8 = 1142856
1 + 142856 = 142857
142857 × 815 = 116428455
116 + 428455 = 428571
1428572 = 142857 × 142857 = 20408122449
20408 + 122449 = 142857

Multiplying by a multiple of 7 will result in 999999 through this process:

142857 × 74 = 342999657
342 + 999657 = 999999

If you square the last three digits and subtract the square of the first three digits, you also get back a cyclic permutation of the number.[citation needed]

8572 = 734449
1422 = 20164
734449 − 20164 = 714285

It is the repeating part in the decimal expansion of the rational number 1/7 = 0.142857. Thus, multiples of 1/7 are simply repeated copies of the corresponding multiples of 142857:

[math]\displaystyle{ \begin{align} \tfrac17 & = 0.\overline{142857}\ldots \\[3pt] \tfrac27 & = 0.\overline{285714}\ldots \\[3pt] \tfrac37 & = 0.\overline{428571}\ldots \\[3pt] \tfrac47 & = 0.\overline{571428}\ldots \\[3pt] \tfrac57 & = 0.\overline{714285}\ldots \\[3pt] \tfrac67 & = 0.\overline{857142}\ldots \\[3pt] \tfrac77 & = 0.\overline{999999}\ldots = 1 \\[3pt] \tfrac87 & = 1.\overline{142857}\ldots \\[3pt] \tfrac97 & = 1.\overline{285714}\ldots \\ & \,\,\,\vdots \end{align} }[/math]

Connection to the enneagram

The 142857 number sequence is used in the enneagram figure, a symbol of the Gurdjieff Work used to explain and visualize the dynamics of the interaction between the two great laws of the Universe (according to G. I. Gurdjieff), the Law of Three and the Law of Seven. The movement of the numbers of 142857 divided by 1/7, 2/7. etc., and the subsequent movement of the enneagram, are portrayed in Gurdjieff's sacred dances known as the movements.[6]

Other properties

The 142857 number sequence is also found in several decimals in which the denominator has a factor of 7. In the examples below, the numerators are all 1, however there are instances where it does not have to be, such as 2/7 (0.285714).

For example, consider the fractions and equivalent decimal values listed below:

1/7 = 0.142857...
1/14 = 0.0714285...
1/28 = 0.03571428...
1/35 = 0.0285714...
1/56 = 0.017857142...
1/70 = 0.0142857...

The above decimals follow the 142857 rotational sequence. There are fractions in which the denominator has a factor of 7, such as 1/21 and 1/42, that do not follow this sequence and have other values in their decimal digits.

References

  1. "Sloane's A006886: Kaprekar numbers". OEIS Foundation. https://oeis.org/A006886. 
  2. "Cyclic number". http://www.daviddarling.info/encyclopedia/C/cyclic_number.html. 
  3. Ecker, Michael W. (March 1983). "The Alluring Lore of Cyclic Numbers". The Two-Year College Mathematics Journal 14 (2): 105–109. doi:10.2307/3026586. 
  4. "Cyclic number". http://planetmath.org/encyclopedia/CyclicNumber.html. 
  5. Hogan, Kathryn (August 2005). "Go figure (cyclic numbers)". http://findarticles.com/p/articles/mi_hb4870/is_200508/ai_n17913296. 
  6. Ouspensky, P. D. (1947). "Chapter XVIII". In Search of the Miraculous: Fragments of an Unknown Teaching. London: Routledge.