This is a front-end for the Online Encyclopedia of Integer Sequences, made by Christian Perfect. The idea is to provide OEIS entries in non-ancient HTML, and then to think about how they're presented visually. The source code is on GitHub.
%I A006064 M5367 #85 Jun 05 2025 13:44:04 %S A006064 0,101,10000000000001,1000000000000000000000102 %N A006064 Smallest junction number with n generators. %C A006064 Strictly speaking, a junction number is a number n with more than one solution to x+digitsum(x) = n. However, it seems best to start this sequence with n=0, for which there is just one solution, x=0. - _N. J. A. Sloane_, Oct 31 2013. %C A006064 a(3) = 10^13 + 1 was found by Narasinga Rao, who reports that Kaprekar verified that it is the smallest term. No details of Kaprekar's proof were given. %C A006064 a(4) = 10^24 + 102 was conjectured by Narasinga Rao. %C A006064 a(5) = 10^1111111111124 + 102. - Conjectured by Narasinga Rao, confirmed by _Max Alekseyev_ and _N. J. A. Sloane_. %C A006064 a(6) = 10^2222222222224 + 10000000000002. - _Max Alekseyev_ %C A006064 a(7) = 10^( (10^24 + 10^13 + 115) / 9 ) + 10^13 + 2. - _Max Alekseyev_ %C A006064 a(8) = 10^( (2*10^24 + 214)/9 ) + 10^24 + 103. - _Max Alekseyev_ %D A006064 M. Gardner, Time Travel and Other Mathematical Bewilderments. Freeman, NY, 1988, p. 116. %D A006064 D. R. Kaprekar, The Mathematics of the New Self Numbers, Privately printed, 311 Devlali Camp, Devlali, India, 1963. %D A006064 Narasinga Rao, A. On a technique for obtaining numbers with a multiplicity of generators. Math. Student 34 1966 79--84 (1967). MR0229573 (37 #5147) %D A006064 N. J. A. Sloane and Simon Plouffe, The Encyclopedia of Integer Sequences, Academic Press, 1995 (includes this sequence). %H A006064 Max Alekseyev, <a href="/A006064/a006064.txt">Table of expressions for a(n), for n=1..100</a> %H A006064 Max A. Alekseyev and N. J. A. Sloane, <a href="https://arxiv.org/abs/2112.14365">On Kaprekar's Junction Numbers</a>, arXiv:2112.14365, 2021; Journal of Combinatorics and Number Theory 12:3 (2022), 115-155. %H A006064 Shyam Sunder Gupta, <a href="https://doi.org/10.1007/978-981-97-2465-9_9">On Some Marvellous Numbers of Kaprekar</a>, Exploring the Beauty of Fascinating Numbers, Springer (2025) Ch. 9, 275-315. %H A006064 D. R. Kaprekar, <a href="/A003052/a003052_2.pdf">The Mathematics of the New Self Numbers</a> [annotated and scanned] %H A006064 N. J. A. Sloane, <a href="https://arxiv.org/abs/2301.03149">"A Handbook of Integer Sequences" Fifty Years Later</a>, arXiv:2301.03149 [math.NT], 2023, p. 21. %H A006064 Terry Trotter, <a href="http://trottermath.net/charlene-numbers/">Charlene numbers</a> %H A006064 <a href="/index/Coi#Colombian">Index entries for Colombian or self numbers and related sequences</a> %F A006064 a(n) = the smallest m such that there are exactly n solutions to A062028(x)=m. %e A006064 a(2) = 101 since 101 is the smallest number with two generators: 101 = A062028(91) = A062028(100). %e A006064 a(4) = 10^24 + 102 = 1000000000000000000000102 has exactly four inverses w.r.t. A062028, namely 999999999999999999999893, 999999999999999999999902, 1000000000000000000000091 and 1000000000000000000000100. %Y A006064 Cf. A003052, A230093, A230100, A230303, A230857 (highest power of 10). %Y A006064 Smallest number m such that u + (sum of base-b digits of u) = m has exactly n solutions, for bases 2 through 10: A230303, A230640, A230638, A230867, A238840, A238841, A238842, A238843, A006064. %K A006064 nonn,base %O A006064 1,2 %A A006064 _N. J. A. Sloane_ %E A006064 Edited, a(5)-a(6) added by _Max Alekseyev_, Jun 01 2011 %E A006064 a(1) added, a(5) corrected, a(7)-a(8) added by _Max Alekseyev_, Oct 26 2013