# Greetings from The On-Line Encyclopedia of Integer Sequences! http://oeis.org/ Search: id:a362804 Showing 1-1 of 1 %I A362804 #9 May 04 2023 14:57:57 %S A362804 1,2,4,6,8,12,16,24,28,30,32,45,48,56,60,64,90,96,112,120,128,180,192, %T A362804 224,240,256,360,384,448,480,496,512,720,768,896,960,992,1024,1440, %U A362804 1536,1792,1920,1984,2048,2880,3072,3584,3840,3968,4096,5760,6144,7168,7680 %N A362804 Numbers k such that the set of divisors {d | k, BitOr(k, d) = k} has an integer harmonic mean. %C A362804 Equivalently, the set of divisors can be defined by {d | k, BitAnd(k, d) = d}. %C A362804 Analogous to harmonic (or Ore) numbers (A001599) where the divisors d of k are restricted by BitOr(k, d) = k or BitAnd(k, d) = d. %C A362804 If k is a term then so is 2*k. The primitive terms are in A362805. Thus, this sequence includes all the powers of 2 (A000079), all the numbers of the form 3*2^m and 15*2^m for m >= 1, and all the numbers of the form 7*2^m for m >= 2. %C A362804 All the even perfect numbers (A000396) are terms: if k = 2^(p-1)*(2^p-1) is a perfect number (where p is a Mersenne exponent, A000043), then the only divisors of k such that BitOr(k, d) = k are 2^(p-1) and k itself, and the harmonic mean of 2^(p-1) and 2^(p-1)*(2^p-1) is 2^p - 1. %C A362804 Are 1 and 45 the only odd terms in this sequence? %H A362804 Amiram Eldar, Table of n, a(n) for n = 1..406 %t A362804 q[n_] := IntegerQ[HarmonicMean[Select[Divisors[n], BitAnd[n, #] == # &]]]; Select[Range[10^4], q] %o A362804 (PARI) div(n) = select(x->(bitor(x, n) == n), divisors(n)); %o A362804 is(n) = {my(d = div(n)); denominator(#d/sum(i = 1, #d, 1/d[i])) == 1;} %Y A362804 Cf. A000043, A000396, A246600, A246601. %Y A362804 Subsequences: A000079, A007283 \ {3}, A005009 \ {7, 14}, A110286 \ {15}, A362805. %Y A362804 Similar sequences: A001599, A006086, A063947, A286325, A319745. %K A362804 nonn,base %O A362804 1,2 %A A362804 _Amiram Eldar_, May 04 2023 # Content is available under The OEIS End-User License Agreement: http://oeis.org/LICENSE