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 A118642 #17 Aug 08 2025 17:17:10 %S A118642 16,27,32,48,54,64,72,80,81,96,100,108,112,125,128,135,144,147,160, %T A118642 162,176,189,192,200,208,216,224,240,243,250,256,260,270,272,273,288, %U A118642 294,297,300,304,320,324,336,340,343,351,352,360,368,375,378,384,399,400,405 %N A118642 Two finite groups are conformal if they have the same number of elements of each order. A natural number n is said to be a conformal order if there exist two conformal groups of order n which are not isomorphic to each other. The sequence lists the conformal orders. %C A118642 Since a(1)= 16 and p^3 is in the sequence for any odd prime p, by taking direct products with cyclic groups we see that n belongs to the sequence if either 16 or p^3 divides n for an odd prime p. However, 72 and 147, which are not of this form, both belong to the sequence. Also, every multiple of each term in the sequence is also a term of the sequence. Conformality of groups is an equivalence relation but there seem to be virtually no known conformality invariants other than group order. %D A118642 F. J. Budden, The Fascination of Groups, Cambridge University Press, 1969. %H A118642 James McCarron, <a href="/A118642/b118642.txt">Table of n, a(n) for n = 1..312</a> %e A118642 a(2)= 27 because there exist two non-isomorphic groups of order 27 each of which has one element of order one and twenty-six elements of order three. %K A118642 hard,nonn %O A118642 1,1 %A A118642 _Des MacHale_ and _Bob Heffernan_, May 10 2006