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 A321087 #7 Oct 27 2018 11:14:41
%S A321087 1,2,7,37,256,2128,20294,216213,2530522,32165101,440388103,6454695553,
%T A321087 100786308221,1669953080587,29265149535076,540884779563305,
%U A321087 10516595791609376,214625521232021413,4588068733776013386,102541337542692407011,2391813703854249362395,58130860852912365134992,1469860403455095402834628,38611523432412179047238389
%N A321087 O.g.f. A(x) satisfies: [x^n] exp(n*A(x)) * (1 - n*x/(1-x)) = 0, for n > 0.
%C A321087 It is remarkable that this sequence should consist entirely of integers.
%C A321087 Compare to: [x^n] exp(n*G(x)) * (1 - n*x) = 0, for n > 0, when G(x) = x + x*G(x)*G'(x), where G(x)/x is the o.g.f. of A088716.
%F A321087 O.g.f. A(x) satisfies: A(x) = x/(1-x) + x*A(x)*A'(x).
%e A321087 O.g.f.: A(x) = x + 2*x^2 + 7*x^3 + 37*x^4 + 256*x^5 + 2128*x^6 + 20294*x^7 + 216213*x^8 + 2530522*x^9 + 32165101*x^10 + ...
%e A321087 ILLUSTRATION OF DEFINITION.
%e A321087 The table of coefficients of x^k/k! in exp(-n*A(x)) * (1 - n*x/(1-x)) begins:
%e A321087 n=1: [1, 0, 1, 28, 801, 30256, 1544425, 103604796, 8828789473, ...];
%e A321087 n=2: [1, 0, 0, 32, 1296, 55632, 2987200, 204441120, 17560833024, ...];
%e A321087 n=3: [1, 0, -3, 0, 1161, 67608, 4053645, 290790216, 25525161585, ...];
%e A321087 n=4: [1, 0, -8, -80, 0, 54304, 4333120, 344829888, 31719439360, ...];
%e A321087 n=5: [1, 0, -15, -220, -2655, 0, 3244825, 340694100, 34696521825, ...];
%e A321087 n=6: [1, 0, -24, -432, -7344, -115344, 0, 242169696, 32423666688, ...];
%e A321087 n=7: [1, 0, -35, -728, -14679, -316568, -6439475, 0, 22110305329, ...];
%e A321087 n=8: [1, 0, -48, -1120, -25344, -633792, -17406080, -451234944, 0, ...]; ...
%e A321087 in which the coefficient of x^n in row n forms a diagonal of zeros.
%e A321087 RELATED SERIES.
%e A321087 (a) Differential Equation.
%e A321087 O.g.f. A(x) satisfies: A(x) = x/(1-x) + x*A(x)*A'(x) where
%e A321087 A'(x) = 1 + 4*x + 21*x^2 + 148*x^3 + 1280*x^4 + 12768*x^5 + 142058*x^6 + ...
%e A321087 A(x)*A'(x) = x + 6*x^2 + 36*x^3 + 255*x^4 + 2127*x^5 + 20293*x^6 + 216212*x^7 + 2530521*x^8 + 32165100*x^9 + ...
%e A321087 so that A(x) - x*A(x)*A'(x) = x/(1-x).
%e A321087 (b) Exponentiation.
%e A321087 exp(A(x)) = 1 + x + 5*x^2/2! + 55*x^3/3! + 1129*x^4/4! + 37541*x^5/5! + 1813381*x^6/6! + 118181155*x^7/7! + 9890849585*x^8/8! + ...
%e A321087 exp(-A(x)) = 1 - x - 3*x^2/2! - 31*x^3/3! - 695*x^4/4! - 25221*x^5/5! - 1299779*x^6/6! - 88812907*x^7/7! - 7702826319*x^8/8! + ...
%o A321087 (PARI) {a(n) = my(A=[1]); for(i=1, n, A=concat(A, 0); m=#A; A[m] = -Vec( exp(m*x*Ser(A))*(1-m*x/(1-x +x^2*O(x^m))))[m+1]/m ); A[n]}
%o A321087 for(n=1, 30, print1(a(n), ", "))
%Y A321087 Cf. A321086, A088716.
%K A321087 nonn
%O A321087 1,2
%A A321087 _Paul D. Hanna_, Oct 27 2018