Search: id:A005563
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%I A005563 M2720
%S A005563 0,3,8,15,24,35,48,63,80,99,120,143,168,195,224,255,288,
%T A005563 323,360,399,440,483,528,575,624,675,728,783,840,899,960,
%U A005563 1023,1088,1155,1224,1295,1368,1443,1520,1599,1680,1763
%N A005563 n(n+2) (or, (n+1)^2 - 1).
%C A005563 Erdos conjectured that n^2 - 1 = k! has a solution iff n is 5, 11 or
71 (when k is 4, 5 or 7).
%C A005563 Second order linear recurrences y(m)=2y(m-1)+A005563(n)y(m-2),y(0)=y(1)=1,
have closed form solutions involving only powers of integers. - Len
Smiley (smiley(AT)math.uaa.alaska.edu), Dec 08 2001
%C A005563 Number of edges in the join of two cycle graphs, both of order n, C_n
* C_n - Roberto E. Martinez II (remartin(AT)fas.harvard.edu), Jan
07 2002
%C A005563 Let k be a positive integer, M_n be the n X n matrix m_(i,j)=k^abs(i-j)
then det(M_n)=(-1)^(n-1)*a(k-1)^(n-1) - Benoit Cloitre (benoit7848c(AT)orange.fr),
May 28 2002
%C A005563 Also numbers n such that 4n + 4 is a square. - Cino Hilliard (hillcino368(AT)gmail.com),
Dec 18 2003
%C A005563 The function sqrt(x^2 + 1), starting with 1, produces an integer after
n(n+2) iterations. - Gerald McGarvey (Gerald.McGarvey(AT)comcast.net),
Aug 19 2004
%C A005563 a(n) mod 3 = 0 iff n mod 3 > 0: a(A008585(n)) = 2; a(A001651(n)) = 0;
a(n) mod 3 = 2*(1-A079978(n)). - Reinhard Zumkeller (reinhard.zumkeller(AT)gmail.com),
Oct 16 2006
%C A005563 a(n)=A067725/3 - Zerinvary Lajos (zerinvarylajos(AT)yahoo.com), Mar 06
2007
%C A005563 A129296(n) = number of divisors of a(n+1) that are not greater than n.
- Reinhard Zumkeller (reinhard.zumkeller(AT)gmail.com), Apr 09 2007
%C A005563 Sequence allows us to find X values of the equation: X^3 + X^2 = Y^2.
To find Y values: b(n)=n(n+1)(n+2). - Mohamed Bouhamida (bhmd95(AT)yahoo.fr),
Nov 06 2007
%C A005563 Sequence allows us to find X values of the equation: X + (X + 1)^2 +
(X + 2)^3 = Y^2. To prove that X = n^2 + 2n: Y^2 = X + (X + 1)^2
+ (X + 2)^3 = X^3 + 7*X^2 + 15X + 9 = (X + 1)(X^2 + 6X + 9) = (X
+ 1)*(X + 3)^2 it means: (X + 1) must be a perfect square, so X =
k^2 - 1 with k>=1. we can put: k = n + 1, which gives: X = n^2 +
2n and Y = (n + 1)(n^2 + 2n + 3). - Mohamed Bouhamida (bhmd95(AT)yahoo.fr),
Nov 12 2007
%C A005563 Comment from R. Guy (rkg(AT)cpsc.ucalgary.ca), Feb 01 2008 (Start):
%C A005563 This is also the number of moves that it takes n frogs to swap places
with n toads on a strip of 2n+1 squares (or positions, or lilypads)
where a move is a single slide or jump, illustrated for n = 2, a(n)
= 8 by
%C A005563 T T - F F
%C A005563 T - T F F
%C A005563 T F T - F
%C A005563 T F T F -
%C A005563 T F - F T
%C A005563 - F T F T
%C A005563 F - T F T
%C A005563 F F T - T
%C A005563 F F - T T
%C A005563 I was alerted to this by the Holton article, but on consulting Singmaster's
sources, I find that the puzzle goes back at least to 1867.
%C A005563 Probably the first to publish the number of moves for n of each animal
was Edouard Lucas in 1883. (End)
%C A005563 For n>0: A143053(a(n)) = A000290(n+1). - Reinhard Zumkeller (reinhard.zumkeller(AT)gmail.com),
Jul 20 2008
%C A005563 a(n+1)=terms of rank 0,1,3,6,10=A000217 of A120072 (3,8,5,15,). [From
Paul Curtz (bpcrtz(AT)free.fr), Oct 28 2008]
%C A005563 For all n=A (0,3,8,15,24,..), X=[A000027] (1,2,3,4,5,...,), Y=[A000012]
(1,1,1,1,...,) we have the Pell's equation X^2-A*Y^2=1. Example:
1-0*1=1; 2^2-3*1=1; 3^2-8*1=1; 4^2-15*1=1; and so on. [From Vincenzo
Librandi (vincenzo.librandi(AT)tin.it), Mar 08 2009]
%C A005563 A053186(a(n)) = 2*n. [From Reinhard Zumkeller (reinhard.zumkeller(AT)gmail.com),
May 20 2009]
%C A005563 Final digit belongs to a periodic sequence: 0, 3, 8, 5, 4, 5, 8, 3, 0,
9. [From Mohamed Bouhamida (bhmd95(AT)yahoo.fr), Sep 04 2009] [Comment
edited by N. J. A. Sloane, Sep 24 2009]
%C A005563 Comment from A. K. Devaraj (dkandadai(AT)yahoo.com), Sep 18 2009: (Start)
%C A005563 Let f(x) be a polynomial in x. Then f(x + n*f(x)) is congruent to 0 (mod(f(x));
here n belongs to N.
%C A005563 There is nothing interesting in the quotients f(x + n*f(x))/f(x) when
x belongs to Z.
%C A005563 However, when x is irrational these quotients consist of two parts, a)
rational integers and b) integer multiples of x.
%C A005563 The present sequence represents the non-integer part when the polynomial
is x^2 + x + 1 and x = sqrt(2),
%C A005563 f(x+n*f(x))/f(x) = A056108(n) + a(n)*sqrt(2).
%C A005563 (End)
%C A005563 For n>=1, a(n) is the number for which 1/a(n) = 0.0101... (A000035) in
base (n+1). [From Rick L. Shepherd (rshepherd2(AT)hotmail.com), Sep
27 2009]
%D A005563 R. K. Guy, Unsolved Problems in Theory of Numbers, Section D25.
%D A005563 Derek Holton, Math in School, 37 #1 (Jan 2008) 20-22,
%D A005563 Edouard Lucas, Recreations Mathematiques, Gauthier-Villars, Vol. 2 (1883)
141-143.
%D A005563 N. J. A. Sloane and Simon Plouffe, The Encyclopedia of Integer Sequences,
Academic Press, 1995 (includes this sequence).
%H A005563 R. K. Guy, Catwalks, Sandsteps and Pascal Pyramids, J. Integer Seqs., Vol. 3 (2000), #00.1.6
%H A005563 Milan Janjic, Enumerative Formulas
for Some Functions on Finite Sets
%H A005563 S. Plouffe,
Approximations de S\'{e}ries G\'{e}n\'{e}ratrices et Quelques Conjectures, Dissertation, Universit\'{e} du Qu\'{e}bec \`{a} Montr\'{e}al,
1992.
%H A005563 S. Plouffe,
1031 Generating Functions and Conjectures, Universit\'{e} du
Qu\'{e}bec \`{a} Montr\'{e}al, 1992.
%H A005563 Eric Weisstein's World of Mathematics, Near-Square Prime
%H A005563 Index entries for sequences related to
linear recurrences with constant coefficients
%F A005563 G.f.: ( 3 - x ) / ( 1 - x )^3.
%F A005563 C(n+1, 1)*C(n+3, 1). - Zerinvary Lajos (zerinvarylajos(AT)yahoo.com),
Jun 06 2005
%F A005563 A002378(a(n))=A002378(n)*A002378(n+1); e.g. A002378(15)=240=12*20 - Charlie
Marion (charliemath(AT)verizon.net), Dec 29 2003
%F A005563 a(n)=sum(sum(j-k, j=2..n),k=0..n), n>=1. - Zerinvary Lajos (zerinvarylajos(AT)yahoo.com),
May 11 2007
%F A005563 a(n)==A134582(n+1)/4 - Zerinvary Lajos (zerinvarylajos(AT)yahoo.com),
Feb 01 2008
%F A005563 a(n)=Real((n+1+i)^2) [From Gerald Hillier (adr.rabbicat(AT)gmail.com),
Oct 12 2008]
%F A005563 G.f.: x*(1+x)/exp(x) . [From Zerinvary Lajos (zerinvarylajos(AT)yahoo.com),
Apr 03 2009]
%F A005563 a(n) = (n!+(n+1)!)/(n-1)!..n>0 [From Gary Detlefs (gdetlefs(AT)aol.com),
Aug 10 2009]
%F A005563 a(n)=2*n+a(n-1)-1 (with a(1)=0) [From Vincenzo Librandi (vincenzo.librandi(AT)tin.it),
Nov 07 2009]
%e A005563 For n=2, a(2)=2*2+0-1=3; n=3, a(3)=2*3+3-1=8; n=4, a(4)=2*4+8-1=15 [From
Vincenzo Librandi (vincenzo.librandi(AT)tin.it), Nov 07 2009]
%p A005563 [seq(2*binomial(n,2)-n,n=2..43)]; - Zerinvary Lajos (zerinvarylajos(AT)yahoo.com),
Nov 25 2006
%p A005563 a:=n->sum (n,j=3..n): seq(a(n),n=2..43); - Zerinvary Lajos (zerinvarylajos(AT)yahoo.com),
Mar 21 2007
%p A005563 a:=n->sum(sum(j-k, j=2..n),k=0..n): seq(a(n), n=1..42); - Zerinvary Lajos
(zerinvarylajos(AT)yahoo.com), May 11 2007
%p A005563 a:=n->sum(sum(3, j=3..n)/3, k=1..n): seq(a(n), n=2..43); - Zerinvary
Lajos (zerinvarylajos(AT)yahoo.com), May 30 2007
%p A005563 A005563:=(-3+z)/(z-1)**3; [S. Plouffe in his 1992 dissertation.]
%p A005563 with(combinat, fibonacci):seq(fibonacci(3, i)-2,i=1..42); - Zerinvary
Lajos (zerinvarylajos(AT)yahoo.com), Mar 20 2008
%p A005563 a:=n->sum(1+sum(1, k=4..n),k=1..n):seq(a(n), n=2...43); - Zerinvary Lajos
(zerinvarylajos(AT)yahoo.com), Jun 11 2008
%p A005563 restart: G(x):=x*(1+x)/exp(x): f[0]:=G(x): for n from 1 to 43 do f[n]:=diff(f[n-1],
x) od: x:=0: seq(abs(f[n]),n=2..43);# [From Zerinvary Lajos (zerinvarylajos(AT)yahoo.com),
Apr 03 2009]
%t A005563 Table[(m^2 - 1), {m, 42}] - Zerinvary Lajos (zerinvarylajos(AT)yahoo.com),
Mar 21 2007
%o A005563 (Other) sage: [lucas_number1(3,n,1) for n in xrange(1, 43)] # [From Zerinvary
Lajos (zerinvarylajos(AT)yahoo.com), May 16 2009]
%Y A005563 A column of triangle A102537.
%Y A005563 a(n+1), n>=2, first column (used for the Lyman series of the hydrogen
atom) of triangle A120070.
%Y A005563 Cf. A013468, A007531, A062196, A002378, A000290(n) = a(n-1) + 1.
%Y A005563 Cf. A046092, A067725, A123865, A123866, A123867, A123868.
%Y A005563 Cf. A028560.
%Y A005563 Sequence in context: A086959 A083656 A013648 this_sequence A132411 A147998
A164003
%Y A005563 Adjacent sequences: A005560 A005561 A005562 this_sequence A005564 A005565
A005566
%K A005563 nonn,easy,new
%O A005563 0,2
%A A005563 N. J. A. Sloane (njas(AT)research.att.com).
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