Hyperelliptic Curves, Continued Fractions and Somos Sequences

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Concerning (Bh) — thus 5-Somos — Don Zagier inter alia writes: “One computes the first few (in my case, 300) terms Bn numerically, studies their numerical growth, and tries to fit this data by a nice analytic expression. One quickly finds that the growth is roughly exponential in n2 , but with some slow fluctuations around this and also with a dependency on the parity of n. This suggests trying the Ansatz Bn = c±bnan2 , where (−1) n = ±1. This is easily seen to give a solution to our recursion if a is the root of a12 = a4 + 1, and the numerical value a = 1.07283 (approx) does indeed give a reasonably good fit to the data, but eventually fails more and more thoroughly. Looking more carefully, we try the same Ansatz but with c± replaced by a function c±(n) which lies between fixed limits but is almost periodic in n, and this works, but with a new value a = 1.07425 (approx) . . . . Here I put in a pause so that we can catch our breath. Expanding the function c±(n) numerically into a Fourier series, we discover that it is a Jacobi theta function, and since theta functions (or quotients of them) are elliptic functions, this leads quickly to elliptic curves . . . .” 4
Concerning (Bh) — thus 5-Somos — Don Zagier inter alia writes: “One computes the first few (in my case, 300) terms Bn numerically, studies their numerical growth, and tries to fit this data by a nice analytic expression. One quickly finds that the growth is roughly exponential in n2 , but with some slow fluctuations around this and also with a dependency on the parity of n. This suggests trying the Ansatz Bn = c±bnan2 , where (−1) n = ±1. This is easily seen to give a solution to our recursion if a is the root of a12 = a4 + 1, and the numerical value a = 1.07283 (approx) does indeed give a reasonably good fit to the data, but eventually fails more and more thoroughly. Looking more carefully, we try the same Ansatz but with c± replaced by a function c±(n) which lies between fixed limits but is almost periodic in n, and this works, but with a new value a = 1.07425 (approx) . . . . Here I put in a pause so that we can catch our breath. Expanding the function c±(n) numerically into a Fourier series, we discover that it is a Jacobi theta function, and since theta functions (or quotients of them) are elliptic functions, this leads quickly to elliptic curves . . . .” 4
Page 1 and 2: Hyperelliptic Curves, Continued Fra
Page 3 and 4: A pseudo-elliptic integral Z x 6t p
Page 9 and 10: Michael Somos’s Sequences The sto
Page 17 and 18: Concerning (Bh) — thus 5-Somos
Page 19 and 20: Concerning (Bh) — thus 5-Somos
Page 21: Concerning (Bh) — thus 5-Somos
Page 25 and 26: The surprising integral Z X 6t dt p
Page 31 and 32: Plainly, the equations detailing ps
Page 43 and 44: Moreover, u ′ = a ′ + b ′√
Page 53 and 54: Units and Torsion The notion unit e
Page 61 and 62: Units in Quadratic Fields and Conti
Page 71 and 72: Continued Fraction of the Square Ro
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Continued Fraction of the Square Ro
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To detail the continued fraction ex
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There is a minor miracle. Because t
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I should point out that any actual
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Second, if we replace D by D + 1 th
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Second, if we replace D by D + 1 th
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In the course of studying continued
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In the course of studying continued
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What the Continued Fraction Does No
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The elliptic case When g = 1 we hav
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The −dh are in fact the abscissæ
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As it happens, a combinatorial/alge
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Elliptic Divisibility Sequences Now
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Remarkably, Ward introduces his seq
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Elliptic Division Polynomials I ins
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4-Somos Suppose (Ch) = (. . . , 2,
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Higher Genus There surely are analo
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Others can do worse, and better. If
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Others can do worse, and better. If
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A cute example à la Somos Whatever
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A cute example à la Somos Whatever
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References Rather than attempt a li
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Hyperelliptic Curves, Continued Fractions and Somos Sequences

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