Zeros of recurrence sequences

Poorten, Alfred J. van der; Schlickewei, Hans Peter

doi:10.1017/s0004972700029646

Cited by 58 publications

(61 citation statements)

References 5 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…[15]). The finiteness result quoted after Theorem K, and therefore the implication (i) ===> (ii) in Theorem K can be deduced from the following finiteness theorem on S-unit equations which was established independently by van der Poorten and Schlickewei [49] and Evertse [13]. In [15] (see also [16]) it has been pointed out that the implication (i) ===> (ii) of Theorem K is in fact equivalent to the above theorem on S-unit equations.…”

Section: Decomposable Form Equations Of General Typementioning

confidence: 93%

Decomposable form equations

Evertse¹,

Győry²

2015

Unit Equations in Diophantine Number Theory

View full text Add to dashboard Cite

Section: Decomposable Form Equations Of General Typementioning

confidence: 93%

Decomposable form equations

Evertse¹,

Győry²

2015

Unit Equations in Diophantine Number Theory

View full text Add to dashboard Cite

“…(A recurrence is non-degenerate if its characteristic polynomial has at least two distinct non-zero complex roots and the ratio of any two distinct non-zero characteristic roots is not a root of unity.) More specifically, it was shown by van der Poorten and Schlickewei [14] and, independently, by Evertse [4, Corollary 3], using Schlickewei's p-adic analogue of Schmidt's Subspace Theorem [7], that the greatest prime factor of u n tends to ∞ as n → ∞. In a similar note, effective lower bounds on the greatest prime divisor and on the greatest square-free factor of a sequence of type (3) were obtained under mild assumptions by Shparlinski [10] and Stewart [11][12][13], based on variants of Baker's theorem on linear forms in the logarithms of algebraic numbers [2].…”

Section: Introductionmentioning

confidence: 90%

On the number of distinct prime factors of a sum of super-powers

Leonetti

Tringali

2018

Journal of Number Theory

View full text Add to dashboard Cite

Abstract. Given k, ℓ ∈ N + , let x i,j be, for 1 ≤ i ≤ k and 0 ≤ j ≤ ℓ, some fixed integers, and define, for every n ∈ N + , sn := k i=1 ℓ j=0 x n j i,j . We prove that the following are equivalent: (a) There are a real θ > 1 and infinitely many indices n for which the number of distinct prime factors of sn is greater than the super-logarithm of n to base θ. for all n. We will give two different proofs of this result, one based on a theorem of Evertse (yielding, for a fixed finite set of primes S, an effective bound on the number of non-degenerate solutions of an S-unit equation in k variables over the rationals) and the other using only elementary methods.As a corollary, we find that, for fixed c 1 , x 1 , . . . , c k , x k ∈ N + , the number of distinct prime factors of c 1 x n 1 + · · · + c k x n k is bounded, as n ranges over N + , if and only if x 1 = · · · = x k .

show abstract

“…In the case when the vn are algebraic, Schlickewei [5] and van der Poorten and Schlickewei [4] have given a quantitative version of this result. Evertse [ 1 ] proved that the equation vn = vm admits only finitely many solutions n ^ m with n, m > 0.…”

Section: = £>(»)mentioning

confidence: 97%