Squares in products in arithmetic progression with at most one term omitted and common difference a prime power

Shanta Laishram; T. N. Shorey; Szabolcs Tengely

Displaying similar documents to “Squares in products in arithmetic progression with at most one term omitted and common difference a prime power”

Squares in arithmetic progression with at most two terms omitted

Shanta Laishram, T. N. Shorey (2008)

Acta Arithmetica

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The equation n(n+d) ⋯ (n+(k-1)d) = by² with ω(d) ≤ 6 or d ≤ 10¹⁰

Shanta Laishram, T. N. Shorey (2007)

Acta Arithmetica

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Almost squares in arithmetic progression (II)

Anirban Mukhopadhyay, T. N. Shorey (2003)

Acta Arithmetica

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Some extensions and refinements of a theorem of Sylvester

N. Saradha, T. N. Shorey, R. Tijdeman (2002)

Acta Arithmetica

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On some arithmetic properties of polynomial expressions involving Stirling numbers of the second kind

Martin Klazar, Florian Luca (2003)

Acta Arithmetica

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Almost perfect powers in arithmetic progression

N. Saradha, T. N. Shorey (2001)

Acta Arithmetica

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The resolution of the diophantine equation x(x+d)...(x+(k-1)d) = by² for fixed d

P. Filakovszky, L. Hajdu (2001)

Acta Arithmetica

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On the Diophantine equation x² - dy⁴ = 1 with prime discriminant II

D. Poulakis, P. G. Walsh (2006)

Colloquium Mathematicae

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Let p denote a prime number. P. Samuel recently solved the problem of determining all squares in the linear recurrence sequence {Tₙ}, where Tₙ and Uₙ satisfy Tₙ² - pUₙ² = 1. Samuel left open the problem of determining all squares in the sequence {Uₙ}. This problem was recently solved by the authors. In the present paper, we extend our previous joint work by completely solving the equation Uₙ = bx², where b is a fixed positive squarefree integer. This result also extends previous work...

A note on arithmetic Diophantine series

Alexander E. Patkowski (2021)

Czechoslovak Mathematical Journal

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We consider an asymptotic analysis for series related to the work of Hardy and Littlewood (1923) on Diophantine approximation, as well as Davenport. In particular, we expand on ideas from some previous work on arithmetic series and the RH. To accomplish this, Mellin inversion is applied to certain infinite series over arithmetic functions to apply Cauchy's residue theorem, and then the remainder of terms is estimated according to the assumption of the RH. In the last section, we use...