论涉及卢卡斯数的某些二阶方程

arXiv - MATH - General Mathematics Pub Date : 2024-09-16 DOI:arxiv-2409.10152

Priyabrata Mandal

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摘要

本文探讨了卢卡斯数与二叉方程之间错综复杂的关系，为数论领域做出了重要贡献。我们首先通过分析卢卡斯数 modulo $4$ 和雅可比符号的全等性质，确定关于卢卡斯数 $L_n= 3x^2$ 的方程在正整数中有唯一的解，特别是 $(n, x) = (2,1)$。我们还证明，只有当 $(n,x)=(5,1)$ 时，斐波那契数 $F_n$ 才能是 $F_n=5x^2$ 的形式。通过进一步研究，我们证明方程 $L_n^2+L_{n+1}^2=x^2$ 有一个唯一的解 $(n,x)=(2,5)$。最后，我们确定了方程 $L_n^\alpha + L_{n+1}^\alpha = x^2$ 的所有非负整数解 $(n,\alpha,x)$，其中 $L_n$ 表示卢卡斯序列中的第 n 项。

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On Certain Diophantine Equations Involving Lucas Numbers

This paper explores the intricate relationships between Lucas numbers and Diophantine equations, offering significant contributions to the field of number theory. We first establish that the equation regarding Lucas number $L_n = 3x^2$ has a unique solution in positive integers, specifically $(n, x) = (2, 1)$, by analyzing the congruence properties of Lucas numbers modulo $4$ and Jacobi symbols. We also prove that a Fibonacci number $F_n$ can be of the form $F_n=5x^2$ only when $(n,x)=(5,1)$. Expanding our investigation, we prove that the equation $L_n^2+L_{n+1}^2=x^2$ admits a unique solution $(n,x)=(2,5)$. In conclusion, we determine all non-negative integer solutions $(n, \alpha, x)$ to the equation $L_n^\alpha + L_{n+1}^\alpha = x^2$, where $L_n$ represents the $n$-th term in the Lucas sequence.

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arXiv - MATH - General Mathematics

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