Design and implementation of symbolic algorithms for the computation of generalized asymptotes

IF 1.2 4区计算机科学 Q4 COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE

Annals of Mathematics and Artificial Intelligence Pub Date : 2023-07-03 DOI:10.1007/s10472-023-09856-z

Marián Fernández de Sevilla, Rafael Magdalena Benedicto, Sonia Pérez-Díaz

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引用次数: 1

Abstract

In this paper we present two algorithms for computing the g-asymptotes or generalized asymptotes, of a plane algebraic curve, \(\mathscr {C}\), implicitly or parametrically defined. The asymptotes of a curve \(\mathscr {C}\) reflect the status of \(\mathscr {C}\) at points with sufficiently large coordinates. It is well known that an asymptote of a curve \(\mathscr {C}\) is a line such that the distance between \(\mathscr {C}\) and the line approaches zero as they tend to infinity. However, a curve \(\mathscr {C}\) may have more general curves than lines describing the status of \(\mathscr {C}\) at infinity. These curves are known as g-asymptotes or generalized asymptotes. The pseudocodes of these algorithms are presented, as well as the corresponding implementations. For this purpose, we use the algebra software Maple. A comparative analysis of the algorithms is carried out, based on some properties of the input curves and their results to analyze the efficiency of the algorithms and to establish comparative criteria. The results presented in this paper are a starting point to generalize this study to surfaces or to curves defined by a non-rational parametrization, as well as to improve the efficiency of the algorithms. Additionally, the methods developed can provide a new and different approach in prediction (regression) or classification algorithms in the machine learning field.

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广义渐近线计算符号算法的设计与实现

本文提出了两种计算隐式或参数定义的平面代数曲线（\mathscr｛C｝\）的g渐近线或广义渐近线的算法。曲线\（\mathscr｛C｝\）的渐近线反映了坐标足够大的点处的\（\math scr｛。众所周知，曲线\（\mathscr｛C｝\）的渐近线是一条线，当它们趋于无穷大时，\（\math scr｛。然而，与描述\（\mathscr｛C｝\）在无穷大处的状态的线相比，曲线\（\math scr｛。这些曲线被称为g渐近线或广义渐近线。给出了这些算法的伪代码以及相应的实现。为此，我们使用代数软件Maple。基于输入曲线的一些特性及其结果，对算法进行了比较分析，以分析算法的效率并建立比较标准。本文给出的结果是将这项研究推广到由非有理参数化定义的曲面或曲线的起点，也是提高算法效率的起点。此外，所开发的方法可以在机器学习领域的预测（回归）或分类算法中提供一种新的不同方法。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Annals of Mathematics and Artificial Intelligence 工程技术-计算机：人工智能

CiteScore

3.00

自引率

8.30%

发文量

审稿时长

>12 weeks

期刊介绍： Annals of Mathematics and Artificial Intelligence presents a range of topics of concern to scholars applying quantitative, combinatorial, logical, algebraic and algorithmic methods to diverse areas of Artificial Intelligence, from decision support, automated deduction, and reasoning, to knowledge-based systems, machine learning, computer vision, robotics and planning. The journal features collections of papers appearing either in volumes (400 pages) or in separate issues (100-300 pages), which focus on one topic and have one or more guest editors. Annals of Mathematics and Artificial Intelligence hopes to influence the spawning of new areas of applied mathematics and strengthen the scientific underpinnings of Artificial Intelligence.