快速数值多元多点计算

Sumanta Ghosh, P. Harsha, Simao Herdade, Mrinal Kumar, Ramprasad Saptharishi
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引用次数: 1

摘要

针对有理数、实数和复数域上的多元多点求值问题,设计了近线性时间数值算法。我们考虑了算法的\emph{精确}版本和\emph{近似}版本。算法的输入是(1)一个$m$变量多项式$f$的系数,每个变量的度数为$d$,(2)点$a_1,..., a_N$,每个点的坐标都有一个以1为界的值和位复杂度$s$。*近似版本:给定一个额外的精度参数$t$,算法计算有理数$\beta_1,\ldots, \beta_N$,使得$|f(a_i) - \beta_i| \leq \frac{1}{2^t}$适用于所有$i$,并且运行时间为$((Nm + d^m)(s + t))^{1 + o(1)}$适用于所有$m$和所有足够大的$d$。*精确版本(当超过有理数时):在所有求值的位复杂度上额外给定一个界$c$,算法计算有理数$f(a_1), ... , f(a_N)$,及时$((Nm + d^m)(s + c))^{1 + o(1)}$对于所有$m$和所有足够大的$d$ . .在此工作之前,对于任何无限域上的多元多点评估(精确或近似)的近线性时间算法似乎仅在单变量多项式的情况下已知,并且在Moroz的最近工作中被发现(FOCS 2021)。在这项工作中,我们将这个结果从单变量扩展到多变量设置。然而,我们的算法基于的思想在概念上似乎与Moroz (FOCS 2021)不同,并且关键地依赖于Bhargava, Ghosh, Guo, Kumar&Umans (FOCS 2022)最近的一种算法,用于有限域上的多元多点评估,以及已知的有效算法,用于计算数论中的有理数重建和快速中文余数问题。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Fast Numerical Multivariate Multipoint Evaluation
We design nearly-linear time numerical algorithms for the problem of multivariate multipoint evaluation over the fields of rational, real and complex numbers. We consider both \emph{exact} and \emph{approximate} versions of the algorithm. The input to the algorithms are (1) coefficients of an $m$-variate polynomial $f$ with degree $d$ in each variable, and (2) points $a_1,..., a_N$ each of whose coordinate has value bounded by one and bit-complexity $s$. * Approximate version: Given additionally an accuracy parameter $t$, the algorithm computes rational numbers $\beta_1,\ldots, \beta_N$ such that $|f(a_i) - \beta_i| \leq \frac{1}{2^t}$ for all $i$, and has a running time of $((Nm + d^m)(s + t))^{1 + o(1)}$ for all $m$ and all sufficiently large $d$. * Exact version (when over rationals): Given additionally a bound $c$ on the bit-complexity of all evaluations, the algorithm computes the rational numbers $f(a_1), ... , f(a_N)$, in time $((Nm + d^m)(s + c))^{1 + o(1)}$ for all $m$ and all sufficiently large $d$. . Prior to this work, a nearly-linear time algorithm for multivariate multipoint evaluation (exact or approximate) over any infinite field appears to be known only for the case of univariate polynomials, and was discovered in a recent work of Moroz (FOCS 2021). In this work, we extend this result from the univariate to the multivariate setting. However, our algorithm is based on ideas that seem to be conceptually different from those of Moroz (FOCS 2021) and crucially relies on a recent algorithm of Bhargava, Ghosh, Guo, Kumar&Umans (FOCS 2022) for multivariate multipoint evaluation over finite fields, and known efficient algorithms for the problems of rational number reconstruction and fast Chinese remaindering in computational number theory.
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