Andrew Arnold scite author profile

We present randomized algorithms to compute the sumset (Minkowski sum) of two integer sets, and to multiply two univariate integer polynomials given by sparse representations. Our algorithm for sumset has cost softly linear in the combined size of the inputs and output. This is used as part of our sparse multiplication algorithm, whose cost is softly linear in the combined size of the inputs, output, and the sumset of the supports of the inputs. As a subroutine, we present a new method for computing the coefficients of a sparse polynomial, given a set containing its support. Our multiplication algorithm extends to multivariate Laurent polynomials over finite fields and rational numbers. Our techniques are based on sparse interpolation algorithms and results from analytic number theory.

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Faster Sparse Interpolation of Straight-Line Programs

Arnold

Giesbrecht

Roche

2013

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Sparse interpolation over finite fields via low-order roots of unity

Arnold

Giesbrecht

Roche

2014

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We present a new Monte Carlo algorithm for the interpolation of a straight-line program as a sparse polynomial f over an arbitrary finite field of size q. We assume a priori bounds D and T are given on the degree and number of terms of f . The approach presented in this paper is a hybrid of the diversified and recursive interpolation algorithms, the two previous fastest known probabilistic methods for this problem. By making effective use of the information contained in the coefficients themselves, this new algorithm improves on the bit complexity of previous methods by a "soft-Oh" factor of T , log D, or log q.

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Multivariate sparse interpolation using randomized Kronecker substitutions

Arnold

Roche

2014

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We present new techniques for reducing a multivariate sparse polynomial to a univariate polynomial. The reduction works similarly to the classical and widely-used Kronecker substitution, except that we choose the degrees randomly based on the number of nonzero terms in the multivariate polynomial. The resulting univariate polynomial often has a significantly lower degree than the Kronecker substitution polynomial, at the expense of a small number of term collisions. As an application, we give a new algorithm for multivariate interpolation which uses these new techniques along with any existing univariate interpolation algorithm.

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Faster sparse multivariate polynomial interpolation of straight-line programs

Arnold

Giesbrecht

Roche

2016

Journal of Symbolic Computation

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Given a straight-line program whose output is a polynomial function of the inputs, we present a new algorithm to compute a concise representation of that unknown function. Our algorithm can handle any case where the unknown function is a multivariate polynomial, with coefficients in an arbitrary finite field, and with a reasonable number of nonzero terms but possibly very large degree. It is competitive with previously known sparse interpolation algorithms that work over an arbitrary finite field, and provides an improvement when there are a large number of variables.

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Andrew Arnold

Output-Sensitive Algorithms for Sumset and Sparse Polynomial Multiplication

Faster Sparse Interpolation of Straight-Line Programs

Sparse interpolation over finite fields via low-order roots of unity

Multivariate sparse interpolation using randomized Kronecker substitutions

Faster sparse multivariate polynomial interpolation of straight-line programs

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