Computing minimal interpolation bases

Jeannerod, Claude-Pierre; Neiger, Vincent; Schost, Éric; Villard, Gilles

doi:10.1016/j.jsc.2016.11.015

Cited by 35 publications

(82 citation statements)

References 41 publications

(78 reference statements)

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“…Although in a slightly different context, we remark that a linear algebra point for normal form computation can be found for the commutative case already in [13, Sections 6.7.1 and 6.72]. More recently, in [3] and [12,Section 7] it is shown that the shifted Popov basis of a k[x]-module given by equations exactly corresponds to some specific rows in a reduced row echelon form of the left nullspace of a constant matrix with much larger dimension than the original polynomial equations. The algorithm we present here is based on the linearization technique of Labhalla, Lombardi and Marlin [14].…”

Section: Introductionmentioning

confidence: 84%

Popov Form Computation for Matrices of Ore Polynomials

Khochtali

Rosenkilde

Storjohann

2017

Proceedings of the 2017 ACM International Symposium on Symbolic and Algebraic Computation

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Let F[∂; σ, δ] be a ring of Ore polynomials over a field. We give a new deterministic algorithm for computing the Popov form P of a non-singular matrix A ∈ F[∂; σ, δ] n×n . Our main focus is to ensure controlled growth in the size of coefficients from F in the case F = k(z), and even k = Q. Our algorithms are based on constructing from A a linear system over F and performing a structured fraction-free Gaussian elimination. The algorithm is output sensitive, with a cost that depends on the orthogonality defect of the input matrix: the sum of the row degrees in A minus the sum of the row degrees in P . The resulting bit-complexity for the differential and shift polynomial case over Q(z) improves upon the previous best.

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Section: Introductionmentioning

confidence: 84%

Popov Form Computation for Matrices of Ore Polynomials

Khochtali

Rosenkilde

Storjohann

2017

Proceedings of the 2017 ACM International Symposium on Symbolic and Algebraic Computation

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“…3] which returns s-Popov bases and is about twice slower than PM-Basis; making this overhead negligible for some usual cases is future work. For completeness, we handle general approximants (with one modulus per column of F) by an iterative approach from [2,47]; faster algorithms are more complex [23][24][25] and use partial linearization techniques.…”

Section: Approximant Bases and Interpolant Basesmentioning

confidence: 99%

“…. This definition is a specialization of those in [3,24], which consider n sets of points, one for each of the n columns of E 1 , . .…”

Section: Interpolant Bases For Matricesmentioning

confidence: 99%

“…Then, we describe our implementation of a key building block: multiplication. Section 3 presents the next major part of our work, concerning algorithms for approximant bases [2,15,25,53] and interpolant bases [3,23,24,47]. We focus on a version of interpolants which is less general than in these references but allows for a more efficient algorithm.…”

Section: Introductionmentioning

confidence: 99%

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Implementations of Efficient Univariate Polynomial Matrix Algorithms and Application to Bivariate Resultants

Hyun

Neiger

Schost

2019

Proceedings of the 2019 International Symposium on Symbolic and Algebraic Computation

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Complexity bounds for many problems on matrices with univariate polynomial entries have been improved in the last few years. Still, for most related algorithms, efficient implementations are not available, which leaves open the question of the practical impact of these algorithms, e.g. on applications such as decoding some errorcorrecting codes and solving polynomial systems or structured linear systems. In this paper, we discuss implementation aspects for most fundamental operations: multiplication, truncated inversion, approximants, interpolants, kernels, linear system solving, determinant, and basis reduction. We focus on prime fields with a word-size modulus, relying on Shoup's C++ library NTL. Combining these new tools to implement variants of Villard's algorithm for the resultant of generic bivariate polynomials (ISSAC 2018), we get better performance than the state of the art for large parameters.

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“…5.3 and 6.14). Jeannerod et al (2017) gave an algorithm achieving a cost similar to that in the first item above, in the more general context of Eq. (2) and thus covering the case of arbitrary orders as well; the cost bound above improves upon that given in (ibid., Thm.…”

Section: Introductionmentioning

confidence: 95%

Fast computation of approximant bases in canonical form

Jeannerod

Neiger

Villard

2020

Journal of Symbolic Computation

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In this article, we design fast algorithms for the computation of approximant bases in shifted Popov normal form. We first recall the algorithm known as PM-Basis, which will be our second fundamental engine after polynomial matrix multiplication: most other fast approximant basis algorithms basically aim at efficiently reducing the input instance to instances for which PM-Basis is fast. Such reductions usually involve partial linearization techniques due to Storjohann, which have the effect of balancing the degrees and dimensions in the manipulated matrices.Following these ideas, Zhou and Labahn gave two algorithms which are faster than PM-Basis for important cases including Hermite-Padé approximation, yet only for shifts whose values are concentrated around the minimum or the maximum value. The three mentioned algorithms were designed for balanced orders and compute approximant bases that are generally not normalized. Here, we show how they can be modified to return the shifted Popov basis without impact on their cost bound; besides, we extend Zhou and Labahn's algorithms to arbitrary orders. Furthermore, we give an algorithm which handles arbitrary shifts with one extra logarithmic factor in the cost bound compared to the above algorithms. To the best of our knowledge, this improves upon previously known algorithms for arbitrary shifts, including for particular cases such as Hermite-Padé approximation. This algorithm is based on a recent divide and conquer approach which reduces the general case to the case where information on the output degree is available. As outlined above, we solve the latter case via partial linearizations and PM-Basis.

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Computing minimal interpolation bases

Cited by 35 publications

References 41 publications

Popov Form Computation for Matrices of Ore Polynomials

Popov Form Computation for Matrices of Ore Polynomials

Implementations of Efficient Univariate Polynomial Matrix Algorithms and Application to Bivariate Resultants

Fast computation of approximant bases in canonical form

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