Interval arithmetic achieves numerical reliability for a wide range of applications, at the price of a performance penalty. For applications to homotopy continuation, one key ingredient is the efficient and reliable evaluation of complex polynomials represented by straight-line programs. This is best achieved using ball arithmetic, a variant of interval arithmetic. In this article, we describe strategies for reducing the performance penalty of basic operations on balls. We also show how to bound the effect of rounding errors at the global level of evaluating a straight-line program. This allows us to introduce a new and faster "transient" variant of ball arithmetic
International audienceWe explicit the link between the computer arithmetic problem of providing corr...
In this paper we show how to reduce the computation of correctly-rounded square roots of binary floa...
We present a new tool that generates bounds on the values and the round-off errors of programs using...
Interval arithmetic achieves numerical reliability for a wide range of applications, at the price of...
33 pagesThe Mathemagix project aims at the development of a ''computer analysis'' system, in which n...
Daisy is a framework for verifying and bounding the magnitudes of rounding errors introduced by floa...
Using error-free transformations, we improve the classic Horner Scheme (HS) to evaluate (univariate)...
The Floating-Point (FP) implementation of a real-valued function is performed with correct rounding ...
This article shows that IEEE-754 double-precision correct rounding of the most common elementary fun...
Roundoff errors cannot be avoided when implementing numerical programs with finite precision. The ab...
10 pagesInternational audienceSIMD instructions on floating-point numbers have been readily available...
This paper presents an algorithm for evaluating the functions of reciprocal, square root, 2x, and lo...
International audienceWe present the design of the Boost interval arithmetic library, a C++ library ...
International audienceWe explicit the link between the computer arithmetic problem of providing corr...
In this paper we show how to reduce the computation of correctly-rounded square roots of binary floa...
We present a new tool that generates bounds on the values and the round-off errors of programs using...
Interval arithmetic achieves numerical reliability for a wide range of applications, at the price of...
33 pagesThe Mathemagix project aims at the development of a ''computer analysis'' system, in which n...
Daisy is a framework for verifying and bounding the magnitudes of rounding errors introduced by floa...
Using error-free transformations, we improve the classic Horner Scheme (HS) to evaluate (univariate)...
The Floating-Point (FP) implementation of a real-valued function is performed with correct rounding ...
This article shows that IEEE-754 double-precision correct rounding of the most common elementary fun...
Roundoff errors cannot be avoided when implementing numerical programs with finite precision. The ab...
10 pagesInternational audienceSIMD instructions on floating-point numbers have been readily available...
This paper presents an algorithm for evaluating the functions of reciprocal, square root, 2x, and lo...
International audienceWe present the design of the Boost interval arithmetic library, a C++ library ...
International audienceWe explicit the link between the computer arithmetic problem of providing corr...
In this paper we show how to reduce the computation of correctly-rounded square roots of binary floa...
We present a new tool that generates bounds on the values and the round-off errors of programs using...