Floating point error is an inevitable drawback of embedded systems implementation. Computing rigorous upper bounds of roundoff errors is absolutely necessary for the validation of critical software. This problem of computing rigorous upper bounds is even more challenging when addressing non-linear programs. In this paper, we propose and compare two new methods based on Bernstein expansions and sparse Krivine-Stengle representations, adapted from the field of the global optimization , to compute upper bounds of roundoff errors for programs implementing polynomial functions. We release two related software package FPBern and FPKiSten, and compare them with state of the art tools. We show that these two methods achieve competitive performance,...
AbstractRounding error bounds of the Forsythe and the Clenshaw–Smith algorithm for the evaluation of...
International audienceThis paper deals with the polynomial linear system solving with errors (PLSwE)...
Multiplicative Newton–Raphson and Goldschmidt algorithms are widely used in current processors to im...
14 pages, 2 figures, 2 tables. Extension of the work in arXiv:1610.07038International audienceFloati...
A longstanding problem related to floating-point implementation of numerical programs is to provide ...
Roundoff errors cannot be avoided when implementing numerical programs with finite precision. The ab...
18 pages, 2 tables, 1 figureInternational audienceA longstanding problem related to floating-point i...
We present a new tool that generates bounds on the values and the round-off errors of programs using...
A roundoff error analysis of formulae for evaluating polynomials is performed. The considered formul...
We present a detailed study of roundoff errors in probabilistic floating-point computations. We deri...
An emerging area of research is to automatically compute reasonably accurate upper bounds on numeric...
Rigorous estimation of maximum floating-point round-off errors is an important capability central to...
AbstractThe error propagation characteristics of the polynomial evaluation schemes of Horner, Clensh...
Les nombres à virgule flottante sont utilisés dans de nombreuses applications pour effectuer des cal...
We present a detailed study of roundoff errors in probabilistic floating-point computations. We deri...
AbstractRounding error bounds of the Forsythe and the Clenshaw–Smith algorithm for the evaluation of...
International audienceThis paper deals with the polynomial linear system solving with errors (PLSwE)...
Multiplicative Newton–Raphson and Goldschmidt algorithms are widely used in current processors to im...
14 pages, 2 figures, 2 tables. Extension of the work in arXiv:1610.07038International audienceFloati...
A longstanding problem related to floating-point implementation of numerical programs is to provide ...
Roundoff errors cannot be avoided when implementing numerical programs with finite precision. The ab...
18 pages, 2 tables, 1 figureInternational audienceA longstanding problem related to floating-point i...
We present a new tool that generates bounds on the values and the round-off errors of programs using...
A roundoff error analysis of formulae for evaluating polynomials is performed. The considered formul...
We present a detailed study of roundoff errors in probabilistic floating-point computations. We deri...
An emerging area of research is to automatically compute reasonably accurate upper bounds on numeric...
Rigorous estimation of maximum floating-point round-off errors is an important capability central to...
AbstractThe error propagation characteristics of the polynomial evaluation schemes of Horner, Clensh...
Les nombres à virgule flottante sont utilisés dans de nombreuses applications pour effectuer des cal...
We present a detailed study of roundoff errors in probabilistic floating-point computations. We deri...
AbstractRounding error bounds of the Forsythe and the Clenshaw–Smith algorithm for the evaluation of...
International audienceThis paper deals with the polynomial linear system solving with errors (PLSwE)...
Multiplicative Newton–Raphson and Goldschmidt algorithms are widely used in current processors to im...