AbstractThe introduction of high-speed circuits to realize an arithmetic function f as a piecewise linear approximation has created a need to understand how the number of segments depends on the interval a≤x≤b and the desired approximation error ε. For the case of optimum non-uniform segments, we show that the number of segments is given as s(ε)∼cε, (ε→0+), where c=14∫ab|f″(x)|dx. Experimental data shows that this approximation is close to the exact number of segments for a set of 14 benchmark functions. We also show that, if the segments have the same width (to reduce circuit complexity), then the number of segments is given by s(ε)∼cε, (ε→0+), where c=(b−a)|f″|max4
We present new consequences of the assumption that time-bounded algorithms can be "compressed" with ...
International audienceEmbedded applications integrate more and more sophisticated computations. Thes...
Developing some techniques for the approximation method, we establish precise versions of the follow...
AbstractThe introduction of high-speed circuits to realize an arithmetic function f as a piecewise l...
In this work efficient geometric algorithms are provided for the linear approximation of digital sig...
AbstractWe give an efficient algorithm for partitioning the domain of a numeric function f into segm...
AbstractThis paper investigates the relationship between approximation error and complexity. A varie...
This paper investigates the relationship between approximation error and complexity. A variety of co...
Abstract:A criteria is developed for the approximations of a logarithmic function to piecewise strai...
International audience—Modern applications embed complex mathematical processing based on compositio...
AbstractRecently, a new technique called the method of approximations has been developed for proving...
© Cody D. Murray and R. Ryan Williams. We present new consequences of the assumption that time-bound...
Developing certain techniques for the approximation method, we establish precise versions of the fol...
We study the circuit diameter of polyhedra, introduced by Borgwardt, Finhold, and Hemmecke (SIDMA 20...
Proving hardness of approximation is a major challenge in the field of fine-grained complexity and c...
We present new consequences of the assumption that time-bounded algorithms can be "compressed" with ...
International audienceEmbedded applications integrate more and more sophisticated computations. Thes...
Developing some techniques for the approximation method, we establish precise versions of the follow...
AbstractThe introduction of high-speed circuits to realize an arithmetic function f as a piecewise l...
In this work efficient geometric algorithms are provided for the linear approximation of digital sig...
AbstractWe give an efficient algorithm for partitioning the domain of a numeric function f into segm...
AbstractThis paper investigates the relationship between approximation error and complexity. A varie...
This paper investigates the relationship between approximation error and complexity. A variety of co...
Abstract:A criteria is developed for the approximations of a logarithmic function to piecewise strai...
International audience—Modern applications embed complex mathematical processing based on compositio...
AbstractRecently, a new technique called the method of approximations has been developed for proving...
© Cody D. Murray and R. Ryan Williams. We present new consequences of the assumption that time-bound...
Developing certain techniques for the approximation method, we establish precise versions of the fol...
We study the circuit diameter of polyhedra, introduced by Borgwardt, Finhold, and Hemmecke (SIDMA 20...
Proving hardness of approximation is a major challenge in the field of fine-grained complexity and c...
We present new consequences of the assumption that time-bounded algorithms can be "compressed" with ...
International audienceEmbedded applications integrate more and more sophisticated computations. Thes...
Developing some techniques for the approximation method, we establish precise versions of the follow...