AbstractWe show how to compute Hong’s bound for the absolute positiveness of a polynomial in d variables with maximum degree δ in O(nlogdn) time, where n is the number of non-zero coefficients. For the univariate case, we give a linear time algorithm. As a consequence, the time bounds for the continued fraction algorithm for real root isolation improve by a factor of δ
AbstractA class of upper bounds for the positive roots of a polynomial is discussed, and it is shown...
AbstractWe consider a certain type of polynomial equations for which there exists—according to Desca...
We consider a nonconstant polynomial P with real coeţients that has at least one negative coeţient a...
AbstractWe show how to compute Hong’s bound for the absolute positiveness of a polynomial in d varia...
AbstractWe propose and study a weighting framework for obtaining bounds on absolute positiveness of ...
AbstractWe propose and study a weighting framework for obtaining bounds on absolute positiveness of ...
In this paper we review the existing linear and quadratic complexity (upper) bounds on the values of...
This paper provides a simple formula for computing such bounds. We also prove that the resulting bou...
In this paper we review the existing linear and quadratic complexity (upper) bounds on the values of...
AbstractA multivariate polynomialP(x1, …,xn) with real coefficients is said to beabsolutely positive...
We present an implementation of the Continued Fractions (CF) real root isolation method using a rece...
AbstractThe maximum computing time of the continued fractions method for polynomial real root isolat...
This thesis describes new results on computing bounds on the values of the positive roots of polynom...
This thesis describes new results on computing bounds on the values of the positive roots of polynom...
This thesis describes new results on computing bounds on the values of the positive roots of polynom...
AbstractA class of upper bounds for the positive roots of a polynomial is discussed, and it is shown...
AbstractWe consider a certain type of polynomial equations for which there exists—according to Desca...
We consider a nonconstant polynomial P with real coeţients that has at least one negative coeţient a...
AbstractWe show how to compute Hong’s bound for the absolute positiveness of a polynomial in d varia...
AbstractWe propose and study a weighting framework for obtaining bounds on absolute positiveness of ...
AbstractWe propose and study a weighting framework for obtaining bounds on absolute positiveness of ...
In this paper we review the existing linear and quadratic complexity (upper) bounds on the values of...
This paper provides a simple formula for computing such bounds. We also prove that the resulting bou...
In this paper we review the existing linear and quadratic complexity (upper) bounds on the values of...
AbstractA multivariate polynomialP(x1, …,xn) with real coefficients is said to beabsolutely positive...
We present an implementation of the Continued Fractions (CF) real root isolation method using a rece...
AbstractThe maximum computing time of the continued fractions method for polynomial real root isolat...
This thesis describes new results on computing bounds on the values of the positive roots of polynom...
This thesis describes new results on computing bounds on the values of the positive roots of polynom...
This thesis describes new results on computing bounds on the values of the positive roots of polynom...
AbstractA class of upper bounds for the positive roots of a polynomial is discussed, and it is shown...
AbstractWe consider a certain type of polynomial equations for which there exists—according to Desca...
We consider a nonconstant polynomial P with real coeţients that has at least one negative coeţient a...
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