On the complexity of real solving bivariate systems

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On the complexity of real solving bivariate systems

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International Conference on Symbolic and Algebraic Computation archive
Proceedings of the 2007 international symposium on Symbolic and algebraic computation table of contents

Waterloo, Ontario, Canada

SESSION: Contributed papers table of contents

Pages: 127 - 134

Year of Publication: 2007

ISBN:978-1-59593-743-8

Authors

Dimitrios I. Diochnos	National University of Athens
Ioannis Z. Emiris	National University of Athens
Elias P. Tsigaridas	LORIA-INRIA Lorraine

Sponsors

ACM: Association for Computing Machinery
SIGSAM: ACM Special Interest Group on Symbolic and Algebraic Manipulation

Publisher

ACM New York, NY, USA

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Downloads (6 Weeks): 5, Downloads (12 Months): 26, Citation Count: 2

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ABSTRACT

We consider exact real solving of well-constrained, bivariate systems of relatively prime polynomials. The main problem is to compute all common real roots in isolating interval representation, and to determine their intersection multiplicities. We present three algorithms and analyze their asymptotic bit complexity, obtaining a bound of Õ_B(N¹⁴) for the purely projection-based method, and Õ_B(N¹²) for two subresultants-based methods: these ignore polylogarithmic factors, and N bounds the degree and the bitsize of the polynomials. The previous record bound was Õ_B(N¹⁴).

Our main tool is signed subresultant sequences, extended to several variables by binary segmentation. We exploit advances on the complexity of univariate root isolation, and extend them to multipoint sign evaluation, sign evaluation of bivariate polynomials over two algebraic numbers, and real root counting over an extension field. Our algorithms apply to the problem of simultaneous inequalities; they also compute the topology of real plane algebraic curves in.

All algorithms have been implemented in maple, in conjunction with numeric filtering. We compare them against fgb/rs and synaps; we also consider maple libraries insulate and top, which compute curve topology. Our software is among the most robust, and its runtimes are within a small constant factor, with respect to the C/C++ libraries.

REFERENCES

Note: OCR errors may be found in this Reference List extracted from the full text article. ACM has opted to expose the complete List rather than only correct and linked references.

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CITED BY 2

	Ioannis Z. Emiris , Elias P. Tsigaridas, Real algebraic numbers and polynomial systems of small degree, Theoretical Computer Science, v.409 n.2, p.186-199, December, 2008
	Eric Berberich , Michael Kerber , Michael Sagraloff, Exact geometric-topological analysis of algebraic surfaces, Proceedings of the twenty-fourth annual symposium on Computational geometry, June 09-11, 2008, College Park, MD, USA