Regression for sets of polynomial equations

Franz J. Király; Paul Von Bünau; Jan S. Müller; Duncan A J Blythe; Frank C. Meinecke; Klaus Muller

Regression for sets of polynomial equations

Franz J. Király, Paul Von Bünau, Jan S. Müller, Duncan A J Blythe, Frank C. Meinecke, Klaus Muller

Research output: Contribution to journal › Article › peer-review

Abstract

We propose a method called ideal regression for approximating an arbitrary system of polynomial equations by a system of a particular type. Using techniques from approximate computational algebraic geometry, we show how we can solve ideal regression directly without resorting to numerical optimization. Ideal regression is useful whenever the solution to a learning problem can be described by a system of polynomial equations. As an example, we demonstrate how to formulate Stationary Subspace Analysis (SSA), a source separation problem, in terms of ideal regression, which also yields a consistent estimator for SSA. We then compare this estimator in simulations with previous optimization-based approaches for SSA.

Original language	English
Pages (from-to)	628-637
Number of pages	10
Journal	Journal of Machine Learning Research
Volume	22
Publication status	Published - 2012
Externally published	Yes

ASJC Scopus subject areas

Artificial Intelligence
Software
Control and Systems Engineering
Statistics and Probability

Cite this

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abstract = "We propose a method called ideal regression for approximating an arbitrary system of polynomial equations by a system of a particular type. Using techniques from approximate computational algebraic geometry, we show how we can solve ideal regression directly without resorting to numerical optimization. Ideal regression is useful whenever the solution to a learning problem can be described by a system of polynomial equations. As an example, we demonstrate how to formulate Stationary Subspace Analysis (SSA), a source separation problem, in terms of ideal regression, which also yields a consistent estimator for SSA. We then compare this estimator in simulations with previous optimization-based approaches for SSA.",

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AU - Király, Franz J.

AU - Von Bünau, Paul

AU - Müller, Jan S.

AU - Blythe, Duncan A J

AU - Meinecke, Frank C.

AU - Muller, Klaus

PY - 2012

Y1 - 2012

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AB - We propose a method called ideal regression for approximating an arbitrary system of polynomial equations by a system of a particular type. Using techniques from approximate computational algebraic geometry, we show how we can solve ideal regression directly without resorting to numerical optimization. Ideal regression is useful whenever the solution to a learning problem can be described by a system of polynomial equations. As an example, we demonstrate how to formulate Stationary Subspace Analysis (SSA), a source separation problem, in terms of ideal regression, which also yields a consistent estimator for SSA. We then compare this estimator in simulations with previous optimization-based approaches for SSA.

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Regression for sets of polynomial equations

Abstract

ASJC Scopus subject areas

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