Regular semi-algebraic system

In computer algebra, a regular semi-algebraic system is a particular kind of triangular system of multivariate polynomials over a real closed field.

Introduction[edit]

Regular chains and triangular decompositions are fundamental and well-developed tools for describing the complex solutions of polynomial systems. The notion of a regular semi-algebraic system is an adaptation of the concept of a regular chain focusing on solutions of the real analogue: semi-algebraic systems.

Any semi-algebraic system $S$ can be decomposed into finitely many regular semi-algebraic systems $S_{1},\ldots ,S_{e}$ such that a point (with real coordinates) is a solution of $S$ if and only if it is a solution of one of the systems $S_{1},\ldots ,S_{e}$ .^[1]

Formal definition[edit]

Let $T$ be a regular chain of $\mathbf {k} [x_{1},\ldots ,x_{n}]$ for some ordering of the variables $\mathbf {x} =x_{1},\ldots ,x_{n}$ and a real closed field $\mathbf {k}$ . Let $\mathbf {u} =u_{1},\ldots ,u_{d}$ and $\mathbf {y} =y_{1},\ldots ,y_{n-d}$ designate respectively the variables of $\mathbf {x}$ that are free and algebraic with respect to $T$ . Let $P\subset \mathbf {k} [\mathbf {x} ]$ be finite such that each polynomial in $P$ is regular with respect to the saturated ideal of $T$ . Define $P_{>}:=\{p>0\mid p\in P\}$ . Let ${\mathcal {Q}}$ be a quantifier-free formula of $\mathbf {k} [\mathbf {x} ]$ involving only the variables of $\mathbf {u}$ . We say that $R:=[{\mathcal {Q}},T,P_{>}]$ is a regular semi-algebraic system if the following three conditions hold.

${\mathcal {Q}}$ defines a non-empty open semi-algebraic set $S$ of $\mathbf {k} ^{d}$ ,
the regular system $[T,P]$ specializes well at every point $u$ of $S$ ,
at each point $u$ of $S$ , the specialized system $[T(u),P(u)_{>}]$ has at least one real zero.

The zero set of $R$ , denoted by $Z_{\mathbf {k} }(R)$ , is defined as the set of points $(u,y)\in \mathbf {k} ^{d}\times \mathbf {k} ^{n-d}$ such that ${\mathcal {Q}}(u)$ is true and $t(u,y)=0,p(u,y)>0$ , for all $t\in T$ and all $p\in P$ . Observe that $Z_{\mathbf {k} }(R)$ has dimension $d$ in the affine space $\mathbf {k} ^{n}$ .

References[edit]

^ Changbo Chen, James H. Davenport, John P. May, Marc Moreno-Maza, Bican Xia, Rong Xiao. Triangular decomposition of semi-algebraic systems. Proceedings of 2010 International Symposium on Symbolic and Algebraic Computation (ISSAC 2010), ACM Press, pp. 187–194, 2010.

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[1] Changbo Chen, James H. Davenport, John P. May, Marc Moreno-Maza, Bican Xia, Rong Xiao. Triangular decomposition of semi-algebraic systems. Proceedings of 2010 International Symposium on Symbolic and Algebraic Computation (ISSAC 2010), ACM Press, pp. 187–194, 2010.

[1]

Introduction[edit]

Formal definition[edit]

See also[edit]

References[edit]