System of polynomial equations

Last updated April 10, 2024

A system of polynomial equations (sometimes simply a polynomial system) is a set of simultaneous equations $f 1 = 0, ..., f h = 0$ where the $f i$ are polynomials in several variables, say $x 1, ..., x n$ , over some field $k$ .

Definition
Basic properties and definitions
What is solving?
Extensions
Trigonometric equations
Solutions in a finite field
Coefficients in a number field or in a finite field with non-prime order
Algebraic representation of the solutions
Regular chains
Rational univariate representation
Solving numerically
General solving algorithms
Homotopy continuation method
Numerically solving from the rational univariate representation
Software packages
See also
References

A solution of a polynomial system is a set of values for the $x i$ s which belong to some algebraically closed field extension $K$ of $k$ , and make all equations true. When $k$ is the field of rational numbers, $K$ is generally assumed to be the field of complex numbers, because each solution belongs to a field extension of $k$ , which is isomorphic to a subfield of the complex numbers.

This article is about the methods for solving, that is, finding all solutions or describing them. As these methods are designed for being implemented in a computer, emphasis is given on fields $k$ in which computation (including equality testing) is easy and efficient, that is the field of rational numbers and finite fields.

Searching for solutions that belong to a specific set is a problem which is generally much more difficult, and is outside the scope of this article, except for the case of the solutions in a given finite field. For the case of solutions of which all components are integers or rational numbers, see Diophantine equation.

Definition

The numerous singular points of the Barth sextic are the solutions of a polynomial system BarthSextic.png — The numerous singular points of the Barth sextic are the solutions of a polynomial system

A simple example of a system of polynomial equations is

{\begin{aligned}x^{2}+y^{2}-5&=0\\xy-2&=0.\end{aligned}}

Its solutions are the four pairs $(x, y) = (1, 2), (2, 1), (-1, -2), (-2, -1)$ . These solutions can easily be checked by substitution, but more work is needed for proving that there are no other solutions.

The subject of this article is the study of generalizations of such an examples, and the description of the methods that are used for computing the solutions.

A system of polynomial equations, or polynomial system is a collection of equations

{\begin{aligned}f_{1}\left(x_{1},\ldots ,x_{m}\right)&=0\\&\;\;\vdots \\f_{n}\left(x_{1},\ldots ,x_{m}\right)&=0,\end{aligned}}

where each $f h$ is a polynomial in the indeterminates $x 1, ..., x m$ , with integer coefficients, or coefficients in some fixed field, often the field of rational numbers or a finite field.^[1] Other fields of coefficients, such as the real numbers, are less often used, as their elements cannot be represented in a computer (only approximations of real numbers can be used in computations, and these approximations are always rational numbers).

A solution of a polynomial system is a tuple of values of $(x 1, ..., x m)$ that satisfies all equations of the polynomial system. The solutions are sought in the complex numbers, or more generally in an algebraically closed field containing the coefficients. In particular, in characteristic zero, all complex solutions are sought. Searching for the real or rational solutions are much more difficult problems that are not considered in this article.

The set of solutions is not always finite; for example, the solutions of the system

{\begin{aligned}x(x-1)&=0\\x(y-1)&=0\end{aligned}}

are a point $(x, y) = (1,1)$ and a line $x = 0$ .^[2] Even when the solution set is finite, there is, in general, no closed-form expression of the solutions (in the case of a single equation, this is Abel–Ruffini theorem).

The Barth surface, shown in the figure is the geometric representation of the solutions of a polynomial system reduced to a single equation of degree 6 in 3 variables. Some of its numerous singular points are visible on the image. They are the solutions of a system of 4 equations of degree 5 in 3 variables. Such an overdetermined system has no solution in general (that is if the coefficients are not specific). If it has a finite number of solutions, this number is at most $53 = 125$ , by Bézout's theorem. However, it has been shown that, for the case of the singular points of a surface of degree 6, the maximum number of solutions is 65, and is reached by the Barth surface.

Basic properties and definitions

A system is overdetermined if the number of equations is higher than the number of variables. A system is inconsistent if it has no complex solution (or, if the coefficients are not complex numbers, no solution in an algebraically closed field containing the coefficients). By Hilbert's Nullstellensatz this means that 1 is a linear combination (with polynomials as coefficients) of the first members of the equations. Most but not all overdetermined systems, when constructed with random coefficients, are inconsistent. For example, the system $x 3 - 1 = 0, x 2 - 1 = 0$ is overdetermined (having two equations but only one unknown), but it is not inconsistent since it has the solution $x = 1$ .

A system is underdetermined if the number of equations is lower than the number of the variables. An underdetermined system is either inconsistent or has infinitely many complex solutions (or solutions in an algebraically closed field that contains the coefficients of the equations). This is a non-trivial result of commutative algebra that involves, in particular, Hilbert's Nullstellensatz and Krull's principal ideal theorem.

A system is zero-dimensional if it has a finite number of complex solutions (or solutions in an algebraically closed field). This terminology comes from the fact that the algebraic variety of the solutions has dimension zero. A system with infinitely many solutions is said to be positive-dimensional.

A zero-dimensional system with as many equations as variables is sometimes said to be well-behaved.^[3] Bézout's theorem asserts that a well-behaved system whose equations have degrees $d 1, ..., d n$ has at most $d 1 \cdot\cdot\cdot d n$ solutions. This bound is sharp. If all the degrees are equal to $d$ , this bound becomes $d n$ and is exponential in the number of variables. (The fundamental theorem of algebra is the special case $n = 1$ .)

This exponential behavior makes solving polynomial systems difficult and explains why there are few solvers that are able to automatically solve systems with Bézout's bound higher than, say, 25 (three equations of degree 3 or five equations of degree 2 are beyond this bound).^{[ citation needed ]}

What is solving?

The first thing to do for solving a polynomial system is to decide whether it is inconsistent, zero-dimensional or positive dimensional. This may be done by the computation of a Gröbner basis of the left-hand sides of the equations. The system is inconsistent if this Gröbner basis is reduced to 1. The system is zero-dimensional if, for every variable there is a leading monomial of some element of the Gröbner basis which is a pure power of this variable. For this test, the best monomial order (that is the one which leads generally to the fastest computation) is usually the graded reverse lexicographic one (grevlex).

If the system is positive-dimensional, it has infinitely many solutions. It is thus not possible to enumerate them. It follows that, in this case, solving may only mean "finding a description of the solutions from which the relevant properties of the solutions are easy to extract". There is no commonly accepted such description. In fact there are many different "relevant properties", which involve almost every subfield of algebraic geometry.

A natural example of such a question concerning positive-dimensional systems is the following: decide if a polynomial system over the rational numbers has a finite number of real solutions and compute them. A generalization of this question is find at least one solution in each connected component of the set of real solutions of a polynomial system. The classical algorithm for solving these question is cylindrical algebraic decomposition, which has a doubly exponential computational complexity and therefore cannot be used in practice, except for very small examples.

For zero-dimensional systems, solving consists of computing all the solutions. There are two different ways of outputting the solutions. The most common way is possible only for real or complex solutions, and consists of outputting numeric approximations of the solutions. Such a solution is called numeric. A solution is certified if it is provided with a bound on the error of the approximations, and if this bound separates the different solutions.

The other way of representing the solutions is said to be algebraic. It uses the fact that, for a zero-dimensional system, the solutions belong to the algebraic closure of the field k of the coefficients of the system. There are several ways to represent the solution in an algebraic closure, which are discussed below. All of them allow one to compute a numerical approximation of the solutions by solving one or several univariate equations. For this computation, it is preferable to use a representation that involves solving only one univariate polynomial per solution, because computing the roots of a polynomial which has approximate coefficients is a highly unstable problem.

Extensions

Trigonometric equations

A trigonometric equation is an equation $g = 0$ where $g$ is a trigonometric polynomial. Such an equation may be converted into a polynomial system by expanding the sines and cosines in it (using sum and difference formulas), replacing $sin(x)$ and $cos(x)$ by two new variables $s$ and $c$ and adding the new equation $s 2 + c 2 - 1 = 0$ .

For example, because of the identity

\cos(3x)=4\cos ^{3}(x)-3\cos(x),

solving the equation

\sin ^{3}(x)+\cos(3x)=0

is equivalent to solving the polynomial system

{\begin{cases}s^{3}+4c^{3}-3c&=0\\s^{2}+c^{2}-1&=0.\end{cases}}

For each solution $(c 0, s 0)$ of this system, there is a unique solution $x$ of the equation such that $0 \leq x < 2 π$ .

In the case of this simple example, it may be unclear whether the system is, or not, easier to solve than the equation. On more complicated examples, one lacks systematic methods for solving directly the equation, while software are available for automatically solving the corresponding system.

Solutions in a finite field

When solving a system over a finite field $k$ with $q$ elements, one is primarily interested in the solutions in $k$ . As the elements of $k$ are exactly the solutions of the equation $x q - x = 0$ , it suffices, for restricting the solutions to $k$ , to add the equation $x i q - x i = 0$ for each variable $x i$ .

Coefficients in a number field or in a finite field with non-prime order

The elements of an algebraic number field are usually represented as polynomials in a generator of the field which satisfies some univariate polynomial equation. To work with a polynomial system whose coefficients belong to a number field, it suffices to consider this generator as a new variable and to add the equation of the generator to the equations of the system. Thus solving a polynomial system over a number field is reduced to solving another system over the rational numbers.

For example, if a system contains ${\sqrt {2}}$ , a system over the rational numbers is obtained by adding the equation $r 22 - 2 = 0$ and replacing ${\sqrt {2}}$ by $r 2$ in the other equations.

In the case of a finite field, the same transformation allows always supposing that the field $k$ has a prime order.

Algebraic representation of the solutions

Regular chains

The usual way of representing the solutions is through zero-dimensional regular chains. Such a chain consists of a sequence of polynomials $f 1 (x 1)$ , $f 2 (x 1, x 2)$ , ..., $f n (x 1, ..., x n)$ such that, for every $i$ such that $1 \leq i \leq n$

$f i$ is a polynomial in $x 1, ..., x i$ only, which has a degree $d i > 0$ in $x i$ ;
the coefficient of $x i d i$ in $f i$ is a polynomial in $x 1, ..., x i -1$ which does not have any common zero with $f 1$ , ..., $f i - 1$ .

To such a regular chain is associated a triangular system of equations

{\begin{cases}f_{1}(x_{1})=0\\f_{2}(x_{1},x_{2})=0\\\quad \vdots \\f_{n}(x_{1},x_{2},\ldots ,x_{n})=0.\end{cases}}

The solutions of this system are obtained by solving the first univariate equation, substituting the solutions in the other equations, then solving the second equation which is now univariate, and so on. The definition of regular chains implies that the univariate equation obtained from $f i$ has degree $d i$ and thus that the system has $d 1 ... d n$ solutions, provided that there is no multiple root in this resolution process (fundamental theorem of algebra).

Every zero-dimensional system of polynomial equations is equivalent (i.e. has the same solutions) to a finite number of regular chains. Several regular chains may be needed, as it is the case for the following system which has three solutions.

{\begin{cases}x^{2}-1=0\\(x-1)(y-1)=0\\y^{2}-1=0.\end{cases}}

There are several algorithms for computing a triangular decomposition of an arbitrary polynomial system (not necessarily zero-dimensional)^[4] into regular chains (or regular semi-algebraic systems).

There is also an algorithm which is specific to the zero-dimensional case and is competitive, in this case, with the direct algorithms. It consists in computing first the Gröbner basis for the graded reverse lexicographic order (grevlex), then deducing the lexicographical Gröbner basis by FGLM algorithm^[5] and finally applying the Lextriangular algorithm.^[6]

This representation of the solutions are fully convenient for coefficients in a finite field. However, for rational coefficients, two aspects have to be taken care of:

The output may involve huge integers which may make the computation and the use of the result problematic.
To deduce the numeric values of the solutions from the output, one has to solve univariate polynomials with approximate coefficients, which is a highly unstable problem.

The first issue has been solved by Dahan and Schost:^[7]^[8] Among the sets of regular chains that represent a given set of solutions, there is a set for which the coefficients are explicitly bounded in terms of the size of the input system, with a nearly optimal bound. This set, called equiprojectable decomposition, depends only on the choice of the coordinates. This allows the use of modular methods for computing efficiently the equiprojectable decomposition.^[9]

The second issue is generally solved by outputting regular chains of a special form, sometimes called shape lemma, for which all $d i$ but the first one are equal to $1$ . For getting such regular chains, one may have to add a further variable, called separating variable, which is given the index $0$ . The rational univariate representation, described below, allows computing such a special regular chain, satisfying Dahan–Schost bound, by starting from either a regular chain or a Gröbner basis.

Rational univariate representation

The rational univariate representation or RUR is a representation of the solutions of a zero-dimensional polynomial system over the rational numbers which has been introduced by F. Rouillier.^[10]

A RUR of a zero-dimensional system consists in a linear combination $x 0$ of the variables, called separating variable, and a system of equations^[11]

{\begin{cases}h(x_{0})=0\\x_{1}=g_{1}(x_{0})/g_{0}(x_{0})\\\quad \vdots \\x_{n}=g_{n}(x_{0})/g_{0}(x_{0}),\end{cases}}

where $h$ is a univariate polynomial in $x 0$ of degree $D$ and $g 0, ..., g n$ are univariate polynomials in $x 0$ of degree less than $D$ .

Given a zero-dimensional polynomial system over the rational numbers, the RUR has the following properties.

All but a finite number linear combinations of the variables are separating variables.
When the separating variable is chosen, the RUR exists and is unique. In particular $h$ and the $g i$ are defined independently of any algorithm to compute them.
The solutions of the system are in one-to-one correspondence with the roots of $h$ and the multiplicity of each root of $h$ equals the multiplicity of the corresponding solution.
The solutions of the system are obtained by substituting the roots of $h$ in the other equations.
If $h$ does not have any multiple root then $g 0$ is the derivative of $h$ .

For example, for the system in the previous section, every linear combination of the variable, except the multiples of $x$ , $y$ and $x + y$ , is a separating variable. If one chooses $t = .mw-parser-output .sfrac{white-space:nowrap}.mw-parser-output .sfrac.tion,.mw-parser-output .sfrac .tion{display:inline-block;vertical-align:-0.5em;font-size:85%;text-align:center}.mw-parser-output .sfrac .num{display:block;line-height:1em;margin:0.0em 0.1em;border-bottom:1px solid}.mw-parser-output .sfrac .den{display:block;line-height:1em;margin:0.1em 0.1em}.mw-parser-output .sr-only{border:0;clip:rect(0,0,0,0);clip-path:polygon(0px 0px,0px 0px,0px 0px);height:1px;margin:-1px;overflow:hidden;padding:0;position:absolute;width:1px}x – y/2$ as a separating variable, then the RUR is

{\begin{cases}t^{3}-t=0\\x={\frac {t^{2}+2t-1}{3t^{2}-1}}\\y={\frac {t^{2}-2t-1}{3t^{2}-1}}.\\\end{cases}}

The RUR is uniquely defined for a given separating variable, independently of any algorithm, and it preserves the multiplicities of the roots. This is a notable difference with triangular decompositions (even the equiprojectable decomposition), which, in general, do not preserve multiplicities. The RUR shares with equiprojectable decomposition the property of producing an output with coefficients of relatively small size.

For zero-dimensional systems, the RUR allows retrieval of the numeric values of the solutions by solving a single univariate polynomial and substituting them in rational functions. This allows production of certified approximations of the solutions to any given precision.

Moreover, the univariate polynomial $h (x 0)$ of the RUR may be factorized, and this gives a RUR for every irreducible factor. This provides the prime decomposition of the given ideal (that is the primary decomposition of the radical of the ideal). In practice, this provides an output with much smaller coefficients, especially in the case of systems with high multiplicities.

Contrarily to triangular decompositions and equiprojectable decompositions, the RUR is not defined in positive dimension.

Solving numerically

General solving algorithms

The general numerical algorithms which are designed for any system of nonlinear equations work also for polynomial systems. However the specific methods will generally be preferred, as the general methods generally do not allow one to find all solutions. In particular, when a general method does not find any solution, this is usually not an indication that there is no solution.

Nevertheless, two methods deserve to be mentioned here.

Newton's method may be used if the number of equations is equal to the number of variables. It does not allow one to find all the solutions nor to prove that there is no solution. But it is very fast when starting from a point which is close to a solution. Therefore, it is a basic tool for the homotopy continuation method described below.
Optimization is rarely used for solving polynomial systems, but it succeeded, circa 1970, in showing that a system of 81 quadratic equations in 56 variables is not inconsistent.^[12] With the other known methods, this remains beyond the possibilities of modern technology, as of 2022^[update]. This method consists simply in minimizing the sum of the squares of the equations. If zero is found as a local minimum, then it is attained at a solution. This method works for overdetermined systems, but outputs an empty information if all local minimums which are found are positive.

Homotopy continuation method

This is a semi-numeric method which supposes that the number of equations is equal to the number of variables. This method is relatively old but it has been dramatically improved in the last decades.^[13]

This method divides into three steps. First an upper bound on the number of solutions is computed. This bound has to be as sharp as possible. Therefore, it is computed by, at least, four different methods and the best value, say $N$ , is kept.

In the second step, a system $g_{1}=0,\,\ldots ,\,g_{n}=0$ of polynomial equations is generated which has exactly $N$ solutions that are easy to compute. This new system has the same number $n$ of variables and the same number $n$ of equations and the same general structure as the system to solve, $f_{1}=0,\,\ldots ,\,f_{n}=0$ .

Then a homotopy between the two systems is considered. It consists, for example, of the straight line between the two systems, but other paths may be considered, in particular to avoid some singularities, in the system

(1-t)g_{1}+tf_{1}=0,\,\ldots ,\,(1-t)g_{n}+tf_{n}=0

.

The homotopy continuation consists in deforming the parameter $t$ from 0 to 1 and following the $N$ solutions during this deformation. This gives the desired solutions for $t=1$ . Following means that, if $t_{1}<t_{2}$ , the solutions for $t=t_{2}$ are deduced from the solutions for $t=t_{1}$ by Newton's method. The difficulty here is to well choose the value of $t_{2}-t_{1}:$ Too large, Newton's convergence may be slow and may even jump from a solution path to another one. Too small, and the number of steps slows down the method.

Numerically solving from the rational univariate representation

To deduce the numeric values of the solutions from a RUR seems easy: it suffices to compute the roots of the univariate polynomial and to substitute them in the other equations. This is not so easy because the evaluation of a polynomial at the roots of another polynomial is highly unstable.

The roots of the univariate polynomial have thus to be computed at a high precision which may not be defined once for all. There are two algorithms which fulfill this requirement.

Aberth method, implemented in MPSolve computes all the complex roots to any precision.
Uspensky's algorithm of Collins and Akritas,^[14] improved by Rouillier and Zimmermann ^[15] and based on Descartes' rule of signs. This algorithms computes the real roots, isolated in intervals of arbitrary small width. It is implemented in Maple (functions fsolve and RootFinding[Isolate]).

Software packages

There are at least four software packages which can solve zero-dimensional systems automatically (by automatically, one means that no human intervention is needed between input and output, and thus that no knowledge of the method by the user is needed). There are also several other software packages which may be useful for solving zero-dimensional systems. Some of them are listed after the automatic solvers.

The Maple function RootFinding[Isolate] takes as input any polynomial system over the rational numbers (if some coefficients are floating point numbers, they are converted to rational numbers) and outputs the real solutions represented either (optionally) as intervals of rational numbers or as floating point approximations of arbitrary precision. If the system is not zero dimensional, this is signaled as an error.

Internally, this solver, designed by F. Rouillier computes first a Gröbner basis and then a Rational Univariate Representation from which the required approximation of the solutions are deduced. It works routinely for systems having up to a few hundred complex solutions.

The rational univariate representation may be computed with Maple function Groebner[RationalUnivariateRepresentation].

To extract all the complex solutions from a rational univariate representation, one may use MPSolve, which computes the complex roots of univariate polynomials to any precision. It is recommended to run MPSolve several times, doubling the precision each time, until solutions remain stable, as the substitution of the roots in the equations of the input variables can be highly unstable.

The second solver is PHCpack,^[13]^[16] written under the direction of J. Verschelde. PHCpack implements the homotopy continuation method. This solver computes the isolated complex solutions of polynomial systems having as many equations as variables.

The third solver is Bertini,^[17]^[18] written by D. J. Bates, J. D. Hauenstein, A. J. Sommese, and C. W. Wampler. Bertini uses numerical homotopy continuation with adaptive precision. In addition to computing zero-dimensional solution sets, both PHCpack and Bertini are capable of working with positive dimensional solution sets.

The fourth solver is the Maple library RegularChains, written by Marc Moreno-Maza and collaborators. It contains various functions for solving polynomial systems by means of regular chains.

Related Research Articles

Algebraic geometry is a branch of mathematics which uses abstract algebraic techniques, mainly from commutative algebra, to solve geometrical problems. Classically, it studies zeros of multivariate polynomials; the modern approach generalizes this in a few different aspects.

<span class="mw-page-title-main">Diophantine equation</span> Polynomial equation whose integer solutions are sought

In mathematics, a Diophantine equation is an equation, typically a polynomial equation in two or more unknowns with integer coefficients, for which only integer solutions are of interest. A linear Diophantine equation equates to a constant the sum of two or more monomials, each of degree one. An exponential Diophantine equation is one in which unknowns can appear in exponents.

In mathematics, an equation is a mathematical formula that expresses the equality of two expressions, by connecting them with the equals sign =. The word equation and its cognates in other languages may have subtly different meanings; for example, in French an équation is defined as containing one or more variables, while in English, any well-formed formula consisting of two expressions related with an equals sign is an equation.

In mathematics, a polynomial is a mathematical expression consisting of indeterminates and coefficients, that involves only the operations of addition, subtraction, multiplication, and positive-integer powers of variables. An example of a polynomial of a single indeterminate $x$ is $x 2 - 4 x + 7$ . An example with three indeterminates is $x 3 + 2 xyz 2 - yz + 1$ .

Hilbert's tenth problem is the tenth on the list of mathematical problems that the German mathematician David Hilbert posed in 1900. It is the challenge to provide a general algorithm that, for any given Diophantine equation, can decide whether the equation has a solution with all unknowns taking integer values.

In mathematics, a system of linear equations is a collection of one or more linear equations involving the same variables. For example,

In mathematics, an irreducible polynomial is, roughly speaking, a polynomial that cannot be factored into the product of two non-constant polynomials. The property of irreducibility depends on the nature of the coefficients that are accepted for the possible factors, that is, the field to which the coefficients of the polynomial and its possible factors are supposed to belong. For example, the polynomial $x 2 - 2$ is a polynomial with integer coefficients, but, as every integer is also a real number, it is also a polynomial with real coefficients. It is irreducible if it is considered as a polynomial with integer coefficients, but it factors as $if it is considered as a polynomial with real coefficients. One says that the polynomial x 2 - 2 is irreducible over the integers but not over the reals.$

In mathematics and specifically in algebraic geometry, the dimension of an algebraic variety may be defined in various equivalent ways.

In mathematics, an affine algebraic plane curve is the zero set of a polynomial in two variables. A projective algebraic plane curve is the zero set in a projective plane of a homogeneous polynomial in three variables. An affine algebraic plane curve can be completed in a projective algebraic plane curve by homogenizing its defining polynomial. Conversely, a projective algebraic plane curve of homogeneous equation $h (x, y, t) = 0$ can be restricted to the affine algebraic plane curve of equation $h (x, y, 1) = 0$ . These two operations are each inverse to the other; therefore, the phrase algebraic plane curve is often used without specifying explicitly whether it is the affine or the projective case that is considered.

In mathematics, and more specifically in computer algebra, computational algebraic geometry, and computational commutative algebra, a Gröbner basis is a particular kind of generating set of an ideal in a polynomial ring $K [x 1, ..., x n]$ over a field $K$ . A Gröbner basis allows many important properties of the ideal and the associated algebraic variety to be deduced easily, such as the dimension and the number of zeros when it is finite. Gröbner basis computation is one of the main practical tools for solving systems of polynomial equations and computing the images of algebraic varieties under projections or rational maps.

In mathematics, especially in the field of algebra, a polynomial ring or polynomial algebra is a ring formed from the set of polynomials in one or more indeterminates with coefficients in another ring, often a field.

In mathematics, an algebraic equation or polynomial equation is an equation of the form $, where P is a polynomial with coefficients in some field, often the field of the rational numbers. For example, is an algebraic equation with integer coefficients and$

In mathematics, to solve an equation is to find its solutions, which are the values that fulfill the condition stated by the equation, consisting generally of two expressions related by an equals sign. When seeking a solution, one or more variables are designated as unknowns. A solution is an assignment of values to the unknown variables that makes the equality in the equation true. In other words, a solution is a value or a collection of values such that, when substituted for the unknowns, the equation becomes an equality. A solution of an equation is often called a root of the equation, particularly but not only for polynomial equations. The set of all solutions of an equation is its solution set.

In mathematics, the resultant of two polynomials is a polynomial expression of their coefficients that is equal to zero if and only if the polynomials have a common root, or, equivalently, a common factor. In some older texts, the resultant is also called the eliminant.

In mathematics and computer algebra, factorization of polynomials or polynomial factorization expresses a polynomial with coefficients in a given field or in the integers as the product of irreducible factors with coefficients in the same domain. Polynomial factorization is one of the fundamental components of computer algebra systems.

In algebra, the greatest common divisor of two polynomials is a polynomial, of the highest possible degree, that is a factor of both the two original polynomials. This concept is analogous to the greatest common divisor of two integers.

Wenjun Wu's method is an algorithm for solving multivariate polynomial equations introduced in the late 1970s by the Chinese mathematician Wen-Tsun Wu. This method is based on the mathematical concept of characteristic set introduced in the late 1940s by J.F. Ritt. It is fully independent of the Gröbner basis method, introduced by Bruno Buchberger (1965), even if Gröbner bases may be used to compute characteristic sets.

In mathematics, and more specifically in computer algebra and elimination theory, a regular chain is a particular kind of triangular set of multivariate polynomials over a field, where a triangular set is a finite sequence of polynomials such that each one contains at least one more indeterminate than the preceding one. The condition that a triangular set must satisfy to be a regular chain is that, for every $k$ , every common zero (in an algebraically closed field) of the $k$ first polynomials may be prolongated to a common zero of the $(k + 1)$ th polynomial. In other words, regular chains allow solving systems of polynomial equations by solving successive univariate equations without considering different cases.

In computer algebra, a triangular decomposition of a polynomial system $S$ is a set of simpler polynomial systems $S 1, ..., S e$ such that a point is a solution of $S$ if and only if it is a solution of one of the systems $S 1, ..., S e$ .

In algebra, linear equations and systems of linear equations over a field are widely studied. "Over a field" means that the coefficients of the equations and the solutions that one is looking for belong to a given field, commonly the real or the complex numbers. This article is devoted to the same problems where "field" is replaced by "commutative ring", or, typically "Noetherian integral domain".

References

↑ Bates et al. 2013 , p. 4
↑ Bates et al. 2013 , p. 8
↑ Songxin Liang, J. Gerhard, D.J. Jeffrey, G. Moroz, A Package for Solving Parametric Polynomial Systems . Communications in Computer Algebra (2009)
↑ Aubry, P.; Maza, M. Moreno (1999). "Triangular Sets for Solving Polynomial Systems: a Comparative Implementation of Four Methods". J. Symb. Comput. 28 (1–2): 125–154. doi: 10.1006/jsco.1999.0270 .
↑ Faugère, J.C.; Gianni, P.; Lazard, D.; Mora, T. (1993). "Efficient Computation of Zero-Dimensional Gröbner Basis by Change of Ordering". Journal of Symbolic Computation. 16 (4): 329–344. doi: 10.1006/jsco.1993.1051 .
↑ Lazard, D. (1992). "Solving zero-dimensional algebraic systems". Journal of Symbolic Computation. 13 (2): 117–131. doi:10.1016/S0747-7171(08)80086-7.
↑ Xavier Dahan and Eric Schost. Sharp Estimates for Triangular Sets . Moreover, recent algorithms for decomposing polynomial systems into triangular decompositions produce regular chains with coefficients matching the results of Dahan and Schost. In proc. ISSAC'04, pages 103--110, ACM Press, 2004
↑ Dahan, Xavier; Moreno Maza, Marc; Schost, Eric; Wu, Wenyuan; Xie, Yuzhen (2005). "Lifting techniques for triangular decompositions" (PDF). Proceedings of ISAAC 2005. ACM Press. pp. 108–105.
↑ Changbo Chen and Marc Moreno-Maza. Algorithms for Computing Triangular Decomposition of Polynomial Systems .In proc. ISSAC'2011, pages 83-90, ACM Press, 2011 and Journal of Symbolic Computation (to appear)
↑ Rouillier, Fabrice (1999). "Solving Zero-Dimensional Systems Through the Rational Univariate Representation". Appl. Algebra Eng. Commun. Comput. 9 (9): 433–461. doi:10.1007/s002000050114. S2CID 25579305.
↑ Saugata Basu; Richard Pollack; Marie-Françoise Roy (2006). Algorithms in real algebraic geometry, chapter 12.4. Springer-Verlag.
↑ Lazard, Daniel (2009). "Thirty years of Polynomial System Solving, and now?". J. Symb. Comput. 44 (3): 2009. doi: 10.1016/j.jsc.2008.03.004 .
1 2 Verschelde, Jan (1999). "Algorithm 795: PHCpack: A general-purpose solver for polynomial systems by homotopy continuation" (PDF). ACM Transactions on Mathematical Software. 25 (2): 251–276. doi:10.1145/317275.317286. S2CID 15485257.
↑ George E. Collins and Alkiviadis G. Akritas, Polynomial Real Root Isolation Using Descartes' Rule of Signs . Proceedings of the 1976 ACM Symposium on Symbolic and Algebraic Computation
↑ Rouillier, F.; Zimmerman, P. (2004). "Efficient isolation of polynomial's real roots". Journal of Computational and Applied Mathematics. 162 (1): 33–50. Bibcode:2004JCoAM.162...33R. doi: 10.1016/j.cam.2003.08.015 .
↑ Release 2.3.86 of PHCpack
↑ Bates et al. 2013
↑ Bertini: Software for Numerical Algebraic Geometry

Bates, Daniel J.; Sommese, Andrew J.; Hauenstein, Jonathan D.; Wampler, Charles W. (2013). Numerically solving polynomial systems with Bertini. Philadelphia: Society for Industrial and Applied Mathematics. ISBN 978-1-61197-269-6.
Cox, David; Little, John; O'Shea, Donal (1997). Ideals, varieties, and algorithms : an introduction to computational algebraic geometry and commutative algebra (2nd ed.). New York: Springer. ISBN 978-0387946801.
Morgan, Alexander (1987). Solving polynomial systems using continuation for engineering and scientific problems (SIAM ed.). Society for Industrial and Applied Mathematics (SIAM, 3600 Market Street, Floor 6, Philadelphia, PA 19104). ISBN 9780898719031.
Sturmfels, Bernd (2002). Solving systems of polynomial equations. Providence, RI: American Mathematical Soc. ISBN 0821832514.

This page is based on this Wikipedia article
Text is available under the CC BY-SA 4.0 license; additional terms may apply.
Images, videos and audio are available under their respective licenses.

[Bates_p4-1] Bates et al. 2013 , p. 4

[2] Bates et al. 2013 , p. 8

[3] Songxin Liang, J. Gerhard, D.J. Jeffrey, G. Moroz, A Package for Solving Parametric Polynomial Systems . Communications in Computer Algebra (2009)

[4] Aubry, P.; Maza, M. Moreno (1999). "Triangular Sets for Solving Polynomial Systems: a Comparative Implementation of Four Methods". J. Symb. Comput. 28 (1–2): 125–154. doi: 10.1006/jsco.1999.0270 .

[5] Faugère, J.C.; Gianni, P.; Lazard, D.; Mora, T. (1993). "Efficient Computation of Zero-Dimensional Gröbner Basis by Change of Ordering". Journal of Symbolic Computation. 16 (4): 329–344. doi: 10.1006/jsco.1993.1051 .

[6] Lazard, D. (1992). "Solving zero-dimensional algebraic systems". Journal of Symbolic Computation. 13 (2): 117–131. doi:10.1016/S0747-7171(08)80086-7.

[7] Xavier Dahan and Eric Schost. Sharp Estimates for Triangular Sets . Moreover, recent algorithms for decomposing polynomial systems into triangular decompositions produce regular chains with coefficients matching the results of Dahan and Schost. In proc. ISSAC'04, pages 103--110, ACM Press, 2004

[8] Dahan, Xavier; Moreno Maza, Marc; Schost, Eric; Wu, Wenyuan; Xie, Yuzhen (2005). "Lifting techniques for triangular decompositions" (PDF). Proceedings of ISAAC 2005. ACM Press. pp. 108–105.

[9] Changbo Chen and Marc Moreno-Maza. Algorithms for Computing Triangular Decomposition of Polynomial Systems .In proc. ISSAC'2011, pages 83-90, ACM Press, 2011 and Journal of Symbolic Computation (to appear)

[10] Rouillier, Fabrice (1999). "Solving Zero-Dimensional Systems Through the Rational Univariate Representation". Appl. Algebra Eng. Commun. Comput. 9 (9): 433–461. doi:10.1007/s002000050114. S2CID 25579305.

[11] Saugata Basu; Richard Pollack; Marie-Françoise Roy (2006). Algorithms in real algebraic geometry, chapter 12.4. Springer-Verlag.

[12] Lazard, Daniel (2009). "Thirty years of Polynomial System Solving, and now?". J. Symb. Comput. 44 (3): 2009. doi: 10.1016/j.jsc.2008.03.004 .

[Vers99-13] 1 2 Verschelde, Jan (1999). "Algorithm 795: PHCpack: A general-purpose solver for polynomial systems by homotopy continuation" (PDF). ACM Transactions on Mathematical Software. 25 (2): 251–276. doi:10.1145/317275.317286. S2CID 15485257.

[14] George E. Collins and Alkiviadis G. Akritas, Polynomial Real Root Isolation Using Descartes' Rule of Signs . Proceedings of the 1976 ACM Symposium on Symbolic and Algebraic Computation

[15] Rouillier, F.; Zimmerman, P. (2004). "Efficient isolation of polynomial's real roots". Journal of Computational and Applied Mathematics. 162 (1): 33–50. Bibcode:2004JCoAM.162...33R. doi: 10.1016/j.cam.2003.08.015 .

[16] Release 2.3.86 of PHCpack

[17] Bates et al. 2013

[18] Bertini: Software for Numerical Algebraic Geometry

[1]

[2]

[3]

[4]

[5]

[6]

[7]

[8]

[9]

[10]

[11]

[12]

[13]

[14]

[15]

[16]

[17]

[18]