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{{Short description|Algorithm for computing Gröbner bases}}
In the theory of [[multivariate polynomial]]s, '''Buchberger's algorithm''' is a method for transforming a given set of polynomials into a [[Gröbner basis]], which is another set of polynomials that have the same common zeros and are more convenient for extracting information on these common zeros. It was introduced by [[Bruno Buchberger]] simultaneously with the definition of Gröbner bases.
The [[Euclidean algorithm]] for computing the polynomial [[
For other Gröbner basis algorithms, see {{slink|Gröbner basis#Algorithms and implementations}}.
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:'''Output''' A [[Gröbner basis]] ''G'' for {{mvar|I}}
:# ''G'' := ''F''
:# For every ''f<sub>i</sub>'', ''f<sub>j</sub>'' in ''G'', denote by ''g<sub>i</sub>'' the leading term of ''f<sub>i</sub>'' with respect to the given [[monomial ordering]], and by ''a<sub>ij</sub>'' the [[least common multiple]] of ''g<sub>i</sub>'' and ''g<sub>j</sub>''.
:# Choose two polynomials in ''G'' and let {{math|1=''S''<sub>''ij''</sub> = {{sfrac|''a''<sub>''ij''</sub> | ''g''<sub>{{var|i}}</sub>}} ''f''<sub>{{var|i}}</sub> − {{sfrac|''a''<sub>''ij''</sub> | ''g''<sub>''j''</sub>}} ''f''<sub>''j''</sub>}} ''(Note that the leading terms here will cancel by construction)''.
:# Reduce ''S''<sub>''ij''</sub>, with the [[multivariate division algorithm]] relative to the set ''G'' until the result is not further reducible. If the result is non-zero, add it to ''G''.
:# Repeat steps
:# Output ''G''
The polynomial ''S''<sub>''ij''</sub> is commonly referred to as the ''S''-polynomial, where ''S'' refers to ''subtraction'' (Buchberger) or ''[[Syzygy (mathematics)|
There are numerous ways to improve this algorithm beyond what has been stated above. For example, one could reduce all the new elements of ''F'' relative to each other before adding them. If the leading terms of ''f<sub>i</sub>'' and ''f<sub>j</sub>'' share no variables in common, then ''S<sub>ij</sub>'' will ''always'' reduce to 0 (if we use only {{mvar|f<sub>i</sub>}} and {{mvar|f<sub>j</sub>}} for reduction), so we needn't calculate it at all.
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== Complexity ==
The [[time complexity|computational complexity]] of Buchberger's algorithm is very difficult to estimate, because of the number of choices that may dramatically change the computation time. Nevertheless, T. W. Dubé has proved<ref>{{cite journal|doi=10.1137/0219053|title=The Structure of Polynomial Ideals and Gröbner Bases|journal=SIAM Journal on Computing|volume=19|issue=4|pages=
:<math>2\left(\frac{d^2}{2} +d\right)^{2^{n-2}}</math>,
where {{math|''n''}} is the number of variables, and {{math|''d''}} the maximal [[total degree]] of the input polynomials. This allows, in theory, to use [[linear algebra]] over the [[vector space]] of the polynomials of degree bounded by this value, for getting an algorithm of complexity
<math>d^{2^{n+o(1)}}</math>.
On the other hand, there are examples<ref>{{cite journal|doi=10.1016/0001-8708(82)90048-2|doi-access=free|title=The complexity of the word problems for commutative semigroups and polynomial ideals|journal=[[Advances in Mathematics]]|volume=46|issue=3|pages=
:<math>d^{2^{\Omega(n)}}</math>,
and the above upper bound of complexity is optimal. Nevertheless, such examples are extremely rare.
Since its discovery, many variants of Buchberger's have been introduced to improve its efficiency. [[Faugère's F4 and F5 algorithms]] are presently the most efficient algorithms for computing Gröbner bases, and allow to compute routinely Gröbner bases consisting of several hundreds of polynomials, having each several hundreds of terms and coefficients of several hundreds of digits.
== Implementations ==
In the [[SymPy|SymPy library]] for [[Python (programming language)|Python]], the (improved) Buchberger algorithm is implemented as <code>sympy.polys.polytools.groebner()</code>.<ref>{{cite web |title=Polynomials Manipulation Module Reference - SymPy 1.14.0 documentation |url=https://docs.sympy.org/latest/modules/polys/reference.html#sympy.polys.polytools.groebner |website=docs.sympy.org}}</ref>
There is an implementation of Buchberger’s algorithm that has been proved correct
within the proof assistant [[Coq (proof assistant)|Coq]].<ref>{{cite journal |last1=Théry |first1=Laurent |title=A Machine-Checked Implementation of Buchberger's Algorithm |journal=Journal of Automated Reasoning |date=2001 |volume=26 |issue=2 |pages=107–137 |doi=10.1023/A:1026518331905}}</ref>
== See also ==
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| doi = 10.1145/1088216.1088219
| mr = 0463136
| s2cid = 15179417
}} <!-- Note: This citation data is from ACM; the citation at MathWorld has several errors. -->
* David Cox, John Little, and Donald O'Shea (1997). ''Ideals, Varieties, and Algorithms: An Introduction to Computational Algebraic Geometry and Commutative Algebra'', Springer. {{ISBN|0-387-94680-2}}.
* Vladimir P. Gerdt, Yuri A. Blinkov (1998). ''Involutive Bases of Polynomial Ideals'', Mathematics and Computers in Simulation, 45:519ff
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