In mathematics, tropical geometry is the study of polynomials and their geometric properties when addition is replaced with minimization and multiplication is replaced with ordinary addition:
So for example, the classical polynomial would become . Such polynomials and their solutions have important applications in optimization problems, for example the problem of optimizing departure times for a network of trains.
Tropical geometry is a variant of algebraic geometry in which polynomial graphs resemble piecewise linear meshes, and in which numbers belong to the tropical semiring instead of a field. Because classical and tropical geometry are closely related, results and methods can be converted between them. Algebraic varieties can be mapped to a tropical counterpart and, since this process still retains some geometric information about the original variety, it can be used to help prove and generalize classical results from algebraic geometry, such as the Brill–Noether theorem, using the tools of tropical geometry. [1]
The basic ideas of tropical analysis were developed independently using the same notation by mathematicians working in various fields. [2] The central ideas of tropical geometry appeared in different forms in a number of earlier works. For example, Victor Pavlovich Maslov introduced a tropical version of the process of integration. He also noticed that the Legendre transformation and solutions of the Hamilton–Jacobi equation are linear operations in the tropical sense. [3] However, only since the late 1990s has an effort been made to consolidate the basic definitions of the theory. This was motivated by its application to enumerative algebraic geometry, with ideas from Maxim Kontsevich [4] and works by Grigory Mikhalkin [5] among others.
The adjective tropical was coined by French mathematicians in honor of the Hungarian-born Brazilian computer scientist Imre Simon, who wrote on the field. Jean-Éric Pin attributes the coinage to Dominique Perrin, [6] whereas Simon himself attributes the word to Christian Choffrut. [7]
Tropical geometry is based on the tropical semiring. This is defined in two ways, depending on max or min convention.
The min tropical semiring is the semiring , with the operations:
The operations and are referred to as tropical addition and tropical multiplication respectively. The identity element for is , and the identity element for is 0.
Similarly, the max tropical semiring is the semiring , with operations:
The identity element for is , and the identity element for is 0.
These semirings are isomorphic, under negation , and generally one of these is chosen and referred to simply as the tropical semiring. Conventions differ between authors and subfields: some use the min convention, some use the max convention.
The tropical semiring operations model how valuations behave under addition and multiplication in a valued field.
Some common valued fields encountered in tropical geometry (with min convention) are:
A tropical polynomial is a function that can be expressed as the tropical sum of a finite number of monomial terms. A monomial term is a tropical product (and/or quotient) of a constant and variables from . Thus a tropical polynomial F is the minimum of a finite collection of affine-linear functions in which the variables have integer coefficients, so it is concave, continuous, and piecewise linear. [8]
Given a polynomial f in the Laurent polynomial ring where K is a valued field, the tropicalization of f, denoted , is the tropical polynomial obtained from f by replacing multiplication and addition by their tropical counterparts and each constant in K by its valuation. That is, if
then
The set of points where a tropical polynomial F is non-differentiable is called its associated tropical hypersurface, denoted (in analogy to the vanishing set of a polynomial). Equivalently, is the set of points where the minimum among the terms of F is achieved at least twice. When for a Laurent polynomial f, this latter characterization of reflects the fact that at any solution to , the minimum valuation of the terms of f must be achieved at least twice in order for them all to cancel. [9]
For X an algebraic variety in the algebraic torus , the tropical variety of X or tropicalization of X, denoted , is a subset of that can be defined in several ways. The equivalence of these definitions is referred to as the Fundamental Theorem of Tropical Geometry. [9]
Let be the ideal of Laurent polynomials that vanish on X in . Define
When X is a hypersurface, its vanishing ideal is a principal ideal generated by a Laurent polynomial f, and the tropical variety is precisely the tropical hypersurface .
Every tropical variety is the intersection of a finite number of tropical hypersurfaces. A finite set of polynomials is called a tropical basis for X if is the intersection of the tropical hypersurfaces of . In general, a generating set of is not sufficient to form a tropical basis. The intersection of a finite number of a tropical hypersurfaces is called a tropical prevariety and in general is not a tropical variety. [9]
Choosing a vector in defines a map from the monomial terms of to by sending the term m to . For a Laurent polynomial , define the initial form of f to be the sum of the terms of f for which is minimal. For the ideal , define its initial ideal with respect to to be
Then define
Since we are working in the Laurent ring, this is the same as the set of weight vectors for which does not contain a monomial.
When K has trivial valuation, is precisely the initial ideal of with respect to the monomial order given by a weight vector . It follows that is a subfan of the Gröbner fan of .
Suppose that X is a variety over a field K with valuation v whose image is dense in (for example a field of Puiseux series). By acting coordinate-wise, v defines a map from the algebraic torus to . Then define
where the overline indicates the closure in the Euclidean topology. If the valuation of K is not dense in , then the above definition can be adapted by extending scalars to larger field which does have a dense valuation.
This definition shows that is the non-Archimedean amoeba over an algebraically closed non-Archimedean field K. [10]
If X is a variety over , can be considered as the limiting object of the amoeba as the base t of the logarithm map goes to infinity. [11]
The following characterization describes tropical varieties intrinsically without reference to algebraic varieties and tropicalization. A set V in is an irreducible tropical variety if it is the support of a weighted polyhedral complex of pure dimension d that satisfies the zero-tension condition and is connected in codimension one. When d is one, the zero-tension condition means that around each vertex, the weighted-sum of the out-going directions of edges equals zero. For higher dimension, sums are taken instead around each cell of dimension after quotienting out the affine span of the cell. [8] The property that V is connected in codimension one means for any two points lying on dimension d cells, there is a path connecting them that does not pass through any cells of dimension less than . [12]
The study of tropical curves (tropical varieties of dimension one) is particularly well developed and is strongly related to graph theory. For instance, the theory of divisors of tropical curves are related to chip-firing games on graphs associated to the tropical curves. [13]
Many classical theorems of algebraic geometry have counterparts in tropical geometry, including:
Oleg Viro used tropical curves to classify real curves of degree 7 in the plane up to isotopy. His method of patchworking gives a procedure to build a real curve of a given isotopy class from its tropical curve.
A tropical line appeared in Paul Klemperer's design of auctions used by the Bank of England during the financial crisis in 2007. [17] Yoshinori Shiozawa defined subtropical algebra as max-times or min-times semiring (instead of max-plus and min-plus). He found that Ricardian trade theory (international trade without input trade) can be interpreted as subtropical convex algebra. [18] [ non-primary source needed ] Tropical geometry has also been used for analyzing the complexity of feedforward neural networks with ReLU activation. [19]
Moreover, several optimization problems arising for instance in job scheduling, location analysis, transportation networks, decision making and discrete event dynamical systems can be formulated and solved in the framework of tropical geometry. [20] A tropical counterpart of the Abel–Jacobi map can be applied to a crystal design. [21] The weights in a weighted finite-state transducer are often required to be a tropical semiring. Tropical geometry can show self-organized criticality. [22]
Tropical geometry has also found applications in several topics within theoretical high energy physics. In particular, tropical geometry has been used to drastically simplify string theory amplitudes to their field-theoretical limits [23] and has found connections to constructions such as the Amplituhedron [24] and tropological (Carrollian) sigma models. [25]
In mathematics, the tensor product of two vector spaces V and W is a vector space to which is associated a bilinear map that maps a pair to an element of denoted .
In commutative algebra, the prime spectrum of a commutative ring is the set of all prime ideals of , and is usually denoted by ; in algebraic geometry it is simultaneously a topological space equipped with the sheaf of rings .
In mathematics, rings are algebraic structures that generalize fields: multiplication need not be commutative and multiplicative inverses need not exist. Informally, a ring is a set equipped with two binary operations satisfying properties analogous to those of addition and multiplication of integers. Ring elements may be numbers such as integers or complex numbers, but they may also be non-numerical objects such as polynomials, square matrices, functions, and power series.
In mathematics, Hilbert's Nullstellensatz is a theorem that establishes a fundamental relationship between geometry and algebra. This relationship is the basis of algebraic geometry. It relates algebraic sets to ideals in polynomial rings over algebraically closed fields. This relationship was discovered by David Hilbert, who proved the Nullstellensatz in his second major paper on invariant theory in 1893.
In mathematics, the exterior algebra or Grassmann algebra of a vector space is an associative algebra that contains which has a product, called exterior product or wedge product and denoted with , such that for every vector in The exterior algebra is named after Hermann Grassmann, and the names of the product come from the "wedge" symbol and the fact that the product of two elements of is "outside"
In mathematics, K-theory is, roughly speaking, the study of a ring generated by vector bundles over a topological space or scheme. In algebraic topology, it is a cohomology theory known as topological K-theory. In algebra and algebraic geometry, it is referred to as algebraic K-theory. It is also a fundamental tool in the field of operator algebras. It can be seen as the study of certain kinds of invariants of large matrices.
In mathematics, in particular in algebraic topology, differential geometry and algebraic geometry, the Chern classes are characteristic classes associated with complex vector bundles. They have since become fundamental concepts in many branches of mathematics and physics, such as string theory, Chern–Simons theory, knot theory, and Gromov–Witten invariants. Chern classes were introduced by Shiing-Shen Chern.
In algebraic geometry, motives is a theory proposed by Alexander Grothendieck in the 1960s to unify the vast array of similarly behaved cohomology theories such as singular cohomology, de Rham cohomology, etale cohomology, and crystalline cohomology. Philosophically, a "motif" is the "cohomology essence" of a variety.
In mathematics, Kähler differentials provide an adaptation of differential forms to arbitrary commutative rings or schemes. The notion was introduced by Erich Kähler in the 1930s. It was adopted as standard in commutative algebra and algebraic geometry somewhat later, once the need was felt to adapt methods from calculus and geometry over the complex numbers to contexts where such methods are not available.
In idempotent analysis, the tropical semiring is a semiring of extended real numbers with the operations of minimum and addition replacing the usual ("classical") operations of addition and multiplication, respectively.
In the field of mathematics known as differential geometry, a generalized complex structure is a property of a differential manifold that includes as special cases a complex structure and a symplectic structure. Generalized complex structures were introduced by Nigel Hitchin in 2002 and further developed by his students Marco Gualtieri and Gil Cavalcanti.
In mathematics, Hochschild homology (and cohomology) is a homology theory for associative algebras over rings. There is also a theory for Hochschild homology of certain functors. Hochschild cohomology was introduced by Gerhard Hochschild (1945) for algebras over a field, and extended to algebras over more general rings by Henri Cartan and Samuel Eilenberg (1956).
In multilinear algebra, the tensor rank decomposition or rank-R decomposition is the decomposition of a tensor as a sum of R rank-1 tensors, where R is minimal. Computing this decomposition is an open problem.
In mathematics, the Newton polytope is an integral polytope associated with a multivariate polynomial. It can be used to analyze the polynomial's behavior when specific variables are considered negligible relative to the others. Specifically, given a vector of variables and a finite family of pairwise distinct vectors from each encoding the exponents within a monomial, consider the multivariate polynomial
This is a glossary of algebraic geometry.
In stochastic analysis, a rough path is a generalization of the notion of smooth path allowing to construct a robust solution theory for controlled differential equations driven by classically irregular signals, for example a Wiener process. The theory was developed in the 1990s by Terry Lyons. Several accounts of the theory are available.
In algebraic geometry, a derived scheme is a homotopy-theoretic generalization of a scheme in which classical commutative rings are replaced with derived versions such as differential graded algebras, commutative simplicial rings, or commutative ring spectra.
In algebra and algebraic geometry, given a commutative Noetherian ring and an ideal in it, the n-th symbolic power of is the ideal
In tropical analysis, tropical cryptography refers to the study of a class of cryptographic protocols built upon tropical algebras. In many cases, tropical cryptographic schemes have arisen from adapting classical (non-tropical) schemes to instead rely on tropical algebras. The case for the use of tropical algebras in cryptography rests on at least two key features of tropical mathematics: in the tropical world, there is no classical multiplication, and the problem of solving systems of tropical polynomial equations has been shown to be NP-hard.
In mathematics, derived noncommutative algebraic geometry, the derived version of noncommutative algebraic geometry, is the geometric study of derived categories and related constructions of triangulated categories using categorical tools. Some basic examples include the bounded derived category of coherent sheaves on a smooth variety, , called its derived category, or the derived category of perfect complexes on an algebraic variety, denoted . For instance, the derived category of coherent sheaves on a smooth projective variety can be used as an invariant of the underlying variety for many cases. Unfortunately, studying derived categories as geometric objects of themselves does not have a standardized name.