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Amoeba (mathematics)

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The amoeba of
The amoeba of Notice the "vacuole" in the middle of the amoeba.
The amoeba of
The amoeba of
Points in the amoeba of Note that the amoeba is actually 3-dimensional, and not a surface (this is not entirely evident from the image).

In complex analysis, a branch of mathematics, an amoeba is a set associated with a polynomial in one or more complex variables. Amoebas have applications in algebraic geometry, especially tropical geometry.

Definition

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Consider the function

defined on the set of all n-tuples of non-zero complex numbers with values in the Euclidean space given by the formula

Here, log denotes the natural logarithm. If p(z) is a polynomial in complex variables, its amoeba is defined as the image of the set of zeros of p under Log, so

Amoebas were introduced in 1994 in a book by Gelfand, Kapranov, and Zelevinsky.[1]

Properties

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Let be the zero locus of a polynomial

where is finite, and if and . Let be the Newton polyhedron of , i.e.,

Then

  • Any amoeba is a closed set.
  • Any connected component of the complement is convex.[2]
  • The area of an amoeba of a not identically zero polynomial in two complex variables is finite.
  • A two-dimensional amoeba has a number of "tentacles", which are infinitely long and exponentially narrow towards infinity.
  • The number of connected components of the complement is not greater than and not less than the number of vertices of .[2]
  • There is an injection from the set of connected components of complement to . The vertices of are in the image under this injection. A connected component of complement is bounded if and only if its image is in the interior of .[2]
  • If , then the area of is not greater than .[2]

Ronkin function

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A useful tool in studying amoebas is the Ronkin function. For p(z), a polynomial in n complex variables, one defines the Ronkin function

by the formula

where denotes Equivalently, is given by the integral

where

The Ronkin function is convex and affine on each connected component of the complement of the amoeba of .[3]

As an example, the Ronkin function of a monomial

with is

References

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  1. ^ Gelfand, I. M.; Kapranov, M. M.; Zelevinsky, A. V. (1994). Discriminants, resultants, and multidimensional determinants. Mathematics: Theory & Applications. Boston, MA: Birkhäuser. ISBN 0-8176-3660-9. Zbl 0827.14036.
  2. ^ Jump up to: a b c d Itenberg et al (2007) p. 3.
  3. ^ Gross, Mark (2004). "Amoebas of complex curves and tropical curves". In Guest, Martin (ed.). UK-Japan winter school 2004—Geometry and analysis towards quantum theory. Lecture notes from the school, University of Durham, Durham, UK, 6–9 January 2004. Seminar on Mathematical Sciences. Vol. 30. Yokohama: Keio University, Department of Mathematics. pp. 24–36. Zbl 1083.14061.
  • Itenberg, Ilia; Mikhalkin, Grigory; Shustin, Eugenii (2007). Tropical algebraic geometry. Oberwolfach Seminars. Vol. 35. Basel: Birkhäuser. ISBN 978-3-7643-8309-1. Zbl 1162.14300.
  • Viro, Oleg (2002), "What Is ... An Amoeba?" (PDF), Notices of the American Mathematical Society, 49 (8): 916–917.

Further reading

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