Brouwer fixed-point theorem

Brouwer's fixed-point theorem is a fixed-point theorem in topology, named after L. E. J. (Bertus) Brouwer. It states that for any continuous function $f$ mapping a nonempty compact convex set to itself, there is a point $x_{0}$ such that $f(x_{0})=x_{0}$ . The simplest forms of Brouwer's theorem are for continuous functions $f$ from a closed interval $I$ in the real numbers to itself or from a closed disk $D$ to itself. A more general form than the latter is for continuous functions from a nonempty convex compact subset $K$ of Euclidean space to itself.

Among hundreds of fixed-point theorems,^[1] Brouwer's is particularly well known, due in part to its use across numerous fields of mathematics. In its original field, this result is one of the key theorems characterizing the topology of Euclidean spaces, along with the Jordan curve theorem, the hairy ball theorem, the invariance of dimension and the Borsuk–Ulam theorem.^[2] This gives it a place among the fundamental theorems of topology.^[3] The theorem is also used for proving deep results about differential equations and is covered in most introductory courses on differential geometry. It appears in unlikely fields such as game theory. In economics, Brouwer's fixed-point theorem and its extension, the Kakutani fixed-point theorem, play a central role in the proof of existence of general equilibrium in market economies as developed in the 1950s by economics Nobel prize winners Kenneth Arrow and Gérard Debreu.

The theorem was first studied in view of work on differential equations by the French mathematicians around Henri Poincaré and Charles Émile Picard. Proving results such as the Poincaré–Bendixson theorem requires the use of topological methods. This work at the end of the 19th century opened into several successive versions of the theorem. The case of differentiable mappings of the $n$ -dimensional closed ball was first proved in 1910 by Jacques Hadamard^[4] and the general case for continuous mappings by Brouwer in 1911.^[5]

^ E.g. F & V Bayart Théorèmes du point fixe on Bibm@th.net Archived December 26, 2008, at the Wayback Machine
^ See page 15 of: D. Leborgne Calcul différentiel et géométrie Puf (1982) ISBN 2-13-037495-6
^ More exactly, according to Encyclopédie Universalis: Il en a démontré l'un des plus beaux théorèmes, le théorème du point fixe, dont les applications et généralisations, de la théorie des jeux aux équations différentielles, se sont révélées fondamentales. Luizen Brouwer by G. Sabbagh
^ Jacques Hadamard: Note sur quelques applications de l’indice de Kronecker in Jules Tannery: Introduction à la théorie des fonctions d’une variable (Volume 2), 2nd edition, A. Hermann & Fils, Paris 1910, pp. 437–477 (French)
^ Brouwer, L. E. J. (1911). "Über Abbildungen von Mannigfaltigkeiten". Mathematische Annalen (in German). 71: 97–115. doi:10.1007/BF01456931. S2CID 177796823.

[1] E.g. F & V Bayart Théorèmes du point fixe on Bibm@th.net Archived December 26, 2008, at the Wayback Machine

[2] See page 15 of: D. Leborgne Calcul différentiel et géométrie Puf (1982) ISBN 2-13-037495-6

[3] More exactly, according to Encyclopédie Universalis: Il en a démontré l'un des plus beaux théorèmes, le théorème du point fixe, dont les applications et généralisations, de la théorie des jeux aux équations différentielles, se sont révélées fondamentales. Luizen Brouwer by G. Sabbagh

[hadamard-1910-4] Jacques Hadamard: Note sur quelques applications de l’indice de Kronecker in Jules Tannery: Introduction à la théorie des fonctions d’une variable (Volume 2), 2nd edition, A. Hermann & Fils, Paris 1910, pp. 437–477 (French)

[brouwer-1910-5] Brouwer, L. E. J. (1911). "Über Abbildungen von Mannigfaltigkeiten". Mathematische Annalen (in German). 71: 97–115. doi:10.1007/BF01456931. S2CID 177796823.

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