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fixed point property
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(Definition)
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Let $X$ be a topological space. If every continuous function $f\colon X\to X$ has a fixed point, then $X$ is said to have the fixed point property.
The fixed point property is obviously preserved under homeomorphisms. If $h\colon X\to Y$ is a homeomorphism between topological spaces $X$ and $Y$ , and $X$ has the fixed point property, and $f\colon Y\to Y$ is continuous, then $h^{-1}\circ f\circ h$ has a fixed point $x\in X$ , and $h(x)$ is a fixed point of $f$ .
- A space with only one point has the fixed point property.
- A closed interval $[a,b]$ of $\sR$ has the fixed point property. This can be seen using the mean value theorem.
- The extended real numbers have the fixed point property, as they are homeomorphic to $[0,1]$ .
- The topologist's sine curve has the fixed point property.
- The real numbers $\sR$ do not have the fixed point property. For example, the map $x\mapsto x+1$ on $\sR$ has no fixed point.
- An open interval $(a,b)$ of $\sR$ does not have the fixed point property. This follows since any such interval is homeomorphic to $\sR$ . Similarly, an open ball in $\sR^n$ does not have the fixed point property.
- Brouwer's Fixed Point Theorem states that in $\sR^n$ , the closed unit ball with the subspace topology has the fixed point property. (Equivalently, $[0,1]^n$ has the fixed point property.) The Schauder Fixed Point Theorem generalizes this result further.
- For each $n\in\sN$ , the real projective space $\RP^{2n}$ has the fixed point property.
- Every simply-connected plane continuum has the fixed-point property.
- The Alexandroff-Urysohn square (also known as the Alexandroff square) has the fixed point property.
- Any topological space with the fixed point property is connected and $\operatorname{T}_0$ .
- Suppose $X$ is a topological space with the fixed point property, and $Y$ is a retract of $X$ . Then $Y$ has the fixed point property.
- Suppose $X$ and $Y$ are topological spaces, and $X\times Y$ has the fixed point property. Then $X$ and $Y$ have the fixed point property. (Proof: If $f\colon X\to X$ is continuous, then $(x,y)\mapsto (f(x),y)$ is continuous, so $f$ has a fixed point.)
- 1
- G. L. Naber, Topological methods in Euclidean spaces, Cambridge University Press, 1980.
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- G. J. Jameson, Topology and Normed Spaces, Chapman and Hall, 1974.
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- L. E. Ward, Topology, An Outline for a First Course, Marcel Dekker, Inc., 1972.
- 4
- Charles Hagopian, The Fixed-Point Property for simply-connected plane continua, Trans. Amer. Math. Soc. 348 (1996) 4525-4548.
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"fixed point property" is owned by yark. [ full author list (2) | owner history (1) ]
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See Also: fixed point
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fixed-point property |
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Cross-references: proof, retract, continuum, plane, projective space, Schauder fixed point theorem, subspace topology, unit ball, closed, Brouwer's fixed point theorem, open ball, interval, open interval, map, real numbers, the topologist's sine curve has the fixed point property, homeomorphic, extended real numbers, closed interval, point, fixed point, homeomorphisms, continuous function, topological space
There are 2 references to this entry.
This is version 17 of fixed point property, born on 2003-09-06, modified 2009-11-09.
Object id is 4704, canonical name is FixedPointProperty.
Accessed 6400 times total.
Classification:
| AMS MSC: | 47H10 (Operator theory :: Nonlinear operators and their properties :: Fixed-point theorems) | | | 54H25 (General topology :: Connections with other structures, applications :: Fixed-point and coincidence theorems) | | | 55M20 (Algebraic topology :: Classical topics :: Fixed points and coincidences) |
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Pending Errata and Addenda
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