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Difference between revisions of "Darbo fixed-point theorem"

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The notion of  "measure of non-compactness"  was first introduced by C. Kuratowski [[#References|[a1]]]. For any bounded set $B$ in a [[Metric space|metric space]] its measure of non-compactness, denoted by $\alpha ( B )$, is defined to be the infimum of the positive numbers $d$ such that $B$ can be covered by a finite number of sets of diameter less than or equal to $d$.
 
The notion of  "measure of non-compactness"  was first introduced by C. Kuratowski [[#References|[a1]]]. For any bounded set $B$ in a [[Metric space|metric space]] its measure of non-compactness, denoted by $\alpha ( B )$, is defined to be the infimum of the positive numbers $d$ such that $B$ can be covered by a finite number of sets of diameter less than or equal to $d$.
  
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where $k$ is a constant, $0 \leq k &lt; 1$, then $T$ has a [[Fixed point|fixed point]]. This theorem is true for the measure $\mu$ also.
 
where $k$ is a constant, $0 \leq k &lt; 1$, then $T$ has a [[Fixed point|fixed point]]. This theorem is true for the measure $\mu$ also.
  
Note that every completely-continuous mapping (or [[Compact mapping|compact mapping]]; cf. also [[Completely-continuous operator|Completely-continuous operator]]) satisfies (a1) with $k = 0$, while all Lipschitz mappings with constant $k$ (cf. [[Lipschitz condition|Lipschitz condition]]) also satisfy (a1). Further, mappings that are not completely continuous but satisfy the condition (a1) are of the form $T = T _ { 1 } + T _ { 2 }$, where $T _ { 1 }$ is completely continuous and <img align="absmiddle" border="0" src="https://www.encyclopediaofmath.org/legacyimages/d/d130/d130020/d13002024.png"/> satisfies the Lipschitz condition with constant $k$. The significance of this type of mapping is due to the fact that compactness of either the domain or the range is not required.
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Note that every completely-continuous mapping (or [[Compact mapping|compact mapping]]; cf. also [[Completely-continuous operator|Completely-continuous operator]]) satisfies (a1) with $k = 0$, while all Lipschitz mappings with constant $k$ (cf. [[Lipschitz condition|Lipschitz condition]]) also satisfy (a1). Further, mappings that are not completely continuous but satisfy the condition (a1) are of the form $T = T _ { 1 } + T _ { 2 }$, where $T _ { 1 }$ is completely continuous and $T_2$ satisfies the Lipschitz condition with constant $k$. The significance of this type of mapping is due to the fact that compactness of either the domain or the range is not required.
  
 
Methods for determining the value of $\mu ( B )$ for a given set $B$ in a Banach space are given in [[#References|[a3]]].
 
Methods for determining the value of $\mu ( B )$ for a given set $B$ in a Banach space are given in [[#References|[a3]]].
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====References====
 
====References====
<table><tr><td valign="top">[a1]</td> <td valign="top">  C. Kuratowski,  "Sur les espaces complets"  ''Fundam. Math.'' , '''15'''  (1930)  pp. 301–309</td></tr><tr><td valign="top">[a2]</td> <td valign="top">  G. Darbo,  "Punti uniti in transformazioni a condominio non compacto"  ''Rend. Sem. Mat. Univ. Padova'' , '''24'''  (1955)  pp. 84–92</td></tr><tr><td valign="top">[a3]</td> <td valign="top">  J. Banas,  K. Goebel,  "Measure of noncompactness in Banach spaces" , M. Dekker  (1980)</td></tr><tr><td valign="top">[a4]</td> <td valign="top">  K. Balachandran,  J.P. Dauer,  "Controllability of nonlinear systems via fixed point theorems"  ''J. Optim. Th. Appl.'' , '''53'''  (1987)  pp. 345–352</td></tr></table>
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[a1] C. Kuratowski,  "Sur les espaces complets"  ''Fundam. Math.'' , '''15'''  (1930)  pp. 301–309
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[a2]   G. Darbo,  "Punti uniti in transformazioni a condominio non compacto"  ''Rend. Sem. Mat. Univ. Padova'' , '''24'''  (1955)  pp. 84–92
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[a3]   J. Banas,  K. Goebel,  "Measure of noncompactness in Banach spaces" , M. Dekker  (1980)
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[a4]   K. Balachandran,  J.P. Dauer,  "Controllability of nonlinear systems via fixed point theorems"  ''J. Optim. Th. Appl.'' , '''53'''  (1987)  pp. 345–352

Latest revision as of 00:06, 15 February 2024

The notion of "measure of non-compactness" was first introduced by C. Kuratowski [a1]. For any bounded set $B$ in a metric space its measure of non-compactness, denoted by $\alpha ( B )$, is defined to be the infimum of the positive numbers $d$ such that $B$ can be covered by a finite number of sets of diameter less than or equal to $d$.

Another measure of non-compactness is the ball measure $\mu ( B )$, or Hausdorff measure, which is defined as the infimum of the positive numbers $r$ such that $B$ can be covered by a finite number of balls of radii smaller than $r$. See also Hausdorff measure.

Roughly speaking, a measure of non-compactness is some function defined on the family of all non-empty bounded subsets of a given metric space such that it is equal to zero on the whole family of relatively compact sets.

G. Darbo used a measure of non-compactness to investigate operators whose properties can be characterized as being intermediate between those of contraction and compact mappings (cf. also Compact mapping; Compact operator; Contraction). He was the first to use the index $\alpha$ in the theory of fixed points [a2]. Darbo's fixed-point theorem is a generalization of the well-known Schauder fixed-point theorem (cf. also Schauder theorem). It states that if $S$ is a non-empty bounded closed convex subset of a Banach space $X$ and $T : S \rightarrow S$ is a continuous mapping such that for any set $E \subset S$,

\begin{equation} \tag{a1} \alpha ( T E ) \leq k \alpha ( E ), \end{equation}

where $k$ is a constant, $0 \leq k < 1$, then $T$ has a fixed point. This theorem is true for the measure $\mu$ also.

Note that every completely-continuous mapping (or compact mapping; cf. also Completely-continuous operator) satisfies (a1) with $k = 0$, while all Lipschitz mappings with constant $k$ (cf. Lipschitz condition) also satisfy (a1). Further, mappings that are not completely continuous but satisfy the condition (a1) are of the form $T = T _ { 1 } + T _ { 2 }$, where $T _ { 1 }$ is completely continuous and $T_2$ satisfies the Lipschitz condition with constant $k$. The significance of this type of mapping is due to the fact that compactness of either the domain or the range is not required.

Methods for determining the value of $\mu ( B )$ for a given set $B$ in a Banach space are given in [a3].

Darbo's fixed-point theorem is useful in establishing the existence of solutions of various classes of differential equations, especially for implicit differential equations, integral equations and integro-differential equations, see [a3]. It is also used to study the controllability problem for dynamical systems represented by implicit differential equations [a4].

References

[a1] C. Kuratowski, "Sur les espaces complets" Fundam. Math. , 15 (1930) pp. 301–309

[a2] G. Darbo, "Punti uniti in transformazioni a condominio non compacto" Rend. Sem. Mat. Univ. Padova , 24 (1955) pp. 84–92

[a3] J. Banas, K. Goebel, "Measure of noncompactness in Banach spaces" , M. Dekker (1980)

[a4] K. Balachandran, J.P. Dauer, "Controllability of nonlinear systems via fixed point theorems" J. Optim. Th. Appl. , 53 (1987) pp. 345–352

How to Cite This Entry:
Darbo fixed-point theorem. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Darbo_fixed-point_theorem&oldid=55480
This article was adapted from an original article by Krishnan Balachandran (originator), which appeared in Encyclopedia of Mathematics - ISBN 1402006098. See original article