Banach fixed point theorem

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The Banach fixed point theorem (also known as the contraction mapping theorem or contraction mapping principle) is an important tool in the theory of metric spaces; it guarantees the existence and uniqueness of fixed points of certain self maps of metric spaces, and provides a constructive method to find those fixed points. The theorem is named after Stefan Banach (1892-1945), and was first stated by Banach in 1922.

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[edit] The theorem

Let (X, d) be a non-empty complete metric space. Let T : XX be a contraction mapping on X, i.e: there is a nonnegative real number q < 1 such that

d(Tx,Ty) \le q\cdot d(x,y)

for all x, y in X. Then the map T admits one and only one fixed point x* in X (this means Tx* = x*). Furthermore, this fixed point can be found as follows: start with an arbitrary element x0 in X and define an iterative sequence by xn = Txn-1 for n = 1, 2, 3, ... This sequence converges, and its limit is x*. The following inequality describes the speed of convergence:

d(x^*, x_n) \leq \frac{q^n}{1-q} d(x_1,x_0).

Equivalently,

d(x^*, x_{n+1}) \leq \frac{q}{1-q} d(x_{n+1},x_n)

and

d(x^*, x_{n+1}) \leq q d(x_n,x^*).

The smallest such value of q is sometimes called the Lipschitz constant.

Note that the requirement d(Tx, Ty) < d(x, y) for all unequal x and y is in general not enough to ensure the existence of a fixed point, as is shown by the map T : [1,∞) → [1,∞) with T(x) = x + 1/x, which lacks a fixed point. However, if the space X is compact, then this weaker assumption does imply all the statements of the theorem.

When using the theorem in practice, the most difficult part is typically to define X properly so that T actually maps elements from X to X, i.e. that Tx is always an element of X.

[edit] Proof

Choose any x_0 \in (X, d). For each n \in \{1, 2, \ldots\}, define x_n = Tx_{n-1}\,\!. We claim that for all n \in \{1, 2, \dots\}, the following is true:

d(x_{n+1}, x_n) \leq q^n d(x_1, x_0).

To show this, we will proceed using induction. The above statement is true for the case n = 1\,\!, for

d(x_{1+1}, x_1) = d(x_2, x_1) = d(Tx_1, Tx_0) \leq qd(x_1, x_0).

Suppose the above statement holds for some k \in \{1, 2, \ldots\}. Then we have

d(x_{(k + 1) + 1}, x_{k + 1})\,\! = d(x_{k + 2}, x_{k + 1})\,\!
= d(Tx_{k + 1}, Tx_k)\,\!
\leq q d(x_{k + 1}, x_k)
\leq q \cdot q^kd(x_1, x_0)
= q^{k + 1}d(x_1, x_0)\,\!.

The inductive assumption is used going from line three to line four. By the principle of mathematical induction, for all n \in \{1, 2, \ldots\}, the above claim is true.

Let \epsilon > 0\,\!. Since 0 \leq q < 1, we can find a large N \in \{1, 2, \ldots\} so that

q^N < \frac{\epsilon(1-q)}{d(x_1, x_0)}.

Using the claim above, we have that for any m\,\!, n \in \{0, 1, \ldots\} with m > n \geq N,

d\left(x_m, x_n\right) \leq d(x_m, x_{m-1}) + d(x_{m-1}, x_{m-2}) + \cdots + d(x_{n+1}, x_n)
\leq q^{m-1}d(x_1, x_0) + q^{m-2}d(x_1, x_0) + \cdots + q^nd(x_1, x_0)
= d(x_1, x_0)q^n \cdot \sum_{k=0}^{m-n-1} q^k
< d(x_1, x_0)q^n \cdot \sum_{k=0}^\infty q^k
= d(x_1, x_0)q^n \frac{1}{1-q}
= q^n \frac{d(x_1, x_0)}{1-q}
< \frac{\epsilon(1-q)}{d(x_1, x_0)}\cdot\frac{d(x_1, x_0)}{1-q}
= \epsilon\,\!.

The inequality in line one follows from repeated applications of the triangle inequality; the series in line four is a geometric series with 0 \leq q < 1 and hence it converges. The above shows that \{x_n\}_{n\geq 0} is a Cauchy sequence in (X, d)\,\! and hence convergent by completeness. So let x^* = \lim_{n\to\infty} x_n. We make two claims: (1) x^*\,\! is a fixed point of T\,\!. That is, Tx^* = x^*\,\!; (2) x^*\,\! is the only fixed point of T\,\! in (X, d)\,\!.

To see (1), we note that for any n \in \{0, 1, \ldots\},

0 \leq d(x_{n+1}, Tx^*) = d(Tx_n, Tx^*) \leq q d(x_n, x^*).

Since qd(x_n, x^*) \to 0 as n \to \infty, the squeeze theorem shows that \lim_{n\to\infty} d(x_{n+1}, Tx^*) = 0. This shows that x_n \to Tx^* as n \to \infty. But x_n \to x^* as n \to \infty, and limits are unique; hence it must be the case that x^* = Tx^*\,\!.

To show (2), we suppose that y\,\! also satisfies Ty = y\,\!. Then

0 \leq d(x^*, y) = d(Tx^*, Ty) \leq q d(x^*, y).

Remembering that 0 \leq q < 1, the above implies that 0 \leq (1-q) d(x^*, y) \leq 0, which shows that d(x^*, y) = 0\,\!, whence by positive definiteness, x^* = y\,\! and the proof is complete.

[edit] Applications

A standard application is the proof of the Picard-Lindelöf theorem about the existence and uniqueness of solutions to certain ordinary differential equations. The sought solution of the differential equation is expressed as a fixed point of a suitable integral operator which transforms continuous functions into continuous functions. The Banach fixed point theorem is then used to show that this integral operator has a unique fixed point.

[edit] Converses

Several converses of the Banach contraction principle exist. The following is due to Czeslaw Bessaga, from 1959:

Let f:X\rightarrow X be a map of an abstract set such that each iterate f n has a unique fixed point. Let q be a real number, 0 < q < 1. Then there exists a complete metric on X such that f is contractive, and q is the contraction constant.

[edit] Generalizations

See the article on fixed point theorems in infinite-dimensional spaces for generalizations.

[edit] References

  • Vasile I. Istratescu, Fixed Point Theory, An Introduction, D.Reidel, the Netherlands (1981). ISBN 90-277-1224-7 See chapter 7.
  • Andrzej Granas and James Dugundji, Fixed Point Theory (2003) Springer-Verlag, New York, ISBN 0-387-00173-5.
  • William A. Kirk and Brailey Sims, Handbook of Metric Fixed Point Theory (2001), Kluwer Academic, London ISBN 0-7923-7073-2.

An earlier version of this article was posted on Planet Math. This article is open content.

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