Fredholm's alternative

In mathematics , Fredholm's alternative named after Ivar Fredholm is a result of Fredholm's theory . It can be expressed in different ways: as a theorem of linear algebra , as a theorem of integral equations, or as a theorem of Fredholm operators . In particular, it says that a complex number not equal to 0 in the spectrum of a compact operator is an eigenvalue .

Version of linear algebra

In a -dimensional vector space , exactly one of the following statements applies to a linear mapping : ${\ displaystyle n}$ ${\ displaystyle V}$ ${\ displaystyle A \ colon V \ to V}$

For every vector in there is a vector in such that . In other words: is surjective. ${\ displaystyle v}$ ${\ displaystyle V}$ ${\ displaystyle u}$ ${\ displaystyle V}$ ${\ displaystyle Au = v}$ ${\ displaystyle A}$
There is an in with , that is: is not injective. ${\ displaystyle u \ neq 0}$ ${\ displaystyle V}$ ${\ displaystyle Au = 0}$ ${\ displaystyle A}$

Fredholm integral equations

Be an integral kernel . Consider the homogeneous Fredholm integral equation , ${\ displaystyle K (x, y)}$

{\ displaystyle \ lambda \ phi (x) - \ int _ {a} ^ {b} K (x, y) \ phi (y) \, dy = 0}

,

as well as the inhomogeneous equation

{\ displaystyle \ lambda \ phi (x) - \ int _ {a} ^ {b} K (x, y) \ phi (y) \, dy = f (x)}

.

Fredholm's alternative says that for a complex number , either the first equation has a nontrivial solution, or the second equation has a solution for any right-hand side . ${\ displaystyle 0 \ neq \ lambda \ in \ mathbb {C}}$ ${\ displaystyle f (x)}$

A sufficient condition for this theorem to be true is the integrability of squares on the rectangle (where a and / or b may also be plus or minus infinity). ${\ displaystyle K (x, y)}$ ${\ displaystyle [a, b] \ times [a, b]}$

Fredholm's alternative

statement

Be a compact operator on and be with . Then there is a Fredholm operator with Fredholm index 0. The Fredholm alternative is now: ${\ displaystyle K \ in K (X)}$ ${\ displaystyle X}$ ${\ displaystyle \ lambda \ in \ mathbb {C}}$ ${\ displaystyle \ lambda \ neq 0}$ ${\ displaystyle Tx: = \ lambda x-Kx}$

Either both have the homogeneous equation

{\ displaystyle \ lambda x-Kx = 0}

as well as the adjoint equation

{\ displaystyle \ lambda x'-K'x '= 0}

only the trivial solution is zero and thus the equations are inhomogeneous

{\ displaystyle \ lambda x-Kx = y}

and

{\ displaystyle \ lambda x'-K'x '= y'}

clearly solvable,

or the homogeneous equation

{\ displaystyle \ lambda x-Kx = 0}

and the adjoint equation

{\ displaystyle \ lambda x'-K'x '= 0}

have exactly linearly independent solutions (where the identical figure denotes) and thus the equation would be inhomogeneous

{\ displaystyle n = \ dim \ ker (\ lambda \ operatorname {id} -K) <\ infty}

{\ displaystyle \ operatorname {id}}

{\ displaystyle \ lambda x-Kx = y}

solvable if and only if .

{\ displaystyle y \ in (\ ker (\ lambda \ operatorname {id} -K ')) ^ {\ bot}}

In connection with the integral equations

Note that the delta distribution is the identity of the convolution . Let be a Banach space , for example, and be a Fredholm operator which through ${\ displaystyle X}$ ${\ displaystyle X = L ^ {2} ([a, b])}$ ${\ displaystyle T \ colon X \ to X}$

{\ displaystyle T \ phi (x) = \ int _ {a} ^ {b} \ lambda \ delta (xy) \ phi (y) -k (x, y) \ phi (y) dy = \ lambda \ phi (x) - \ int _ {a} ^ {b} k (x, y) \ phi (y) dy,}

is defined, where must hold in order to obtain a Fredholm operator. Then there is a compact operator and you can see that this statement generalizes the statement about Fredholm's integral equations. ${\ displaystyle k \ in L ^ {2} ([a, b])}$ ${\ displaystyle \ textstyle \ int _ {a} ^ {b} k (x, y) \ phi (y) dy}$

Fredholm's alternative can then be formulated as follows: A is either an eigenvalue of or it is part of the resolvent set ${\ displaystyle \ lambda \ neq 0}$ ${\ displaystyle K}$

{\ displaystyle \ rho (K) = \ {\ lambda \ in \ mathbb {C}: (\ lambda \ operatorname {id} -K) {\ text {limited invertible}} \}}

.

literature

Dirk Werner : functional analysis , Springer-Verlag, Berlin, ISBN 978-3-540-72533-6 .