Method of continuity

In the mathematics of Banach spaces, the method of continuity provides sufficient conditions for deducing the invertibility of one bounded linear operator from that of another, related operator.

Let B be a Banach space, V a normed vector space, and ${\displaystyle (L_t{)}_{t\in [0,1]}}$ a norm continuous family of bounded linear operators from B into V. Assume that there exists a positive constant C such that for every ${\displaystyle t\in [0,1]}$ and every ${\displaystyle x\in B}$

${\displaystyle ||x|{|}_B\le C||L_t(x)|{|}_V.}$

Then ${\displaystyle L_0}$ is surjective if and only if ${\displaystyle L_1}$ is surjective as well.

The method of continuity is used in conjunction with a priori estimates to prove the existence of suitably regular solutions to elliptic partial differential equations.

We assume that ${\displaystyle L_0}$ is surjective and show that ${\displaystyle L_1}$ is surjective as well.

Subdividing the interval [0,1] we may assume that ${\displaystyle ||L_0-L_1||\le 1/(3C)}$. Furthermore, the surjectivity of ${\displaystyle L_0}$ implies that V is isomorphic to B and thus a Banach space. The hypothesis implies that ${\displaystyle L_1(B)\subseteq V}$ is a closed subspace.

Assume that ${\displaystyle L_1(B)\subseteq V}$ is a proper subspace. Riesz's lemma shows that there exists a ${\displaystyle y\in V}$ such that ${\displaystyle ||y|{|}_V\le 1}$ and ${\displaystyle \mathrm{d}\mathrm{i}\mathrm{s}\mathrm{t}(y,L_1(B))>2/3}$. Now ${\displaystyle y=L_0(x)}$ for some ${\displaystyle x\in B}$ and ${\displaystyle ||x|{|}_B\le C||y|{|}_V}$ by the hypothesis. Therefore

${\displaystyle ||y-L_1(x)|{|}_V=||(L_0-L_1)(x)|{|}_V\le ||L_0-L_1||||x|{|}_B\le 1/3,}$

which is a contradiction since ${\displaystyle L_1(x)\in L_1(B)}$.

• Schauder estimates

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