Littlewood subordination theorem

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In mathematics, the Littlewood subordination theorem, proved by J. E. Littlewood in 1925, is a theorem in operator theory and complex analysis. It states that any holomorphic univalent self-mapping of the unit disk in the complex numbers that fixes 0 induces a contractive composition operator on various function spaces of holomorphic functions on the disk. These spaces include the Hardy spaces, the Bergman spaces and Dirichlet space.

Subordination theorem

Let h be a holomorphic univalent mapping of the unit disk D into itself such that h(0) = 0. Then the composition operator Ch defined on holomorphic functions f on D by

C_h(f) = f\circ h

defines a linear operator with operator norm less than 1 on the Hardy spaces H^p(D), the Bergman spaces A^p(D). (1 ≤ p < ∞) and the Dirichlet space \mathcal{D}(D).

The norms on these spaces are defined by:

\|f\|_{H^p}^p = \sup_r {1\over 2\pi}\int_0^{2\pi} |f(re^{i\theta})|^p \, d\theta
\|f\|_{A^p}^p = {1\over \pi} \iint_D |f(z)|^p\, dx\,dy
\|f\|_{\mathcal D}^2 = {1\over \pi} \iint_D |f^\prime(z)|^2\, dx\,dy= {1\over 4 \pi} \iint_D |\partial_x f|^2 + |\partial_y f|^2\, dx\,dy

Littlewood's inequalities

Let f be a holomorphic function on the unit disk D and let h be a holomorphic univalent mapping of D into itself with h(0) = 0. Then if 0 < r < 1 and 1 ≤ p < ∞

\int_0^{2\pi} |f(h(re^{i\theta}))|^p \, d\theta \le \int_0^{2\pi} |f(re^{i\theta})|^p \, d\theta.

This inequality also holds for 0 < p < 1, although in this case there is no operator interpretation.

Proofs

Case p = 2

To prove the result for H2 it suffices to show that for f a polynomial[1]

Failed to parse (Missing <code>texvc</code> executable. Please see math/README to configure.): \displaystyle{\|C_h f\|^2 \le \|f\|^2,}


Let U be the unilateral shift defined by

Failed to parse (Missing <code>texvc</code> executable. Please see math/README to configure.): \displaystyle{Uf(z)= zf(z)}.


This has adjoint U* given by

U^*f(z) ={f(z)-f(0)\over z}.

Since f(0) = a0, this gives

f= a_0 + zU^*f

and hence

C_h f = a_0 + h C_hU^*f.

Thus

\|C_h f\|^2 = |a_0|^2 + \|hC_hU^*f\|^2 \le |a_0^2|+ \|C_h U^*f\|^2.

Since U*f has degree less than f, it follows by induction that

\|C_h U^*f\|^2 \le \|U^*f\|^2 = \|f\|^2 - |a_0|^2,

and hence

\|C_h f\|^2 \le \|f\|^2.

The same method of proof works for A2 and \mathcal D.

General Hardy spaces

If f is in Hardy space Hp, then it has a factorization[2]

f(z) = f_i(z)f_o(z)

with fi an inner function and fo an outer function.

Then

\|C_h f\|_{H^p} \le \|(C_hf_i) (C_h f_o)\|_{H^p} \le \|C_h f_o\|_{H^p} \le \|C_h f_o^{p/2}\|_{H^2}^{2/p} \le \|f\|_{H^p}.

Inequalities

Taking 0 < r < 1, Littlewood's inequalities follow by applying the Hardy space inequalities to the function

f_r(z)=f(rz).

The inequalities can also be deduced, following Riesz (1925), using subharmonic functions.[3][4] The inequaties in turn immediately imply the subordination theorem for general Bergman spaces.

Notes

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References

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