Bloch space and the norm of the Bergman projection (Q2860905)

Let \(\mathcal{B}\) be the Bloch space on the unit disk \(\mathbb{D}\) of \(\mathbb{C}\) endowed with the norm NEWLINE\[NEWLINE \|f\|_{\mathcal{B}}=|f(0)|+\|(1-|z|^2)|f'(z)|\|_{\infty}. NEWLINE\]NEWLINENEWLINENEWLINEIt is well known that the Bergman projection \(P\) maps \(L^\infty(\mathbb{D})\) to \(\mathcal{B}\) and \(C(\overline{\mathbb{D}})\) to \(\mathcal{B}_0\), respectively, where \(\mathcal{B}_0\) denotes the little Bloch space. In this paper the author proves that both operator norms are equal to \(1+8/\pi\).NEWLINENEWLINEThe author also states that the same techniques can be used to prove that if \(\alpha>-1\) and \(P_{n,\alpha}\) is the weighted Bergman projection defined by NEWLINE\[NEWLINE P_{n,\alpha}(f)(z)=c_\alpha \int_{\mathbb{B}}f(w)\frac{(1-|w|^2)^\alpha}{(1-z\overline w)^{n+1+\alpha}}dV(w), NEWLINE\]NEWLINE where \(dV\) denotes the volume measure on the unit ball \(\mathbb{B}\) of \(\mathbb{C}^n\), then the operator norms of \(P_{n,\alpha}:L^\infty(\mathbb{B})\to \mathcal{B}\) and \(P_{n,\alpha}:C(\overline{\mathbb{B}})\to \mathcal{B}_0\) are equal to NEWLINE\[NEWLINE1+\frac{\Gamma(2+n+\alpha)}{\Gamma((2+n+\alpha)/2)^2}.NEWLINE\]