Von Neumann's inequality
In operator theory, von Neumann's inequality, due to John von Neumann, states that, for a fixed contraction T, the polynomial functional calculus map is itself a contraction.
Formal statement
For a contraction T acting on a Hilbert space and a polynomial p, then the norm of p(T) is bounded by the supremum of |p(z)| for z in the unit disk."[1]
Proof
The inequality can be proved by considering the unitary dilation of T, for which the inequality is obvious.
Generalizations
This inequality is a specific case of Matsaev's conjecture. That is that for any polynomial P and contraction T on [math]\displaystyle{ L^p }[/math]
- [math]\displaystyle{ ||P(T)||_{L^p\to L^p} \le ||P(S)||_{\ell^p\to\ell^p} }[/math]
where S is the right-shift operator. The von Neumann inequality proves it true for [math]\displaystyle{ p=2 }[/math] and for [math]\displaystyle{ p=1 }[/math] and [math]\displaystyle{ p=\infty }[/math] it is true by straightforward calculation. S.W. Drury has shown in 2011 that the conjecture fails in the general case.[2]
References
See also
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