Hille-Tamarkin operator
Let $ T $
be an integral operator from $ L _ {p} ( Y, \nu ) $
into $ L _ {q} ( X, \mu ) $,
i.e., there exists a $ ( \mu \times \nu ) $-
measurable function $ T ( x,y ) $
on $ X \times Y $
such that $ Tf ( x ) = \int {T ( x,y ) } {d \nu ( y ) } $
a.e. on $ X $.
Then $ T $
is called a Hille–Tamarkin operator if
$$ \int\limits {\left ( \int\limits {\left | {T ( x,y ) } \right | ^ {p ^ \prime } } {d \nu ( y ) } \right ) ^ { {q / {p ^ \prime } } } } {d \mu ( x ) } < \infty, $$
where $ {1 / p } + {1 / { {p ^ \prime } } } = 1 $. By taking $ p = q = 2 $ one obtains the class of Hilbert–Schmidt operators (cf. Hilbert–Schmidt operator). Replacing $ \| \cdot \| _ {p} $, respectively $ \| \cdot \| _ {q} $, by arbitrary Banach function norms $ \rho _ {2} $, respectively $ \rho _ {1} $, one obtains the class of Hille–Tamarkin operators between Banach function spaces (sometimes called integral operators of finite double norm, see [a1]). Under some mild hypotheses on the norms, one can show that Hille–Tamarkin operators have rather strong compactness properties (see [a2]).
References
[a1] | A.C. Zaanen, "Riesz spaces" , II , North-Holland (1983) |
[a2] | A.R. Schep, "Compactness properties of Carleman and Hille–Tamarkin operators" Canad. J. Math. , 37 (1985) pp. 921–933 |
Hille-Tamarkin operator. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Hille-Tamarkin_operator&oldid=22579