We consider a scalar integral equation $z(t)=a(t)-\int^t_0 C(t,s)[z(s)+G(s,z(s))]ds$ where $|G(t,z)|\leq \phi(t)|z|$, $C$ is convex, and $a\in (L^{\infty}\cap L^2)[0,\infty)$. Related to this is the linear equation $x(t)=a(t)-\int^t_0 C(t,s)x(s)ds$ and the resolvent equation $R(t,s)=C(t,s)-\int^t_s C(t,u)R(u,s)du$. A Liapunov functional is constructed which gives qualitative results about all three equations. We have two goals. First, we are interested in conditions under which properties of $C$ are transferred into properties of the resolvent $R$ which is used in the variation-of-parameters formula. We establish conditions on $C$ and functions $b$ so that $\int^t_0 C(t,s)b(s)ds \to 0$ as $t \to \infty$ and is in $L^2[0,\infty)$ implies that $\int^t_0 R(t,s)b(s)ds \to 0$ as $t \to \infty$ and is in $L^2[0,\infty)$. Such results are fundamental in proving that the solution $z$ satisfies $z(t) \to a(t)$ as $t \to \infty$ and that $\int^{\infty}_0 (z(t)-a(t))^2dt <\infty$.
@article{95,
title = {Kernel-resolvent relations for and integral equation},
journal = {Tatra Mountains Mathematical Publications},
volume = {49},
year = {2011},
doi = {10.2478/tatra.v48i0.95},
language = {EN},
url = {http://dml.mathdoc.fr/item/95}
}
Burton, Theodore A. Kernel-resolvent relations for and integral equation. Tatra Mountains Mathematical Publications, Tome 49 (2011) . doi : 10.2478/tatra.v48i0.95. http://gdmltest.u-ga.fr/item/95/