We face a rigidity problem for the fractional $p$-Laplace operator to extend to this new framework some tools useful for the linear case. It is known that $(-Delta)^s(1-|x|^{2})^s_+$ and $-Delta_p(1-|x|^{rac{p}{p-1}})$ are constant functions in $(-1,1)$ for fixed $p$ and $s$. We evaluated $(-Delta_p)^s(1-|x|^{rac{p}{p-1}})^s_+$ proving that it is not constant in $(-1,1)$ for some $pin (1,+infty)$ and $sin (0,1)$. This conclusion is obtained numerically thanks to the use of very accurate Gaussian numerical quadrature formulas.
Some evaluations of the fractional p-Laplace operator on radial functions
Francesca Colasuonno;
2022-01-01
Abstract
We face a rigidity problem for the fractional $p$-Laplace operator to extend to this new framework some tools useful for the linear case. It is known that $(-Delta)^s(1-|x|^{2})^s_+$ and $-Delta_p(1-|x|^{rac{p}{p-1}})$ are constant functions in $(-1,1)$ for fixed $p$ and $s$. We evaluated $(-Delta_p)^s(1-|x|^{rac{p}{p-1}})^s_+$ proving that it is not constant in $(-1,1)$ for some $pin (1,+infty)$ and $sin (0,1)$. This conclusion is obtained numerically thanks to the use of very accurate Gaussian numerical quadrature formulas.File in questo prodotto:
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