No Arabic abstract
We give an estimate of the general divided differences $[x_0,dots,x_m;f]$, where some of the $x_i$s are allowed to coalesce (in which case, $f$ is assumed to be sufficiently smooth). This estimate is then applied to significantly strengthen Whitney and Marchaud celebrated inequalities in relation to Hermite interpolation. For example, one of the numerous corollaries of this estimate is the fact that, given a function $fin C^{(r)}(I)$ and a set $Z={z_j}_{j=0}^mu$ such that $z_{j+1}-z_j geq lambda |I|$, for all $0le j le mu-1$, where $I:=[z_0, z_mu]$, $|I|$ is the length of $I$ and $lambda$ is some positive number, the Hermite polynomial ${mathcal L}(cdot;f;Z)$ of degree $le rmu+mu+r$ satisfying ${mathcal L}^{(j)}(z_ u; f;Z) = f^{(j)}(z_ u)$, for all $0le u le mu$ and $0le jle r$, approximates $f$ so that, for all $xin I$, [ big|f(x)- {mathcal L}(x;f;Z) big| le C left( mathop{rm dist} olimits(x, Z) right)^{r+1} int_{mathop{rm dist} olimits(x, Z)}^{2|I|}frac{omega_{m-r}(f^{(r)},t,I)}{t^2}dt , ] where $m :=(r+1)(mu+1)$, $C=C(m, lambda)$ and $mathop{rm dist} olimits(x, Z) := min_{0le j le mu} |x-z_j|$.
In this article, we investigate the multilinear distorted multiplier estimate (Coifman-Meyer type theorem) associated with the Schr{o}dinger operator $H=-Delta + V$ in the framework of the corresponding distorted Fourier transform. Our result is the distorted analog of the multilinear Coifman-Meyer multiplier operator theorem in cite{CM1}, which extends the bilinear estimates of Germain, Hani and Walshs in cite{PZS} to the multilinear case for all dimensions. As applications, we give the estimate of Leibnizs law of integer order derivations for the multilinear distorted multiplier for the first time and we obtain small data scattering for a kind of generalized mass-critical NLS with good potential in low dimensions $d=1,2$.
By applying the MC algorithm and the Bauer-Muir transformation for continued fractions, in this paper we shall give six examples to show how to establish an infinite set of continued fraction formulas for certain Ramanujan-type series, such as Catalans constant, the exponential function, etc.
We establish partial semigroup property of Riemann-Liouville and Caputo fractional differential operators. Using this result we prove theorems on reduction of multi-term fractional differential systems to single-term and multi-order systems, and prove existence and uniqueness of solution to multi-term Caputo fractional differential systems
Using the Laplace derivative a Perron type integral, the Laplace integral, is defined. Moreover, it is shown that this integral includes Perron integral and to show that the inclusion is proper, an example of a function is constructed, which is Laplace integrable but not Perron integrable. Properties of integrals such as fundamental theorem of calculus, Hakes theorem, integration by parts, convergence theorems, mean value theorems, the integral remainder form of Taylors theorem with an estimation of the remainder, are established. It turns out that concerning the Alexiewiczs norm, the space of all Laplace integrable functions is incomplete and contains the set of all polynomials densely. Applications are shown to Poisson integral, a system of generalised ordinary differential equations and higher-order generalised ordinary differential equation.
It is proved that for class $A_gamma={qin L_1[0,1]: qgeq 0, int_0^1 q^gamma,dx=1}$, where $gammain (0,1)$, there exists a potential $q_*in A_gamma$ such that minimal eigenvalue $lambda_1(q_*)$ of boundary problem $$ -y+q_*y=lambda y, y(0)=y(1)=0 $$ is equal to $m_gamma=inf_{qin A_gamma}lambda_1(q)$. The equality $m_gamma=1$ for $gammaleq 1-2pi^{-2}$ and the inequality $m_gamma<1$ for $gamma>1-2pi^{-2}$ are also obtained.