具分段常数微分方程零解的全局吸引性

考虑具分段常数微分方程x′(t)=r(t)f(x([t])),t 0,其中r(t)非负连续,f有下界且具有负Schwarz导数,f∈C3(R,R),xf(x)<0当x≠0,f′(0)<0,[.]表示最大整数函数,证明了当-f′(0)n∫+1nr(s)ds≤2且∞∫0r(s)ds=∞时,方程的零解是全局吸引的.     

扇形域上高阶Schwarz边值问题

本文主要讨论一类角度为θ=π/α,α≥1/2的扇形域上高阶多解析方程的Schwarz边值问题.通过构造适当的高阶-Schwarz算子和Pompeiu算子,我们给出了详细的解表达式.本文把边值问题进一步推广到高阶情形,丰富了扇形域上边值问题的发展.     

非Lipschitz条件下半鞅随机微分方程解的唯一性(英文)

本文研究了非Lipschitz条件下半鞅随机微分方程.利用It(o)分析和Gronwall不等式,探讨了随机微分方程无爆炸解,并证明了随机微分方程解的唯一性.     

时标上一类最优控制问题的存在性

本文引进了时标上线性回归型微分方程的弱解并证明其弱解的存在唯一性，建立了时标上的Fatou引理，在此基础上，我们证明了受控系统为线性回归型微分方程的Lagrange最优控制问题解的存在性。     

非线性退缩椭圆型方程Neumann问题正解的存在性

利用变形后的山路引理[1 ] ,研究了一类非线性退缩椭圆型方程Neumann问题正解的存在性与不存在性     

一类奇异p－拉普拉斯方程径向解的存在性

研究奇异p-拉普拉斯方程div(|u|     

Banach空间中一类C~∞函数芽的分裂引理

分裂引理是突变论的基本定理。文［１］给出了Ｈｉｌｂｅｒ对空间中一类Ｃ~∞函数芽相应的结论。继［１］，我们将证明自反Ｂａｎａｃｈ空间中这类Ｃ~∞函数芽的分裂引理。     

广义Riemann可积与Lebesgue可积关系注记

研究了有限区间上无界函数及无限区间上函数的广义Riemann可积性、广义Riemann绝对可积性与Lebesgue可积性之间的关系 ,得到了一些充分必要条件     

关于C^1—0泛函的极小极大原理的一个注记

用非光滑分析的思想,对C~(1-0)泛函进行了分析,得到了关于C~(1-0)泛函的几个极小极大定理。     

Two-dimensional asymptotic expansions for large deviations of spherically distributed random vectors if the dominating point degenerates asymptotically

A geometric approach to asymptotic expansions for large-deviation probabilities, developed for the Gaussian law by Breitung and Richter [J. Multivariate Anal.,58, 1–20 (1996)], will be extended in the present paper to the class of spherical measures by utilizing their common geometric properties. This approach consists of rewriting the probabilities under consideration as large parameter values of the Laplace transform of a suitably defined function, expanding this function in a power series, and then applying Watson’s lemma. A geometric representation of the Laplace transform allows one to combine the global and local properties of both the underlying measure and the large-deviation domain. A special new type of difficulty is to be dealt with because the so-called dominating points of the large-deviation domain degenerate asymptotically. As is shown in Richter and Schumacher (in print), the typical statistical applications of large-deviation theory lead to such situations. In the present paper, consideration is restricted to a certain two-dimensional domain of large-deviations having asymptotically degenerating dominating points. The key assumption is a parametrized expansion for the inverse $\bar g^{ - 1} $ of the negative logarithm of the density-generating function of the two-dimensional spherical law under consideration.