基样条插值的极限性质(英文)

本文证明了当 m→∞时‖ s( k)m f- f( k) ‖ p→ 0 ( 1 <p<∞ ,k=0 ,1 ,2… )的充要条件是 f∈Bπ,p,其中 Bπ,p=Bπ∩ Lp( R) ,Bπ 表示指数 π型的整函数在 R上限制为有界函数所构成的集合 ,而Smf是在整数点对 f插值的唯一确定的 m-1次基样条 .进而得到了函数类 Bπ,p的三个等价的特征刻划 .

样条型矩阵有理插值

矩阵值有理插值在部分实现问题和系统线性理论的模型简化问题中起重要的作用 ,顾传青给出了矩阵值有理插值的Lagrange基形式 .我们根据基样条插值的性质构造了一种样条型的矩阵值有理插值 ,这种插值形式避免了高次Lagrange多项式插值的不稳定性 。

插值样条δ-序列求解非线性对流扩散方程

提出了一种用广义函数δ序列求解偏微分方程的数值方法.首先对一阶B样条函数N1(x)进行卷积得到四阶B样条函数N4(x),用N4(x)的线性组合构造出三次样条插值基函数;然后用样条插值基序列逼近δ函数,利用δ函数的性质构造插值样条δ序列,该δ序列具有对称、Riesz基和插值性质.以非线性对流扩散方程(伯格方程)为例,用插值样条δ序列离散该方程的空间形式,用四阶龙格库塔方法描述发展过程,取得了较好的精度.为减少计算量,加快插值函数的收敛速度,进一步提高求解精度,对δ序列进行了改进,对同一算例进行数值实验,结果表明,改进后的算法求解过程稳定发展,能够有效描述局部快速变化的情况.

采用三角形面积坐标的四边形17节点样条单元

利用二元4次样条插值基和三角形面积坐标构造17节点四边形单元.这个新单元具有4次完备阶,通过一些算例测试表明了该单元有较高精度并对网格畸变不敏感.

三次样条Hermite插值基构造四边形薄板单元

薄板弯曲单元被广泛地应用到工程问题的有限元计算中.然而,由于协调的薄板弯曲位移型单元要求挠度和转角(即位移的函数值和导数值)都是连续的,导致很难直接构造协调的位移型薄板单元.在数学上,样条是满足一定协调性的分片光滑的多项式,有限元的形函数可以视为样条函数.本文基于三角形面积坐标和B网方法,利用三次样条Hermite插值基重构了两个协调的薄板弯曲单元.由于单元形函数是基于四边形构造的,避免了等参变换,可以有效地降低网格畸变对计算精度的影响.

基于SBFEM和样条插值的多边形偶应力/应变梯度理论单元

偶应力/应变梯度理论是刻画材料在细观或微观尺度的应变非局部化现象的理论,其基本方程是在传统连续体力学二阶微分方程基础上增加含有材料长度参数的四阶微分方程.偶应力/应变梯度理论有限元的节点参数包含位移的函数值和导数值,并由C^(0-1)和C^(1)增强分片检验要求单元对位移函数满足2次完备性和C^(0)连续.相比三角形和四边形单元,构造具有高阶完备性的多边形单元形状函数更有难度,目前还缺少用于求解偶应力和应变梯度理论的多边形单元的研究.本文采用比例边界有限元方法(SBFEM)和基于离散Kirchhoff理论的多边形薄板样条单元(DKPS)相结合的方法,构造用于求解偶应力/应变梯度理论的多边形单元(SBFEMd3-DKPSd2).分别用SBFEM中环向3次单元和DKPS单元计算单元应变和应变梯度的刚度矩阵,避免了单元形状函数表达式的计算,并满足偶应力/应变梯度理论分片检验的要求.数值算例显示,该单元对凸多边形、非凸多边形和1-irregular退化的网格都有很好的计算精度.

H^1()和S_(m,1)(IR)的同构

设Ｈ１（ＺＩ）为离散的Ｈａｒｄｙ空间，即Ｈ１（ＺＩ）＝｛ｙ∈ｌ１（ＺＩ）：Ｈｙ＝｛Ｈｙｊ｝∈ｌ１（ＺＩ），其中Ｈｙｊ＝ｋ≠ｊ（ｋ－ｊ）－１ｙｊ为离散的希尔伯特变换．令Ｓｍ，１（ＩＲ）表示属于Ｌ１（ＩＲ）的ｍ－１次基样条的全体．本文证得∩ｍＳｍ，１（ＩＲ）与Ｈ１（ＺＩ）同构．

基于离散Kirchhoff理论的多边形样条薄板单元

在有限元方法中,采用多边形单元可以有效地模拟材料的力学性能,又使得网格剖分变得灵活方便.此外,允许退化情形的多边形单元可以处理出现悬节点的奇异网格.但目前对多边形薄板单元的研究却不多.多边形单元的研究难点在于插值基函数的构造.本文采用样条和基于三角形面积坐标的B网方法,将多边形进行三角剖分,通过适当选取连续性条件消去内部节点自由度,构造允许1-irregular退化的多边形样条插值基函数,再结合离散Kirchhoff理论得到多边形薄板弯曲单元,记为DKPS单元.该单元的插值自由度为各个顶点处的扰度和两个转角,并对直角坐标具有二次完备性,可以处理凸多边形、凹多边形和退化的网格.而且,采用多项式B网方法,可以方便地进行单元刚度矩阵的计算,无需使用数值积分公式.数值实验显示该单元对畸变网格仍然能保持很好的计算精度,是一种高效的单元.

Downhole microseismic data reconstruction and imaging based on combination of spline interpolation and curveletsparse constrained interpolation

When cause of the aliasing lack probl using borehole sensors and microseimic events to image, spatial aliasing often occurred be- of sensors underground and the distance between the sensors which were too large. To solve em, data reconstruction is often needed. Curvelet transform sparsity constrained inversion was widely used in the seismic data reconstruction field for its anisotropic, muhiscale and local basis. However, for the downhole ease, because the number of sampling point is mueh larger than the number of the sensors, the advantage of the cnrvelet basis can＇t perform very well. To mitigate the problem, the method that joints spline and curvlet-based compressive sensing was proposed. First, we applied the spline interpolation to the first arri- vals that to be interpolated. And the events are moved to a certain direction, such as horizontal, which can be represented by the curvelet basis sparsely. Under the spasity condition, curvelet-based compressive sensing was applied for the data, and directional filter was also used to mute the near vertical noises. After that, the events were shifted to the spline line to finish the interpolation workflow. The method was applied to a synthetic mod- el, and better result was presented than using curvelet transform interpolation directly. We applied the method to a real dataset, a mieroseismic downhole observation field data in Nanyang, using Kirchhoff migration method to image the microseimic event. Compared with the origin data, artifacts were suppressed on a certain degree.