原函数

yuán hán shù
  • primitive;antiderivative;original
原函数原函数
原函数[yuán hán shù]
  1. W2~1空间中的最佳数值原函数

    The optimal numerical primitive function in the space w_2 ~ 1

  2. 定义了n重导数,n元绝对连续函数,广义n重原函数及牛顿n重积分。

    It defines n-ple derivative , n-ary absolutely continuous function , generalized n-ple primitive function and Newton n-ple integral .

  3. 原函数存在与Riemann可积

    Existence of Primitive Function and Riemann Integrability

  4. 传统的RBF隐式曲面几何变换算法是:在给定点使用逆变换,然后用逆变换后的点,在原函数中计算函数值。

    The conventional algorithm to transform an RBF implicit surface is to apply inverse transformation to the given point and to evaluate the original function at the inversely transformed point .

  5. 本文针对微分中值类问题的不同特征,归纳出三种辅助函数的构造方法,即原函数法,常数k值法,微分方程法。

    According to different features of the value-kind questions in differential calculous , three kinds of auxiliary functions structures can be concluded . They are original function method , constant K value method and differential calculous equation method .

  6. 提出支持向量机对可积分函数的原函数的求解方法并给出求解径向基核函数(RBF)的原函数的示例。

    The method of using SVM to solve primitive function of integrable function is proposed and a simulation for solving primitive function of Radial Basis Function ( RBF ) is given in this paper .

  7. 本文对含有阶梯函数、Dirac函数的简支梁挠曲线的四阶微分方程进行Laplace变换,然后再进行逆变换,求出原函数,最后利用边界条件推导并建立连续梁的新三弯矩方程。

    New equation is derived from an object function by means of initial values af-ter the differential equation of deflection in the simply supported beam with step func-tion , and dirac function is laplace transformed and inverse transformed .

  8. 高阶导数与原函数统一性的研究

    Study on the Unity of the Higher-order Derivation & Primary Function

  9. 关于分段连续函数的原函数的连续性及其应用

    On the Original Functional Continuity of Sectional-continuous Function and Its Application

  10. 构造中值问题辅助函数的原函数法

    Object Function Method to Construct Auxiliary Functions for Intermediate Value Problems

  11. 导数与原函数结构定理的注记

    A Note on Structure Theorem of Derivative & Primary Function

  12. 关于函数的原函数与可积性关系的讨论

    On the Relationship between Primitive Functions and Integrality of Functions

  13. 可积函数的原函数的存在性问题

    The Existence of Primitive Function of Integrable Function Problems

  14. 分段函数、函数的可积性与原函数存在性

    Piecewise Function , Integrability and Existence of Primitive Function

  15. 原函数导数逼近数据重构的通量差分分裂方法

    New reconstruction method of flux difference scheme based on primitive function derivative difference

  16. 模糊数值函数积分原函数的可导性问题

    The Differentiability of Primitives for the Fuzzy-Valued Functions

  17. 对于原函数存在定理的推广,给出了另一种证明;

    Mine is another proof about generalization of the existence theorem of original function ;

  18. B-积分下的原函数

    The primitive functions of B integrable functions

  19. 关于原函数存在条件的讨论

    Discussion on existential conditions of primitive function

  20. 函数的原函数的图形称为的积分曲线。

    The graph of the antiderivative of the function is called the integral curve of .

  21. 用面积原理证明了原函数存在定理;

    Application of the area principle may enable some problems to be visual and eaSy .

  22. 复杂特型函数高阶导数与原函数统一性的推广

    Generalization of the Unity of the Complicated Special Function 's Higher-order Derivation and Primary Function

  23. 用面积证明原函数存在定理和调和级数的发散性

    Proving to the Existence Theorem of Primitive Functions and Divergence of Harmonic Series with Area Principle

  24. 特殊类型函数高阶导数与原函数的统一公式

    An Universal Formula to Compute the Higher-Order Derivative and the Primary Function of Special Kinds of Functions

  25. 如果你想要严格的近似等式,那就意味着我们要用切线逼近来取代原函数。

    If you want strict equalities in approximations means that we replace the function by its tangent approximation .

  26. 原函数的存在性

    The existence of anti-derivatives

  27. 设Φ(t)是黎曼ξ-函数傅里叶余弦变换式中的原函数。

    Let Φ( t ) be original function defined by the Fourier transform of Riemann ξ - function .

  28. 乘积的原函数

    The anti-derivatives of product

  29. 阐明了积分等于原函数增量以及连续与可原、连续与积分的关系,说明了积分的几何意义是无限个微分曲边梯形面积之和。

    And also shows that the geometric meaning of integral is the area sum of infinite differential curve trapezoid .

  30. 它们意味着我们可以,用一些相近的线性公式来替代原函数。

    They mean that we replace the function , actually , by some closest linear formula that will be nearby .