共查询到19条相似文献,搜索用时 265 毫秒
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本文提出两个新的估计量,利用观察数据中的总体辅助信息来估计有限总体分布函数,并通过两个人工总体的模拟实验,比较新的估计量、传统的估计量及Rao,Kover&Mantel(1990)提出的估计量的相对平均误差与相对标准差。结果表明,从相对标准差的角度分析,两个新的估计量有一个是四个估计量中精度最好的一个,另一个也有很好的表现;而且它们在模型有所偏差时都具备了较好的稳健性。 相似文献
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过程能力指数(C_p)估计的关键是对总体标准差的估计。在多个子样本情形下,采用4个无偏估计量■,■_s,■_R,■_p分别估计总体标准差σ,证明了直接以此为基础的过程能力指数的估计量都是有偏的,且都有高估C_p的倾向;之后构造了C_p的4个无偏估计量;探讨了其中3个无偏估计量的估计效率;最后结合案例计算了C_p的不同估计值。 相似文献
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用s去估计总体分布的标准差σ不是无偏估计,在特定总体分布下,可以通过简单的修正达到无偏估计.修正系数的确定与样本容量有关. 相似文献
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我们在前文[2]介绍了多组试验时正态分布均值的估计公式,本文继续介绍如何通过多组试验数据来估计正态总体的标准差。 一、各组试验次数相等 设正态总体X~N(μ,σ),其中均值μ和标准差σ未知。今有m组样本,每组样本大小n相等,其试验数据如下:求标准差σ的估计σ。 我们记第i组 相似文献
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An Alternative Method for Solving Lagrange's First-Order Partial Differential Equation with Linear Function Coefficients
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Syed Md Himayetul Islam & J. Das 《偏微分方程(英文版)》2015,28(3):208-224
An alternative method of solving Lagrange's first-order partial differential equation of the form $$(a_1x+b_1y+c_1z)p+(a_2x+b_2y+c_2z)q=a_3x+b_3y+c_3z,$$ where p=∂z/∂x, q=∂z/∂y and a_i, b_i, c_i (i=1,2,3) are all real numbers has been presented here. 相似文献
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讨论了一类三次系统x=-y(1-βx2)-(a1x a2x2 a3x3),y=b1x b2x2 b3x3的极限环问题.对包含一个奇点或多个奇点的极限环的唯一性和唯二性给出了若干充分条件. 相似文献
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具有三对特殊方向的一类平面齐五次系统的全局拓扑结构 总被引:1,自引:0,他引:1
研究了一类平面齐五次系统dxdxdt=a50x5+a41x4y+a32x3y2+a23x2y3+a14xy4+a05y5,dydt=b50x5+b41x4y+b32x3y2+b23x2y3+b14xy4+b05y5当其只有唯一的有限远奇点且具有三对特殊方向时的全局拓扑结构及系数条件.假设系统只有唯一的有限远奇点(0,0),不妨设b50=0,其特殊方向由示性方程G(θ)=0给出,引进poincare变换研究无穷远奇点,再根据定理中的系数条件,列出系统所有可能的无穷远奇点和特殊方向,并判断其类型,由此画出系统具有三对特殊方向时的全局相图. 相似文献
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研究一类Kolmogorov捕食系统dx/dt=x(a_0-a_1x+a_2x~(n-1)-a_3x~n+a_4xy~m),dy/dt=y(b_1x~n-b2),得到了存在唯一极限环和不存在极限环的充要条件,从而推广了前人相关的结果. 相似文献
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In this paper we discuss a method used to find the smallest nontrivial positive integer solutions to . The method, which is an improvement over a simple brute force approach, can be applied to search the solution to similar equations involving sixth, eighth and tenth powers.
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This paper studies Menon–Sury’s identity in a general case, i.e., the Menon–Sury’s identity involving Dirichlet characters in residually finite Dedekind domains. By using the filtration of the ring \({\mathfrak {D}}/{\mathfrak {n}}\) and its unit group \(U({\mathfrak {D}}/{\mathfrak {n}})\), we explicitly compute the following two summations:
$$\begin{aligned} \sum _{\begin{array}{c} a\in U({\mathfrak {D}}/{\mathfrak {n}}) \\ b_1, \ldots , b_r\in {\mathfrak {D}}/{\mathfrak {n}} \end{array}} N(\langle a-1,b_1, b_2, \ldots , b_r \rangle +{\mathfrak {n}})\chi (a) \end{aligned}$$and
$$\begin{aligned} \sum _{\begin{array}{c} a_{1},\ldots , a_{s}\in U({\mathfrak {D}}/{\mathfrak {n}}) \\ b_1, \ldots , b_r\in {\mathfrak {D}}/{\mathfrak {n}} \end{array}} N(\langle a_{1}-1,\ldots , a_{s}-1,b_1, b_2, \ldots , b_r \rangle +{\mathfrak {n}})\chi _{1}(a_1) \cdots \chi _{s}(a_s), \end{aligned}$$where \({\mathfrak {D}}\) is a residually finite Dedekind domain and \({\mathfrak {n}}\) is a nonzero ideal of \({\mathfrak {D}}\), \(N({\mathfrak {n}})\) is the cardinality of quotient ring \({\mathfrak {D}}/{\mathfrak {n}}\), \(\chi _{i}~(1\le i\le s)\) are Dirichlet characters mod \({\mathfrak {n}}\) with conductor \({\mathfrak {d}}_i\).
相似文献17.
Asymptotic Behavior in a Quasilinear Fully Parabolic Chemotaxis System with Indirect Signal Production and Logistic Source
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Dan Li & Zhongping Li 《偏微分方程(英文版)》2021,34(2):129-143
In this paper, we study the asymptotic behavior of solutions to a quasilinear
fully parabolic chemotaxis system with indirect signal production and logistic sourceunder homogeneous Neumann boundary conditions in a smooth bounded domain $Ω⊂\mathbb{R}^n$ $(n ≥1)$, where $b ≥0$, $γ ≥1$, $a_i ≥1$, $µ$, $b_i >0$ $(i =1,2)$, $D$, $S∈ C^2([0,∞))$ fulfilling $D(s) ≥ a_0(s+1)^{−α}$, $0 ≤ S(s) ≤ b_0(s+1)^β$ for all $s ≥ 0,$ where $a_0,b_0 > 0$ and $α,β ∈ \mathbb{R}$ are
constants. The purpose of this paper is to prove that if $b ≥ 0$ and $µ > 0$ sufficiently
large, the globally bounded solution $(u,v,w)$ with nonnegative initial data $(u_0,v_0,w_0)$ satisfies $$\Big\| u(·,t)− \Big(\frac{b}{µ}\Big)^{\frac{1}{γ}}\Big\|_{L^∞(Ω)}+\Big\| v(·,t)−\frac{b_1b_2}{a_1a_2}\Big(\frac{b}{µ}\Big)^{\frac{1}{γ}}\Big\| _{L^∞(Ω)} +\Big\| w(·,t)−\frac{b_2}{a_2}\Big(\frac{b}{µ}\Big)^{\frac{1}{γ}}\Big\| _{L^∞(Ω)}→0$$ as $t→∞$. 相似文献
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А. Л. Лукашов 《Analysis Mathematica》1998,24(1):111-130
The Chebyshev-Markov problem about real algebraic functions of the form $A_n (x) = \frac{{x^n + c_1 x^{n - 1} + ... + c_n }}{{\left( {\prod {_{i = 1}^{2n} } \left( {1 - a_{i,n} x} \right)} \right)^{1/2} }}$ deviated least from zero on a system of intervals $\left[ {b_1 ;b_2 } \right] \cup ... \cup \left[ {b_{2p - 1} ;b_{2p} } \right], - \infty< b_1 \leqslant b_2< ...< b_{2p - 1} \leqslant b_{2p}< + \infty $ is considered. The expression under the square root above is a real polynomial of degree less than 2n, which is positive on [b 1;b 2p ]. The solution of this problem is given in a parametric form in terms of automorphic Schottky-Burside functions. Similar functions were first used by N. I. Akhyeser in the approximation theory. 相似文献
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设α是环R的一个自同态,称环R是α-斜Armendariz环,如果在R[x;α]中,(∑_(i=0)~ma_ix~i)(∑_(j=0)~nb_jx~j)=0,那么a_ia~i(b_j)=0,其中0≤i≤m,0≤j≤n.设R是α-rigid环,则R上的上三角矩阵环的子环W_n(p,q)是α~—-斜Armendariz环. 相似文献