共查询到20条相似文献,搜索用时 78 毫秒
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樊守芳 《数学的实践与认识》2018,(17)
首先探讨了闭区间上非负连续函数列积分构成的数列极限问题,给出了极限值与函数最值有关的结论.然后利用此结论,研究了闭区间上非负连续函数列积分的第一积分中值定理"中间点"构成数列的单调性与敛散性,得到了一系列结论. 相似文献
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关于weierstrass逼近定理的几点注记 总被引:2,自引:0,他引:2
Weierstrass逼近定理是函数逼近论中的重要定理之一,定理阐述了闭区间上的连续函数可以用一多项式去逼近.将该定理进行推广:即使一个函数是几乎处处连续的,也不一定具有与连续函数相类似的逼近性质,但是一个处处不连续的函数却有可能具有这样的性质.证明了定义在闭区间上且与连续函数几乎处处相等的函数具有类似的逼近性质,并给出了weierstrass逼近定理的一个推广应用. 相似文献
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函数的连续性是函数的重要性质,常量函数、幂函数、指数函数、对数函数、三角函数、反三角函数以及由它们经过有限次四则运算与复合运算所得到的函数都是连续函数。 相似文献
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判别函数列一致收敛的方法有函数列一致收敛定义、Cauchy一致收敛准则、limn→∞supx∈D|fn(x)-f(x)|=0及Dini定理,本文由函数列的等度连续性,可得出几个有界闭区间上连续函数列一致收敛的充要条件,推广了Dini定理. 相似文献
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Murat Sahin 《Applied mathematics and computation》2011,217(12):5416-5420
Let a0, a1, … , ar−1 be positive numbers and define a sequence {qm}, with initial conditions q0 = 0 and q1 = 1, and for all m ? 2, qm = atqm−1 + qm−2 where m ≡ t(mod r). For r = 2, the author called the sequence {qm} as the generalized Fibonacci sequences and studied it in [1]. But, it remains open to find a closed form of the generating function for general {qm}. In this paper, we solve this open problem, that is, we find a closed form of the generating function for {qm}in terms of the continuant. 相似文献
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席高文 《数学的实践与认识》2007,37(5):117-124
通过Fibonacci序列和Lucas序列的生成函数,利用导函数的性质,得到了Fibonacci序列和Lucas序列构成的混合卷积∑a1+a2+…+ak+b1+b2+…+b1+c1+c2+…+cm=na1Fa1+1…akFak+1.Fb1…Fb1.Lc1+1…Lcm+1的计算公式. 相似文献
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研究了长度为2n-1的二元GMW序列的迹表示,用从F2n到F2的迹函数的和式给出了GMW序列的一种简洁的迹表示,并且通过这种迹表示得到了一种新的快速生成GMW序列的方法和一种求GMW序列的极小多项式的方法.最后,还证明了两个GMW序列具有相同极小多项式的一个充要条件. 相似文献
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Trace Representation of Legendre Sequences 总被引:3,自引:0,他引:3
In this paper, a Legendre sequence of period p for any odd prime p is explicitely represented as a sum of trace functions from GF(2
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) to GF(2), where n is the order of 2 mod p. 相似文献
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Sándor Kiss 《Periodica Mathematica Hungarica》2005,51(2):31-35
Summary Let <InlineEquation ID=IE"1"><EquationSource Format="TEX"><![CDATA[<InlineEquation ID=IE"2"><EquationSource Format="TEX"><![CDATA[<InlineEquation
ID=IE"3"><EquationSource Format="TEX"><![CDATA[<InlineEquation ID=IE"4"><EquationSource Format="TEX"><![CDATA[<InlineEquation
ID=IE"5"><EquationSource Format="TEX"><![CDATA[<InlineEquation ID=IE"6"><EquationSource Format="TEX"><![CDATA[<InlineEquation
ID=IE"7"><EquationSource Format="TEX"><![CDATA[<InlineEquation ID=IE"8"><EquationSource Format="TEX"><![CDATA[<InlineEquation
ID=IE"9"><EquationSource Format="TEX"><![CDATA[<InlineEquation ID=IE"10"><EquationSource Format="TEX"><![CDATA[<InlineEquation
ID=IE"11"><EquationSource Format="TEX"><![CDATA[<InlineEquation ID=IE"12"><EquationSource Format="TEX"><![CDATA[<InlineEquation
ID=IE"13"><EquationSource Format="TEX"><![CDATA[<InlineEquation ID=IE"14"><EquationSource Format="TEX"><![CDATA[<InlineEquation
ID=IE"15"><EquationSource Format="TEX"><![CDATA[$]]></EquationSource></InlineEquation>]]></EquationSource></InlineEquation>]]></EquationSource></InlineEquation>]]></EquationSource></InlineEquation>]]></EquationSource></InlineEquation>]]></EquationSource></InlineEquation>]]></EquationSource></InlineEquation>]]></EquationSource></InlineEquation>]]></EquationSource></InlineEquation>]]></EquationSource></InlineEquation>]]></EquationSource></InlineEquation>]]></EquationSource></InlineEquation>]]></EquationSource></InlineEquation>]]></EquationSource></InlineEquation>]]></EquationSource></InlineEquation>\mathcal{A}=\{a_{1},a_{2},\dots{}\}$
$(a_{1} \le a_{2} \le \dots{})$ be an infinite sequence of nonnegative integers, and let $R(n)$ denote the number of solutions
of $a_{x}+a_{y}=n$ $(a_{x},a_{y}\in\mathcal{A})$. P. Erd?s, A. Sárk?zyand V. T. Sós proved that if $\lim_{N\to\infty}\frac{B(\mathcal{A},N)}{\sqrt{N}}=+\infty$
then $|\Delta_{1}(R(n))|$ cannot be bounded, where ${B(\mathcal{A},N)}$ denotes the number of blocks formed by consecutive
integers in $\mathcal{A}$ up to $N$ and $\Delta_{k}$ denotes the $k$-th difference. The aim of this paper is to extend this
result to $\Delta_{k}(R(n))$ for any fixed $k\ge2$. 相似文献
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刻划了特征为4的Galois环上本原序列最高权位序列的相关函数、线性度和元素分布等密码特征。 相似文献
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Periodica Mathematica Hungarica - Let a1&;lt;... be an infinite sequence of positive integers, let k≥2 be a fixed integer and denote by Rk(n) the number of solutions of n=ai1+ai2+...+aik.... 相似文献
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An increasing sequence of positive integers {n1, n2, …} is called a sum-free sequence if every term is never a sum of distinct smaller terms. We prove that there exist sum-free sequences {nk} with polynomial growth and such that limk→∞ nk+1/nk = 1. 相似文献
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Miloud Mihoubi 《Discrete Mathematics》2008,308(12):2450-2459
This paper concerns the study of the Bell polynomials and the binomial type sequences. We mainly establish some relations tied to these important concepts. Furthermore, these obtained results are exploited to deduce some interesting relations concerning the Bell polynomials which enable us to obtain some new identities for the Bell polynomials. Our results are illustrated by some comprehensive examples. 相似文献