Binomial Sums with Pell and Lucas Polynomials

Starting from a representation formula for 2 × 2 non-singular complex matrices in terms of 2nd kind Chebyshev polynomials, a link is observed between the 1st kind Chebyshev polinomials and traces of matrix powers. Then, the standard composition of matrix powers is used in order to derive composition identities of 2nd and 1st kind Chebyshev polynomials. Before concluding the paper, the possibility to extend this procedure to the multivariate Chebyshev and Lucas polynomials is touched on.

Download Full-text

Some Properties of the(p,q)-Fibonacci and(p,q)-Lucas Polynomials

Journal of Applied Mathematics ◽

10.1155/2012/264842 ◽

2012 ◽

Vol 2012 ◽

pp. 1-18 ◽

Cited By ~ 6

Author(s):

GwangYeon Lee ◽

Mustafa Asci

Keyword(s):

Generating Functions ◽

Combinatorial Identities ◽

Fibonacci Polynomials ◽

Lucas Polynomials ◽

Pascal Matrix ◽

Riordan Arrays ◽

Combinatorial Sums

Riordan arrays are useful for solving the combinatorial sums by the help of generating functions. Many theorems can be easily proved by Riordan arrays. In this paper we consider the Pascal matrix and define a new generalization of Fibonacci polynomials called(p,q)-Fibonacci polynomials. We obtain combinatorial identities and by using Riordan method we get factorizations of Pascal matrix involving(p,q)-Fibonacci polynomials.

Download Full-text

On the k -Lucas Numbers and Lucas Polynomials

Turkish Journal of Analysis and Number Theory ◽

10.12691/tjant-5-4-1 ◽

2017 ◽

Vol 5 (4) ◽

pp. 121-125 ◽

Cited By ~ 3

Author(s):

Ali Boussayoud ◽

Mohamed Kerada ◽

Nesrine Harrouche

Keyword(s):

Lucas Numbers ◽

Lucas Polynomials

Download Full-text

Proof of Sun's Conjecture on the Divisibility of Certain Binomial Sums

The Electronic Journal of Combinatorics ◽

10.37236/3100 ◽

2013 ◽

Vol 20 (4) ◽

Cited By ~ 4

Author(s):

Victor J. W. Guo

Keyword(s):

Left Hand ◽

Right Hand ◽

The Right ◽

Binomial Sums

In this paper, we prove the following result conjectured by Z.-W. Sun:$$(2n-1){3n\choose n}|\sum_{k=0}^{n}{6k\choose 3k}{3k\choose k}{6(n-k)\choose 3(n-k)}{3(n-k)\choose n-k}$$by showing that the left-hand side divides each summand on the right-hand side.

Download Full-text

Nested (inverse) binomial sums and new iterated integrals for massive Feynman diagrams

10.22323/1.211.0020 ◽

2014 ◽

Author(s):

Clemens Gunter Raab ◽

Jakob Ablinger ◽

Johannes Bluemlein ◽

Carsten Schneider

Keyword(s):

Feynman Diagrams ◽

Iterated Integrals ◽

Binomial Sums

Download Full-text

Asymptotic behaviors with convergence rates of distributions of negative-binomial sums

Science and Technology Development Journal ◽

10.32508/stdj.v22i4.1689 ◽

2020 ◽

Vol 22 (4) ◽

pp. 415-421

Author(s):

Tran Loc Hung ◽

Phan Tri Kien ◽

Nguyen Tan Nhut

Keyword(s):

Limit Theorems ◽

Negative Binomial ◽

Convergence Rates ◽

Random Variables ◽

Rates Of Convergence ◽

Weak Limit ◽

Probability Metric ◽

Weak Limit Theorems ◽

Distribution Theorem ◽

Binomial Sums

The negative-binomial sum is an extension of a geometric sum. It has been arisen from the necessity to resolve practical problems in telecommunications, network analysis, stochastic finance and insurance mathematics, etc. Up to the present, the topics related to negative-binomial sums like asymptotic distributions and rates of convergence have been investigated by many mathematicians. However, in a lot of various situations, the results concerned the rates of convergence for negative-binomial sums are still restrictive. The main purpose of this paper is to establish some weak limit theorems for negative-binomial sums of independent, identically distributed (i.i.d.) random variables via Gnedenko's Transfer Theorem originated by Gnedenko and Fahim (1969). Using Zolotarev's probability metric, the rate of convergence in weak limit theorems for negativebinomial sum are established. The received results are the rates of convergence in weak limit theorem for partial sum of i.i.d random variables related to symmetric stable distribution (Theorem 1), and asymptotic distribution together with the convergence rates for negative-binomial sums of i.i.d. random variables concerning to symmetric Linnik laws and Generalized Linnik distribution (Theorem 2 and Theorem 3). Based on the results of this paper, the analogous results for geometric sums of i.i.d. random variables will be concluded as direct consequences. However, the article has just been solved for the case of 1 <a < 2; it is quite hard to estimate in the case of a 2 (0;1) via the Zolotarev's probability metric. Mathematics Subject Classification 2010: 60G50; 60F05; 60E07.

Download Full-text