On Sums of Products of Horadam Numbers

Similar documents
Sums of Squares and Products of Jacobsthal Numbers

ALTERNATING SUMS OF FIBONACCI PRODUCTS

Formulas for sums of squares and products of Pell numbers

ON SUMS OF SQUARES OF PELL-LUCAS NUMBERS. Gian Mario Gianella University of Torino, Torino, Italy, Europe.

AREAS OF POLYGONS WITH COORDINATES OF VERTICES FROM HORADAM AND LUCAS NUMBERS. 1. Introduction

ON SUMS OF SQUARES OF ODD AND EVEN TERMS OF THE LUCAS SEQUENCE

Math 324 Summer 2012 Elementary Number Theory Notes on Mathematical Induction

G. Sburlati GENERALIZED FIBONACCI SEQUENCES AND LINEAR RECURRENCES

MATH 324 Summer 2011 Elementary Number Theory. Notes on Mathematical Induction. Recall the following axiom for the set of integers.

arxiv: v1 [math.co] 20 Aug 2015

ON IMPROVEMENTS OF THE BUTTERFLY THEOREM

THE p-adic VALUATION OF LUCAS SEQUENCES

Squares from D( 4) and D(20) Triples

Some congruences concerning second order linear recurrences

Several Generating Functions for Second-Order Recurrence Sequences

BALANCING NUMBERS : SOME IDENTITIES KABERI PARIDA. Master of Science in Mathematics. Dr. GOPAL KRISHNA PANDA

THE ORDER OF APPEARANCE OF PRODUCT OF CONSECUTIVE FIBONACCI NUMBERS

SOME SUMS FORMULAE FOR PRODUCTS OF TERMS OF PELL, PELL- LUCAS AND MODIFIED PELL SEQUENCES

198 VOLUME 46/47, NUMBER 3

Summation of Certain Infinite Lucas-Related Series

TILING PROOFS OF SOME FORMULAS FOR THE PELL NUMBERS OF ODD INDEX

On Some Properties of Bivariate Fibonacci and Lucas Polynomials

DIOPHANTINE QUADRUPLES FOR SQUARES OF FIBONACCI AND LUCAS NUMBERS

A LINEAR BINOMIAL RECURRENCE AND THE BELL NUMBERS AND POLYNOMIALS

A RECIPROCAL SUM RELATED TO THE RIEMANN ζ FUNCTION. 1. Introduction. 1 n s, k 2 = n 1. k 3 = 2n(n 1),

Discrete Structures Lecture Sequences and Summations

Balancing sequences of matrices with application to algebra of balancing numbers

PAijpam.eu ON THE BOUNDS FOR THE NORMS OF R-CIRCULANT MATRICES WITH THE JACOBSTHAL AND JACOBSTHAL LUCAS NUMBERS Ş. Uygun 1, S.

arxiv: v1 [math.nt] 17 Nov 2011

On arithmetic functions of balancing and Lucas-balancing numbers

On the Pell Polynomials

Examples of Finite Sequences (finite terms) Examples of Infinite Sequences (infinite terms)

Applied Mathematics Letters

NOTE ON FIBONACCI PRIMALITY TESTING John Brillhart University of Arizona, Tucson, AZ (Submitted August 1996-Final Revision January 1997)

The generalized order-k Fibonacci Pell sequence by matrix methods

The Third Order Jacobsthal Octonions: Some Combinatorial Properties

THE GENERALIZED TRIBONACCI NUMBERS WITH NEGATIVE SUBSCRIPTS

Compositions of n with no occurrence of k. Phyllis Chinn, Humboldt State University Silvia Heubach, California State University Los Angeles

Two Identities Involving Generalized Fibonacci Numbers

arxiv: v1 [math.co] 11 Aug 2015

CALCULATING EXACT CYCLE LENGTHS IN THE GENERALIZED FIBONACCI SEQUENCE MODULO p

Combinations. April 12, 2006

Definition: A sequence is a function from a subset of the integers (usually either the set

Some Generalized Fibonomial Sums related with the Gaussian q Binomial sums

Yi Wang Department of Applied Mathematics, Dalian University of Technology, Dalian , China (Submitted June 2002)

Generalized Identities on Products of Fibonacci-Like and Lucas Numbers

Impulse Response Sequences and Construction of Number Sequence Identities

4 Linear Recurrence Relations & the Fibonacci Sequence

Fibonacci and Lucas Identities the Golden Way

Partition of Integers into Distinct Summands with Upper Bounds. Partition of Integers into Even Summands. An Example

On Linear Recursive Sequences with Coefficients in Arithmetic-Geometric Progressions

Certain Diophantine equations involving balancing and Lucas-balancing numbers

Every subset of {1, 2,...,n 1} can be extended to a subset of {1, 2, 3,...,n} by either adding or not adding the element n.

COMPLEX FACTORIZATION BY CHEBYSEV POLYNOMIALS

arxiv: v1 [math.nt] 20 Sep 2018

McGill University Faculty of Science. Solutions to Practice Final Examination Math 240 Discrete Structures 1. Time: 3 hours Marked out of 60

On identities with multinomial coefficients for Fibonacci-Narayana sequence

ON QUADRAPELL NUMBERS AND QUADRAPELL POLYNOMIALS

Trigonometric Pseudo Fibonacci Sequence

Divisibility in the Fibonacci Numbers. Stefan Erickson Colorado College January 27, 2006

Exact Determinants of the RFPrLrR Circulant Involving Jacobsthal, Jacobsthal-Lucas, Perrin and Padovan Numbers

Counting Palindromic Binary Strings Without r-runs of Ones

Permanents and Determinants of Tridiagonal Matrices with (s, t)-pell Numbers

On the complex k-fibonacci numbers

On h(x)-fibonacci octonion polynomials

F. T. HOWARD AND CURTIS COOPER

On Some Combinations of Non-Consecutive Terms of a Recurrence Sequence

DIOPHANTINE EQUATIONS, FIBONACCI HYPERBOLAS, AND QUADRATIC FORMS. Keith Brandt and John Koelzer

ADVANCED PROBLEMS AND SOLUTIONS. Edited by Raymond E. Whitney

INCOMPLETE BALANCING AND LUCAS-BALANCING NUMBERS

Linear recurrence relations with the coefficients in progression

5. Sequences & Recursion

PHYS 301 HOMEWORK #5

Sets of MOLSs generated from a single Latin square

Recurrence Relations

ON THE POSSIBLE QUANTITIES OF FIBONACCI NUMBERS THAT OCCUR IN SOME TYPES OF INTERVALS

On Gaussian Pell Polynomials and Their Some Properties

12 Sequences and Recurrences

arxiv: v2 [math.co] 8 Oct 2015

Further generalizations of the Fibonacci-coefficient polynomials

BMO Round 1 Problem 1 Generalisation

k-jacobsthal and k-jacobsthal Lucas Matrix Sequences

The Fibonacci Identities of Orthogonality

COMBINATORIAL COUNTING

s-generalized Fibonacci Numbers: Some Identities, a Generating Function and Pythagorean Triples

Lucas Polynomials and Power Sums

A LIMITED ARITHMETIC ON SIMPLE CONTINUED FRACTIONS

COMPLEMENTARY FAMILIES OF THE FIBONACCI-LUCAS RELATIONS. Ivica Martinjak Faculty of Science, University of Zagreb, Zagreb, Croatia

THE LOG-BEHAVIOR OF THE SEQUENCE FOR THE PARTIAL SUM OF A LOG-CONVEX SEQUENCE. 1. Introduction

COM S 330 Lecture Notes Week of Feb 9 13

A PROOF OF MELHAM S CONJECTURE

arxiv: v1 [math.nt] 6 Apr 2018

Generating Functions (Revised Edition)

A MATRIX GENERALIZATION OF A THEOREM OF FINE

NEW IDENTITIES FOR THE COMMON FACTORS OF BALANCING AND LUCAS-BALANCING NUMBERS

Ex. Here's another one. We want to prove that the sum of the cubes of the first n natural numbers is. n = n 2 (n+1) 2 /4.

LINEAR RECURRENCES AND CHEBYSHEV POLYNOMIALS

AND OCCUPANCY PROBLEMS

Gaussian Modified Pell Sequence and Gaussian Modified Pell Polynomial Sequence

Sums. ITT9131 Konkreetne Matemaatika

Transcription:

KYUNGPOOK Math J 49(009), 483-49 On Sums of Products of Horadam Numbers Zvonko ƒerin Kopernikova 7, 10010 Zagreb, Croatia, Europe e-mail : cerin@mathhr Abstract In this paper we give formulae for sums of products of two Horadam type generalized Fibonacci numbers with the same recurrence equation and with possibly different initial conditions Analogous improved alternating sums are also studied as well as various derived sums when terms are multiplied either by binomial coecients or by members of the sequence of natural numbers These formulae are related to the recent work of Belbachir and Bencherif, ƒerin and ƒerin and Gianella 1 Introduction The generalized Fibonacci sequence {w n } = {w n (a 0, b 0 ; p, q)} is dened by w 0 = a 0, w 1 = b 0, w n = p w n 1 q w n (n ), where a 0, b 0, p and q are arbitrary complex numbers, with q 0 The numbers w n have been studied by Horadam (see, eg [10]) A useful and interesting special cases are {U n } = {w n (0, 1; p, q)} and {V n } = {w n (, p; p, q)} that were investigated by Lucas [11] For integers a 0, c 0, 0, b > 0 and d > 0, let P = U a+b U c+d, Q = U a+b V c+d and R = V a+b V c+d In [1] some formulae for the sums n =0 P, n =0 Q, n =0 R, n =0 ( 1) P, n =0 ( 1) Q and n =0 ( 1) R have been discovered in the special case when b = d = and q = ±1 Even in these restricted case they gave unication of earlier results by ƒerin and by ƒerin and Gianella for Fibonacci, Lucas, Pell and Pell-Lucas numbers (see [3] [9]) In [] the author eliminated all restrictions from the article [1] on b, d and q (except that q 0) Some other types of sums have also been studied like the improved alternating sums (when we multiply terms by increasing powers of a xed complex number), the sums with binomial coecients and sums in which we multiply terms by increasing natural numbers The goal in this paper is to extend these results to Horadam type generalized Fibonacci numbers Even in this more general case these sums could be evaluated using the sum of a geometric series Received May 6, 008; accepted May 6, 009 000 Mathematics Subect Classication: Primary 11B39, 11Y55, 05A19 Key words and phrases: Horadam generalized Fibonacci numbers, Lucas numbers, sums of products 483

484 Zvonko čerin Sums of products of two Horadam numbers We rst want to nd the formula for the sum Ψ 1 = w a+b (a 0, b 0 ; p, q) w c+d (c 0, d 0 ; p, q) =0 when a 0, b 0, c 0, d 0, p and q 0 are complex numbers and n 0, a 0, c 0, b > 0 and d > 0 are integers Let α and β be the roots of x p x + q = 0 Then α = p + and β = p, where = p 4 q Moreover, α β =, α + β = p, α β = q and the Binet forms of w n, U n and V n are w n = (b 0 a 0 β) α n + (a 0 α b 0 ) β n, U n = αn β n α β α β, V n = α n + β n, if α β, and w n = α n 1 (a 0 α + n (b 0 a 0 α)), U n = n α n 1, V n = α n, if α = β Let A 1 = b 0 a 0 α, A = d 0 c 0 α, B 1 = a 0 β b 0, B = c 0 β d 0 Let E = α b+d, F = α b β d, G = α d β b and H = β b+d Let e = α a+c B 1 B, f = α a β c A B 1, g = α c β a A 1 B and h = β a+c A 1 A When E 1, for any integer n 0, let E n = En+1 1 E 1 We similarly dene F n, G n and H n On the other hand, when α b β b, for any integer n 0, let b n = αb(n+1) β b(n+1) and α b n (α b β b b n = αb(n+1) β b(n+1) ) β b n (α b β b ) We similarly dene d n and d n For any integer n 0, let λ n = n + 1 Let T = α a+c Let C 1 = A 1 a + a 0 α, C = A c + c 0 α, K 1 = b d A 1 A, K 3 = C 1 C and K = b A 1 C + d A C 1 Let K 4 = K 1 + K + K 3 Let K, M, N and P be n ( n + 1) K 1 + 3 n K + 6 K 3, n E n+3 ( n + n 1) E n+ + (n + 1) E n+1 E(E + 1), n E n+3 ( n + 1) E n+ + (n + 1) E n+1 + E(E 1), E n+3 E n+ + E n+1 (E 1) (n + 1) K T Theorem 1 (a) When = 0 and E = 1, then Ψ 1 = 6 (b) When = 0 and E 1, then Ψ 1 = T [ K 1 M + K N + K 3 P ] (E 1) 3 Proof (a) Recall that when = 0, then w a+b (a 0, b 0 ; p, q) = α a 1+b [ b A 1 + C 1 ]

On Sums of Products of Horadam Numbers 485 and w c+d (c 0, b 0 ; p, q) = α c 1+d [ d A + C ] Since, E = α b+d = 1, we see that the product is equal to =0 1 = n + 1, n =0 follows that Ψ 1 has the above value (b) Since = 0, the product is equal to =0 E = w a+b (a 0, b 0 ; p, q) w c+d (c 0, d 0 ; p, q) T [ K 1 + K + K 3 ] n(n + 1) =, and n =0 = w a+b (a 0, b 0 ; p, q) w c+d (c 0, d 0 ; p, q) T E [ K 1 + K + K 3 ] P (E 1), n 3 =0 E = it follows that Ψ 1 has the above value n(n + 1)( n + 1), it 6 N (E 1) 3, and n =0 E = M (E 1) 3, The following theorem covers for the sum Ψ 1 the cases when 0 It uses Table 1 that should be read as follows The symbols and in column E mean E 1 and E = 1 In column b they mean α b β b and α b = β b In columns F, G, H and d they have analogous meanings The third subcase should be read as follows: When ( 0), E = 1 and α b = β b, then G = 1 and H = F and for F 1 the product Ψ 1 is equal to λ n (e + g) + F n (f + h) Theorem When 0, then Table 1 gives the value of Ψ 1 In all other cases the product Ψ 1 is equal to λ n (e + f + g + h) Proof of row 1 When 0, we have w a+b (a 0, b 0 ; p, q) = 1 [ α a B 1 (α b ) + β a A 1 (β b ) ] and w c+d (c 0, d 0 ; p, q) = 1 [ α c B (α d ) + β c A (β d ) ] Hence, the product w a+b (a 0, b 0 ; p, q) w c+d (c 0, d 0 ; p, q) is equal to e E + f F + g G + h H =0 E = E n, we get Ψ 1 = e E n + f F n + g G n + h H n

486 Zvonko čerin E F G H b d Ψ 1 1 E n e + F n f + G n g + H n h λ n e + F n f + b n g + H n h 3 F λ n (e + g) + F n (f + h) 4 λ n e + d n f + G n g + H n h 5 G λ n (e + f) + G n (g + h) 6 (see 5) 7 (see 3) 8 λ n (e + g) + d n (f + h) 9 λ n (e + h) + d n f + d n g 10 E n e + λ n f + G n g + b n h 11 E E n (e + g) + λ n (f + h) 1 d n e + λ n f + G n g + H n h 13 G λ n (e + f) + G n (g + h) 14 d n e + λ n (f + g) + d n h 15 (see 11) 16 d n (e + g) + λ n (f + h) 17 b n e + F n f + λ n g + H n h 18 F λ n (e + g) + F n (f + h) 19 E n e + F n f + λ n g + d n h 0 E E n (e + f) + λ n (g + h) 1 b n (e + f) + λ n (g + h) E n e + b n f + G n g + λ n h 3 E E n (e + g) + λ n (f + h) 4 E n e + F n f + d n g + λ n h 5 E E n (e + f) + λ n (g + h) Table 1: The product Ψ 1 when 0

On Sums of Products of Horadam Numbers 487 Proof of row When 0 and E = α b+d = 1, we get w a+b (a 0, b 0 ; p, q) w c+d (c 0, d 0 ; p, q) = e + ff + g ( β b α b ) + hh =0 1 = λ n, n =0 F = F n and n =0 that Ψ 1 = e λ n + f F n + g b n + h H n Proof of row 3 When 0, E = α b+d = 1 and α b = β b, then and H = β b β d = α b β d = F Hence, ( ) β b = b n (for α b β b ), it follows α b G = β b α d = α b α d = E = 1 w a+b (a 0, b 0 ; p, q) w c+d (c 0, d 0 ; p, q) = e + g + (f + h)f =0 1 = λ n and n =0 F = F n (for F 1, of course), it follows that the product Ψ 1 is equal to (e + g) λ n + (f + h) F n The missing case in the Table 1 after the third row is clearly when E = 1, α b = β b and F = 1 The above product is w a+b (a 0, b 0 ; p, q) w c+d (c 0, d 0 ; p, q) = e + f + g + h, so that Ψ 1 = λ n (e + f + g + h) The selection p = 0, q = 1, b = and d = shows that this case can actually happen Ũ n+1 Notice that α n = V n + U n and β n = V n U n for 0 and α n = β n = n + 1 = Ṽn for = 0 Hence, it is clear that each of the above expressions for the sum Ψ 1 could be transformed into an expression in Lucas numbers U n and V n (or Ũ n and Ṽn) In most cases these formulae are more complicated then the ones given above This applies also to other sums that we consider in this paper 3 Sum with binomial coecients In this section we consider the sum ( ) n Ψ = w a+b (a 0, b 0 ; p, q) w c+d (c 0, d 0 ; p, q), =0 when a 0, b 0, c 0, d 0, p and q 0 are complex numbers and n 0, a 0, c 0, b > 0 and d > 0 are integers Let V and U be n E [(n E + 1) K 1 + (E + 1) K ] + (E + 1) K 3 and E K 4 + K 3

488 Zvonko čerin Theorem 3 (a) When = 0, then (b) When 0, then Proof (b) Since T K 3, if n = 0, Ψ = T U, if n = 1, T (E + 1) n V, if n, Ψ = (E + 1)n e + (F + 1) n f + (G + 1) n g + (H + 1) n h ( ) n w a+b (a 0, b 0 ; p, q) w c+d (c 0, d 0 ; p, q) = ( ) n e E + f F + g G + h H, from n ( n ) =0 E = (E + 1) n, it follows that Ψ indeed has the above value 4 The improved alternating sums, I In this section we consider the sums obtained from the sums Ψ 1 and Ψ by multiplication of their terms with the powers of a xed complex number k When k = 1 we obtain the familiar alternating sums More precisely, we study the sums Ψ 3 = Ψ 4 = =0 k w a+b (a 0, b 0 ; p, q) w c+d (c 0, d 0 ; p, q), =0 ( ) n k w a+b (a 0, b 0 ; p, q) w c+d (c 0, d 0 ; p, q), when a 0, b 0, c 0, d 0, p and q 0 are complex numbers and n 0, a 0, c 0, b > 0 and d > 0 are integers Let E = k α b+d, F = k α b β d, G = k α d β b and H = k β b+d When E 1, for any integer n 0, let E n = En+1 1 E 1 We similarly dene F n, G n and H n In this section we can assume that k 1 and k 0 because the case when k = 1 was treated earlier while for k = 0 all sums are equal to zero With this new meaning of the symbols E, F, G and H we have the following result Theorem 4 (a) The values given in Theorems 1 and express the sum Ψ 3 In particular, when 0, then the Table 1 gives the values of Ψ 3 In all other cases the product Ψ 3 is equal to λ n (e + f + g + h) (b) The values given in Theorem 3 for the sums Ψ express also the sum Ψ 4

On Sums of Products of Horadam Numbers 489 Proof (b) Since ( ) ( ) n n e E k + f F + g G + h H w a+b (a 0, b 0 ; p, q) w c+d (c 0, d 0 ; p, q) =, from n ( n ) =0 E = (E + 1) n, it follows that Ψ 4 indeed has the same expression as the sum Ψ 5 Terms multiplied by natural numbers In this section we study the sums Ψ 5 = ( + 1) w a+b (a 0, b 0 ; p, q) w c+d (c 0, d 0 ; p, q), Ψ 6 = =0 =0 ( ) n ( + 1) w a+b (a 0, b 0 ; p, q) w c+d (c 0, d 0 ; p, q), when a 0, b 0, c 0, d 0, p and q 0 are complex numbers and n 0, a 0, c 0, b > 0 and d > 0 are integers Let E = α b+d, F = α b β d, G = α d β b, H = β b+d Let e = α a+c B 1 B, f = α a β c A B 1, g = α c β a A 1 B, h = β a+c A 1 A When E 1, for any integer n 0, let E n = (n + 1)En+ (n + )E n+1 + 1 (E 1) We similarly dene F n, G n and H n On the other hand, when α b β b, for any integer n 0, let and b n = αb(n+) + (n + 1)β b(n+) (n + )α b β n+1 α b n (α b β b ) b n = βb(n+) + (n + 1)α b(n+) (n + )β b α n+1 β b n (α b β b ) We similarly dene d n and d (n + 1)(n + ) n For any integer n 0, let λ n = Let M and N denote n E [ n+3 n (n + 1) E ( 3 n + 6 n 1 )] + (n + ) E n+1 [ (3 n + 3 n ) E (n + 1) ] + E ( E + 1) and (E 1) [ n (n + 1) E n+3 n (n + ) E n+ +(n + ) (n + 1) E n+1 E ] Theorem 5 (a) When = 0 and E = 1, then the sum Ψ 5 is equal to λ n T [ n(3 n + 1) K 1 + 4 n K + 6 K 3 ] 6 (b) When = 0 and E 1, then the sum Ψ 5 is equal to T (E 1) 4 [ K1 M + K N + K 3 (E 1) 4 E n ]

490 Zvonko čerin Proof (b) Since = 0, we have ( + 1) w a+b (a 0, b 0 ; p, q) w c+d (c 0, d 0 ; p, q) = ( + 1) ( α a+b 1 [ b A 1 + C 1 ] ) ( α c+d 1 [ d A + C ] ) = ( + 1) T E [ K 1 + K + K 3 ] =0 ( + 1) E = E n, n =0 ( + 1) N E = (E 1), and 4 ( + 1) E M = (E 1) 4, =0 it follows that Ψ 5 has the above value Theorem 6 When 0, then the Table 1 gives the values of Ψ 5 In all other cases the product Ψ 5 is equal to λ n (e + f + g + h) Proof of row 1 in Table 1 for Ψ 5 When 0, we have ( + 1) w a+b (a 0, b 0 ; p, q) w c+d (c 0, d 0 ; p, q) = ( + 1) ( e E = ( + 1) ( 1 [ B1 α a+b + A 1 β a+b ]) ( 1 [ B α c+d c+d + A β ]) + f F + g G + h ) H =0 ( + 1)E = E n, we get Ψ 5 = e E n + ff n + g G n + hh n For any integer n 0, let En = (n + 1) E + 1, En Fn, G n, Hn, Fn, G n and Hn similarly Let = E n (E + 1) n 1 We dene M = n E(E + 1) n 3 (E n + E n E n 1), N = n E(E + 1) n (E n + 1) Theorem 7 (a) When = 0, then T K 3, if n = 0, T E K 4 + K 3 ], if n = 1, Ψ 6 = T [ ] 3 E (K 4 + K + 3 K 1 ) + 4 E K 4 + K 3, if n =, T [ M K 1 + N K + En K 3 ], if n 3 (b) When 0, then Ψ 6 = En Proof (b) Since ( + 1) ( n e + F n f + G n g + Hn h ) w a+b (a 0, b 0 ; p, q) w c+d (c 0, d 0 ; p, q) = 1 ( + 1) ( n ) ( e E + f F + g G + h H ),

On Sums of Products of Horadam Numbers 491 from n =0 ( + 1) ( ) n E = En, it follows that Ψ 6 indeed has the above value 6 The improved alternating sums, II In this section we study the following sums obtained by multiplying the terms of the sums Ψ 5 and Ψ 6 with the powers of the xed complex number k Of course, for k = 1, we get the sums Ψ 5 and Ψ 6 from the sums Ψ 7 and Ψ 8 Ψ 7 = Ψ 8 = =0 k ( + 1) w a+b (a 0, b 0 ; p, q) w c+d (c 0, d 0 ; p, q), =0 ( ) n k ( + 1) w a+b (a 0, b 0 ; p, q) w c+d (c 0, d 0 ; p, q), when a 0, b 0, c 0, d 0, p and q 0 are complex numbers and n 0, a 0, c 0, b > 0 and d > 0 are integers Let E = k α b+d, F = k α b β d, G = k α d β b and H = k β b+d When E 1, for any integer n 0, let E n = (n + 1)En+ (n + )E n+1 + 1 We similarly dene (E 1) F n, G n and H n On the other hand, when α b β b, for any integer n 0, we dene b n and b n as in the previous section We similarly dene d n and d n In this section (n + 1)(n + ) λ n is again Theorem 8 The expressions for Ψ 5 in Theorems 5 and 6 describe also the sum Ψ 7 (with the new meaning of E, F, G and H) Theorem 9 The expressions for Ψ 6 in Theorem 7 describe also the sum Ψ 8 (with the new meaning of E, F, G and H) References [1] H Belbachir and F Bencherif, Sums of products of generalized Fibonacci and Lucas numbers, Ars Combinatoria, (to appear) [] Z ƒerin, Sums of products of generalized Fibonacci and Lucas numbers, Demonstratio Mathematica, 4() (009), 47-58 [3] Z ƒerin, Properties of odd and even terms of the Fibonacci sequence, Demonstratio Mathematica, 39(1) (006), 55-60 [4] Z ƒerin, On sums of squares of odd and even terms of the Lucas sequence, Proccedings of the Eleventh International Conference on Fibonacci Numbers and their Applications, Congressus Numerantium, 194(009), 103-107 [5] Z ƒerin, Some alternating sums of Lucas numbers, Central European Journal of Mathematics 3(1) (005), 1-13

49 Zvonko čerin [6] Z ƒerin, Alternating Sums of Fibonacci Products, Atti del Seminario Matematico e Fisico dell'università di Modena e Reggio Emilia, 53(005), 331-344 [7] Z ƒerin and G M Gianella, On sums of squares of Pell-Lucas numbers, INTEGERS: Electronic Journal of Combinatorial Number Theory, 6(006), A15 [8] Z ƒerin and G M Gianella, Formulas for sums of squares and products of Pell numbers, Acc Sc Torino - Atti Sci Fis, 140(006), 113-1 [9] Z ƒerin and G M Gianella, On sums of Pell numbers, Acc Sc Torino - Atti Sci Fis, 141(007), 3-31 [10] A F Horadam, Generating Functions for Powers of a Certain Generalized Sequence of Numbers, Duke Math J, 3(1965), 437-446 [11] E Lucas, Théorie des Fonctions Numériques Simplement Périodiques, American Journal of Mathematics 1(1878), 184-40 [1] N J A Sloane, On-Line Encyclopedia of Integer Sequences, http://wwwresearchattcom/~nas/sequences/

2024 © sciencedocbox.com Privacy Policy | Terms of Service | Feedback