Alternating sums of reciprocal generalized Fibonacci numbers

Recently Holliday and Komatsu extended the results of Ohtsuka and Nakamura on reciprocal sums of Fibonacci numbers to reciprocal sums of generalized Fibonacci numbers. The aim of this work is to give similar results for the alternating sums of reciprocals of the generalized Fibonacci numbers with indices in arithmetic progression. Finally we note our generalizations of some results of Holliday and Komatsu.

AMS Subject Classification

Primary 11B37; secondary 11B39

For a positive integer p, the generalized Fibonacci numbers U _n are defined for n≥0 by

If p = 1,2, then U _n are called the Fibonacci numbers F _n and Pell numbers P _n , respectively. Also, if p is any variable x, then U _n are called Fibonacci polynomials F _n (x).

(Ohtsuka and Nakamura 2008/2009) have found the formulas for the integer part of ${\left({\sum }_{k=n}^{\infty }\frac{1}{F_k}\right)}^{-1}$ and ${\left({\sum }_{k=n}^{\infty }\frac{1}{F_k^2}\right)}^{-1}$. (Holliday and Komatsu 2011) generalized these identities to the generalized Fibonacci numbers as follows

where ⌊·⌋ is the floor function.

Similar properties were investigated in several different ways; see (Wu and Zhang 2012; Wu and Zhang 2013; Zhang 2011). Recently, (Kuhapatanakul 2013) gave a similar formula (1) for alternating sums of reciprocal generalized Fibonacci numbers.

In this paper we consider the alternating sums of reciprocals of the generalized Fibonacci numbers with indices in arithmetic progression and evaluate the integer part to the reciprocals of these sums. That is, we derive and prove the formulas of the following forms

where a,b are non-negative integers with b < a. We also extend two identities (1) and (2) by replacing U _k with U_{a k−b}.

We begin with some identities of the generalized Fibonacci numbers whose will be used in the proofs of main theorem.

Lemma 1.

Let n,r be two integers with n > r > 0. Then

1. (i)

   U _r U _n+1 + U _r−1 U _n = U _n+r.

2. (ii)

   U _r U _n−1 − U _r−1 U _n = (−1)^r−1 U _n−r.

3. (iii)

   $U_n^2-U_{n-r}{U}_{n+r}={(-1)}^{n-r}{U}_r^2$

Proof.

Every proof is done by induction and omitted.

Lemma 2.

Let n,r be two integers with n > r > 0. Then

1. (i)

   $U_{n+r}-U_{n-r}>U_r^2$

2. (ii)

   $U_{n+r}^2-U_{n-r}^2>\left|U_n^4-U_{n+r}^2{U}_{n-r}^2+U_r^4\right|$

Proof.

By using three identities of Lemma 1, we have

and

as desired.

We are now ready to verify our results.

Theorem 1.

Let a,b be two integers with 0 ≤ b < a and f(n) = a n−b. Suppose f(n−1)>0 for all positive integer n. Then for t = 1,2 we have

Proof.

Since the proofs of both cases t = 1 and t = 2 are quite similar, we only give a proof for t = 2. We see that f(n) > a for all n. By Lemma 2 (i i),

we get

Thus,

By applying the above inequality repeatedly, we obtain

In a similar way, we have

so

Repeating the above inequality, we obtain

Using Lemma 1(iii), we have

The numerator of the right hand side of above equation is positive if f(n−1) + n is even. Also, the numerator is negative if f(n−1) + n is odd.

Case I: If f(n−1) + n is even, then

so we obtain

Combining the (4) and (5), we get

it is equivalent to

where f(n−1) + n is even.

Case II: If f(n−1) + n is odd, then

We obtain

Combining the (3) and (6), we get

it is equivalent to

where f(n−1)+n is odd.

This completes the proof.

Remark 1.

• If f(n−1) + n = a(n−1) + n − b is even, then we have “both a and b are odd” or “ a,b,n are even” or “a is even and b,n are odd”.

• If f(n−1) + n = a(n−1) + n − b is odd, then we have “a is odd and b is even” or “ a,b are even and n is odd” or “ a,n are even and b is odd”.

Now we present some examples of Theorem 1 in the following corollary

Corollary 1

For a positive integer n > 1, we have

1. (i)

   $⌊{\left(\sum _{k=n}^{\infty }\frac{{(-1)}^k}{U_k}\right)}^{-1}⌋={(-1)}^n\left(U_n+U_{n-1}\right)-1.$

2. (ii)

   $⌊{\left(\sum _{k=n}^{\infty }\frac{{(-1)}^k}{U_k^2}\right)}^{-1}⌋={(-1)}^n\left(U_n^2+U_{n-1}^2\right)-1.$

3. (iii)

   $⌊{\left(\sum _{\begin{array}{c}k=n\\ n\mathit{\text{even}}\end{array}}^{\infty }\frac{{(-1)}^k}{U_{2k}}\right)}^{-1}⌋=U_{2n}+U_{2n-2}$

4. (iv)

   $⌊{\left(\sum _{\begin{array}{c}k=n\\ n\mathit{\text{even}}\end{array}}^{\infty }\frac{{(-1)}^k}{U_{2k-1}}\right)}^{-1}⌋=U_{2n-1}+U_{2n-3}-1$

Some examples for the Fibonacci numbers.

Example 1

For a positive integer n > 1, we have

1. (i)

   $⌊{\left(\sum _{k=n}^{\infty }\frac{{(-1)}^k}{F_k}\right)}^{-1}⌋={(-1)}^n{F}_{n+1}-1.$

2. (ii)

   $⌊{\left(\sum _{k=n}^{\infty }\frac{{(-1)}^k}{F_k^2}\right)}^{-1}⌋={(-1)}^n{F}_{2n-1}-1.$

We will obtain generalizations of the result of (Holliday and Komatsu 2011) on the reciprocal sums of U _k to the reciprocal sums of U_{a k−b}.

Theorem 2.

Let a,b be two integers with 0 ≤ b < a and f(n) = a n − b. Suppose f(n−1) ≥ 0 for all positive integer n. Then for t = 1,2 we have

Proof.

We only give a proof for t=1 as that of t=2 is similar. Since f(n)≥a for all n, we get

Using Lemma 1 (i) and above inequality, we have

Thus, we obtain

Similarly, we can show that

On the other hand, we have

The numerator of the right hand side of above equation is positive if f(n−1) is odd. Also, the numerator is negative if f(n−1) is even.

If f(n−1) is odd, then we can verify that

and if f(n−1) is even, then we get

Combining the (7) and (9), we obtain

it is equivalent to

where a(n−1)−b is odd.

Combining the (8) and (10), we obtain

it is equivalent to

where a(n−1)−b is even.

Remark 2.

• If f(n−1) = a(n−1)−b is odd, then we have “a is even and b is odd” or “ a,b,n are odd” or “a is odd and b,n are even”.

• If f(n−1) = a(n−1)−b is even, then we have “both a and b are even” or “ a,b are odd and n is even” or “ a,n are odd and b is even”.

Since $U_n^2-U_{n-1}^2={\mathit{\text{pU}}}_n{U}_{n-1}-{(-1)}^n$, if we take a = 1 in Theorem 2, we obtain the identities (1) and (2). Also, if we take b = 0, then we get the same results given in (Wu and Zhang 2013). In addition we have more results for t = 1,2 such as

1. (i)

   $⌊{\left(\sum _{k=n}^{\infty }\frac{1}{U_{2k}^t}\right)}^{-1}⌋=U_{2n}^t-U_{2n-2}^t-1.$

2. (ii)

   $⌊{\left(\sum _{k=n}^{\infty }\frac{1}{U_{2k-1}^t}\right)}^{-1}⌋=U_{2n}^t-U_{2n-2}^t.$

3. (iii)

   $⌊{\left(\sum _{k=n}^{\infty }\frac{1}{U_{3k-1}^t}\right)}^{-1}⌋=\left\{\begin{array}{c}{U}_{3n-1}^t-U_{3n-4}^t,\\ \text{if}n\text{is odd};\\ U_{3n-1}^t-U_{3n-4}^t-1,\\ \text{if}n\text{is even}.\end{array}\right.$

4. (iv)

   $⌊{\left(\sum _{k=n}^{\infty }\frac{1}{U_{3k-2}^t}\right)}^{-1}⌋=\left\{\begin{array}{c}{U}_{3n-2}^t-U_{3n-5}^t,\\ \text{if}n\text{is even};\\ U_{3n-2}^t-U_{3n-5}^t-1,\\ \text{if}n\text{is odd}.\end{array}\right.$

This research is supported by a research grant for new scholars from the Thailand Research Fund (TRF), Grant No. MRG5680127, and the Kasetsart University Research and Development Institute (KURDI), Thailand.

Authors and Affiliations

1. Department of Mathematics, Faculty of Science, Kasetsart University, Bangkok, Thailand

   Kantaphon Kuhapatanakul

Corresponding author

Correspondence to Kantaphon Kuhapatanakul.

Competing interests

The author declares that he has no competing interests.

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