Sums of finite products of Bernoulli functions

In this paper, we consider three types of functions given by sums of finite products of Bernoulli functions and derive their Fourier series expansions. In addition, we express each of them in terms of Bernoulli functions.

As is well known, the Bernoulli polynomials \(B_{m}(x)\) are given by the generating function

When \(x=0\), \(B_{m}=B_{m}(0)\) are called Bernoulli numbers. For any real number x, we let

denote the fractional part of x.

Fourier series expansion of higher-order Bernoulli functions was treated in the recent paper [11]. Here we will consider the following three types of functions given by sums of finite products of Bernoulli functions and derive their Fourier series expansions. In addition, we will express each of them in terms of Bernoulli functions.

1. (1)

   \(\alpha_{m}(\langle x\rangle ) = \sum_{c_{1} + c_{2} + \cdots+ c_{r} = m, c_{1},\ldots,c_{r} \geq0} B_{c_{1}}(\langle x\rangle ) B_{c_{2}} (\langle x\rangle ) \cdots B_{c_{r}}(\langle x\rangle )\) (\(m \geq1\));

2. (2)

   \(\beta_{m}(\langle x\rangle )\) = \(\sum_{c_{1} + c_{2} + \cdots+ c_{r} = m, c_{1},\ldots,c_{r} \geq0} \frac{1}{c_{1}! c_{2}! \cdots c_{r}!} B_{c_{1}}(\langle x\rangle )B_{c_{2}}(\langle x\rangle ) \cdots B_{c_{r}} (\langle x\rangle )\) (\(m \geq1\));

3. (3)

   \(\gamma_{r,m}(\langle x\rangle )=\sum_{c_{1} + c_{2} + \cdots+ c_{r} = m, c_{1},\ldots,c_{r} \geq1} \frac{1}{c_{1} c_{2} \cdots c_{r}} B_{c_{1}} (\langle x\rangle )B_{c_{2}}(\langle x\rangle ) \cdots B_{c_{r}}(\langle x \rangle )\) (\(m \geq r \)).

For elementary facts about Fourier analysis, the reader may refer to any book (for example, see [12, 13]).

As to \(\beta_{m}(\langle x\rangle)\), we note that the next polynomial identity follows immediately from Theorems 3.1 and 3.2, which is in turn derived from the Fourier series expansion of \(\beta_{m}(\langle x\rangle)\):

where

The obvious polynomial identities can be derived also for \(\alpha _{m}(\langle x\rangle)\) and \(\gamma_{m}(\langle x\rangle)\) from Theorems 2.1 and 2.2, and Theorems 4.1 and 4.2, respectively. It is remarkable that from the Fourier series expansion of the function \(\sum_{k=1}^{m-1} \frac {1}{k(m-k)}B_{k}(\langle x\rangle)B_{m-k}(\langle x\rangle)\) we can derive the Faber-Pandharipande-Zagier identity (see [14–16]) and the Miki identity (see [15–19]).

Let \(\alpha_{m}(x) = \sum_{c_{1} + c_{2} + \cdots+ c_{r} = m} B_{c_{1}}(x) B_{c_{2}}(x) \cdots B_{c_{r}}(x)\) (\(m \geq1\)). Here the sum runs over all nonnegative integers \(c_{1} , c_{2} , \ldots, c_{r}\) with \(c_{1} + c_{2} + \cdots+ c_{r} = m\) (\(r \geq1\)). Then we will consider the function

defined on \((- \infty, \infty)\), which is periodic with period 1.

The Fourier series of \(\alpha_{m}(\langle x\rangle) \) is

where

Before proceeding further, we need to observe the following.

From this, we have

and

For \(m\geq1\), we put

where we understand that, for \(r-m\leq0\) and \(a=0\), the inner sum is \(\delta_{m,r}\).

Observe here that the sum over all \(c_{1} + c_{2} + \cdots+ c_{r} = m\) of any term with a of \(B_{c_{e}}\) and b of \(\delta_{1,c_{f}}\) (\(1 \leq e\), \(f \leq r\), \(a+b=r\)), all give the same sum

which is not an empty sum as long as \(m + a - r \geq0 \), i.e., \(a \geq r - m\).

Thus

and

Now, we are ready to determine the Fourier coefficients \(A_{n}^{(m)}\).

Case 1 : \(n \neq0\).

where \(A_{n}^{(0)}= \int_{0} ^{1} e^{-2\pi i nx} \,dx = 0\).

Case 2: \(n = 0 \).

Let us recall the following facts about Bernoulli functions \(B_{m}(\langle x\rangle)\):

1. (a)

   for \(m \geq2 \),

   $$ B_{m}\bigl(\langle x\rangle\bigr) = - m! \sum _{\substack{n= - \infty\\ n \neq0}}^{\infty} \frac{e^{2\pi i nx}}{(2\pi i n)^{m}}; $$

   (2.13)
2. (b)

   for \(m = 1 \),

   $$ - \sum_{\substack{n= - \infty\\ n \neq0}}^{\infty} \frac{e^{2\pi i nx}}{2\pi i n} = \textstyle\begin{cases} B_{1}(\langle x\rangle)& \text{for } x\notin\mathbb{Z}, \\ 0& \text{for } x\in\mathbb{Z}. \end{cases} $$

   (2.14)

\(\alpha_{m}(\langle x\rangle)\) (\(m \geq1\)) is piecewise \(C^{\infty}\). Moreover, \(\alpha_{m}(\langle x\rangle) \) is continuous for those positive integers m with \(\Delta_{m}=0\) and discontinuous with jump discontinuities at integers for those positive integers m with \(\Delta_{m} \neq0\).

Assume first that m is a positive integer with \(\Delta_{m}=0\). Then \(\alpha_{m} (1) = \alpha_{m} (0)\). Hence \(\alpha_{m} (\langle x\rangle)\) is piecewise \(C^{\infty}\) and continuous. Thus the Fourier series of \(\alpha_{m} (\langle x\rangle)\) converges uniformly to \(\alpha_{m} (\langle x\rangle)\), and

We can now state our first result.

Theorem 2.1

For each positive integer l, we let

Assume that \(\Delta_{m} = 0\) for a positive integer m. Then we have the following.

1. (a)

   \(\sum_{c_{1} + c_{2} + \cdots+ c_{r} = m} B_{c_{1}}(\langle x\rangle)B_{c_{2}}(\langle x\rangle) \cdots B_{c_{r}}(\langle x\rangle)\) has the Fourier series expansion

   $$\begin{aligned}& \sum_{c_{1} + c_{2} + \cdots+ c_{r} = m} B_{c_{1}}\bigl(\langle x\rangle \bigr)B_{c_{2}}\bigl(\langle x\rangle\bigr) \cdots B_{c_{r}}\bigl( \langle x\rangle\bigr) \\& \quad = \frac{1}{m+r} \Delta_{m+1} - \sum _{\substack{n= - \infty\\ n \neq0}}^{\infty} \Biggl( \frac {1}{m+r} \sum _{j=1}^{m} \frac{(m+r)_{j}}{(2\pi i n)^{j}} \Delta _{m-j+1} \Biggr)e^{2\pi i nx}, \end{aligned}$$

   for all \(x \in\mathbb{R}\), where the convergence is uniform.

2. (b)
   $$\begin{aligned}& \sum_{c_{1} + c_{2} + \cdots+ c_{r} = m} B_{c_{1}}\bigl(\langle x\rangle \bigr)B_{c_{2}}\bigl(\langle x\rangle\bigr) \cdots B_{c_{r}}\bigl( \langle x\rangle\bigr) \\& \quad = \frac{1}{m+r} \Delta_{m+1}+ \frac{1}{m+r} \sum _{j=2}^{m} \binom {m+r}{j} \Delta_{m-j+1} B_{j}\bigl(\langle x\rangle\bigr) , \end{aligned}$$

   for all \(x \in\mathbb{R}\), where \(B_{j}(\langle x\rangle)\) is the Bernoulli function.

Assume next that \(\Delta_{m} \neq0\) for a positive integer m. Then \(\alpha_{m} (1) \neq\alpha_{m} (0)\). Hence \(\alpha_{m} (\langle x\rangle)\) is piecewise \(C^{\infty}\) and discontinuous with jump discontinuities at integers. The Fourier series of \(\alpha_{m} (\langle x\rangle)\) converges pointwise to \(\alpha _{m} (\langle x\rangle)\) for \(x \notin\mathbb{Z}\) and converges to

for \(x \in\mathbb{Z}\).

Now, we can state our second result.

Theorem 2.2

For each positive integer l, we let

Assume that \(\Delta_{m} \neq0\) for a positive integer m. Then we have the following.

Let \(\beta_{m}(x) = \sum_{c_{1} + c_{2} + \cdots+ c_{r} = m} \frac {1}{c_{1}! c_{2}! \cdots c_{r}!} B_{c_{1}}(x)B_{c_{2}}(x) \cdots B_{c_{r}}(x)\) (\(m \geq1\)). Here the sum runs over all nonnegative integers \(c_{1} , c_{2} , \ldots, c_{r}\) with \(c_{1} + c_{2} + \cdots+ c_{r} = m\) (\(r \geq1\)). Then we will consider the function

defined on \((- \infty, \infty)\), which is periodic with period 1. The Fourier series of \(\beta_{m}(\langle x\rangle)\) is

where

Before proceeding further, we need to observe the following.

From this, we have

and

Let

where we understand that, for \(r-m\leq0\) and \(a=0\), the inner sum is \(\delta_{m,r}\).

Observe here that the sum over all \(c_{1} + c_{2} + \cdots+ c_{r} = m\) of any term with a of \(B_{c_{e}}\) and b of \(\delta_{1,c_{f}}\) (\(1 \leq e\), \(f \leq r\), \(a+b=r\)), all give the same sum

which is not an empty sum as long as \(m+a -r \geq0\), i.e., \(a \geq r-m\).

Also, we have

and

Now, we would like to determine the Fourier coefficients \(B_{n}^{(m)}\).

Case 1: \(n\neq0\).

where \(B_{n}^{(0)}=\int_{0}^{1}e^{-2\pi i n x}\,dx = 0\).

Case 2: \(n=0\).

\(\beta_{m}(\langle x\rangle)\) (\(m\geq1\)) is piecewise \(C^{\infty}\). Moreover, \(\beta_{m}(\langle x\rangle)\) is continuous for those positive integers m with \(\Omega_{m} =0\) and discontinuous with jump discontinuities at integers for those positive integers m with \(\Omega_{m} \neq0\).

Assume first that \(\Omega_{m} =0\) for a positive integer m. Then \(\beta_{m}(1)=\beta_{m}(0)\). Hence \(\beta_{m}(\langle x\rangle)\) is piecewise \(C^{\infty}\) and continuous. Thus the Fourier series of \(\beta _{m}(\langle x\rangle)\) converges uniformly to \(\beta_{m}(\langle x\rangle)\), and

Now, we can state our first result.

Theorem 3.1

For each positive integer l, we let

Assume that \(\Omega_{m} = 0\) for a positive integer m. Then we have the following.

1. (a)

   \(\sum_{c_{1} + c_{2} + \cdots+ c_{r} = m} \frac{1}{c_{1}! c_{2}! \cdots c_{r}!} B_{c_{1}}(\langle x\rangle) B_{c_{2}}(\langle x\rangle) \cdots B_{c_{r}}(\langle x\rangle)\) has the Fourier series expansion

   $$ \begin{aligned}[b] &\sum_{c_{1} + c_{2} + \cdots+ c_{r} = m} \frac{1}{c_{1}! c_{2}! \cdots c_{r}!} B_{c_{1}}\bigl(\langle x\rangle\bigr) B_{c_{2}} \bigl(\langle x\rangle\bigr) \cdots B_{c_{r}}\bigl(\langle x\rangle\bigr) \\ &\quad = \frac{1}{r} \Omega_{m+1} - \sum _{\substack{n=-\infty\\ n\neq0}}^{\infty} \Biggl(\sum_{j=1}^{m} \frac{r^{j-1}}{(2\pi i n)^{j}}\Omega_{m-j+1} \Biggr)e^{2\pi i n x}, \end{aligned} $$

   (3.15)

   for all \(x\in(-\infty,\infty)\), where the convergence is uniform.

2. (b)
   $$ \begin{aligned}[b] &\sum_{c_{1} + c_{2} + \cdots+ c_{r} = m} \frac{1}{c_{1}! c_{2}! \cdots c_{r}!} B_{c_{1}}\bigl(\langle x\rangle\bigr) B_{c_{2}} \bigl(\langle x\rangle\bigr) \cdots B_{c_{r}}\bigl(\langle x\rangle\bigr) \\ & \quad = \frac{1}{r} \Omega_{m+1} + \sum _{j=2}^{m} \frac {r^{j-1}}{j!}\Omega_{m-j+1} B_{j}\bigl(\langle x\rangle\bigr), \end{aligned} $$

   (3.16)

   for all \(x\in(-\infty,\infty)\), where \(B_{j}(\langle x\rangle)\) is the Bernoulli function.

Assume next that m is a positive integer with \(\Omega_{m} \neq0\). Then \(\beta_{m}(1)\neq\beta_{m}(0)\). Hence \(\beta_{m}(\langle x\rangle)\) is piecewise \(C^{\infty}\) and discontinuous with jump discontinuities at integers. Thus the Fourier series of \(\beta_{m}(\langle x\rangle)\) converges pointwise to \(\beta_{m}(\langle x\rangle)\) for \(x\notin\mathbb{Z}\) and converges to

for \(x\in\mathbb{Z}\).

Now, we can state our second result.

Theorem 3.2

For each positive integer l, let

Assume that \(\Omega_{m}\neq0\) for a positive integer m. Then we have the following.

Here the convergence is pointwise.

Here \(B_{j}(\langle x\rangle)\) is the Bernoulli function.

Let \(\gamma_{r,m}(x)=\sum_{c_{1} + c_{2} + \cdots+ c_{r} = m, c_{1},\ldots ,c_{r} \geq1} \frac{1}{c_{1} c_{2} \cdots c_{r}} B_{c_{1}}(x)B_{c_{2}}(x) \cdots B_{c_{r}}(x)\) (\(m \geq r \geq1\)). Here the sum is over all positive integers \(c_{1} , c_{2} , \ldots, c_{r}\) with \(c_{1} + c_{2} + \cdots+ c_{r} = m\).

Thus,

with \(\gamma_{r,r-1}(x) =0\).

Replacing m by \(m+1\), we get

Denoting \(\int_{0}^{1}\gamma_{r,m}(x)\,dx \) by \(a_{r,m}\), we have

where \(\Lambda_{r,m} = \gamma_{r,m}(1) - \gamma_{r,m}(0)\). From the recurrence relation (4.4), we can easily show that

Observe here that the sum over all positive integers \(c_{1},\ldots,c_{r}\) satisfying \(c_{1} + c_{2} + \cdots+ c_{r} = m\) of any term with a of \(B_{c_{e}}\) and b of \(\delta_{1,c_{f}}\) (\(1 \leq e\), \(f \leq r\), \(a+b=r\)), all give the same sum

and that, as \(m+a -r \geq a\), there are no empty sums.

Here we note that, for \(a=0\), the inner sum is \(\delta_{m,r}\) since it corresponds to the sums

Also, \(\gamma_{r,m}(1) = \gamma_{r,m}(0) \Leftrightarrow\Lambda _{r,m} =0\).

Now, we would like to consider the function

defined on \((-\infty,\infty)\), which is periodic with period 1.

The Fourier series of \(\gamma_{r,m}(\langle x\rangle)\) is

where

Now, we are going to determine the Fourier coefficients \(C_{n}^{(r,m)}\).

Case 1: \(n\neq0\).

From this, we obtain

Here,

and

Thus

Finally, we obtain, for \(n \neq0\),

Also, we note that, for \(n \neq0\),

Thus, for \(n \neq0\), (4.17) together with (4.18) determine all \(C_{n}^{(r,m)}\) recursively.

Case 2: \(n = 0 \).

\(\gamma_{r,m}(\langle x\rangle)\) (\(m\geq r \geq1\)) is piecewise \(C^{\infty}\). In addition, \(\gamma_{r,m}(\langle x\rangle)\) is continuous for those positive integers r, m with \(\Lambda_{r,m} = 0\) and discontinuous with jump discontinuities at integers for those positive integers \(r,m\) with \(\Lambda_{r,m} \neq0\).

Assume first that \(\Lambda_{r,m} = 0 \) for some integers r, m with \(m \geq r \geq1\). Then \(\gamma_{r,m}(1)=\gamma_{r,m}(0)\). Hence \(\gamma _{r,m}(\langle x\rangle)\) is piecewise \(C^{\infty}\) and continuous. Thus the Fourier series of \(\gamma_{m}(\langle x\rangle)\) converges uniformly to \(\gamma_{m}(\langle x\rangle)\), and

where \(C_{0}^{(r,m)}\) is given by (4.19), and \(C_{n}^{(r,m)}\), for each \(n \neq0\), are determined by relations (4.17) and (4.18).

Now, we are ready to state our first theorem.

Theorem 4.1

For all integers s, l, with \(l \geq s \geq1 \), we let

Assume that \(\Lambda_{r,m} = 0 \) for some integers \(r,m\) with \(m \geq r \geq1\). Then we have the following.

\(\sum_{c_{1} + c_{2} + \cdots+ c_{r} = m, c_{1},\ldots,c_{r} \geq1} \frac {1}{c_{1} \cdots c_{r}} B_{c_{1}}(\langle x\rangle) \cdots B_{c_{r}}(\langle x\rangle)\) has the Fourier series expansion

where \(C_{0}^{(r,m)}= \sum_{j=1}^{r-1} (-1)^{j-1}\frac{ (r)_{j-1}}{ m^{j}} \Lambda_{r-j+1,m+1}\), with \(C_{0}^{(1,m)}= 0\), and \(C_{n}^{(r,m)}\), for each \(n \neq0\), are determined recursively from

and

Here the convergence is uniform.

Next, assume that \(\Lambda_{r,m} \neq0 \) for some integers \(r,m\) with \(m \geq r \geq1\). Then \(\gamma_{r,m}(1) \neq\gamma_{r,m}(0)\). Hence \(\gamma_{r,m}(\langle x\rangle)\) is piecewise \(C^{\infty}\) and discontinuous with jump discontinuities at integers. Then the Fourier series of \(\gamma_{r,m}(\langle x\rangle)\) converges pointwise to \(\gamma_{r,m}(\langle x\rangle)\) for \(x\notin\mathbb{Z}\) and converges to

for \(x\in\mathbb{Z}\).

Now, we can state our second result.

Theorem 4.2

For all integers s, l with \(l \geq s \geq1 \), we let

Assume that \(\Lambda_{r,m} \neq0 \) for some integers r, m with \(m \geq r \geq1\). Let \(C_{0}^{(r,m)}\), \(C_{n}^{(r,m)}\) (\(n \neq0\)) be as in Theorem  4.1. Then we have the following.

The third author is appointed as a chair professor at Tianjin Polytechnic University by Tianjin City in China from August 2015 to August 2019.

Authors and Affiliations

1. Department of Mathematics, Texas A&M University - Kingsville, Kingsville, TX, 78363, USA

   Ravi P Agarwal

2. Department of Mathematics, Sogang University, Seoul, 121-742, Republic of Korea

   Dae San Kim

3. Department of Mathematics, Kwangwoon University, Seoul, 139-701, Republic of Korea

   Taekyun Kim

4. Department of Mathematics, College of Science, Tianjin Polytechnic University, Tianjin, 300160, China

   Taekyun Kim

5. Department of Mathematics Education and RINS, Gyeongsang National University, Jinju, Gyeongsangnamdo, 52828, Republic of Korea

   Jongkyum Kwon

Corresponding author

Correspondence to Taekyun Kim.

Competing interests

The authors declare that they have no competing interests.

Authors’ contributions

All authors contributed equally to the manuscript and typed, read, and approved the final manuscript.

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