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24 Bernoulli and Euler PolynomialsProperties

§24.13 Integrals

Contents
  1. §24.13(i) Bernoulli Polynomials
  2. §24.13(ii) Euler Polynomials
  3. §24.13(iii) Compendia

§24.13(i) Bernoulli Polynomials

24.13.1 \int B_{n}\left(t\right)\,\mathrm{d}t=\frac{B_{n+1}\left(t\right)}{n+1}+\text{%
const.},
24.13.2 \int_{x}^{x+1}B_{n}\left(t\right)\,\mathrm{d}t=x^{n},n=1,2,\dots,
24.13.5 \int_{1/4}^{3/4}B_{n}\left(t\right)\,\mathrm{d}t=\frac{E_{n}}{2^{2n+1}}.

For m,n=1,2,\dotsc,

24.13.6 \int_{0}^{1}B_{n}\left(t\right)B_{m}\left(t\right)\,\mathrm{d}t=\frac{(-1)^{n-%
1}m!n!}{(m+n)!}B_{m+n}.

For integrals of the form \int_{0}^{x}B_{n}\left(t\right)B_{m}\left(t\right)\,\mathrm{d}t and \int_{0}^{x}B_{n}\left(t\right)B_{m}\left(t\right)B_{k}\left(t\right)\,\mathrm%
{d}t see Agoh and Dilcher (2011).

§24.13(ii) Euler Polynomials

24.13.7 \int E_{n}\left(t\right)\,\mathrm{d}t=\frac{E_{n+1}\left(t\right)}{n+1}+\text{%
const.},
24.13.10 \int_{0}^{1/2}E_{2n-1}\left(t\right)\,\mathrm{d}t=\frac{E_{2n}}{n2^{2n+1}},n=1,2,\dots.

For m,n=1,2,\dotsc,

24.13.11 \int_{0}^{1}E_{n}\left(t\right)E_{m}\left(t\right)\,\mathrm{d}t=(-1)^{n}4\frac%
{(2^{m+n+2}-1)m!n!}{(m+n+2)!}B_{m+n+2}.

§24.13(iii) Compendia

For Laplace and inverse Laplace transforms see Prudnikov et al. (1992a, §§3.28.1–3.28.2) and Prudnikov et al. (1992b, §§3.26.1–3.26.2). For other integrals see Prudnikov et al. (1990, pp. 55–57).