EUDML

We prove: (I) For all integers n ≥ 2 and real numbers x ∈ (0,π) we have $α \leq \sum_{j = 1}^{n - 1} 1 / (n ² - j ²) s i n (j x) \leq β$ , with the best possible constant bounds α = (15-√2073)/10240 √(1998-10√2073) = -0.1171..., β = 1/3. (II) The inequality $0 < \sum_{j = 1}^{n - 1} (n ² - j ²) s i n (j x)$ holds for all even integers n ≥ 2 and x ∈ (0,π), and also for all odd integers n ≥ 3 and x ∈ (0,π - π/n].

A sharp bound for a sine polynomial

Horst Alzer; Stamatis Koumandos — 2003

Colloquium Mathematicae

We prove that $| \sum_{k = 1}^{n} s i n ((2 k - 1) x) / k | < S i (π) = 1.8519 . . .$ for all integers n ≥ 1 and real numbers x. The upper bound Si(π) is best possible. This result refines inequalities due to Fejér (1910) and Lenz (1951).

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A note on a monotonicity property of Bessel functions.

Positive trigonometric sums and applications.

On a class of integrals involving a Bessel function times Gegenbauer polynomials.

Some inequalities for the sine integral.

On a positive sine sum

Inequalities for two sine polynomials

A sharp bound for a sine polynomial