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Fedor Petrov
Fedor Petrov
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I am looking for an asymptotic expansion of J(n)

$J(n)=\frac {2} {\pi} \int_{0}^{\pi/n} \prod_{k=1}^n \frac {sinkx} {sinx} dx$, n=2,3,4$J(n)=\frac {2} {\pi} \int_{0}^{\pi/n} \prod_{k=1}^n \frac {\sin kx} {\sin x} dx$,... $n=2,3,4,\dots$ The first approximation is managed to get $F_1(n)=\frac {n!} {\sqrt{\pi A}}$[/math], [math]$A=n(n-1)(2n+5)/36$

Is a general expansion known for this?

I am looking for an asymptotic expansion of J(n)

$J(n)=\frac {2} {\pi} \int_{0}^{\pi/n} \prod_{k=1}^n \frac {sinkx} {sinx} dx$, n=2,3,4,... The first approximation is managed to get $F_1(n)=\frac {n!} {\sqrt{\pi A}}$[/math], [math]$A=n(n-1)(2n+5)/36$

Is a general expansion known for this?

I am looking for an asymptotic expansion of J(n)

$J(n)=\frac {2} {\pi} \int_{0}^{\pi/n} \prod_{k=1}^n \frac {\sin kx} {\sin x} dx$, $n=2,3,4,\dots$ The first approximation is managed to get $F_1(n)=\frac {n!} {\sqrt{\pi A}}$, $A=n(n-1)(2n+5)/36$

Is a general expansion known for this?

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Mikhail Gaichenkov
Mikhail Gaichenkov
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Asymptotic expansion of an integral

I am looking for an asymptotic expansion of J(n)

$J(n)=\frac {2} {\pi} \int_{0}^{\pi/n} \prod_{k=1}^n \frac {sinkx} {sinx} dx$, n=2,3,4,... The first approximation is managed to get $F_1(n)=\frac {n!} {\sqrt{\pi A}}$[/math], [math]$A=n(n-1)(2n+5)/36$

Is a general expansion known for this?