Excellent. Let me follow you.
T(x):=\sum_{n=1}^{\infty}\frac{\sin(n(\pi-x))}{n^3} for ##-\pi < x < \pi##
Regarding this as Fourier series, ##n^{3}## in denominator shows that T(x) is tertial function of x from integration by parts in the calculation of components. We can write T(x) with...
I would try another transformation
S=Re(-i\sum_{n=1}^\infty \frac{e^{\frac{\pi n i}{2}}}{n^3})
=\lim_{x\rightarrow 1} Re(-i (\frac{\pi i}{2})^3 \int dx \int dx \int dx \sum_{n=1}^\infty e^{\frac{\pi nx i}{2}})
with convention that all the integral constants are zero.
S=\frac{\pi^3}{8}Re( -...
Though I am not good at chemistry, I think hydrogen ion, i.e. proton and proton-neutron core, pass the semipermeable membrane including ones in living organism. Why not ?
In a narrow sense of mathematics, you are right. But in physics almost all the numbers in calculation is approximate. I am afraid that thinking of integer 583 just is not practical.
I asked Wolfram as shown
There seems no integers to satisfy the relation. In neighbor, (2,3,27) satisfies
a^2+b^2+c^2=582 and (2,2,24),(6,8,22) satisfies
a^2+b^2+c^2=584 where I excluded (0,10,22) which includes physically prohibited 0.
Thanks for pointing out the difficulty. From my last line
\frac{8}{\pi^3}S=\frac{1}{2}\int_{0}^{\infty} p^2 dp \ (\sum_{n=1}^\infty \sin \frac{n\pi} {2}\sin \frac{pn\pi} {2} )
In here
\sum_{n=1}^\infty \sin \frac{n\pi} {2}\sin \frac{pn\pi} {2}=\frac{1}{2}\sum_{n=1}^\infty [\cos...
The result of attempt 2 would be written as
\frac{A}{s}+\frac{B}{s+c}
where
c=R_\rho^{-1}(C_\rho^{-1}+C_2^{-1})
You can get constants A and B by calculation. You find it sum of simple pole functions. You do not have to do this reduction in applying residue theorem. The result of attempt 2...
Axes are x and y as I wrote x- y- directions of velocity in my post #2.
In xy coordinate, ##P(x_p,0)##. The contact point on the slope ##C(x_C,y_C)## in xy axes coordinate is
x_C=x_P+R\phi \cos \beta+x_{C0}
y_C=-R\phi \sin \beta+y_{C0}
where ##(x_{C0}, y_{C0})## is initial position of C when...