Prove that $|Si(1/x) - \frac \pi 2| \leq 2x$ for $x>0$, where $Si(x)=\int_0^x \frac{\sin t}t \, dt$.
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i proved a stronger statement $|Si(1/x) - \frac \pi 2| \leq x/2$ – Mohammed M. Zerrak Mar 02 '20 at 13:07
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1For $x > 0$, we have $$\frac \pi 2 - \operatorname {Si} x = \int_x^\infty \frac {\sin t} t dt = \frac {\cos x} x - \int_x^\infty \frac {\cos t} {t^2} dt, \ \left| \frac \pi 2 - \operatorname {Si} x \right| \leq \left| \frac {\cos x} x \right| + \int_x^\infty \left| \frac {\cos t} {t^2} \right| dt \leq \frac 2 x.$$ It can be proved that $|\pi/2 - \operatorname {Si} x| \leq 1/x$. – Maxim Mar 05 '20 at 18:03
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@Maxim Thanks. That makes sense – wlad Mar 05 '20 at 21:35
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$|Si(x)- \pi /2|=|\int_{x}^{\infty} \frac {sin(t)}{t} dt |\leq| \int_{x}^{\infty} \frac {e^{it}}{t} dt|$
$=|[\frac {e^{it}}{it}]_{x}^{\infty}-\bigg (\int_{x}^{\infty} \frac {e^{it}}{-it^2} dt\bigg ) | $
$=|-[\frac {e^{it}}{ix}]+\bigg (\int_{x}^{\infty} \frac {e^{it}}{it^2} dt\bigg ) | $
$=|\frac 1{x}\bigg (\int_{1}^{\infty} \frac {e^{itx}-e^{ix}}{t^2} dt\bigg ) | $
$=|\frac 1{x}\bigg (\int_{1}^{\infty} \frac {e^{ix(t-1)}-1}{t^2} dt\bigg ) | $
so what it's all comes to; is proving :
$=|\bigg (\int_{1}^{\infty} \frac {e^{ix(t-1)}-1}{t^2} dt\bigg ) | \leq 1$
let $v=x(t-1)$ :
$=|\bigg (\int_{1}^{\infty} \frac {e^{ix(t-1)}-1}{t^2} dt\bigg ) | \leq 1$
is equivalent to :
$=|\bigg (\int_{0}^{\infty} \frac {e^{iv}-1}{(v+x)^2}\times x dv\bigg ) | \leq 1$
$|\bigg (\int_{0}^{\infty} \frac {e^{iv}-1}{(v+x)^2}\times x dv\bigg ) | = |[\frac {i(1-e^{iv})-v}{(v+x)^2}]+\bigg (\int_{0}^{\infty} \frac {i(1-e^{iv})-v}{2(v+x)^3}\times x dv\bigg ) |=|\bigg (\int_{0}^{\infty} \frac {i(1-e^{iv})-v}{2(v+x)^3}\times x dv\bigg ) |$
we use $ |(1-e^{iv})|\leq |v|$
$\leq |\bigg (\int_{0}^{\infty} \frac {2v}{2(v+x)^3}\times x dv\bigg ) |=|\bigg (\int_{0}^{\infty} \frac {vx}{(v+x)^3} dv\bigg ) | = |\bigg (\int_{0}^{\infty} \frac {x}{2(v+x)^2} dv\bigg ) |$
last equality is obtained by integration by parts
therefore
$|\bigg (\int_{0}^{\infty} \frac {x}{2(v+x)^2} dv\bigg ) |\leq \frac 1{2}$
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i kind of got stuck right there ; but i hope this might add some insight , or guide someone else – Mohammed M. Zerrak Feb 29 '20 at 16:30
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Did you notice that the problem is for $\text{Si}\left(\frac{1}{x}\right)$ and not $\text{Si}\left({x}\right)$ – Claude Leibovici Feb 29 '20 at 17:14
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i fixed it ; for my calculations i tried to prove $Si(x)-\pi /2 \leq 1/x$ – Mohammed M. Zerrak Feb 29 '20 at 18:31
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I will prove it for $x = 2n\pi$ where $n \in \mathbb Z$:
First, restate the inequality to be proved as $$|\operatorname{Si}(x) - \frac{\pi}2| < \frac1x$$
Then
$$\int_0^{2n\pi} \frac{\sin t}{t}\,dt = \frac\pi2 - \int_{2n\pi}^\infty \frac{\sin t}{t}\,dt = \sum_{k=n}^\infty \left(\int_{2n\pi}^{(2n+1)\pi}\frac{\sin t}t\,dt + \int_{(2n+1)\pi}^{2(n+1)\pi}\frac{\sin t}t\,dt\right).$$
Now notice that $$\frac{1}{(2n+1)\pi}<\int_{2n\pi}^{(2n+1)\pi}\frac{\sin t}t\,dt < \frac{1}{2n\pi}$$ and $$-\frac{1}{(2n+1)\pi}<\int_{(2n+1)\pi}^{2(n+1)\pi}\frac{\sin t}t\,dt < -\frac{1}{2(n+1)\pi},$$ so $$\sum_{k=n}^\infty \left(\frac{1}{(2n+1)\pi} - \frac{1}{(2n+1)\pi} \right)< \sum_{k=n}^\infty \left(\int_{2n\pi}^{(2n+1)\pi}\frac{\sin t}t\,dt + \int_{(2n+1)\pi}^{2(n+1)\pi}\frac{\sin t}t\,dt\right) < \sum_{k=n}^\infty \left(\frac{1}{2n\pi} - \frac{1}{2(n+1)\pi} \right)$$
The LHS series equals $0$ and the RHS series telescopes to $\frac{1}{2n\pi}$, so $$0 < \int_0^{2n\pi} \frac{\sin t}{t}\,dt < \frac{1}{2n\pi}.$$
A similar argument can be made for odd multiples of $\pi$.
The argument can be made in general by noticing that $[x\pi,(x+2)\pi]$ can be broken up into the two sets $[x\pi, \lceil x \rceil \pi] \cup [(1 + \lceil x \rceil) \pi, (x+2)\pi]$ and $[\lceil x \rceil \pi, (1 + \lceil x \rceil) \pi]$.
wlad
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